Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
NAND Flash and Mobile LPDDR
168-Ball Package-on-Package (PoP) MCP
Combination Memory (TI OMAP)
MT29C4G48MAYBAAKQ-5 WT, MT29C4G48MAZBAAKQ-5 WT,
MT29C4G96MAYBACJG-5 WT, MT29C4G96MAZBACJG-5 WT,
MT29C8G96MAYBADJV-5 WT, MT29C8G96MAZBADJV-5 WT
MT29C4G48MAZBAAKQ-5 IT, MT29C4G96MAZBACJG-5 IT
MT29C8G96MAZBADJV-5 IT
Features
Figure 1: PoP Block Diagram
Micron NAND Flash and LPDDR components
RoHS-compliant, “green” package
Separate NAND Flash and LPDDR interfaces
Space-saving multichip package/package-on-package
combination
• Low-voltage operation (1.70–1.95V)
• Wireless temperature range: –25°C to +85°C
• Industrial temperature range: –40°C to +85°C
NAND Flash
Power
•
•
•
•
NAND Flash
Device
NAND Flash
Interface
NAND Flash-Specific Features
Organization
• Page size
– x8: 2112 bytes (2048 + 64 bytes)
– x16: 1056 words (1024 + 32 words)
• Block size: 64 pages (128K + 4K bytes)
LPDRAM Power
LPDRAM
Device
LPDRAM
Interface
Mobile LPDDR-Specific Features
•
•
•
•
•
•
•
•
No external voltage reference required
No minimum clock rate requirement
1.8V LVCMOS-compatible inputs
Programmable burst lengths
Partial-array self refresh (PASR)
Deep power-down (DPD) mode
Selectable output drive strength
STATUS REGISTER READ (SRR) supported1
Notes:
1. Contact factory for remapped SRR output.
2. For physical part markings, see on page .
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168ball_nand_lpddr_j4p2_j4x2_j4x3_omap.pdf - Rev. C 12/12
1
Micron Technology, Inc. reserves the right to change products or specifications without notice.
2011 Micron Technology, Inc. All rights reserved.
Products and specifications discussed herein are subject to change by Micron without notice.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Part Numbering Information
Micron NAND Flash and LPDRAM devices are available in different configurations and densities. The MCP/PoP
part numbering guide is available at www.micron.com/numbering.
Figure 2: Part Number Chart
MT 29C XX XXX X
X
X
X
XX -X
XX XX
Micron Technology
Production Status
Product Family
Operating Temperature Range
NAND Flash Density
LPDRAM Access Time
LPDRAM Density
Package Codes
Operating Voltage Range
Chip Count
NAND Flash Configuration
LPDRAM Configuration
Device Marking
Due to the size of the package, the Micron-standard part number is not printed on the top of the device. Instead,
an abbreviated device mark consisting of a 5-digit alphanumeric code is used. The abbreviated device marks are
cross-referenced to the Micron part numbers at the FBGA Part Marking Decoder site: www.micron.com/decoder.
To view the location of the abbreviated mark on the device, refer to customer service note CSN-11, “Product Mark/
Label,” at www.micron.com/csn.
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2
Micron Technology, Inc. reserves the right to change products or specifications without notice.
2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Contents
MCP General Description ...............................................................................................................................
Ball Assignments and Descriptions .................................................................................................................
Electrical Specifications ..................................................................................................................................
Device Diagrams ............................................................................................................................................
Package Dimensions .......................................................................................................................................
4Gb, 8Gb: x8, x16 NAND Flash Memory ...........................................................................................................
Features .....................................................................................................................................................
General Description .......................................................................................................................................
Architecture ...................................................................................................................................................
Device and Array Organization ........................................................................................................................
Asynchronous Interface Bus Operation ...........................................................................................................
Asynchronous Enable/Standby ...................................................................................................................
Asynchronous Commands ..........................................................................................................................
Asynchronous Addresses ............................................................................................................................
Asynchronous Data Input ...........................................................................................................................
Asynchronous Data Output .........................................................................................................................
Write Protect# ............................................................................................................................................
Ready/Busy# ..............................................................................................................................................
Device Initialization .......................................................................................................................................
Command Definitions ....................................................................................................................................
Reset Operations ............................................................................................................................................
RESET (FFh) ...............................................................................................................................................
Identification Operations ................................................................................................................................
READ ID (90h) ............................................................................................................................................
READ ID Parameter Tables ..............................................................................................................................
READ PARAMETER PAGE (ECh) ......................................................................................................................
Bare Die Parameter Page Data Structure Tables ................................................................................................
READ UNIQUE ID (EDh) ................................................................................................................................
Feature Operations .........................................................................................................................................
SET FEATURES (EFh) ..................................................................................................................................
GET FEATURES (EEh) .................................................................................................................................
Status Operations ...........................................................................................................................................
READ STATUS (70h) ...................................................................................................................................
READ STATUS ENHANCED (78h) ................................................................................................................
Column Address Operations ...........................................................................................................................
RANDOM DATA READ (05h-E0h) ................................................................................................................
RANDOM DATA READ TWO-PLANE (06h-E0h) ............................................................................................
RANDOM DATA INPUT (85h) ......................................................................................................................
PROGRAM FOR INTERNAL DATA INPUT (85h) ...........................................................................................
Read Operations .............................................................................................................................................
READ MODE (00h) .....................................................................................................................................
READ PAGE (00h-30h) ................................................................................................................................
READ PAGE CACHE SEQUENTIAL (31h) ......................................................................................................
READ PAGE CACHE RANDOM (00h-31h) ....................................................................................................
READ PAGE CACHE LAST (3Fh) ..................................................................................................................
READ PAGE TWO-PLANE 00h-00h-30h .......................................................................................................
Program Operations .......................................................................................................................................
PROGRAM PAGE (80h-10h) .........................................................................................................................
PROGRAM PAGE CACHE (80h-15h) .............................................................................................................
PROGRAM PAGE TWO-PLANE (80h-11h) ....................................................................................................
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2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Erase Operations ............................................................................................................................................ 81
ERASE BLOCK (60h-D0h) ............................................................................................................................ 81
ERASE BLOCK TWO-PLANE (60h-D1h) ....................................................................................................... 82
Internal Data Move Operations ....................................................................................................................... 83
READ FOR INTERNAL DATA MOVE (00h-35h) ............................................................................................. 84
PROGRAM FOR INTERNAL DATA MOVE (85h–10h) ..................................................................................... 85
PROGRAM FOR INTERNAL DATA MOVE TWO-PLANE (85h-11h) ................................................................. 86
Block Lock Feature ......................................................................................................................................... 87
WP# and Block Lock ................................................................................................................................... 87
UNLOCK (23h-24h) .................................................................................................................................... 87
LOCK (2Ah) ................................................................................................................................................ 90
LOCK TIGHT (2Ch) ..................................................................................................................................... 91
BLOCK LOCK READ STATUS (7Ah) .............................................................................................................. 92
One-Time Programmable (OTP) Operations .................................................................................................... 94
Legacy OTP Commands .............................................................................................................................. 94
OTP DATA PROGRAM (80h-10h) ................................................................................................................. 95
RANDOM DATA INPUT (85h) ...................................................................................................................... 96
OTP DATA PROTECT (80h-10) ..................................................................................................................... 97
OTP DATA READ (00h-30h) ......................................................................................................................... 99
Two-Plane Operations ................................................................................................................................... 101
Two-Plane Addressing ............................................................................................................................... 101
Interleaved Die (Multi-LUN) Operations ......................................................................................................... 110
Error Management ........................................................................................................................................ 111
Internal ECC and Spare Area Mapping for ECC ............................................................................................... 113
Electrical Specifications ................................................................................................................................. 115
Electrical Specifications – DC Characteristics and Operating Conditions .......................................................... 117
Electrical Specifications – AC Characteristics and Operating Conditions .......................................................... 119
Electrical Specifications – Program/Erase Characteristics ................................................................................ 122
Asynchronous Interface Timing Diagrams ...................................................................................................... 123
2Gb: x16, x32 Mobile LPDDR SDRAM ............................................................................................................. 135
Features .................................................................................................................................................... 135
General Description .................................................................................................................................. 137
Functional Block Diagrams ............................................................................................................................ 138
Electrical Specifications ................................................................................................................................. 140
Electrical Specifications – IDD Parameters ....................................................................................................... 143
Electrical Specifications – AC Operating Conditions ........................................................................................ 149
Output Drive Characteristics .......................................................................................................................... 154
Functional Description .................................................................................................................................. 157
Commands ................................................................................................................................................... 158
DESELECT ................................................................................................................................................ 159
NO OPERATION ........................................................................................................................................ 159
LOAD MODE REGISTER ............................................................................................................................ 159
ACTIVE ..................................................................................................................................................... 159
READ ........................................................................................................................................................ 160
WRITE ...................................................................................................................................................... 161
PRECHARGE ............................................................................................................................................. 162
BURST TERMINATE .................................................................................................................................. 163
AUTO REFRESH ........................................................................................................................................ 163
SELF REFRESH .......................................................................................................................................... 164
DEEP POWER-DOWN ................................................................................................................................ 164
Truth Tables .................................................................................................................................................. 165
State Diagram ............................................................................................................................................... 170
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2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Initialization ................................................................................................................................................. 171
Standard Mode Register ................................................................................................................................. 174
Burst Length ............................................................................................................................................. 175
Burst Type ................................................................................................................................................. 175
CAS Latency .............................................................................................................................................. 176
Operating Mode ........................................................................................................................................ 177
Extended Mode Register ................................................................................................................................ 178
Temperature-Compensated Self Refresh ..................................................................................................... 178
Partial-Array Self Refresh ........................................................................................................................... 179
Output Drive Strength ............................................................................................................................... 179
Status Read Register ...................................................................................................................................... 180
Bank/Row Activation ..................................................................................................................................... 182
READ Operation ............................................................................................................................................ 183
WRITE Operation .......................................................................................................................................... 194
PRECHARGE Operation ................................................................................................................................. 206
Auto Precharge .............................................................................................................................................. 206
Concurrent Auto Precharge ........................................................................................................................ 207
AUTO REFRESH Operation ............................................................................................................................ 213
SELF REFRESH Operation .............................................................................................................................. 214
Power-Down ................................................................................................................................................. 215
Deep Power-Down .................................................................................................................................... 217
Clock Change Frequency ............................................................................................................................... 219
Revision History ............................................................................................................................................ 220
Rev. C – 12/12 ............................................................................................................................................ 220
Rev. B – 10/12 ............................................................................................................................................ 220
Rev. A – 05/11 ............................................................................................................................................ 220
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168ball_nand_lpddr_j4p2_j4x2_j4x3_omap.pdf - Rev. C 12/12
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Micron Technology, Inc. reserves the right to change products or specifications without notice.
2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
List of Figures
Figure 1: PoP Block Diagram ............................................................................................................................ 1
Figure 2: Part Number Chart ............................................................................................................................ 2
Figure 3: 168-Ball VFBGA (NAND x8, x16; LPDDR x32) Ball Assignments .......................................................... 12
Figure 4: 168-Ball (Single LPDDR) Functional Block Diagram .......................................................................... 17
Figure 5: 168-Ball (Dual LPDDR) Functional Block Diagram ............................................................................ 18
Figure 6: 168-Ball VFBGA (Package Code: JG) .................................................................................................. 19
Figure 7: 168-Ball VFBGA (Package Code: JV) .................................................................................................. 20
Figure 8: 168-Ball WFBGA (Package Code: KQ) ................................................................................................ 21
Figure 9: NAND Flash Die (LUN) Functional Block Diagram ............................................................................ 24
Figure 10: Array Organization – MT29F4G08 (x8) ............................................................................................ 25
Figure 11: Array Organization – MT29F4G16 (x16) .......................................................................................... 26
Figure 12: Array Organization – MT29F8G08 and MT29F16G08 (x8) ................................................................. 27
Figure 13: Array Organization – MT29F8G16 (x16) .......................................................................................... 28
Figure 14: Asynchronous Command Latch Cycle ............................................................................................ 30
Figure 15: Asynchronous Address Latch Cycle ................................................................................................ 31
Figure 16: Asynchronous Data Input Cycles .................................................................................................... 32
Figure 17: Asynchronous Data Output Cycles ................................................................................................. 33
Figure 18: Asynchronous Data Output Cycles (EDO Mode) ............................................................................. 34
Figure 19: READ/BUSY# Open Drain .............................................................................................................. 35
Figure 20: tFall and tRise (3.3V V CC) ................................................................................................................ 36
Figure 21: tFall and tRise (1.8V V CC) ................................................................................................................ 36
Figure 22: IOL vs. Rp (VCC = 3.3V V CC) .............................................................................................................. 37
Figure 23: IOL vs. Rp (1.8V V CC) ....................................................................................................................... 37
Figure 24: TC vs. Rp ....................................................................................................................................... 38
Figure 25: R/B# Power-On Behavior ............................................................................................................... 39
Figure 26: RESET (FFh) Operation .................................................................................................................. 43
Figure 27: READ ID (90h) with 00h Address Operation .................................................................................... 44
Figure 28: READ ID (90h) with 20h Address Operation .................................................................................... 44
Figure 29: READ PARAMETER (ECh) Operation .............................................................................................. 48
Figure 30: READ UNIQUE ID (EDh) Operation ............................................................................................... 52
Figure 31: SET FEATURES (EFh) Operation .................................................................................................... 54
Figure 32: GET FEATURES (EEh) Operation .................................................................................................... 55
Figure 33: READ STATUS (70h) Operation ...................................................................................................... 59
Figure 34: READ STATUS ENHANCED (78h) Operation ................................................................................... 60
Figure 35: RANDOM DATA READ (05h-E0h) Operation ................................................................................... 61
Figure 36: RANDOM DATA READ TWO-PLANE (06h-E0h) Operation .............................................................. 62
Figure 37: RANDOM DATA INPUT (85h) Operation ........................................................................................ 63
Figure 38: PROGRAM FOR INTERNAL DATA INPUT (85h) Operation .............................................................. 65
Figure 39: READ PAGE (00h-30h) Operation ................................................................................................... 69
Figure 40: READ PAGE (00h-30h) Operation with Internal ECC Enabled .......................................................... 69
Figure 41: READ PAGE CACHE SEQUENTIAL (31h) Operation ......................................................................... 70
Figure 42: READ PAGE CACHE RANDOM (00h-31h) Operation ....................................................................... 71
Figure 43: READ PAGE CACHE LAST (3Fh) Operation ..................................................................................... 72
Figure 44: READ PAGE TWO-PLANE (00h-00h-30h) Operation ........................................................................ 74
Figure 45: PROGRAM PAGE (80h-10h) Operation ............................................................................................ 76
Figure 46: PROGRAM PAGE CACHE (80h–15h) Operation (Start) ..................................................................... 78
Figure 47: PROGRAM PAGE CACHE (80h–15h) Operation (End) ...................................................................... 78
Figure 48: PROGRAM PAGE TWO-PLANE (80h–11h) Operation ....................................................................... 80
Figure 49: ERASE BLOCK (60h-D0h) Operation .............................................................................................. 81
Figure 50: ERASE BLOCK TWO-PLANE (60h–D1h) Operation .......................................................................... 82
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2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Figure 51: READ FOR INTERNAL DATA MOVE (00h-35h) Operation ................................................................ 84
Figure 52: READ FOR INTERNAL DATA MOVE (00h–35h) with RANDOM DATA READ (05h–E0h) ..................... 84
Figure 53: INTERNAL DATA MOVE (85h-10h) with Internal ECC Enabled ........................................................ 85
Figure 54: INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT with Internal ECC Enabled ............ 85
Figure 55: PROGRAM FOR INTERNAL DATA MOVE (85h–10h) Operation ........................................................ 85
Figure 56: PROGRAM FOR INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT (85h) .................... 86
Figure 57: PROGRAM FOR INTERNAL DATA MOVE TWO-PLANE (85h-11h) Operation .................................... 86
Figure 58: Flash Array Protected: Invert Area Bit = 0 ........................................................................................ 88
Figure 59: Flash Array Protected: Invert Area Bit = 1 ........................................................................................ 88
Figure 60: UNLOCK Operation ....................................................................................................................... 89
Figure 61: LOCK Operation ............................................................................................................................ 90
Figure 62: LOCK TIGHT Operation ................................................................................................................. 91
Figure 63: PROGRAM/ERASE Issued to Locked Block ...................................................................................... 92
Figure 64: BLOCK LOCK READ STATUS .......................................................................................................... 92
Figure 65: BLOCK LOCK Flowchart ................................................................................................................ 93
Figure 66: OTP DATA PROGRAM (After Entering OTP Operation Mode) ........................................................... 96
Figure 67: OTP DATA PROGRAM Operation with RANDOM DATA INPUT (After Entering OTP Operation Mode) ...
97
Figure 68: OTP DATA PROTECT Operation (After Entering OTP Protect Mode) ................................................. 98
Figure 69: OTP DATA READ ........................................................................................................................... 99
Figure 70: OTP DATA READ with RANDOM DATA READ Operation ................................................................ 100
Figure 71: TWO-PLANE PAGE READ ............................................................................................................. 102
Figure 72: TWO-PLANE PAGE READ with RANDOM DATA READ ................................................................... 103
Figure 73: TWO-PLANE PROGRAM PAGE ...................................................................................................... 103
Figure 74: TWO-PLANE PROGRAM PAGE with RANDOM DATA INPUT .......................................................... 104
Figure 75: TWO-PLANE PROGRAM PAGE CACHE MODE ............................................................................... 105
Figure 76: TWO-PLANE INTERNAL DATA MOVE ........................................................................................... 106
Figure 77: TWO-PLANE INTERNAL DATA MOVE with TWO-PLANE RANDOM DATA READ ............................ 107
Figure 78: TWO-PLANE INTERNAL DATA MOVE with RANDOM DATA INPUT ............................................... 108
Figure 79: TWO-PLANE BLOCK ERASE ......................................................................................................... 109
Figure 80: TWO-PLANE/MULTIPLE-DIE READ STATUS Cycle ........................................................................ 109
Figure 81: Spare Area Mapping (x8) ............................................................................................................... 113
Figure 82: Spare Area Mapping (x16) ............................................................................................................. 114
Figure 83: RESET Operation .......................................................................................................................... 123
Figure 84: READ STATUS Cycle ..................................................................................................................... 123
Figure 85: READ STATUS ENHANCED Cycle .................................................................................................. 124
Figure 86: READ PARAMETER PAGE ............................................................................................................. 124
Figure 87: READ PAGE .................................................................................................................................. 125
Figure 88: READ PAGE Operation with CE# “Don’t Care” ............................................................................... 126
Figure 89: RANDOM DATA READ .................................................................................................................. 127
Figure 90: READ PAGE CACHE SEQUENTIAL ................................................................................................ 128
Figure 91: READ PAGE CACHE RANDOM ...................................................................................................... 129
Figure 92: READ ID Operation ...................................................................................................................... 130
Figure 93: PROGRAM PAGE Operation .......................................................................................................... 130
Figure 94: PROGRAM PAGE Operation with CE# “Don’t Care” ........................................................................ 131
Figure 95: PROGRAM PAGE Operation with RANDOM DATA INPUT .............................................................. 131
Figure 96: PROGRAM PAGE CACHE .............................................................................................................. 132
Figure 97: PROGRAM PAGE CACHE Ending on 15h ........................................................................................ 132
Figure 98: INTERNAL DATA MOVE ............................................................................................................... 133
Figure 99: INTERNAL DATA MOVE (85h-10h) with Internal ECC Enabled ....................................................... 133
Figure 100: INTERNAL DATA MOVE (85h-10h) with Random Data Input with Internal ECC Enabled ............... 134
Figure 101: ERASE BLOCK Operation ............................................................................................................ 134
Figure 102: Functional Block Diagram (x16) .................................................................................................. 138
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2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
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Functional Block Diagram (x32) .................................................................................................. 139
Typical Self Refresh Current vs. Temperature ................................................................................ 148
ACTIVE Command ..................................................................................................................... 160
READ Command ........................................................................................................................ 161
WRITE Command ....................................................................................................................... 162
PRECHARGE Command ............................................................................................................. 163
DEEP POWER-DOWN Command ................................................................................................ 164
Simplified State Diagram ............................................................................................................ 170
Initialize and Load Mode Registers .............................................................................................. 172
Alternate Initialization with CKE LOW ......................................................................................... 173
Standard Mode Register Definition .............................................................................................. 174
CAS Latency ............................................................................................................................... 177
Extended Mode Register ............................................................................................................. 178
Status Read Register Timing ........................................................................................................ 180
Status Register Definition ............................................................................................................ 181
READ Burst ................................................................................................................................ 184
Consecutive READ Bursts ............................................................................................................ 185
Nonconsecutive READ Bursts ...................................................................................................... 186
Random Read Accesses ............................................................................................................... 187
Terminating a READ Burst ........................................................................................................... 188
READ-to-WRITE ......................................................................................................................... 189
READ-to-PRECHARGE ................................................................................................................ 190
Data Output Timing – tDQSQ, tQH, and Data Valid Window (x16) ................................................. 191
Data Output Timing – tDQSQ, tQH, and Data Valid Window (x32) ................................................. 192
Data Output Timing – tAC and tDQSCK ........................................................................................ 193
Data Input Timing ...................................................................................................................... 195
Write – DM Operation ................................................................................................................. 196
WRITE Burst ............................................................................................................................... 197
Consecutive WRITE-to-WRITE .................................................................................................... 198
Nonconsecutive WRITE-to-WRITE .............................................................................................. 198
Random WRITE Cycles ............................................................................................................... 199
WRITE-to-READ – Uninterrupting ............................................................................................... 200
WRITE-to-READ – Interrupting ................................................................................................... 201
WRITE-to-READ – Odd Number of Data, Interrupting .................................................................. 202
WRITE-to-PRECHARGE – Uninterrupting .................................................................................... 203
WRITE-to-PRECHARGE – Interrupting ........................................................................................ 204
WRITE-to-PRECHARGE – Odd Number of Data, Interrupting ....................................................... 205
Bank Read – With Auto Precharge ................................................................................................ 208
Bank Read – Without Auto Precharge ........................................................................................... 210
Bank Write – With Auto Precharge ............................................................................................... 211
Bank Write – Without Auto Precharge .......................................................................................... 212
Auto Refresh Mode ..................................................................................................................... 213
Self Refresh Mode ....................................................................................................................... 215
Power-Down Entry (in Active or Precharge Mode) ........................................................................ 216
Power-Down Mode (Active or Precharge) ..................................................................................... 217
Deep Power-Down Mode ............................................................................................................ 218
Clock Stop Mode ........................................................................................................................ 219
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Micron Technology, Inc. reserves the right to change products or specifications without notice.
2011 Micron Technology, Inc. All rights reserved.
�Micron Confidential and Proprietary
168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
List of Tables
Table 1: x8, x16 NAND Ball Descriptions ......................................................................................................... 13
Table 2: x32 LPDDR Ball Descriptions ............................................................................................................ 14
Table 3: Non-Device-Specific Descriptions ..................................................................................................... 15
Table 4: Absolute Maximum Ratings .............................................................................................................. 16
Table 5: Recommended Operating Conditions ................................................................................................ 16
Table 6: Array Addressing – MT29F4G08 (x8) .................................................................................................. 25
Table 7: Array Addressing – MT29F4G16 (x16) ................................................................................................. 26
Table 8: Array Addressing – MT29F8G08 and MT29F16G08 (x8) ....................................................................... 27
Table 9: Array Addressing – MT29F8G16 ( x16) ................................................................................................ 28
Table 10: Asynchronous Interface Mode Selection .......................................................................................... 29
Table 11: Command Set ................................................................................................................................. 40
Table 12: Two-Plane Command Set ................................................................................................................ 42
Table 13: READ ID Parameters for Address 00h ............................................................................................... 45
Table 14: READ ID Parameters for Address 20h ............................................................................................... 47
Table 15: Parameter Page Data Structure ........................................................................................................ 49
Table 16: Feature Address Definitions ............................................................................................................. 53
Table 17: Feature Address 90h – Array Operation Mode ................................................................................... 54
Table 18: Feature Addresses 01h: Timing Mode ............................................................................................... 56
Table 19: Feature Addresses 80h: Programmable I/O Drive Strength ................................................................ 57
Table 20: Feature Addresses 81h: Programmable R/B# Pull-Down Strength ...................................................... 57
Table 21: Status Register Definition ................................................................................................................ 58
Table 22: Block Lock Address Cycle Assignments ............................................................................................ 89
Table 23: Block Lock Status Register Bit Definitions ........................................................................................ 92
Table 24: Error Management Details ............................................................................................................. 111
Table 25: Absolute Maximum Ratings ............................................................................................................ 115
Table 26: Recommended Operating Conditions ............................................................................................. 115
Table 27: Valid Blocks ................................................................................................................................... 115
Table 28: Capacitance ................................................................................................................................... 116
Table 29: Test Conditions .............................................................................................................................. 116
Table 30: DC Characteristics and Operating Conditions (3.3V) ....................................................................... 117
Table 31: DC Characteristics and Operating Conditions (1.8V) ....................................................................... 118
Table 32: AC Characteristics: Command, Data, and Address Input (3.3V) ........................................................ 119
Table 33: AC Characteristics: Command, Data, and Address Input (1.8V) ........................................................ 119
Table 34: AC Characteristics: Normal Operation (3.3V) .................................................................................. 120
Table 35: AC Characteristics: Normal Operation (1.8V) .................................................................................. 120
Table 36: Program/Erase Characteristics ....................................................................................................... 122
Table 37: Configuration Addressing – 2Gb ..................................................................................................... 136
Table 38: Absolute Maximum Ratings ............................................................................................................ 140
Table 39: AC/DC Electrical Characteristics and Operating Conditions ............................................................ 140
Table 40: Capacitance (x16, x32) ................................................................................................................... 142
Table 41: IDD Specifications and Conditions, –25°C to +85°C (x16) .................................................................. 143
Table 42: IDD Specifications and Conditions, –25°C to +85°C (x32) .................................................................. 144
Table 43: IDD Specifications and Conditions, –40°C to +105°C (x16) ................................................................. 145
Table 44: IDD Specifications and Conditions, –40°C to +105°C (x32) ................................................................. 146
Table 45: IDD6 Specifications and Conditions ................................................................................................. 147
Table 46: Electrical Characteristics and Recommended AC Operating Conditions ........................................... 149
Table 47: Target Output Drive Characteristics (Full Strength) .......................................................................... 154
Table 48: Target Output Drive Characteristics (Three-Quarter Strength) ......................................................... 155
Table 49: Target Output Drive Characteristics (One-Half Strength) ................................................................. 156
Table 50: Truth Table – Commands ............................................................................................................... 158
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Features
Table 51:
Table 52:
Table 53:
Table 54:
Table 55:
DM Operation Truth Table ............................................................................................................. 159
Truth Table – Current State Bank n – Command to Bank n ............................................................... 165
Truth Table – Current State Bank n – Command to Bank m .............................................................. 167
Truth Table – CKE .......................................................................................................................... 169
Burst Definition Table .................................................................................................................... 175
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
MCP General Description
MCP General Description
Micron package-on-package (PoP) MCP products combine NAND Flash and Mobile
LPDRAM devices in a single MCP. These products target mobile applications with lowpower, high-performance, and minimal package-footprint design requirements. The
NAND Flash and Mobile LPDRAM devices are also members of the Micron discrete
memory products portfolio.
The NAND Flash and Mobile LPDRAM devices are packaged with separate interfaces
(no shared address, control, data, or power balls). This bus architecture supports an optimized interface to processors with separate NAND Flash and Mobile LPDRAM buses.
The NAND Flash and Mobile LPDRAM devices have separate core power connections
and share a common ground (that is, V SS is tied together on the two devices).
The bus architecture of this device also supports separate NAND Flash and Mobile
LPDRAM functionality without concern for device interaction.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Ball Assignments and Descriptions
Ball Assignments and Descriptions
Figure 3: 168-Ball VFBGA (NAND x8, x16; LPDDR x32) Ball Assignments
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
18
17
19
20
21
22
23
A
DNU
DNU DQ17 VDDQ DQ19 DM2 VDDQ DQ21 DQ23 VDDQ
CK
VDD
DQ9 DQ11 VDDQ DQ13 DM1 VDDQ DQ15 DM3 DQ25 DNU
DNU
A
B
DNU
DNU DQ16 VSSQ DQ18 DQS2 VSSQ DQ20 DQ22 VSSQ
CK#
VSS
DQ8 DQ10 VSSQ DQ12 DQS1 VSSQ DQ14 DQS3 DQ24 DNU
DNU
B
C
DM0 DQS0
VSSQ VDDQ
C
D
DQ7
DQ6
DQ26 DQ27
D
E
VDDQ VSSQ
DQ28 DQ29
E
F
DQ5
DQ4
VSSQ VDDQ
F
G
DQ3
DQ2
DQ30 DQ31
G
H
VDDQ VSSQ
J
DQ1
DQ0
K
VDD
VSS
L
VCC
M
VSS
VDD
CKE0 CKE1
VSS
H
J
WE#
K
VSS
CAS# RAS#
L
I/O1
I/O0
CS0# CS1#
M
N
I/O3
I/O2
A0
A1
N
P
VCC
VSS
A2
A3
P
R
I/O5
I/O4
A4
A5
R
T
I/O7
I/O6
A6
A7
T
U
VCC
VSS
A8
A9
U
V
WE#
RE#
A10
A11
V
W
ALE
NC
A12
A13
W
Y
CE1# CE0#
A14
VDD
Y
AA
VCC
VSS
VSS
VDD
AA
AB
DNU
DNU
I/O8
I/O10
VSS
I/O12 I/O14
VSS
AC
DNU
DNU
I/O9
I/O11
VCC I/O13 I/O15
VCC
NC
1
2
3
4
6
8
9
5
7
NC
R/B#
VSS
VSS
NC
NC
NC
NC
NC
VSS
BA0
DNU
DNU
AB
NC
NC
CLE
VCC
TQ
NC
NC
NC
NC
NC
NC
BA1
DNU
DNU
AC
10
11
12
13
14
15
16
17
18
19
20
21
22
23
LOCK WP#
Top View – Ball Down
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NAND
LPDDR
Supply
Ground
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Ball Assignments and Descriptions
Table 1: x8, x16 NAND Ball Descriptions
Note:
Symbol
Type
ALE
Input
Address latch enable: When ALE is HIGH, addresses can be
transferred to the on-chip address register.
Description
CE0#, CE1#
Input
Chip enable: Gates transfers between the host system and
the NAND device.
CE1# is used when a second CE# is required and is RFU1 in all
other configurations.
CLE
Input
Command latch enable: When CLE is HIGH, commands can be
transferred to the on-chip command register.
LOCK
Input
When LOCK is HIGH during power-up, the BLOCK LOCK function is enabled. To disable BLOCK LOCK, connect LOCK to VSS
during power-up, or leave it unconnected (internal pulldown).
RE#
Input
Read enable: Gates information from the NAND device to the
host system.
WE#
Input
Write enable: Gates information from the host system to the
NAND device.
WP#
Input
Write protect: Driving WP# LOW blocks ERASE and
PROGRAM operations.
I/O[15:0]
Input/
output
Data inputs/outputs: The bidirectional I/Os transfer address,
data, and instruction information. Data is output only during
READ operations; at other times the I/Os are inputs.
I/O[15:8] are RFU for x8 NAND devices.
R/B#
Output
Ready/busy: Open-drain, active-LOW output that indicates
when an internal operation is in progress.
VCC
Supply
VCC: NAND power supply.
1. Balls marked RFU may or may not be connected internally. These balls should not be
used. Contact factory for details.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Ball Assignments and Descriptions
Table 2: x32 LPDDR Ball Descriptions
Note:
Symbol
Type
Description
A[14:0]
Input
Address inputs: Specifies the row or column address. Also
used to load the mode registers. The maximum LPDDR address is determined by density and configuration. Consult the
LPDDR product data sheet for the maximum address for a
given density and configuration. Unused address balls
become RFU.1
BA0, BA1
Input
Bank address inputs: Specifies one of the 4 banks.
CAS#
Input
Column select: Specifies which command to execute.
CK, CK#
Input
CK is the system clock. CK and CK# are differential clock
inputs. All address and control signals are sampled and
referenced on the crossing of the rising edge of CK with the
falling edge of CK#.
CKE0, CKE1
Input
Clock enable.
CKE0 is used for a single LPDDR product.
CKE1 is used for dual LPDDR products and is considered RFU
for single LPDDR MCPs.
CS0#, CS1#
Input
Chip select:
CS0# is used for a single LPDDR product.
CS1# is used for dual LPDDR products and is considered RFU
for single LPDDR MCPs.
DM[3:0]
Input
Data mask: Determines which bytes are written
during WRITE operations.
RAS#
Input
Row select: Specifies the command to execute.
WE#
Input
Write enable: Specifies the command to execute.
DQ[31:0]
Input/
output
Data bus: Data inputs/outputs.
DQS[3:0]
Input/
output
Data strobe: Coordinates READ/WRITE transfers of data; one
DQS per DQ byte.
TQ
Output
Temperature sensor output: TQ HIGH when LPDDR TJ
exceeds 85°C.
VDD
Supply
VDD: LPDDR power supply.
VDDQ
Supply
VDDQ: LPDDR I/O power supply.
VSSQ
Supply
VSSQ: LPDDR I/O ground.
1. Balls marked RFU may or may not be connected internally. These balls should not be
used. Contact factory for details.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Ball Assignments and Descriptions
Table 3: Non-Device-Specific Descriptions
Note:
Symbol
Type
VSS
Supply
Description
Symbol
Type
DNU
–
Do not use: Must be grounded or left floating.
NC
–
No connect: Not internally connected.
RFU1
–
Reserved for future use.
VSS: Shared ground.
Description
1. Balls marked RFU may or may not be connected internally. These balls should not be
used. Contact factory for details.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications
Electrical Specifications
Table 4: Absolute Maximum Ratings
Parameters/Conditions
Symbol
Min
Max
Unit
VCC, VDD, VDDQ supply voltage
relative to VSS
VCC, VDD,
VDDQ
–1.0
2.4
V
VIN
–0.5
2.4 or (supply voltage1 +
0.3V), whichever is less
V
–55
+150
°C
Voltage on any pin
relative to VSS
Storage temperature range
Note:
1. Supply voltage references VCC, VDD, or VDDQ.
Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only, and functional operation of
the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability.
Table 5: Recommended Operating Conditions
Parameters
Symbol
Min
Typ
Max
Unit
Supply voltage
VCC, VDD
1.70
1.80
1.95
V
VDDQ
1.70
1.80
1.95
V
–
–25
–
+85
°C
I/O supply voltage
Operating temperature range
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device Diagrams
Device Diagrams
Figure 4: 168-Ball (Single LPDDR) Functional Block Diagram
CE0#
VCC
CLE
ALE
RE#
NAND Flash
I/O
WE#
WP#
R/B#
LOCK
VSS
CS0#
VDD
CK
VDDQ
CK#
CKE0
DM
LPDDR
RAS#
DQ
CAS#
WE#
DQS
TQ
Address,
VSS
BA0, BA1
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VSSQ
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device Diagrams
Figure 5: 168-Ball (Dual LPDDR) Functional Block Diagram
CE0#
VCC
CLE
ALE
NAND Flash
RE#
I/O
WE#
WP#
R/B#
VSS
CS0, CS1#
VDD
CK
VDDQ
CK#
DM
LPDDR
CKE0, CKE1
(Die 0 and 1)
RAS#
DQ
CAS#
WE#
DQS
TQ
Address,
VSS
BA0, BA1
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VSSQ
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Package Dimensions
Package Dimensions
Figure 6: 168-Ball VFBGA (Package Code: JG)
Seating
plane
0.08 A
0.58 ±0.05
A
168X Ø0.34
Solder ball
material: SAC105.
Dimensions apply
to solder balls postreflow on Ø0.28
SMD ball pads.
Ball A1 ID
Ball A1 ID
23 22 21 20 19 18 17 16 15 14 13 12 1110 9 8 7 6 5 4 3 2 1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
11 CTR
12 ±0.1
0.9 MAX
0.5 TYP
0.5 TYP
11 CTR
0.23 MIN
12 ±0.1
Note:
1. All dimensions are in millimeters.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Package Dimensions
Figure 7: 168-Ball VFBGA (Package Code: JV)
Seating
plane
0.08 A
0.68 ±0.05
A
168X Ø0.34
Solder ball
material: SAC105.
Dimensions apply S
to solder balls post- R
reflow on Ø0.28
SMD ball pads.
Ball A1 ID
Ball A1 ID
23 22 21 20 19 18 17 16 15 14 13 12 1110 9 8 7 6 5 4 3 2 1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
11 CTR
12 ±0.1
1.0 MAX
0.5 TYP
0.5 TYP
11 CTR
0.23 MIN
12 ±0.1
Note:
1. All dimensions are in millimeters.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Package Dimensions
Figure 8: 168-Ball WFBGA (Package Code: KQ)
Seating
plane
0.08 A
0.43 ±0.05
A
168X Ø0.34
Solder ball
material: SAC105.
Dimensions apply S
to solder balls post- R
reflow on Ø0.28
SMD ball pads.
Ball A1 ID
Ball A1 ID
23 22 21 20 19 18 17 16 15 14 13 12 1110 9 8 7 6 5 4 3 2 1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
11 CTR
12 ±0.1
0.75 MAX
0.5 TYP
0.5 TYP
11 CTR
0.23 MIN
12 ±0.1
Note:
1. All dimensions are in millimeters.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
4Gb, 8Gb: x8, x16 NAND Flash Memory
4Gb, 8Gb: x8, x16 NAND Flash Memory
Features
• Open NAND Flash Interface (ONFI) 1.0-compliant1
• Single-level cell (SLC) technology
• Organization
– Page size x8: 2112 bytes (2048 + 64 bytes)
– Page size x16: 1056 words (1024 + 32 words)
– Block size: 64 pages (128K + 4K bytes)
– Plane size: 2 planes x 2048 blocks per plane
– Device size: 4Gb: 4096 blocks; 8Gb: 8192 blocks
• Asynchronous I/O performance
– tRC/tWC: 20ns (3.3V), 25ns (1.8V)
• Array performance
– Read page: 25μs2
– Program page: 200μs (TYP: 1.8V, 3.3V)2
– Erase block: 700μs (TYP)
• Command set: ONFI NAND Flash Protocol
• Advanced command set
– Program page cache mode3
– Read page cache mode3
– One-time programmable (OTP) mode
– Two-plane commands3
– Interleaved die (LUN) operations
– Read unique ID
– Block lock (1.8V only)
– Internal data move
• Operation status byte provides software method for detecting
– Operation completion
– Pass/fail condition
– Write-protect status
• Ready/Busy# (R/B#) signal provides a hardware method of detecting operation completion
• WP# signal: Write protect entire device
• Blocks 0–15 (block addresses 00h–0Fh) are valid when shipped from factory with
ECC; for minimum required ECC, see Error Management
• Block 0 requires 1-bit ECC if PROGRAM/ERASE cycles are less than 1000
• RESET (FFh) required as first command after power-on
• Alternate method of device initialization (Nand_Init) after power-up (contact factory)
• Internal data move operations supported within the plane from which data is read
• Quality and reliability
– Data retention: 10 years
• Operating voltage range
– VCC: 2.7–3.6V
– VCC: 1.7–1.95V
• Operating temperature
– Commercial: 0°C to +70°C
– Industrial (IT): –40ºC to +85ºC
Notes:
1. The ONFI 1.0 specification is available at www.onfi.org.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
General Description
2. See Electrical Specifications – Program/Erase Characteristics (page 122) for tR_ECC and
tPROG_ECC specifications.
3. These commands supported only with ECC disabled.
General Description
Micron NAND Flash devices include an asynchronous data interface for high-performance I/O operations. These devices use a highly multiplexed 8-bit bus (I/Ox) to transfer
commands, address, and data. There are five control signals used to implement the
asynchronous data interface: CE#, CLE, ALE, WE#, and RE#. Additional signals control
hardware write protection and monitor device status (R/B#).
This hardware interface creates a low pin-count device with a standard pinout that remains the same from one density to another, enabling future upgrades to higher densities with no board redesign.
A target is the unit of memory accessed by a chip enable signal. A target contains one or
more NAND Flash die. A NAND Flash die is the minimum unit that can independently
execute commands and report status. A NAND Flash die, in the ONFI specification, is
referred to as a logical unit (LUN). There is at least one NAND Flash die per chip enable
signal. For further details, see Device and Array Organization.
This device has an internal 4-bit ECC that can be enabled using the GET/SET features.
See Internal ECC and Spare Area Mapping for ECC for more information.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Architecture
Architecture
These devices use NAND Flash electrical and command interfaces. Data, commands,
and addresses are multiplexed onto the same pins and received by I/O control circuits.
The commands received at the I/O control circuits are latched by a command register
and are transferred to control logic circuits for generating internal signals to control device operations. The addresses are latched by an address register and sent to a row decoder to select a row address, or to a column decoder to select a column address.
Data is transferred to or from the NAND Flash memory array, byte by byte (x8) or word
by word (x16), through a data register and a cache register.
The NAND Flash memory array is programmed and read using page-based operations
and is erased using block-based operations. During normal page operations, the data
and cache registers act as a single register. During cache operations, the data and cache
registers operate independently to increase data throughput. The status register reports
the status of die operations.
Figure 9: NAND Flash Die (LUN) Functional Block Diagram
VCC
I/Ox
I/O
control
VSS
Address register
Status register
Command register
CE#
Column decode
CLE
WE#
Control
logic
Row decode
ALE
RE#
WP#
LOCK1
NAND Flash
array
(2 planes)
Data register
R/B#
Cache register
ECC
Note:
1. The LOCK pin is used on the 1.8V device.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device and Array Organization
Device and Array Organization
Figure 10: Array Organization – MT29F4G08 (x8)
2112 bytes
2112 bytes
DQ7
Cache Register
2048
64
2048
64
Data Register
2048
64
2048
64
2048 blocks
per plane
1 block
DQ0
1 page
= (2K + 64 bytes)
1 block
= (2K + 64) bytes x 64 pages
= (128K + 4K) bytes
1 plane
= (128K + 4K) bytes x 2048 blocks
= 2112Mb
1 block
4096 blocks
per device
1 device = 2112Mb x 2 planes
= 4224Mb
Plane of
even-numbered blocks
(0, 2, 4, 6, ..., 4092, 4094)
Plane of
odd-numbered blocks
(1, 3, 5, 7, ..., 4093, 4095)
Table 6: Array Addressing – MT29F4G08 (x8)
Cycle
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
First
CA7
CA6
CA5
CA4
CA3
CA2
CA1
CA0
Second
LOW
LOW
LOW
LOW
CA11
CA10
CA9
CA8
Third
BA7
BA6
PA5
PA4
PA3
PA2
PA1
PA0
Fourth
BA15
BA14
BA13
BA12
BA11
BA10
BA9
BA8
Fifth
LOW
LOW
LOW
LOW
LOW
LOW
BA17
BA16
Notes:
1. Block address concatenated with page address = actual page address. CAx = column address; PAx = page address; BAx = block address.
2. If CA11 is 1, then CA[10:6] must be 0.
3. BA6 controls plane selection.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device and Array Organization
Figure 11: Array Organization – MT29F4G16 (x16)
1056 words
1056 words
DQ15
Cache Register
1024
32
1024
32
Data Register
1024
32
1024
32
2048 blocks
per plane
1 block
DQ0
1 page
= (1K + 32 words)
1 block
= (1K + 32) words x 64 pages
= (64K + 2K) words
1 plane
= (64K + 2K) words x 2048 blocks
= 2112Mb
1 device
= 2112Mb x 2 planes
= 4224Mb
1 block
4096 blocks
per device
Plane of
even-numbered blocks
(0, 2, 4, 6, ..., 4092, 4094)
Plane of
odd-numbered blocks
(1, 3, 5, 7, ..., 4093, 4095)
Table 7: Array Addressing – MT29F4G16 (x16)
Cycle
I/O[15:8]
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
First
LOW
CA7
CA6
CA5
CA4
CA3
CA2
CA1
CA0
Second
LOW
LOW
LOW
LOW
LOW
LOW
CA10
CA9
CA8
Third
LOW
BA7
BA6
PA5
PA4
PA3
PA2
PA1
PA0
Fourth
LOW
BA15
BA14
BA13
BA12
BA11
BA10
BA9
BA8
Fifth
LOW
LOW
LOW
LOW
LOW
LOW
LOW
BA17
BA16
Notes:
1. Block address concatenated with page address = actual page address. CAx = column address; PAx = page address; BAx = block address.
2. If CA10 = 1, then CA[9:5] must be 0.
3. BA6 controls plane selection.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device and Array Organization
Figure 12: Array Organization – MT29F8G08 and MT29F16G08 (x8)
Die 0
2112 bytes
Die 1
2112 bytes
2112 bytes
2112 bytes
I/O7
Cache Register
2048
64
2048
64
2048
64
2048
64
Data Register
2048
64
2048
64
2048
64
2048
64
I/O0
1 page = (2K + 64 bytes)
2048 blocks
per plane
1 block
1 block
1 block
1 block
1 block = (2K + 64) bytes x 64 pages
= (128K + 4K) bytes
1 plane = (128K + 4K) bytes x 2048 blocks
= 2112Mb
4096 blocks
per die
1 die
Plane 0: evennumbered blocks
(0, 2, 4, 6, ...,
4092, 4094)1
Note:
Plane 1: oddnumbered blocks
(1, 3, 5, 7, ...,
4093, 4095)
Plane 0: evennumbered blocks
(4096, 4098, ...,
8188, 8190)
Plane 1: oddnumbered blocks
(4097, 4099, ...,
8189, 8191)
= 2112Mb x 2 planes
= 4224Mb
1 device = 4224Mb x 2 die
= 8448Mb
1. Die 0, Plane 0: BA18 = 0; BA6 = 0. Die 0, Plane 1: BA18 = 0; BA6 = 1.
Die 1, Plane 0: BA18 = 1; BA6 = 0. Die 1, Plane 1: BA18 = 1; BA6 = 1.
Table 8: Array Addressing – MT29F8G08 and MT29F16G08 (x8)
Cycle
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
First
CA7
CA6
CA5
CA4
CA3
CA2
CA1
CA0
Second
LOW
LOW
LOW
LOW
CA11
CA10
CA9
CA8
Third
BA7
BA6
PA5
PA4
PA3
PA2
PA1
PA0
Fourth
BA15
BA14
BA13
BA12
BA11
BA10
BA9
BA8
Fifth
LOW
LOW
LOW
LOW
LOW
BA183
BA17
BA16
Notes:
1. CAx = column address; PAx = page address; BAx = block address.
2. If CA11 is 1, then CA[10:6] must be 0.
3. Die address boundary: 0 = 0–4Gb; 1 = 4Gb–8Gb.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device and Array Organization
Figure 13: Array Organization – MT29F8G16 (x16)
Die 0
1056 words
Die 1
1056 words
1056 words
1056 words
I/O7
Cache Register
1024
32
1024
32
1024
32
1024
32
Data Register
1024
32
1024
32
1024
32
1024
32
I/O0
1 page = (1K + 32 words)
2048 blocks
per plane
1 block
1 block
1 block
1 block
1 block = (1K + 32) words x 64 pages
= (64K + 2K) words
1 plane = (128K + 4K) bytes x 2048 blocks
= 2112Mb
4096 blocks
per die
1 die
Plane 0: evennumbered blocks
(0, 2, 4, 6, ...,
4092, 4094)1
Note:
Plane 1: oddnumbered blocks
(1, 3, 5, 7, ...,
4093, 4095)
Plane 0: evennumbered blocks
(4096, 4098, ...,
8188, 8190)
Plane 1: oddnumbered blocks
(4097, 4099, ...,
8189, 8191)
= 2112Mb x 2 planes
= 4224Mb
1 device = 4224Mb x 2 die
= 8448Mb
1. Die 0, Plane 0: BA18 = 0; BA6 = 0. Die 0, Plane 1: BA18 = 0; BA6 = 1.
Die 1, Plane 0: BA18 = 1; BA6 = 0. Die 1, Plane 1: BA18 = 1; BA6 = 1.
Table 9: Array Addressing – MT29F8G16 ( x16)
Cycle
I/O[15:8]
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/O0
First
LOW
CA7
CA6
CA5
CA4
CA3
CA2
CA1
CA0
Second
LOW
LOW
LOW
LOW
LOW
LOW
CA10
CA9
CA8
Third
LOW
BA7
BA6
PA5
PA4
PA3
PA2
PA1
PA0
Fourth
LOW
BA15
BA14
BA13
BA12
BA11
BA10
BA9
PA8
Fifth
LOW
LOW
LOW
LOW
LOW
LOW
BA183
BA17
BA16
Notes:
1. Block address concatenated with page address = actual page address. CAx = column address; PAx = page address; BAx = block address.
2. If CA10 = 1, then CA[9:5] must be 0.
3. Die address boundary: 0 = 0–4Gb; 1 = 4Gb–8Gb.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Asynchronous Interface Bus Operation
The bus on the device is multiplexed. Data I/O, addresses, and commands all share the
same pins. I/O[15:8] are used only for data in the x16 configuration. Addresses and
commands are always supplied on I/O[7:0].
The command sequence typically consists of a COMMAND LATCH cycle, address input
cycles, and one or more data cycles, either READ or WRITE.
Table 10: Asynchronous Interface Mode Selection
Mode1
CE#
CLE
ALE
WE#
RE#
I/Ox
WP#
Standby2
H
X
X
X
X
X
0V/VCC
Command input
L
H
L
H
X
H
Address input
L
L
H
H
X
H
Data input
L
L
L
H
X
H
Data output
L
L
L
H
X
X
Write protect
X
X
X
X
X
L
Notes:
X
1. Mode selection settings for this table: H = Logic level HIGH; L = Logic level LOW; X = VIH
or VIL.
2. WP# should be biased to CMOS LOW or HIGH for standby.
Asynchronous Enable/Standby
When the device is not performing an operation, the CE# pin is typically driven HIGH
and the device enters standby mode. The memory will enter standby if CE# goes HIGH
while data is being transferred and the device is not busy. This helps reduce power consumption.
The CE# “Don’t Care” operation enables the NAND Flash to reside on the same asynchronous memory bus as other Flash or SRAM devices. Other devices on the memory
bus can then be accessed while the NAND Flash is busy with internal operations. This
capability is important for designs that require multiple NAND Flash devices on the
same bus.
A HIGH CLE signal indicates that a command cycle is taking place. A HIGH ALE signal
signifies that an ADDRESS INPUT cycle is occurring.
Asynchronous Commands
An asynchronous command is written from I/O[7:0] to the command register on the rising edge of WE# when CE# is LOW, ALE is LOW, CLE is HIGH, and RE# is HIGH.
Commands are typically ignored by die (LUNs) that are busy (RDY = 0); however, some
commands, including READ STATUS (70h) and READ STATUS ENHANCED (78h), are
accepted by die (LUNs) even when they are busy.
For devices with a x16 interface, I/O[15:8] must be written with zeros when a command
is issued.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Figure 14: Asynchronous Command Latch Cycle
CLE
tCLS
tCS
tCLH
tCH
CE#
tWP
WE#
tALS
tALH
tDS
tDH
ALE
I/Ox
COMMAND
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Asynchronous Addresses
An asynchronous address is written from I/O[7:0] to the address register on the rising
edge of WE# when CE# is LOW, ALE is HIGH, CLE is LOW, and RE# is HIGH.
Bits that are not part of the address space must be LOW (see Device and Array Organization). The number of cycles required for each command varies. Refer to the command
descriptions to determine addressing requirements.
Addresses are typically ignored by die (LUNs) that are busy (RDY = 0); however, some
addresses are accepted by die (LUNs) even when they are busy; for example, like address cycles that follow the READ STATUS ENHANCED (78h) command.
Figure 15: Asynchronous Address Latch Cycle
CLE
tCLS
tCS
CE#
tWC
tWP
tWH
WE#
tALS
tALH
ALE
tDS tDH
I/Ox
Col
add 1
Col
add 2
Row
add 1
Row
add 2
Don’t Care
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Row
add 3
Undefined
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Asynchronous Data Input
Data is written from I/O[7:0] to the cache register of the selected die (LUN) on the rising
edge of WE# when CE# is LOW, ALE is LOW, CLE is LOW, and RE# is HIGH.
Data input is ignored by die (LUNs) that are not selected or are busy (RDY = 0). Data is
written to the data register on the rising edge of WE# when CE#, CLE, and ALE are LOW,
and the device is not busy.
Data is input on I/O[7:0] on x8 devices and on I/O[15:0] on x16 devices.
Figure 16: Asynchronous Data Input Cycles
CLE
tCLH
CE#
tALS
tCH
ALE
tWC
tWP
tWP
tWP
WE#
tWH
tDS
I/Ox
tDH
DIN M
tDS
tDH
DIN M+1
tDS
tDH
DIN N
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Asynchronous Data Output
Data can be output from a die (LUN) if it is in a READY state. Data output is supported
following a READ operation from the NAND Flash array. Data is output from the cache
register of the selected die (LUN) to I/O[7:0] on the falling edge of RE# when CE# is
LOW, ALE is LOW, CLE is LOW, and WE# is HIGH.
If the host controller is using a tRC of 30ns or greater, the host can latch the data on the
rising edge of RE# (see the figure below for proper timing). If the host controller is using
a tRC of less than 30ns, the host can latch the data on the next falling edge of RE#.
Using the READ STATUS ENHANCED (78h) command prevents data contention following an interleaved die (multi-LUN) operation. After issuing the READ STATUS ENHANCED (78h) command, to enable data output, issue the READ MODE (00h) command.
Data output requests are typically ignored by a die (LUN) that is busy (RDY = 0); however, it is possible to output data from the status register even when a die (LUN) is busy by
first issuing the READ STATUS or READ STATUS ENHANCED (78h) command.
Figure 17: Asynchronous Data Output Cycles
tCEA
CE#
tREA
tREA
tRP
tCHZ
tREA
tREH
tCOH
RE#
tRHZ
tRHZ
tRHOH
DOUT
I/Ox
tRR
DOUT
DOUT
tRC
RDY
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Figure 18: Asynchronous Data Output Cycles (EDO Mode)
CE#
tRC
tRP
tCHZ
tREH
tCOH
RE#
tREA
tCEA
I/Ox
tREA
tRHZ
tRLOH
tRHOH
DOUT
DOUT
DOUT
tRR
RDY
Don’t Care
Write Protect#
The write protect# (WP#) signal enables or disables PROGRAM and ERASE operations
to a target. When WP# is LOW, PROGRAM and ERASE operations are disabled. When
WP# is HIGH, PROGRAM and ERASE operations are enabled.
It is recommended that the host drive WP# LOW during power-on until V CC is stable to
prevent inadvertent PROGRAM and ERASE operations (see Device Initialization for additional details).
WP# must be transitioned only when the target is not busy and prior to beginning a
command sequence. After a command sequence is complete and the target is ready,
WP# can be transitioned. After WP# is transitioned, the host must wait tWW before issuing a new command.
The WP# signal is always an active input, even when CE# is HIGH. This signal should
not be multiplexed with other signals.
Ready/Busy#
The ready/busy# (R/B#) signal provides a hardware method of indicating whether a target is ready or busy. A target is busy when one or more of its die (LUNs) are busy
(RDY = 0). A target is ready when all of its die (LUNs) are ready (RDY = 1). Because each
die (LUN) contains a status register, it is possible to determine the independent status
of each die (LUN) by polling its status register instead of using the R/B# signal (see Status Operations for details regarding die (LUN) status).
This signal requires a pull-up resistor, Rp, for proper operation. R/B# is HIGH when the
target is ready, and transitions LOW when the target is busy. The signal's open-drain
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
driver enables multiple R/B# outputs to be OR-tied. Typically, R/B# is connected to an
interrupt pin on the system controller.
The combination of Rp and capacitive loading of the R/B# circuit determines the rise
time of the R/B# signal. The actual value used for Rp depends on the system timing requirements. Large values of Rp cause R/B# to be delayed significantly. Between the 10%
and 90% points on the R/B# waveform, the rise time is approximately two time constants (TC).
TC = R × C
Where R = Rp (resistance of pull-up resistor), and C = total capacitive load.
The fall time of the R/B# signal is determined mainly by the output impedance of the
R/B# signal and the total load capacitance. Approximate Rp values using a circuit load
of 100pF are provided in Figure 24 (page 38).
The minimum value for Rp is determined by the output drive capability of the R/B# signal, the output voltage swing, and V CC.
VCC (MAX) - VOL (MAX)
IOL + ȈIL
Where ȈIL is the sum of the input currents of all devices tied to the R/B# pin.
Rp =
Figure 19: READ/BUSY# Open Drain
Rp
VCC
R/B#
Open drain output
IOL
VSS
Device
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Figure 20: tFall and tRise (3.3V VCC)
3.50
3.00
2.50
tFall tRise
2.00
V
1.50
1.00
0.50
0.00
–1
0
2
4
0
2
4
TC
Notes:
6
VCC 3.3V
1. tFall and tRise calculated at 10% and 90% points.
2. tRise dependent on external capacitance and resistive loading and output transistor impedance.
3. tRise primarily dependent on external pull-up resistor and external capacitive loading.
4. tFall = 10ns at 3.3V.
5. See TC values in Figure 24 (page 38) for approximate Rp value and TC.
Figure 21: tFall and tRise (1.8V VCC)
3.50
3.00
2.50
tFall
2.00
tRise
V
1.50
1.00
0.50
0.00
-1
0
2
4
0
TC
Notes:
1.
2.
3.
4.
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4
6
VCC1.8V
tFall
and tRise are calculated at 10% and 90% points.
is primarily dependent on external pull-up resistor and external capacitive loading.
tFall ≈ 7ns at 1.8V.
See TC values in Figure 24 (page 38) for TC and approximate Rp value.
tRise
36
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Figure 22: IOL vs. Rp (VCC = 3.3V VCC)
3.50
3.00
2.50
2.00
,��P$�
1.50
1.00
0.50
0.00
0
2000
400 0
6000
8000
10,000
12,000
Rp (ȍ)
IOL at VCC (MAX)
Figure 23: IOL vs. Rp (1.8V VCC)
3.50
3.00
2.50
2.00
I (mA)
1.50
1.00
0.50
0.00
0
2000
4000
6000
8000
10,000
12,000
Rp (ȍ)
IOL at VCC (MAX)
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Bus Operation
Figure 24: TC vs. Rp
1200
1000
800
T(ns)
600
400
200
0
0�����������2000���������4000��������6000��������8000������10,000������12,000
Rp (ȍ)
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IOL at VCC (MAX)
RC = TC
C = 100pF
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Device Initialization
Device Initialization
Micron NAND Flash devices are designed to prevent data corruption during power
transitions. V CC is internally monitored. (The WP# signal supports additional hardware
protection during power transitions.) When ramping V CC, use the following procedure
to initialize the device:
1. Ramp V CC.
2. The host must wait for R/B# to be valid and HIGH before issuing RESET (FFh) to
any target. The R/B# signal becomes valid when 50μs has elapsed since the beginning the V CC ramp, and 10μs has elapsed since V CC reaches V CC (MIN).
3. If not monitoring R/B#, the host must wait at least 100μs after V CC reaches V CC
(MIN). If monitoring R/B#, the host must wait until R/B# is HIGH.
4. The asynchronous interface is active by default for each target. Each LUN draws
less than an average of 10mA (IST) measured over intervals of 1ms until the RESET
(FFh) command is issued.
5. The RESET (FFh) command must be the first command issued to all targets (CE#s)
after the NAND Flash device is powered on. Each target will be busy for 1ms after a
RESET command is issued. The RESET busy time can be monitored by polling
R/B# or issuing the READ STATUS (70h) command to poll the status register.
6. The device is now initialized and ready for normal operation.
Figure 25: R/B# Power-On Behavior
50μs (MIN)
VCC
VCC = VCC (MIN)
10μs
(MAX)
R/B#
100μs (MAX)
VCC ramp
starts
Reset (FFh)
is issued
Invalid
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Command Definitions
Command Definitions
Table 11: Command Set
Command
Cycle #1
Number of
Valid
Address
Cycles
Data
Input
Cycles
FFh
0
–
–
Yes
Yes
READ ID
90h
1
–
–
No
No
READ PARAMETER PAGE
ECh
1
–
–
No
No
READ UNIQUE ID
EDh
1
–
–
No
No
GET FEATURES
EEh
1
–
–
No
No
SET FEATURES
EFh
1
4
–
No
No
READ STATUS
70h
0
–
–
Yes
READ STATUS ENHANCED
78h
3
–
–
Yes
Yes
Command
Valid While
Command Selected LUN
is Busy1
Cycle #2
Valid While
Other LUNs
are Busy2
Notes
Reset Operations
RESET
Identification Operation
Feature Operations
Status Operations
Column Address Operations
RANDOM DATA READ
05h
2
–
E0h
No
Yes
RANDOM DATA INPUT
85h
2
Optional
–
No
Yes
PROGRAM FOR
INTERNAL DATA MOVE
85h
5
Optional
–
No
Yes
READ MODE
00h
0
–
–
No
Yes
READ PAGE
00h
5
–
30h
No
Yes
READ PAGE CACHE SEQUENTIAL
31h
0
–
–
No
Yes
4, 5
READ PAGE CACHE
RANDOM
00h
5
–
31h
No
Yes
4, 5
READ PAGE CACHE LAST
3Fh
0
–
–
No
Yes
4, 5
PROGRAM PAGE
80h
5
Yes
10h
No
Yes
PROGRAM PAGE CACHE
80h
5
Yes
15h
No
Yes
60h
3
–
D0h
No
Yes
5
–
35h
No
Yes
3
READ OPERATIONS
Program Operations
4, 6
Erase Operations
ERASE BLOCK
Internal Data Move Operations
READ FOR INTERNAL
DATA MOVE
00h
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Command Definitions
Table 11: Command Set (Continued)
Command
Cycle #1
Number of
Valid
Address
Cycles
Data
Input
Cycles
85h
5
Optional
10h
No
Yes
23h
3
–
–
No
Yes
BLOCK UNLOCK HIGH
24h
3
–
–
No
Yes
BLOCK LOCK
2Ah
–
–
–
No
Yes
BLOCK LOCK-TIGHT
2Ch
–
–
–
No
Yes
BLOCK LOCK READ
STATUS
7Ah
3
–
–
No
Yes
Command
PROGRAM FOR INTERNAL DATA MOVE
Valid While
Command Selected LUN
is Busy1
Cycle #2
Valid While
Other LUNs
are Busy2
Notes
Block Lock Operations
BLOCK UNLOCK LOW
One-Time Programmable (OTP) Operations
OTP DATA LOCK BY
PAGE (ONFI)
80h
5
No
10h
No
No
7
OTP DATA PROGRAM
(ONFI)
80h
5
Yes
10h
No
No
7
OTP DATA READ (ONFI)
00h
5
No
30h
No
No
7
Notes:
1. Busy means RDY = 0.
2. These commands can be used for interleaved die (multi-LUN) operations (see Interleaved
Die (Multi-LUN) Operations (page 110)).
3. Do not cross plane address boundaries when using READ for INTERNAL DATA MOVE and
PROGRAM for INTERNAL DATA MOVE.
4. These commands supported only with ECC disabled.
5. Issuing a READ PAGE CACHE series (31h, 00h-31h, 3Fh) command when the array is busy
(RDY = 1, ARDY = 0) is supported if the previous command was a READ PAGE (00h-30h)
or READ PAGE CACHE series command; otherwise, it is prohibited.
6. Issuing a PROGRAM PAGE CACHE (80h-15h) command when the array is busy (RDY = 1,
ARDY = 0) is supported if the previous command was a PROGRAM PAGE CACHE
(80h-15h) command; otherwise, it is prohibited.
7. OTP commands can be entered only after issuing the SET FEATURES command with the
feature address.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Command Definitions
Table 12: Two-Plane Command Set
Note 4 applies to all parameters and conditions
Number of
Valid
ComAddress
mand
Cycles
Cycle #1
Command
Command
Cycle #2
Number of
Valid
Address
Cycles
Command
Cycle #3
Valid While Valid While
Selected
Other LUNs
LUN is Busy
are Busy Notes
READ PAGE TWOPLANE
00h
5
00h
5
30h
No
Yes
READ FOR TWOPLANE INTERNAL
DATA MOVE
00h
5
00h
5
35h
No
Yes
1
RANDOM DATA
READ TWO-PLANE
06h
5
E0h
–
–
No
Yes
2
PROGRAM PAGE
TWO-PLANE
80h
5
11h-80h
5
10h
No
Yes
PROGRAM PAGE
CACHE MODE TWOPLANE
80h
5
11h-80h
5
15h
No
Yes
PROGRAM FOR
TWO-PLANE INTERNAL DATA MOVE
85h
5
11h-85h
5
10h
No
Yes
1
BLOCK ERASE TWOPLANE
60h
3
D1h-60h
3
D0h
No
Yes
3
Notes:
1. Do not cross plane boundaries when using READ FOR INTERNAL DATA MOVE TWOPLANE or PROGRAM FOR TWO-PLANE INTERNAL DATA MOVE.
2. The RANDOM DATA READ TWO-PLANE command is limited to use with the PAGE READ
TWO-PLANE command.
3. D1h command can be omitted.
4. These commands supported only with ECC disabled.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Reset Operations
Reset Operations
RESET (FFh)
The RESET command is used to put the memory device into a known condition and to
abort the command sequence in progress.
READ, PROGRAM, and ERASE commands can be aborted while the device is in the busy
state. The contents of the memory location being programmed or the block being
erased are no longer valid. The data may be partially erased or programmed, and is invalid. The command register is cleared and is ready for the next command. The data
register and cache register contents are marked invalid.
The status register contains the value E0h when WP# is HIGH; otherwise it is written
with a 60h value. R/B# goes LOW for tRST after the RESET command is written to the
command register.
The RESET command must be issued to all CE#s as the first command after power-on.
The device will be busy for a maximum of 1ms.
Figure 26: RESET (FFh) Operation
Cycle type
I/O[7:0]
Command
FF
tWB
tRST
R/B#
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Identification Operations
Identification Operations
READ ID (90h)
The READ ID (90h) command is used to read identifier codes programmed into the target. This command is accepted by the target only when all die (LUNs) on the target are
idle.
Writing 90h to the command register puts the target in read ID mode. The target stays in
this mode until another valid command is issued.
When the 90h command is followed by an 00h address cycle, the target returns a 5-byte
identifier code that includes the manufacturer ID, device configuration, and part-specific information.
When the 90h command is followed by a 20h address cycle, the target returns the 4-byte
ONFI identifier code.
Figure 27: READ ID (90h) with 00h Address Operation
Cycle type
Command
Address
DOUT
DOUT
DOUT
DOUT
DOUT
Byte 0
Byte 1
Byte 2
Byte 3
Byte 4
tWHR
I/O[7:0]
Note:
90h
00h
1. See the READ ID Parameter tables for byte definitions.
Figure 28: READ ID (90h) with 20h Address Operation
Cycle type
Command
Address
DOUT
DOUT
DOUT
DOUT
4Fh
4Eh
46h
49h
tWHR
I/O[7:0]
Note:
90h
20h
1. See READ ID Parameter tables for byte definitions.
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READ ID Parameter Tables
READ ID Parameter Tables
Table 13: READ ID Parameters for Address 00h
b = binary; h = hexadecimal
Options
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
Value
Micron
0
0
1
0
1
1
0
0
2Ch
4Gb, x8, 3.3V
1
1
0
1
1
1
0
0
DCh
MT29F4G16ABADA
4Gb, x16, 3.3V
1
1
0
0
1
1
0
0
CCh
MT29F4G08ABBDA
4Gb, x8, 1.8V
1
0
1
0
1
1
0
0
ACh
MT29F4G16ABBDA
4Gb, x16, 1.8V
1
0
1
1
1
1
0
0
BCh
MT29F8G08ADBDA
8Gb, x8, 1.8V
1
0
1
0
0
0
1
1
A3h
MT29F8G16ADBDA
8Gb, x16, 1.8V
1
0
1
1
0
0
1
1
B3h
MT29F8G08ADADA
8Gb, x8, 3.3V
1
1
0
1
0
0
1
1
D3h
MT29F8G16ADADA
8Gb, x16, 3.3V
1
1
0
0
0
0
1
1
C3h
MT29F16G08AJADA
16Gb, x8, 3.3V
1
1
0
1
0
0
1
1
D3h
1
0
0
00b
2
0
1
01b
Byte 0 – Manufacturer ID
Manufacturer
Byte 1 – Device ID
MT29F4G08ABADA
Byte 2
Number of die per CE
Cell type
SLC
0
Number of simultaneously
programmed pages
2
Interleaved operations between multiple die
Not supported
Cache programming
Supported
1
Byte value
MT29F4G08ABADA
1
0
0
1
0
0
0
0
90h
MT29F4G16ABADA
1
0
0
1
0
0
0
0
90h
MT29F4G08ABBDA
1
0
0
1
0
0
0
0
90h
MT29F4G16ABBDA
1
0
0
1
0
0
0
0
90h
MT29F8G08ADBDA
1
1
0
1
0
0
0
1
D1h
MT29F8G16ADBDA
1
1
0
1
0
0
0
1
D1h
MT29F8G08ADADA
1
1
0
1
0
0
0
1
D1h
MT29F8G16ADADA
1
1
0
1
0
0
0
1
D1h
MT29F16G08AJADA
1
1
0
1
0
0
0
1
D1h
0
1
01b
0
0
00b
1
01b
0
0b
1b
Byte 3
Page size
2KB
Spare area size (bytes)
64B
Block size (without spare)
128KB
Organization
1
0
1
1b
01b
x8
0
0b
x16
1
1b
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ ID Parameter Tables
Table 13: READ ID Parameters for Address 00h (Continued)
b = binary; h = hexadecimal
Options
Serial access
(MIN)
Byte value
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
Value
1.8V
25ns
0
0
0xxx0b
3.3V
20ns
1
0
1xxx0b
MT29F4G08ABADA
1
0
0
1
0
1
0
1
95h
MT29F4G16ABADA
1
1
0
1
0
1
0
1
D5h
MT29F4G08ABBDA
0
0
0
1
0
1
0
1
15h
MT29F4G16ABBDA
0
1
0
1
0
1
0
1
55h
MT29F8G08ADBDA
0
0
0
1
0
1
0
1
15h
MT29F8G16ADBDA
0
1
0
1
0
1
0
1
55h
MT29F8G08ADADA
1
0
0
1
0
1
0
1
95h
MT29F8G16ADADA
1
1
0
1
0
1
0
1
D5h
MT29F16G08AJADA
1
0
0
1
0
1
0
1
95h
1
0
10b
Byte 4
Internal ECC level
4-bit ECC/512 (main) +
4 (spare) + 8 (parity)
bytes
Planes per CE#
2
4
0
1
1
0
01b
10b
Plane size
2Gb
Internal ECC
ECC disabled
0
0b
ECC enabled
1
1b
Byte value
1
0
1
101b
MT29F4G08ABADA
0
1
0
1
0
1
1
0
56h
MT29F4G16ABADA
0
1
0
1
0
1
1
0
56h
MT29F4G08ABBDA
0
1
0
1
0
1
1
0
56h
MT29F4G16ABBDA
0
1
0
1
0
1
1
0
56h
MT29F8G08ADBDA
0
1
0
1
1
0
1
0
5Ah
MT29F8G16ADBDA
0
1
0
1
1
0
1
0
5Ah
MT29F8G08ADADA
0
1
0
1
1
0
1
0
5Ah
MT29F8G16ADADA
0
1
0
1
1
0
1
0
5Ah
MT29F16G08AJADA
0
1
0
1
1
0
1
0
5Ah
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ ID Parameter Tables
Table 14: READ ID Parameters for Address 20h
h = hexadecimal
Byte
Options
I/07
I/06
I/05
I/04
I/03
I/02
I/01
I/00
Value
0
“O”
0
1
0
0
1
1
1
1
4Fh
1
“N”
0
1
0
0
1
1
1
0
4Eh
2
“F”
0
1
0
0
0
1
1
0
46h
3
“I”
0
1
0
0
1
0
0
1
49h
4
Undefined
X
X
X
X
X
X
X
X
XXh
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ PARAMETER PAGE (ECh)
READ PARAMETER PAGE (ECh)
The READ PARAMETER PAGE (ECh) command is used to read the ONFI parameter page
programmed into the target. This command is accepted by the target only when all die
(LUNs) on the target are idle.
Writing ECh to the command register puts the target in read parameter page mode. The
target stays in this mode until another valid command is issued.
When the ECh command is followed by an 00h address cycle, the target goes busy for tR.
If the READ STATUS (70h) command is used to monitor for command completion, the
READ MODE (00h) command must be used to re-enable data output mode. Use of the
READ STATUS ENHANCED (78h) command is prohibited while the target is busy and
during data output.
A minimum of three copies of the parameter page are stored in the device. Each parameter page is 256 bytes. If desired, the RANDOM DATA READ (05h-E0h) command can be
used to change the location of data output.
Figure 29: READ PARAMETER (ECh) Operation
Cycle type
I/O[7:0]
Command
Address
ECh
00h
tWB
tR
DOUT
DOUT
DOUT
DOUT
DOUT
DOUT
P00
P10
…
P01
P11
…
tRR
R/B#
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Bare Die Parameter Page Data Structure Tables
Bare Die Parameter Page Data Structure Tables
Table 15: Parameter Page Data Structure
Byte
Description
Value
0–3
Parameter page signature
4Fh, 4Eh, 46h, 49h
4–5
Revision number
6–7
Features supported
8–9
02h, 00h
MT29F4G08ABBDA3W
18h, 00h
MT29F4G16ABBDA3W
19h, 00h
MT29F8G08ADBDA3W
1Ah, 00h
MT29F8G16ADBDA3W
1Bh, 00h
MT29F4G08ABADA3W
18h, 00h
MT29F4G16ABADA3W
19h, 00h
MT29F8G08ADADA3W
1Ah, 00h
MT29F8G16ADADA3W
1Bh, 00h
Optional commands supported
3Fh, 00h
10–31
Reserved
00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h
32–43
Device manufacturer
4Dh, 49h, 43h, 52h, 4Fh, 4Eh, 20h, 20h, 20h, 20h, 20h,
20h
44–63
Device model
64
MT29F4G08ABBDA3W
4Dh, 54h, 32h, 39h, 46h, 34h, 47h, 30h, 38h, 41h, 42h,
42h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F4G16ABBDA3W
4Dh, 54h, 32h, 39h, 46h, 34h, 47h, 31h, 36h, 41h, 42h,
42h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F8G08ADBDA3W
4Dh, 54h, 32h, 39h, 46h, 38h, 47h, 30h, 38h, 41h, 44h,
42h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F8G16ADBDA3W
4Dh, 54h, 32h, 39h, 46h, 38h, 47h, 31h, 36h, 41h, 44h,
42h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F4G08ABADA3W
4Dh, 54h, 32h, 39h, 46h, 34h, 47h, 30h, 38h, 41h, 42h,
41h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F4G16ABADA3W
4Dh, 54h, 32h, 39h, 46h, 34h, 47h, 31h, 36h, 41h, 42h,
41h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F8G08ADADA3W
4Dh, 54h, 32h, 39h, 46h, 38h, 47h, 30h, 38h, 41h, 44h,
41h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
MT29F8G16ADADA3W
4Dh, 54h, 32h, 39h, 46h, 38h, 47h, 31h, 36h, 41h, 44h,
41h, 44h, 41h, 33h, 57h, 20h, 20h, 20h, 20h
Manufacturer ID
2Ch
65–66
Date code
00h, 00h
67–79
Reserved
00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h
80–83
Number of data bytes per page
00h, 08h, 00h, 00h
84–85
Number of spare bytes per page
40h, 00h
86–89
Number of data bytes per partial page
00h, 02h, 00h, 00h
90–91
Number of spare bytes per partial page
10h, 00h
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Bare Die Parameter Page Data Structure Tables
Table 15: Parameter Page Data Structure (Continued)
Byte
Description
Value
92–95
Number of pages per block
40h, 00h, 00h, 00h
96–99
Number of blocks per unit
00h, 10h, 00h, 00h
100
Number of logical units
MT29F4G08ABBDA3W
01h
MT29F4G16ABBDA3W
01h
MT29F8G08ADBDA3W
02h
MT29F8G16ADBDA3W
02h
MT29F4G08ABADA3W
01h
MT29F4G16ABADA3W
01h
MT29F8G08ADADA3W
02h
MT29F8G16ADADA3W
02h
101
Number of address cycles
23h
102
Number of bits per cell
01h
103–104 Bad blocks maximum per unit
50h, 00h
105–106 Block endurance
01h, 05h
107
Guaranteed valid blocks at beginning of target
01h
108–109 Block endurance for guaranteed valid blocks
00h, 00h
110
Number of programs per page
04h
111
Partial programming attributes
00h
112
Number of bits ECC bits
04h
113
Number of interleaved address bits
01h
114
Interleaved operation attributes
0Eh
115–127 Reserved
128
I/O pin capacitance
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00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h
MT29F4G08ABBDA3W
0Ah
MT29F4G16ABBDA3W
0Ah
MT29F8G08ADBDA3W
14h
MT29F8G16ADBDA3W
14h
MT29F4G08ABADA3W
0Ah
MT29F4G16ABADA3W
0Ah
MT29F8G08ADADA3W
14h
MT29F8G16ADADA3W
14h
50
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Bare Die Parameter Page Data Structure Tables
Table 15: Parameter Page Data Structure (Continued)
Byte
Description
129–130 Timing mode support
131–132 Program cache timing
mode support
133–134
tPROG
135–136
tBERS
137–138
tR
139–140
tCCs
Value
MT29F4G08ABBDA3W
1Fh, 00h
MT29F4G16ABBDA3W
1Fh, 00h
MT29F8G08ADBDA3W
1Fh, 00h
MT29F8G16ADBDA3W
1Fh, 00h
MT29F4G08ABADA3W
3Fh, 00h
MT29F4G16ABADA3W
3Fh, 00h
MT29F8G08ADADA3W
3Fh, 00h
MT29F8G16ADADA3W
3Fh, 00h
MT29F4G08ABBDA3W
1Fh, 00h
MT29F4G16ABBDA3W
1Fh, 00h
MT29F8G08ADBDA3W
1Fh, 00h
MT29F8G16ADBDA3W
1Fh, 00h
MT29F4G08ABADA3W
3Fh, 00h
MT29F4G16ABADA3W
3Fh, 00h
MT29F8G08ADADA3W
3Fh, 00h
MT29F8G16ADADA3W
3Fh, 00h
(MAX) page program time
58h, 02h
(MAX) block erase time
B8h, 0Bh
(MAX) page read time
19h, 00h
(MIN)
64h, 00h
141–163 Reserved
00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h
164–165 Vendor-specific revision number
01h, 00h
166–253 Vendor-specific
01h, 00h, 00h, 02h, 04h, 80h, 01h, 81h, 04h, 01h, 02h,
01h,0Ah, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h,00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h,00h, 00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h,00h, 00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h, 00h,00h, 00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h, 00h, 00h,00h, 00h, 00h, 00h, 00h,
00h, 00h, 00h, 00h, 00h, 00h, 00h,00h, 00h, 00h, 00h
254–255 Integrity CRC
Set at test
256–511 Value of bytes 0–255
512–767 Value of bytes 0–255
768+
Additional redundant parameter pages
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READ UNIQUE ID (EDh)
READ UNIQUE ID (EDh)
The READ UNIQUE ID (EDh) command is used to read a unique identifier programmed
into the target. This command is accepted by the target only when all die (LUNs) on the
target are idle.
Writing EDh to the command register puts the target in read unique ID mode. The target stays in this mode until another valid command is issued.
When the EDh command is followed by an 00h address cycle, the target goes busy for
If the READ STATUS (70h) command is used to monitor for command completion,
the READ MODE (00h) command must be used to re-enable data output mode.
tR.
After tR completes, the host enables data output mode to read the unique ID. When the
asynchronous interface is active, one data byte is output per RE# toggle.
Sixteen copies of the unique ID data are stored in the device. Each copy is 32 bytes. The
first 16 bytes of a 32-byte copy are unique data, and the second 16 bytes are the complement of the first 16 bytes. The host should XOR the first 16 bytes with the second 16
bytes. If the result is 16 bytes of FFh, then that copy of the unique ID data is correct. In
the event that a non-FFh result is returned, the host can repeat the XOR operation on a
subsequent copy of the unique ID data. If desired, the RANDOM DATA READ (05h-E0h)
command can be used to change the data output location.
The upper eight I/Os on a x16 device are not used and are a “Don’t Care” for x16 devices.
Figure 30: READ UNIQUE ID (EDh) Operation
Cycle type
I/O[7:0]
Command
Address
EDh
00h
tWB
tR
DOUT
DOUT
DOUT
DOUT
DOUT
DOUT
U00
U10
…
U01
U11
…
tRR
R/B#
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Feature Operations
Feature Operations
The SET FEATURES (EFh) and GET FEATURES (EEh) commands are used to modify the
target's default power-on behavior. These commands use a one-byte feature address to
determine which subfeature parameters will be read or modified. Each feature address
(in the 00h to FFh range) is defined in below. The SET FEATURES (EFh) command
writes subfeature parameters (P1–P4) to the specified feature address. The GET FEATURES command reads the subfeature parameters (P1–P4) at the specified feature address.
When a feature is set, by default it remains active until the device is power cycled. It is
volatile. Unless otherwise specified in the features table, once a device is set it remains
set, even if a RESET (FFh) command is issued. GET/SET FEATURES commands can be
used after required RESET to enable features before system BOOT ROM process.
Internal ECC can be enabled/disabled using SET FEATURES (EFh). The SET FEATURES
command (EFh), followed by address 90h, followed by four data bytes (only the first data byte is used) will enable/disable internal ECC.
The sequence to enable internal ECC with SET FEATURES is EFh(cmd)-90h(addr)08h(data)-00h(data)-00h(data)-00h(data)-wait(tFEAT).
The sequence to disable internal ECC with SET FEATURES is EFh(cmd)-90h(addr)00h(data)-00h(data)-00h(data)-00h(data)-wait(tFEAT). The GET FEATURES command
is EEh.
Table 16: Feature Address Definitions
Feature Address
Reserved
01h
Timing mode
02h–7Fh
Reserved
80h
Programmable output drive strength
81h
Programmable RB# pull-down strength
82h–FFh
90h
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Definition
00h
Reserved
Array operation mode
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Feature Operations
Table 17: Feature Address 90h – Array Operation Mode
Subfeature
Parameter
Options
1/O7
I/O6
I/O5
I/O4
I/O3
I/O2
I/O1
I/O0
Value
Notes
1
P1
Operation
mode option
Normal
Reserved (0)
0
00h
OTP
operation
Reserved (0)
1
01h
1
1
03h
OTP
protection
Reserved (0)
Disable ECC
Reserved (0)
0
0
0
0
00h
1
Enable ECC
Reserved (0)
1
0
0
0
08h
1
P2
Reserved
Reserved (0)
00h
Reserved (0)
00h
Reserved (0)
00h
P3
Reserved
P4
Reserved
1. These bits are reset to 00h on power cycle.
Note:
SET FEATURES (EFh)
The SET FEATURES (EFh) command writes the subfeature parameters (P1–P4) to the
specified feature address to enable or disable target-specific features. This command is
accepted by the target only when all die (LUNs) on the target are idle.
Writing EFh to the command register puts the target in the set features mode. The target
stays in this mode until another command is issued.
The EFh command is followed by a valid feature address. The host waits for tADL before
the subfeature parameters are input. When the asynchronous interface is active, one
subfeature parameter is latched per rising edge of WE#.
After all four subfeature parameters are input, the target goes busy for tFEAT. The READ
STATUS (70h) command can be used to monitor for command completion.
Feature address 01h (timing mode) operation is unique. If SET FEATURES is used to
modify the interface type, the target will be busy for tITC.
Figure 31: SET FEATURES (EFh) Operation
Cycle type
Command
Address
DIN
DIN
DIN
DIN
P1
P2
P3
P4
tADL
I/O[7:0]
EFh
FA
tWB
tFEAT
R/B#
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Feature Operations
GET FEATURES (EEh)
The GET FEATURES (EEh) command reads the subfeature parameters (P1–P4) from the
specified feature address. This command is accepted by the target only when all die
(LUNs) on the target are idle.
Writing EEh to the command register puts the target in get features mode. The target
stays in this mode until another valid command is issued.
When the EEh command is followed by a feature address, the target goes busy for tFEAT.
If the READ STATUS (70h) command is used to monitor for command completion, the
READ MODE (00h) command must be used to re-enable data output mode.
After tFEAT completes, the host enables data output mode to read the subfeature parameters.
Figure 32: GET FEATURES (EEh) Operation
Cycle type
I/Ox
Command
Address
EEh
FA
tWB
tFEAT
DOUT
DOUT
DOUT
DOUT
P1
P2
P3
P4
tRR
R/B#
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Feature Operations
Table 18: Feature Addresses 01h: Timing Mode
Subfeature
Parameter
Options
I/O7
I/O6
I/O5
I/O4
I/O3
I/O2
I/O1
I/O0
Value
Notes
P1
Timing mode
Mode 0
(default)
Reserved (0)
0
0
0
00h
1, 2
Mode 1
Reserved (0)
0
0
1
01h
2
Mode 2
Reserved (0)
0
1
0
02h
2
Mode 3
Reserved (0)
0
1
1
03h
2
Mode 4
Reserved (0)
1
0
0
04h
2
Mode 5
Reserved (0)
1
0
1
05h
3
P2
Reserved (0)
00h
Reserved (0)
00h
Reserved (0)
00h
P3
P4
Notes:
1. The timing mode feature address is used to change the default timing mode. The timing
mode should be selected to indicate the maximum speed at which the device will receive commands, addresses, and data cycles. The five supported settings for the timing
mode are shown. The default timing mode is mode 0. The device returns to mode 0
when the device is power cycled. Supported timing modes are reported in the parameter page.
2. Supported for both 1.8V and 3.3V.
3. Supported for 3.3V only.
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Feature Operations
Table 19: Feature Addresses 80h: Programmable I/O Drive Strength
Subfeature
Parameter
Options
I/O7
I/O6
I/O5
I/O4
I/O3
I/O2
I/O1
I/O0
Value
Notes
1
P1
I/O drive strength
Full (default)
Reserved (0)
0
0
00h
Three-quarters
Reserved (0)
0
1
01h
One-half
Reserved (0)
1
0
02h
One-quarter
Reserved (0)
1
1
03h
P2
Reserved (0)
00h
Reserved (0)
00h
Reserved (0)
00h
P3
P4
Note:
1. The programmable drive strength feature address is used to change the default I/O
drive strength. Drive strength should be selected based on expected loading of the
memory bus. This table shows the four supported output drive strength settings. The
default drive strength is full strength. The device returns to the default drive strength
mode when the device is power cycled. AC timing parameters may need to be relaxed if
I/O drive strength is not set to full.
Table 20: Feature Addresses 81h: Programmable R/B# Pull-Down Strength
Subfeature
Parameter
Options
I/O7
I/O6
I/O5
I/O4
I/O3
I/O2
I/O1
I/O0
Value
Notes
1
P1
R/B# pull-down
strength
Full (default)
0
0
00h
Three-quarters
0
1
01h
One-half
1
0
02h
One-quarter
1
1
03h
P2
Reserved (0)
00h
Reserved (0)
00h
Reserved (0)
00h
P3
P4
Note:
1. This feature address is used to change the default R/B# pull-down strength. Its strength
should be selected based on the expected loading of R/B#. Full strength is the default,
power-on value.
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Status Operations
Status Operations
Each die (LUN) provides its status independently of other die (LUNs) on the same target
through its 8-bit status register.
After the READ STATUS (70h) or READ STATUS ENHANCED (78h) command is issued,
status register output is enabled. The contents of the status register are returned on I/
O[7:0] for each data output request.
When the asynchronous interface is active and status register output is enabled,
changes in the status register are seen on I/O[7:0] as long as CE# and RE# are LOW; it is
not necessary to toggle RE# to see the status register update.
While monitoring the status register to determine when a data transfer from the Flash
array to the data register (tR) is complete, the host must issue the READ MODE (00h)
command to disable the status register and enable data output (see Read Operations).
The READ STATUS (70h) command returns the status of the most recently selected die
(LUN). To prevent data contention during or following an interleaved die (multi-LUN)
operation, the host must enable only one die (LUN) for status output by using the READ
STATUS ENHANCED (78h) command (see Interleaved Die (Multi-LUN) Operations).
With internal ECC enabled, a READ STATUS command is required after completion of
the data transfer (tR_ECC) to determine whether an uncorrectable read error occurred.
Table 21: Status Register Definition
SR
Bit
Program
Page
Program Page
Cache Mode
Page Read
Page Read
Cache Mode
7
Write protect
Write protect
Write protect
Write protect
6
RDY
RDY1 cache
RDY
RDY1 cache
RDY
0 = Busy
1 = Ready
5
ARDY
ARDY2
ARDY
ARDY2
ARDY
Don't Care
4
–
–
–
–
–
Don't Care
3
–
–
Rewrite
recommended3
–
–
0 = Normal or uncorrectable
1 = Rewrite recommended
Block Erase
Description
Write protect 0 = Protected
1 = Not protected
2
–
–
–
–
–
Don't Care
1
FAILC (N - 1)
FAILC (N - 1)
Reserved
–
–
Don't Care
FAIL (N)
FAIL4
–
FAIL
0
FAIL
Notes:
0 = Successful PROGRAM/
ERASE/READ
1 = Error in PROGRAM/
ERASE/READ
1. Status register bit 6 is 1 when the cache is ready to accept new data. R/B# follows bit 6.
2. Status register bit 5 is 0 during the actual programming operation. If cache mode is
used, this bit will be 1 when all internal operations are complete.
3. A status register bit defined as Rewrite Recommended signifies that the page includes
acertain number of READ errors per sector (512B (main) + 4B (spare) + 8B (parity). A rewriteof this page is recommended. (Up to a 4-bit error has been corrected if internal
ECC was enabled.)
4. A status register bit defined as FAIL signifies that an uncorrectable READ error has occurred.
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Status Operations
READ STATUS (70h)
The READ STATUS (70h) command returns the status of the last-selected die (LUN) on
a target. This command is accepted by the last-selected die (LUN) even when it is busy
(RDY = 0).
If there is only one die (LUN) per target, the READ STATUS (70h) command can be used
to return status following any NAND command.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command
must be used to select the die (LUN) that should report status. In this situation, using
the READ STATUS (70h) command will result in bus contention, as two or more die
(LUNs) could respond until the next operation is issued. The READ STATUS (70h) command can be used following all single-die (LUN) operations.
Figure 33: READ STATUS (70h) Operation
Cycle type
Command
DOUT
tWHR
I/O[7:0]
70h
SR
READ STATUS ENHANCED (78h)
The READ STATUS ENHANCED (78h) command returns the status of the addressed die
(LUN) on a target even when it is busy (RDY = 0). This command is accepted by all die
(LUNs), even when they are BUSY (RDY = 0).
Writing 78h to the command register, followed by three row address cycles containing
the page, block, and LUN addresses, puts the selected die (LUN) into read status mode.
The selected die (LUN) stays in this mode until another valid command is issued. Die
(LUNs) that are not addressed are deselected to avoid bus contention.
The selected LUN's status is returned when the host requests data output. The RDY and
ARDY bits of the status register are shared for all planes on the selected die (LUN). The
FAILC and FAIL bits are specific to the plane specified in the row address.
The READ STATUS ENHANCED (78h) command also enables the selected die (LUN) for
data output. To begin data output following a READ-series operation after the selected
die (LUN) is ready (RDY = 1), issue the READ MODE (00h) command, then begin data
output. If the host needs to change the cache register that will output data, use the
RANDOM DATA READ TWO-PLANE (06h-E0h) command after the die (LUN) is ready.
Use of the READ STATUS ENHANCED (78h) command is prohibited during the poweron RESET (FFh) command and when OTP mode is enabled. It is also prohibited following some of the other reset, identification, and configuration operations. See individual
operations for specific details.
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Status Operations
Figure 34: READ STATUS ENHANCED (78h) Operation
Cycle type
Command
Address
Address
Address
DOUT
tWHR
I/Ox
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78h
R1
R2
60
R3
SR
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Column Address Operations
Column Address Operations
The column address operations affect how data is input to and output from the cache
registers within the selected die (LUNs). These features provide host flexibility for managing data, especially when the host internal buffer is smaller than the number of data
bytes or words in the cache register.
When the asynchronous interface is active, column address operations can address any
byte in the selected cache register.
RANDOM DATA READ (05h-E0h)
The RANDOM DATA READ (05h-E0h) command changes the column address of the selected cache register and enables data output from the last selected die (LUN). This
command is accepted by the selected die (LUN) when it is ready (RDY = 1; ARDY = 1). It
is also accepted by the selected die (LUN) during CACHE READ operations
(RDY = 1; ARDY = 0).
Writing 05h to the command register, followed by two column address cycles containing
the column address, followed by the E0h command, puts the selected die (LUN) into
data output mode. After the E0h command cycle is issued, the host must wait at least
tWHR before requesting data output. The selected die (LUN) stays in data output mode
until another valid command is issued.
In devices with more than one die (LUN) per target, during and following interleaved
die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command must be
issued prior to issuing the RANDOM DATA READ (05h-E0h). In this situation, using the
RANDOM DATA READ (05h-E0h) command without the READ STATUS ENHANCED
(78h) command will result in bus contention because two or more die (LUNs) could
output data.
Figure 35: RANDOM DATA READ (05h-E0h) Operation
Cycle type
DOUT
DOUT
Command
Address
Address
Command
tRHW
I/O[7:0]
Dn
Dn + 1
DOUT
DOUT
DOUT
Dk
Dk + 1
Dk + 2
tWHR
05h
C1
C2
E0h
SR[6]
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Column Address Operations
RANDOM DATA READ TWO-PLANE (06h-E0h)
The RANDOM DATA READ TWO-PLANE (06h-E0h) command enables data output on
the addressed die’s (LUN’s) cache register at the specified column address. This command is accepted by a die (LUN) when it is ready (RDY = 1; ARDY = 1).
Writing 06h to the command register, followed by two column address cycles and three
row address cycles, followed by E0h, enables data output mode on the address LUN’s
cache register at the specified column address. After the E0h command cycle is issued,
the host must wait at least tWHR before requesting data output. The selected die (LUN)
stays in data output mode until another valid command is issued.
Following a two-plane read page operation, the RANDOM DATA READ TWO-PLANE
(06h-E0h) command is used to select the cache register to be enabled for data output.
After data output is complete on the selected plane, the command can be issued again
to begin data output on another plane.
In devices with more than one die (LUN) per target, after all of the die (LUNs) on the
target are ready (RDY = 1), the RANDOM DATA READ TWO-PLANE (06h-E0h) command
can be used following an interleaved die (multi-LUN) read operation. Die (LUNs) that
are not addressed are deselected to avoid bus contention.
In devices with more than one die (LUN) per target, during interleaved die (multi-LUN)
operations where more than one or more die (LUNs) are busy (RDY = 1; ARDY = 0 or
RDY = 0; ARDY = 0), the READ STATUS ENHANCED (78h) command must be issued to
the die (LUN) to be selected prior to issuing the RANDOM DATA READ TWO-PLANE
(06h-E0h). In this situation, using the RANDOM DATA READ TWO-PLANE (06h-E0h)
command without the READ STATUS ENHANCED (78h) command will result in bus
contention, as two or more die (LUNs) could output data.
If there is a need to update the column address without selecting a new cache register
or LUN, the RANDOM DATA READ (05h-E0h) command can be used instead.
Figure 36: RANDOM DATA READ TWO-PLANE (06h-E0h) Operation
Cycle
type
DOUT
DOUT
Command
Address
Address
Address
Address
Address
Command
tRHW
I/O[7:0]
Dn
Dn + 1
DOUT
DOUT
DOUT
Dk
Dk + 1
Dk + 2
tWHR
06h
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C1
C2
R1
R2
62
R3
E0h
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Column Address Operations
RANDOM DATA INPUT (85h)
The RANDOM DATA INPUT (85h) command changes the column address of the selected cache register and enables data input on the last-selected die (LUN). This command
is accepted by the selected die (LUN) when it is ready (RDY = 1; ARDY = 1). It is also accepted by the selected die (LUN) during cache program operations
(RDY = 1; ARDY = 0).
Writing 85h to the command register, followed by two column address cycles containing
the column address, puts the selected die (LUN) into data input mode. After the second
address cycle is issued, the host must wait at least tADL before inputting data. The selected die (LUN) stays in data input mode until another valid command is issued.
Though data input mode is enabled, data input from the host is optional. Data input
begins at the column address specified.
The RANDOM DATA INPUT (85h) command is allowed after the required address cycles
are specified, but prior to the final command cycle (10h, 11h, 15h) of the following commands while data input is permitted: PROGRAM PAGE (80h-10h), PROGRAM PAGE
CACHE (80h-15h), PROGRAM FOR INTERNAL DATA MOVE (85h-10h), and PROGRAM
FOR TWO-PLANE INTERNAL DATA MOVE (85h-11h).
In devices that have more than one die (LUN) per target, the RANDOM DATA INPUT
(85h) command can be used with other commands that support interleaved die (multiLUN) operations.
Figure 37: RANDOM DATA INPUT (85h) Operation
As defined for PAGE
(CACHE) PROGRAM
Cycle type
DIN
DIN
As defined for PAGE
(CACHE) PROGRAM
Command
Address
Address
DIN
DIN
DIN
Dk
Dk + 1
Dk + 2
tADL
I/O[7:0]
Dn
Dn + 1
85h
C1
C2
RDY
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Column Address Operations
PROGRAM FOR INTERNAL DATA INPUT (85h)
The PROGRAM FOR INTERNAL DATA INPUT (85h) command changes the row address
(block and page) where the cache register contents will be programmed in the NAND
Flash array. It also changes the column address of the selected cache register and enables data input on the specified die (LUN). This command is accepted by the selected
die (LUN) when it is ready (RDY = 1; ARDY = 1). It is also accepted by the selected die
(LUN) during cache programming operations (RDY = 1; ARDY = 0).
Write 85h to the command register. Then write two column address cycles and three
row address cycles. This updates the page and block destination of the selected device
for the addressed LUN and puts the cache register into data input mode. After the fifth
address cycle is issued the host must wait at least tADL before inputting data. The selected LUN stays in data input mode until another valid command is issued. Though data
input mode is enabled, data input from the host is optional. Data input begins at the
column address specified.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command is allowed after the required address cycles are specified, but prior to the final command cycle (10h, 11h, 15h)
of the following commands while data input is permitted: PROGRAM PAGE (80h-10h),
PROGRAM PAGE TWO-PLANE (80h-11h), PROGRAM PAGE CACHE (80h-15h), PROGRAM FOR INTERNAL DATA MOVE (85h-10h), and PROGRAM FOR TWO-PLANE INTERNAL DATA MOVE (85h-11h). When used with these commands, the LUN address
and plane select bits are required to be identical to the LUN address and plane select
bits originally specified.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command enables the host to modify the original page and block address for the data in the cache register to a new page
and block address.
In devices that have more than one die (LUN) per target, the PROGRAM FOR INTERNAL
DATA INPUT (85h) command can be used with other commands that support interleaved die (multi-LUN) operations.
The PROGRAM FOR INTERNAL DATA INPUT (85h) command can be used with the
RANDOM DATA READ (05h-E0h) or RANDOM DATA READ TWO-PLANE (06h-E0h)
commands to read and modify cache register contents in small sections prior to programming cache register contents to the NAND Flash array. This capability can reduce
the amount of buffer memory used in the host controller.
The RANDOM DATA INPUT (85h) command can be used during the PROGRAM FOR
INTERNAL DATA MOVE command sequence to modify one or more bytes of the original data. First, data is copied into the cache register using the 00h-35h command sequence, then the RANDOM DATA INPUT (85h) command is written along with the address of the data to be modified next. New data is input on the external data pins. This
copies the new data into the cache register.
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Column Address Operations
Figure 38: PROGRAM FOR INTERNAL DATA INPUT (85h) Operation
Cycle type
DIN
DIN
Command
Address
Address
Address
Address
Address
Command
DIN
DIN
DIN
Dk
Dk + 1
Dk + 2
tADL
I/O[7:0]
Dn
Dn + 1
85h
C1
C2
R1
R2
R3
10h
RDY
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Read Operations
Read Operations
The READ PAGE (00h-30h) command, when issued by itself, reads one page from the
NAND Flash array to its cache register and enables data output for that cache register.
During data output the following commands can be used to read and modify the data in
the cache registers: RANDOM DATA READ (05h-E0h) and RANDOM DATA INPUT (85h).
Read Cache Operations
To increase data throughput, the READ PAGE CACHE series (31h, 00h-31h) commands
can be used to output data from the cache register while concurrently copying a page
from the NAND Flash array to the data register.
To begin a read page cache sequence, begin by reading a page from the NAND Flash array to its corresponding cache register using the READ PAGE (00h-30h) command.
R/B# goes LOW during tR and the selected die (LUN) is busy (RDY = 0, ARDY = 0). After
tR (R/B# is HIGH and RDY = 1, ARDY = 1), issue either of these commands:
• READ PAGE CACHE SEQUENTIAL (31h) – copies the next sequential page from the
NAND Flash array to the data register
• READ PAGE CACHE RANDOM (00h-31h) – copies the page specified in this command
from the NAND Flash array to its corresponding data register
After the READ PAGE CACHE series (31h, 00h-31h) command has been issued, R/B#
goes LOW on the target, and RDY = 0 and ARDY = 0 on the die (LUN) for tRCBSY while
the next page begins copying data from the array to the data register. After tRCBSY,
R/B# goes HIGH and the die’s (LUN’s) status register bits indicate the device is busy
with a cache operation (RDY = 1, ARDY = 0). The cache register becomes available and
the page requested in the READ PAGE CACHE operation is transferred to the data register. At this point, data can be output from the cache register, beginning at column address 0. The RANDOM DATA READ (05h-E0h) command can be used to change the column address of the data output by the die (LUN).
After outputting the desired number of bytes from the cache register, either an additional READ PAGE CACHE series (31h, 00h-31h) operation can be started or the READ
PAGE CACHE LAST (3Fh) command can be issued.
If the READ PAGE CACHE LAST (3Fh) command is issued, R/B# goes LOW on the target,
and RDY = 0 and ARDY = 0 on the die (LUN) for tRCBSY while the data register is copied
into the cache register. After tRCBSY, R/B# goes HIGH and RDY = 1 and
ARDY = 1, indicating that the cache register is available and that the die (LUN) is ready.
Data can then be output from the cache register, beginning at column address 0. The
RANDOM DATA READ (05h-E0h) command can be used to change the column address
of the data being output.
For READ PAGE CACHE series (31h, 00h-31h, 3Fh), during the die (LUN) busy time,
tRCBSY, when RDY = 0 and ARDY = 0, the only valid commands are status operations
(70h, 78h) and RESET (FFh). When RDY = 1 and ARDY = 0, the only valid commands
during READ PAGE CACHE series (31h, 00h-31h) operations are status operations (70h,
78h), READ MODE (00h), READ PAGE CACHE series (31h, 00h-31h), RANDOM DATA
READ (05h-E0h), and RESET (FFh).
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Read Operations
Two-Plane Read Operations
Two-plane read page operations improve data throughput by copying data from more
than one plane simultaneously to the specified cache registers. This is done by prepending one or more READ PAGE TWO-PLANE (00h-00h-30h) commands in front of
the READ PAGE (00h-30h) command.
When the die (LUN) is ready, the RANDOM DATA READ TWO-PLANE (06h-E0h) command determines which plane outputs data. During data output, the following commands can be used to read and modify the data in the cache registers: RANDOM DATA
READ (05h-E0h) and RANDOM DATA INPUT (85h).
Two-Plane Read Cache Operations
Two-plane read cache operations can be used to output data from more than one cache
register while concurrently copying one or more pages from the NAND Flash array to
the data register. This is done by prepending READ PAGE TWO-PLANE (00h-00h-30h)
commands in front of the PAGE READ CACHE RANDOM (00h-31h) command.
To begin a two-plane read page cache sequence, begin by issuing a READ PAGE TWOPLANE operation using the READ PAGE TWO-PLANE (00h-00h-30h) and READ PAGE
(00h-30h) commands. R/B# goes LOW during tR and the selected die (LUN) is busy
(RDY = 0, ARDY = 0). After tR (R/B# is HIGH and RDY = 1, ARDY = 1), issue either of these
commands:
• READ PAGE CACHE SEQUENTIAL (31h) – copies the next sequential pages from the
previously addressed planes from the NAND Flash array to the data registers.
• READ PAGE TWO-PLANE (00h-00h-30h) [in some cases, followed by READ PAGE
CACHE RANDOM (00h-31h)] – copies the pages specified from the NAND Flash array
to the corresponding data registers.
After the READ PAGE CACHE series (31h, 00h-31h) command has been issued, R/B#
goes LOW on the target, and RDY = 0 and ARDY = 0 on the die (LUN) for tRCBSY while
the next pages begin copying data from the array to the data registers. After tRCBSY,
R/B# goes HIGH and the LUN’s status register bits indicate the device is busy with a
cache operation (RDY = 1, ARDY = 0). The cache registers become available and the pages requested in the READ PAGE CACHE operation are transferred to the data registers.
Issue the RANDOM DATA READ TWO-PLANE (06h-E0h) command to determine which
cache register will output data. After data is output, the RANDOM DATA READ TWOPLANE (06h-E0h) command can be used to output data from other cache registers. After a cache register has been selected, the RANDOM DATA READ (05h-E0h) command
can be used to change the column address of the data output.
After outputting data from the cache registers, either an additional TWO-PLANE READ
CACHE series (31h, 00h-31h) operation can be started or the READ PAGE CACHE LAST
(3Fh) command can be issued.
If the READ PAGE CACHE LAST (3Fh) command is issued, R/B# goes LOW on the target,
and RDY = 0 and ARDY = 0 on the die (LUN) for tRCBSY while the data registers are copied into the cache registers. After tRCBSY, R/B# goes HIGH and RDY = 1 and ARDY = 1,
indicating that the cache registers are available and that the die (LUN) is ready. Issue the
RANDOM DATA READ TWO-PLANE (06h-E0h) command to determine which cache
register will output data. After data is output, the RANDOM DATA READ TWO-PLANE
(06h-E0h) command can be used to output data from other cache registers. After a
cache register has been selected, the RANDOM DATA READ (05h-E0h) command can
be used to change the column address of the data output.
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Read Operations
For READ PAGE CACHE series (31h, 00h-31h, 3Fh), during the die (LUN) busy time,
tRCBSY, when RDY = 0 and ARDY = 0, the only valid commands are status operations
(70h, 78h) and RESET (FFh). When RDY = 1 and ARDY = 0, the only valid commands
during READ PAGE CACHE series (31h, 00h-31h) operations are status operations (70h,
78h), READ MODE (00h), two-plane read cache series (31h, 00h-00h-30h, 00h-31h),
RANDOM DATA READ (06h-E0h, 05h-E0h), and RESET (FFh).
READ MODE (00h)
The READ MODE (00h) command disables status output and enables data output for
the last-selected die (LUN) and cache register after a READ operation (00h-30h,
00h-3Ah, 00h-35h) has been monitored with a status operation (70h, 78h). This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN) during READ PAGE CACHE (31h, 00h-31h) operations
(RDY = 1 and ARDY = 0).
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command
must be used to select only one die (LUN) prior to issuing the READ MODE (00h) command. This prevents bus contention.
READ PAGE (00h-30h)
The READ PAGE (00h–30h) command copies a page from the NAND Flash array to its
respective cache register and enables data output. This command is accepted by the die
(LUN) when it is ready (RDY = 1, ARDY = 1).
To read a page from the NAND Flash array, write the 00h command to the command
register, then write n address cycles to the address registers, and conclude with the 30h
command. The selected die (LUN) will go busy (RDY = 0, ARDY = 0) for tR as data is
transferred.
To determine the progress of the data transfer, the host can monitor the target's R/B#
signal or, alternatively, the status operations (70h, 78h) can be used. If the status operations are used to monitor the LUN's status, when the die (LUN) is ready
(RDY = 1, ARDY = 1), the host disables status output and enables data output by issuing
the READ MODE (00h) command. When the host requests data output, output begins
at the column address specified.
During data output the RANDOM DATA READ (05h-E0h) command can be issued.
When internal ECC is enabled, the READ STATUS (70h) command is required after the
completion of the data transfer (tR_ECC) to determine whether an uncorrectable read
error occured. (tR_ECC is the data transferred with internal ECC enabled.)
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations the READ STATUS ENHANCED (78h) command
must be used to select only one die (LUN) prior to the issue of the READ MODE (00h)
command. This prevents bus contention.
The READ PAGE (00h-30h) command is used as the final command of a two-plane read
operation. It is preceded by one or more READ PAGE TWO-PLANE (00h-00h-30h) commands. Data is transferred from the NAND Flash array for all of the addressed planes to
their respective cache registers. When the die (LUN) is ready
(RDY = 1, ARDY = 1), data output is enabled for the cache register linked to the plane
addressed in the READ PAGE (00h-30h) command. When the host requests data output,
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Read Operations
output begins at the column address last specified in the READ PAGE (00h-30h) command. The RANDOM DATA READ TWO-PLANE (06h-E0h) command is used to enable
data output in the other cache registers.
Figure 39: READ PAGE (00h-30h) Operation
Cycle type
I/O[7:0]
Command
Address
Address
Address
Address
Address
Command
00h
C1
C2
R1
R2
R3
30h
tWB
tR
DOUT
DOUT
DOUT
Dn
Dn+1
Dn+2
tRR
RDY
Figure 40: READ PAGE (00h-30h) Operation with Internal ECC Enabled
tR_ECC
RDY
I/O[7:0]
00h
Address
Address
Address
Address
Address
30h
70h
Status
00h
DOUT (serial access)
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
READ PAGE CACHE SEQUENTIAL (31h)
The READ PAGE CACHE SEQUENTIAL (31h) command reads the next sequential page
within a block into the data register while the previous page is output from the cache
register. This command is accepted by the die (LUN) when it is ready
(RDY = 1, ARDY = 1). It is also accepted by the die (LUN) during READ PAGE CACHE
(31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
To issue this command, write 31h to the command register. After this command is issued, R/B# goes LOW and the die (LUN) is busy (RDY = 0, ARDY = 0) for tRCBSY. After
tRCBSY, R/B# goes HIGH and the die (LUN) is busy with a cache operation
(RDY = 1, ARDY = 0), indicating that the cache register is available and that the specified
page is copying from the NAND Flash array to the data register. At this point, data can
be output from the cache register beginning at column address 0. The RANDOM DATA
READ (05h-E0h) command can be used to change the column address of the data being
output from the cache register.
The READ PAGE CACHE SEQUENTIAL (31h) command can be used to cross block
boundaries. If the READ PAGE CACHE SEQUENTIAL (31h) command is issued after the
last page of a block is read into the data register, the next page read will be the next logical block in which the 31h command was issued. Do not issue the READ PAGE CACHE
SEQUENTIAL (31h) to cross die (LUN) boundaries. Instead, issue the READ PAGE
CACHE LAST (3Fh) command.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Read Operations
Figure 41: READ PAGE CACHE SEQUENTIAL (31h) Operation
Cycle type
I/O[7:0]
Command
Address x5
Command
00h
Page Address M
30h
tWB
Command
31h
tR
RR
tWB
tRCBSY
DOUT
DOUT
DOUT
Command
D0
…
Dn
31h
tWB
tRR
DOUT
D0
tRCBSY
tRR
RDY
Page M
Page M+1
READ PAGE CACHE RANDOM (00h-31h)
The READ PAGE CACHE RANDOM (00h-31h) command reads the specified block and
page into the data register while the previous page is output from the cache register.
This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is
also accepted by the die (LUN) during READ PAGE CACHE (31h, 00h-31h) operations
(RDY = 1 and ARDY = 0).
To issue this command, write 00h to the command register, then write n address cycles
to the address register, and conclude by writing 31h to the command register. The column address in the address specified is ignored. The die (LUN) address must match the
same die (LUN) address as the previous READ PAGE (00h-30h) command or, if applicable, the previous READ PAGE CACHE RANDOM (00h-31h) command.
After this command is issued, R/B# goes LOW and the die (LUN) is busy
(RDY = 0, ARDY = 0) for tRCBSY. After tRCBSY, R/B# goes HIGH and the die (LUN) is busy
with a cache operation (RDY = 1, ARDY = 0), indicating that the cache register is available and that the specified page is copying from the NAND Flash array to the data register. At this point, data can be output from the cache register beginning at column address 0. The RANDOM DATA READ (05h-E0h) command can be used to change the column address of the data being output from the cache register.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations the READ STATUS ENHANCED (78h) command followed by the READ MODE (00h) command must be used to select only one die (LUN)
and prevent bus contention.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Read Operations
Figure 42: READ PAGE CACHE RANDOM (00h-31h) Operation
Cycle type
I/O[7:0]
Command
Address x5
Command
00h
Page Address M
30h
tWB
tR
Command
Address x5
Command
00h
Page Address N
31h
tWB
RR
tRCBSY
DOUT
DOUT
DOUT
Command
D0
…
Dn
00h
tRR
RDY
Page M
1
Cycle type
I/O[7:0]
DOUT
Command
Address x5
Command
Dn
00h
Page Address P
31h
tWB
DOUT
D0
tRCBSY
tRR
RDY
Page N
1
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Read Operations
READ PAGE CACHE LAST (3Fh)
The READ PAGE CACHE LAST (3Fh) command ends the read page cache sequence and
copies a page from the data register to the cache register. This command is accepted by
the die (LUN) when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN)
during READ PAGE CACHE (31h, 00h-31h) operations (RDY = 1 and ARDY = 0).
To issue the READ PAGE CACHE LAST (3Fh) command, write 3Fh to the command register. After this command is issued, R/B# goes LOW and the die (LUN) is busy
(RDY = 0, ARDY = 0) for tRCBSY. After tRCBSY, R/B# goes HIGH and the die (LUN) is
ready (RDY = 1, ARDY = 1). At this point, data can be output from the cache register, beginning at column address 0. The RANDOM DATA READ (05h-E0h) command can be
used to change the column address of the data being output from the cache register.
In devices that have more than one LUN per target, during and following interleaved die
(multi-LUN) operations the READ STATUS ENHANCED (78h) command followed by
the READ MODE (00h) command must be used to select only one die (LUN) and prevent bus contention.
Figure 43: READ PAGE CACHE LAST (3Fh) Operation
As defined for
READ PAGE CACHE
(SEQUENTIAL OR RANDOM)
Cycle type
I/O[7:0]
Command
31h
tWB
tRCBSY
DOUT
DOUT
DOUT
Command
D0
…
Dn
3Fh
tRR
tWB
tRCBSY
DOUT
DOUT
DOUT
D0
…
Dn
tRR
RDY
Page Address N
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Read Operations
READ PAGE TWO-PLANE 00h-00h-30h
The READ PAGE TWO-PLANE (00h-00h-30h) operation is similar to the PAGE READ
(00h-30h) operation. It transfers two pages of data from the NAND Flash array to the data registers. Each page must be from a different plane on the same die.
To enter the READ PAGE TWO-PLANE mode, write the 00h command to the command
register, and then write five address cycles for plane 0 (BA6 = 0). Next, write the 00h
command to the command register, and five address cycles for plane 1 (BA6 = 1). Finally, issue the 30h command. The first-plane and second-plane addresses must meet the
two-plane addressing requirements, and, in addition, they must have identical column
addresses.
After the 30h command is written, page data is transferred from both planes to their respective data registers in tR. During these transfers, R/B# goes LOW. When the transfers
are complete, R/B# goes HIGH. To read out the data from the plane 0 data register,
pulse RE# repeatedly. After the data cycle from the plane 0 address completes, issue a
RANDOM DATA READ TWO-PLANE (06h-E0h) command to select the plane 1 address,
then repeatedly pulse RE# to read out the data from the plane 1 data register.
Alternatively, the READ STATUS (70h) command can monitor data transfers. When the
transfers are complete, status register bit 6 is set to 1. To read data from the first of the
two planes, the user must first issue the RANDOM DATA READ TWO-PLANE (06h-E0h)
command and pulse RE# repeatedly.
When the data cycle is complete, issue a RANDOM DATA READ TWO-PLANE (06h-E0h)
command to select the other plane. To output the data beginning at the specified column address, pulse RE# repeatedly.
Use of the READ STATUS ENHANCED (78h) command is prohibited during and following a PAGE READ TWO-PLANE operation.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Read Operations
Figure 44: READ PAGE TWO-PLANE (00h-00h-30h) Operation
CLE
WE#
ALE
RE#
Page address M
00h
I/Ox
Col
add 1
Col
add 2
Row
add 1
Column address J
Row
add 2
Page address M
Row
add 3
Col
add 1
00h
Col
add 2
Row
add 1
Column address J
Plane 0 address
Row
add 2
Row
add 3
30h
tR
Plane 1 address
R/B#
1
CLE
WE#
ALE
RE#
I/Ox
DOUT 0
DOUT 1
DOUT
06h
Col
add 1
Col
add 2
Row
add 1
Plane 0 data
Row
add 2
Row
add 3
Plane 1 address
E0h
DOUT 0
DOUT 1
DOUT
Plane 1 data
R/B#
1
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Program Operations
Program Operations
Program operations are used to move data from the cache or data registers to the NAND
array. During a program operation the contents of the cache and/or data registers are
modified by the internal control logic.
Within a block, pages must be programmed sequentially from the least significant page
address to the most significant page address (0, 1, 2, ….., 63). During a program operation, the contents of the cache and/or data registers are modified by the internal control
logic.
Program Operations
The PROGRAM PAGE (80h-10h) command, when not preceded by the PROGRAM PAGE
TWO-PLANE (80h-11h) command, programs one page from the cache register to the
NAND Flash array. When the die (LUN) is ready (RDY = 1, ARDY = 1), the host should
check the FAIL bit to verify that the operation has completed successfully.
Program Cache Operations
The PROGRAM PAGE CACHE (80h-15h) command can be used to improve program operation system performance. When this command is issued, the die (LUN) goes busy
(RDY = 0, ARDY = 0) while the cache register contents are copied to the data register,
and the die (LUN) is busy with a program cache operation (RDY = 1, ARDY = 0. While
the contents of the data register are moved to the NAND Flash array, the cache register
is available for an additional PROGRAM PAGE CACHE (80h-15h) or PROGRAM PAGE
(80h-10h) command.
For PROGRAM PAGE CACHE series (80h-15h) operations, during the die (LUN) busy
times, tCBSY and tLPROG, when RDY = 0 and ARDY = 0, the only valid commands are
status operations (70h, 78h) and reset (FFh). When RDY = 1 and ARDY = 0, the only valid
commands during PROGRAM PAGE CACHE series (80h-15h) operations are status operations (70h, 78h), PROGRAM PAGE CACHE (80h-15h), PROGRAM PAGE (80h-10h),
RANDOM DATA INPUT (85h), PROGRAM FOR INTERNAL DATA INPUT (85h), and RESET (FFh).
Two-Plane Program Operations
The PROGRAM PAGE TWO-PLANE (80h-11h) command can be used to improve program operation system performance by enabling multiple pages to be moved from the
cache registers to different planes of the NAND Flash array. This is done by prepending
one or more PROGRAM PAGE TWO-PLANE (80h-11h) commands in front of the PROGRAM PAGE (80h-10h) command.
Two-Plane Program Cache Operations
The PROGRAM PAGE TWO-PLANE (80h-11h) command can be used to improve program cache operation system performance by enabling multiple pages to be moved
from the cache registers to the data registers and, while the pages are being transferred
from the data registers to different planes of the NAND Flash array, free the cache registers to receive data input from the host. This is done by prepending one or more PROGRAM PAGE TWO-PLANE (80h-11h) commands in front of the PROGRAM PAGE
CACHE (80h-15h) command.
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Program Operations
PROGRAM PAGE (80h-10h)
The PROGRAM PAGE (80h-10h) command enables the host to input data to a cache register, and moves the data from the cache register to the specified block and page address in the array of the selected die (LUN). This command is accepted by the die (LUN)
when it is ready (RDY = 1, ARDY = 1). It is also accepted by the die (LUN) when it is busy
with a PROGRAM PAGE CACHE (80h-15h) operation (RDY = 1, ARDY = 0).
To input a page to the cache register and move it to the NAND array at the block and
page address specified, write 80h to the command register. Unless this command has
been preceded by a PROGRAM PAGE TWO-PLANE (80h-11h) command, issuing the 80h
to the command register clears all of the cache registers' contents on the selected target.
Then write n address cycles containing the column address and row address. Data input
cycles follow. Serial data is input beginning at the column address specified. At any time
during the data input cycle the RANDOM DATA INPUT (85h) and PROGRAM FOR INTERNAL DATA INPUT (85h) commands may be issued. When data input is complete,
write 10h to the command register. The selected LUN will go busy
(RDY = 0, ARDY = 0) for tPROG as data is transferred.
To determine the progress of the data transfer, the host can monitor the target's R/B#
signal or, alternatively, the status operations (70h, 78h) may be used. When the die
(LUN) is ready (RDY = 1, ARDY = 1), the host should check the status of the FAIL bit.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command
must be used to select only one die (LUN) for status output. Use of the READ STATUS
(70h) command could cause more than one die (LUN) to respond, resulting in bus contention.
The PROGRAM PAGE (80h-10h) command is used as the final command of a two-plane
program operation. It is preceded by one or more PROGRAM PAGE TWO-PLANE
(80h-11h) commands. Data is transferred from the cache registers for all of the addressed planes to the NAND array. The host should check the status of the operation by
using the status operations (70h, 78h).
When internal ECC is enabled, the duration of array programming time is tPROG_ECC.
During tPROG_ECC, the internal ECC generates parity bits when error detection is complete.
Figure 45: PROGRAM PAGE (80h-10h) Operation
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
DIN
Command
D0
D1
…
Dn
10h
Command
DOUT
70h
Status
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tPROG
tWB
or
tPROG_ECC
RDY
PROGRAM PAGE CACHE (80h-15h)
The PROGRAM PAGE CACHE (80h-15h) command enables the host to input data to a
cache register; copies the data from the cache register to the data register; then moves
the data register contents to the specified block and page address in the array of the selected die (LUN). After the data is copied to the data register, the cache register is availa-
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Program Operations
ble for additional PROGRAM PAGE CACHE (80h-15h) or PROGRAM PAGE (80h-10h)
commands. The PROGRAM PAGE CACHE (80h-15h) command is accepted by the die
(LUN) when it is ready (RDY =1, ARDY = 1). It is also accepted by the die (LUN) when
busy with a PROGRAM PAGE CACHE (80h-15h) operation (RDY = 1, ARDY = 0).
To input a page to the cache register to move it to the NAND array at the block and page
address specified, write 80h to the command register. Unless this command has been
preceded by a PROGRAM PAGE TWO-PLANE (80h-11h) command, issuing the 80h to
the command register clears all of the cache registers' contents on the selected target.
Then write n address cycles containing the column address and row address. Data input
cycles follow. Serial data is input beginning at the column address specified. At any time
during the data input cycle the RANDOM DATA INPUT (85h) and PROGRAM FOR INTERNAL DATA INPUT (85h) commands may be issued. When data input is complete,
write 15h to the command register. The selected LUN will go busy
(RDY = 0, ARDY = 0) for tCBSY to allow the data register to become available from a previous program cache operation, to copy data from the cache register to the data register,
and then to begin moving the data register contents to the specified page and block address.
To determine the progress of tCBSY, the host can monitor the target's R/B# signal or, alternatively, the status operations (70h, 78h) can be used. When the LUN’s status shows
that it is busy with a PROGRAM CACHE operation (RDY = 1, ARDY = 0), the host should
check the status of the FAILC bit to see if a previous cache operation was successful.
If, after tCBSY, the host wants to wait for the program cache operation to complete,
without issuing the PROGRAM PAGE (80h-10h) command, the host should monitor ARDY until it is 1. The host should then check the status of the FAIL and FAILC bits.
In devices with more than one die (LUN) per target, during and following interleaved
die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command must be
used to select only one die (LUN) for status output. Use of the READ STATUS (70h) command could cause more than one die (LUN) to respond, resulting in bus contention.
The PROGRAM PAGE CACHE (80h-15h) command is used as the final command of a
two-plane program cache operation. It is preceded by one or more PROGRAM PAGE
TWO-PLANE (80h-11h) commands. Data for all of the addressed planes is transferred
from the cache registers to the corresponding data registers, then moved to the NAND
Flash array. The host should check the status of the operation by using the status operations (70h, 78h).
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Program Operations
Figure 46: PROGRAM PAGE CACHE (80h–15h) Operation (Start)
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
DIN
Command
D0
D1
…
Dn
15h
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tWB
tCBSY
RDY
1
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
DIN
Command
D0
D1
…
Dn
15h
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tWB
tCBSY
RDY
1
Figure 47: PROGRAM PAGE CACHE (80h–15h) Operation (End)
As defined for
PAGE CACHE PROGRAM
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
DIN
Command
D0
D1
…
Dn
15h
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tWB
tCBSY
RDY
1
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
DIN
Command
D0
D1
…
Dn
10h
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tWB
tLPROG
RDY
1
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Program Operations
PROGRAM PAGE TWO-PLANE (80h-11h)
The PROGRAM PAGE TWO-PLANE (80h-11h) command enables the host to input data
to the addressed plane's cache register and queue the cache register to ultimately be
moved to the NAND Flash array. This command can be issued one or more times. Each
time a new plane address is specified that plane is also queued for data transfer. To input data for the final plane and to begin the program operation for all previously
queued planes, issue either the PROGRAM PAGE (80h-10h) command or the PROGRAM
PAGE CACHE (80h-15h) command. All of the queued planes will move the data to the
NAND Flash array. This command is accepted by the die (LUN) when it is ready
(RDY = 1).
To input a page to the cache register and queue it to be moved to the NAND Flash array
at the block and page address specified, write 80h to the command register. Unless this
command has been preceded by a PROGRAM PAGE TWO-PLANE (80h-11h) command,
issuing the 80h to the command register clears all of the cache registers' contents on the
selected target. Write five address cycles containing the column address and row address; data input cycles follow. Serial data is input beginning at the column address
specified. At any time during the data input cycle, the RANDOM DATA INPUT (85h) and
PROGRAM FOR INTERNAL DATA INPUT (85h) commands can be issued. When data
input is complete, write 11h to the command register. The selected die (LUN) will go
busy (RDY = 0, ARDY = 0) for tDBSY.
To determine the progress of tDBSY, the host can monitor the target's R/B# signal or,
alternatively, the status operations (70h, 78h) can be used. When the LUN's status
shows that it is ready (RDY = 1), additional PROGRAM PAGE TWO-PLANE (80h-11h)
commands can be issued to queue additional planes for data transfer. Alternatively, the
PROGRAM PAGE (80h-10h) or PROGRAM PAGE CACHE (80h-15h) commands can be issued.
When the PROGRAM PAGE (80h-10h) command is used as the final command of a twoplane program operation, data is transferred from the cache registers to the NAND
Flash array for all of the addressed planes during tPROG. When the die (LUN) is ready
(RDY = 1, ARDY = 1), the host should check the status of the FAIL bit for each of the
planes to verify that programming completed successfully.
When the PROGRAM PAGE CACHE (80h-15h) command is used as the final command
of a program cache two-plane operation, data is transferred from the cache registers to
the data registers after the previous array operations finish. The data is then moved
from the data registers to the NAND Flash array for all of the addressed planes. This occurs during tCBSY. After tCBSY, the host should check the status of the FAILC bit for
each of the planes from the previous program cache operation, if any, to verify that programming completed successfully.
For the PROGRAM PAGE TWO-PLANE (80h-11h), PROGRAM PAGE (80h-10h), and PROGRAM PAGE CACHE (80h-15h) commands, see Two-Plane Operations for two-plane addressing requirements.
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Program Operations
Figure 48: PROGRAM PAGE TWO-PLANE (80h–11h) Operation
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
Command
Command
Address
D0
…
Dn
11h
80h
...
tADL
I/O[7:0]
80h
C1
C2
R1
R2
R3
tWB tDBSY
RDY
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Erase Operations
Erase Operations
Erase operations are used to clear the contents of a block in the NAND Flash array to
prepare its pages for program operations.
Erase Operations
The ERASE BLOCK (60h-D0h) command, when not preceded by the ERASE BLOCK
TWO-PLANE (60h-D1h) command, erases one block in the NAND Flash array. When the
die (LUN) is ready (RDY = 1, ARDY = 1), the host should check the FAIL bit to verify that
this operation completed successfully.
TWO-PLANE ERASE Operations
The ERASE BLOCK TWO-PLANE (60h-D1h) command can be used to further system
performance of erase operations by allowing more than one block to be erased in the
NAND array. This is done by prepending one or more ERASE BLOCK TWO-PLANE (60hD1h) commands in front of the ERASE BLOCK (60h-D0h) command. See Two-Plane
Operations for details.
ERASE BLOCK (60h-D0h)
The ERASE BLOCK (60h-D0h) command erases the specified block in the NAND Flash
array. This command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1).
To erase a block, write 60h to the command register. Then write three address cycles
containing the row address; the page address is ignored. Conclude by writing D0h to the
command register. The selected die (LUN) will go busy (RDY = 0, ARDY = 0) for tBERS
while the block is erased.
To determine the progress of an ERASE operation, the host can monitor the target's
R/B# signal, or alternatively, the status operations (70h, 78h) can be used. When the die
(LUN) is ready (RDY = 1, ARDY = 1) the host should check the status of the FAIL bit.
In devices that have more than one die (LUN) per target, during and following interleaved die (multi-LUN) operations, the READ STATUS ENHANCED (78h) command
must be used to select only one die (LUN) for status output. Use of the READ STATUS
(70h) command could cause more than one die (LUN) to respond, resulting in bus contention.
The ERASE BLOCK (60h-D0h) command is used as the final command of an erase twoplane operation. It is preceded by one or more ERASE BLOCK TWO-PLANE (60h-D1h)
commands. All blocks in the addressed planes are erased. The host should check the
status of the operation by using the status operations (70h, 78h). See Two-Plane Operations for two-plane addressing requirements.
Figure 49: ERASE BLOCK (60h-D0h) Operation
Cycle type
I/O[7:0]
Command
Address
Address
Address
Command
60h
R1
R2
R3
D0h
tWB
tBERS
RDY
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Erase Operations
ERASE BLOCK TWO-PLANE (60h-D1h)
The ERASE BLOCK TWO-PLANE (60h-D1h) command queues a block in the specified
plane to be erased in the NAND Flash array. This command can be issued one or more
times. Each time a new plane address is specified, that plane is also queued for a block
to be erased. To specify the final block to be erased and to begin the ERASE operation
for all previously queued planes, issue the ERASE BLOCK (60h-D0h) command. This
command is accepted by the die (LUN) when it is ready (RDY = 1, ARDY = 1).
To queue a block to be erased, write 60h to the command register, then write three address cycles containing the row address; the page address is ignored. Conclude by writing D1h to the command register. The selected die (LUN) will go busy (RDY = 0, ARDY =
0) for tDBSY.
To determine the progress of tDBSY, the host can monitor the target's R/B# signal, or
alternatively, the status operations (70h, 78h) can be used. When the LUN's status
shows that it is ready (RDY = 1, ARDY = 1), additional ERASE BLOCK TWO-PLANE (60hD1h) commands can be issued to queue additional planes for erase. Alternatively, the
ERASE BLOCK (60h-D0h) command can be issued to erase all of the queued blocks.
For two-plane addressing requirements for the ERASE BLOCK TWO-PLANE (60h-D1h)
and ERASE BLOCK (60h-D0h) commands, see Two-Plane Operations.
Figure 50: ERASE BLOCK TWO-PLANE (60h–D1h) Operation
Cycle type
I/O[7:0]
Command
Address
Address
Address
Command
60h
R1
R2
R3
D1h
tWB
Command
Address
60h
...
tDBSY
RDY
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Internal Data Move Operations
Internal Data Move Operations
Internal data move operations make it possible to transfer data within a device from
one page to another using the cache register. This is particularly useful for block management and wear leveling.
The INTERNAL DATA MOVE operation is a two-step process consisting of a READ FOR
INTERNAL DATA MOVE (00h-35h) and a PROGRAM FOR INTERNAL DATA MOVE
(85h-10h) command. To move data from one page to another on the same plane, first
issue the READ FOR INTERNAL DATA MOVE (00h-35h) command. When the die (LUN)
is ready (RDY = 1, ARDY = 1), the host can transfer the data to a new page by issuing the
PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command. When the die (LUN) is
again ready (RDY = 1, ARDY = 1), the host should check the FAIL bit to verify that this
operation completed successfully.
To prevent bit errors from accumulating over multiple INTERNAL DATA MOVE operations, it is recommended that the host read the data out of the cache register after the
READ FOR INTERNAL DATA MOVE (00h-35h) completes and prior to issuing the PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command. The RANDOM DATA READ
(05h-E0h) command can be used to change the column address. The host should check
the data for ECC errors and correct them. When the PROGRAM FOR INTERNAL DATA
MOVE (85h-10h) command is issued, any corrected data can be input. The PROGRAM
FOR INTERNAL DATA INPUT (85h) command can be used to change the column address.
It is not possible to use the READ FOR INTERNAL DATA MOVE operation to move data
from one plane to another or from one die (LUN) to another. Instead, use a READ PAGE
(00h-30h) or READ FOR INTERNAL DATA MOVE (00h-35h) command to read the data
out of the NAND, and then use a PROGRAM PAGE (80h-10h) command with data input
to program the data to a new plane or die (LUN).
Between the READ FOR INTERNAL DATA MOVE (00h-35h) and PROGRAM FOR INTERNAL DATA MOVE (85h-10h) commands, the following commands are supported: status
operations (70h, 78h) and column address operations (05h-E0h, 06h-E0h, 85h). The RESET operation (FFh) can be issued after READ FOR INTERNAL DATA MOVE (00h-35h),
but the contents of the cache registers on the target are not valid.
In devices that have more than one die (LUN) per target, once the READ FOR INTERNAL DATA MOVE (00h-35h) is issued, interleaved die (multi-LUN) operations are prohibited until after the PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command is
issued.
Two-Plane Read for Internal Data Move Operations
Two-plane internal data move read operations improve read data throughput by copying data simultaneously from more than one plane to the specified cache registers. This
is done by issuing the READ PAGE TWO-PLANE (00h-00h-30h) command or the READ
FOR INTERNAL DATA MOVE (00h-00h-35h) command.
The INTERNAL DATA MOVE PROGRAM TWO-PLANE (85h-11h) command can be used
to further system performance of PROGRAM FOR INTERNAL DATA MOVE operations
by enabling movement of multiple pages from the cache registers to different planes of
the NAND Flash array. This is done by prepending one or more PROGRAM FOR INTERNAL DATA MOVE (85h-11h) commands in front of the PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command. See Two-Plane Operations for details.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Internal Data Move Operations
READ FOR INTERNAL DATA MOVE (00h-35h)
The READ FOR INTERNAL DATA MOVE (00h-35h) command is functionally identical to
the READ PAGE (00h-30h) command, except that 35h is written to the command register instead of 30h.
Though it is not required, it is recommended that the host read the data out of the device to verify the data prior to issuing the PROGRAM FOR INTERNAL DATA MOVE
(85h-10h) command to prevent the propagation of data errors.
If internal ECC is enabled, the data does not need to be toggled out by the host to be
corrected and moving data can then be written to a new page without data reloading,
which improves system performance.
Figure 51: READ FOR INTERNAL DATA MOVE (00h-35h) Operation
Cycle type
Command
Address
Address
Address
Address
Address
Command
00h
C1
C2
R1
R2
R3
35h
I/O[7:0]
tWB
tR
DOUT
DOUT
DOUT
Dn
Dn+1
Dn+2
tRR
RDY
Figure 52: READ FOR INTERNAL DATA MOVE (00h–35h) with RANDOM DATA READ (05h–E0h)
Cycle type
I/O[7:0]
Command
Address
Address
Address
Address
Address
Command
00h
C1
C2
R1
R2
R3
35h
tWB
tR
DOUT
DOUT
DOUT
D0
…
Dj + n
tRR
RDY
1
Cycle type
Command
Address
Address
Command
DOUT
DOUT
DOUT
Dk
Dk + 1
Dk + 2
tWHR
I/O[7:0]
05h
C1
C2
E0h
RDY
1
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Internal Data Move Operations
Figure 53: INTERNAL DATA MOVE (85h-10h) with Internal ECC Enabled
tR_ECC
tPROG_ECC
R/B#
I/O[7:0]
00h
Address
(5 cycles)
35h
70h
Source address
Status
DOUT
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
85h
Address
(5 cycles)
10h
70h
Destination address
DOUT is optional
Status
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
Figure 54: INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT with Internal ECC Enabled
tR_ECC
tPROG_ECC
R/B#
I/O[7:0]
00h
Address
(5 cycles)
35h
Source address
70h
Status
DOUT
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
Address
(5 cycles) Data 85h
85h
DOUT is optional
Address
(2 cycles) Data 10h
70h
Destination address
Column address 1, 2
(Unlimitted repetitions are possible)
PROGRAM FOR INTERNAL DATA MOVE (85h–10h)
The PROGRAM FOR INTERNAL DATA MOVE (85h-10h) command is functionally identical to the PROGRAM PAGE (80h-10h) command, except that when 85h is written to the
command register, cache register contents are not cleared.
Figure 55: PROGRAM FOR INTERNAL DATA MOVE (85h–10h) Operation
Cycle type
I/O[7:0]
Command
Address
Address
Address
Address
Address
Command
85h
C1
C2
R1
R2
R3
10h
tWB
tPROG
RDY
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Internal Data Move Operations
Figure 56: PROGRAM FOR INTERNAL DATA MOVE (85h-10h) with RANDOM DATA INPUT (85h)
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
Di
Di + 1
tWHR
I/O[7:0]
85h
C1
C2
R1
R2
R3
RDY
1
Cycle type
Command
Address
Address
DIN
DIN
DIN
Command
Dj
Dj + 1
Dj + 2
10h
tWHR
I/O[7:0]
85h
C1
C2
tWB
tPROG
RDY
1
PROGRAM FOR INTERNAL DATA MOVE TWO-PLANE (85h-11h)
The PROGRAM FOR INTERNAL DATA MOVE TWO-PLANE (85h-11h) command is functionally identical to the PROGRAM PAGE TWO-PLANE (85h-11h) command, except that
when 85h is written to the command register, cache register contents are not cleared.
See Program Operations for further details.
Figure 57: PROGRAM FOR INTERNAL DATA MOVE TWO-PLANE (85h-11h) Operation
Cycle type
Command
Address
Address
Address
Address
Address
DIN
DIN
DIN
Command
Command
Address
D0
…
Dn
11h
85h
...
tADL
I/O[7:0]
85h
C1
C2
R1
R2
R3
tWB tDBSY
RDY
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Block Lock Feature
Block Lock Feature
The block lock feature protects either the entire device or ranges of blocks from being
programmed and erased. Using the block lock feature is preferable to using WP# to prevent PROGRAM and ERASE operations.
Block lock is enabled and disabled at power-on through the LOCK pin. At power-on, if
LOCK is LOW, all BLOCK LOCK commands are disabled. However if LOCK is HIGH at
power-on, the BLOCK LOCK commands are enabled and, by default, all the blocks on
the device are protected, or locked, from PROGRAM and ERASE operations, even if WP#
is HIGH.
Before the contents of the device can be modified, the device must first be unlocked.
Either a range of blocks or the entire device may be unlocked. PROGRAM and ERASE
operations complete successfully only in the block ranges that have been unlocked.
Blocks, once unlocked, can be locked again to protect them from further PROGRAM
and ERASE operations.
Blocks that are locked can be protected further, or locked tight. When locked tight, the
device’s blocks can no longer be locked or unlocked until the device is power cycled.
WP# and Block Lock
The following is true when the block lock feature is enabled:
• Holding WP# LOW locks all blocks, provided the blocks are not locked tight.
• If WP# is held LOW to lock blocks, then returned to HIGH, a new UNLOCK command
must be issued to unlock blocks.
UNLOCK (23h-24h)
By default at power-on, if LOCK is HIGH, all the blocks are locked and protected from
PROGRAM and ERASE operations. The UNLOCK (23h) command is used to unlock a
range of blocks. Unlocked blocks have no protection and can be programmed or erased.
The UNLOCK command uses two registers, a lower boundary block address register and
an upper boundary block address register, and the invert area bit to determine what
range of blocks are unlocked. When the invert area bit = 0, the range of blocks within
the lower and upper boundary address registers are unlocked. When the invert area bit
= 1, the range of blocks outside the boundaries of the lower and upper boundary address registers are unlocked. The lower boundary block address must be less than the
upper boundary block address. The figures below show examples of how the lower and
upper boundary address registers work with the invert area bit.
To unlock a range of blocks, issue the UNLOCK (23h) command followed by the appropriate address cycles that indicate the lower boundary block address. Then issue the
24h command followed by the appropriate address cycles that indicate the upper boundary block address. The least significant page address bit, PA0, should be set to 1 if setting the invert area bit; otherwise, it should be 0. The other page address bits should be
0.
Only one range of blocks can be specified in the lower and upper boundary block address registers. If after unlocking a range of blocks the UNLOCK command is again issued, the new block address range determines which blocks are unlocked. The previous
unlocked block address range is not retained.
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Block Lock Feature
Figure 58: Flash Array Protected: Invert Area Bit = 0
Block 4095
Block 4094
Block 4093
Block 4092
Block 4091
Block 4090
Block 4089
Block 4088
Block. 4087
..
..
..
..
..
..
.
Block 0002
Block 0001
Block 0000
Protected
area
FFCh
Upper block boundary
FF8h
Lower block boundary
Unprotected
area
Protected
area
Figure 59: Flash Array Protected: Invert Area Bit = 1
Block 4095
Block 4094
Block 4093
Block 4092
Block 4091
Block 4090
Block 4089
Block 4088
Block. 4087
..
..
..
..
..
..
.
Block 0002
Block 0001
Block 0000
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Unprotected
Area
FFCh
Upper block boundary
FF8h
Lower block boundary
Protected
area
Unprotected
area
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Block Lock Feature
Table 22: Block Lock Address Cycle Assignments
I/O[15:8]1
I/O7
I/O6
I/O5
I/O4
I/O3
I/O2
I/O1
I/O0
First
LOW
BA7
BA6
LOW
LOW
LOW
LOW
LOW
Invert area bit2
Second
LOW
BA15
BA14
BA13
BA12
BA11
BA10
BA9
BA8
Third
LOW
LOW
LOW
LOW
LOW
LOW
LOW
BA17
BA16
ALE Cycle
Notes:
1. I/O[15:8] is applicable only for x16 devices.
2. Invert area bit is applicable for 24h command; it may be LOW or HIGH for 23h command.
Figure 60: UNLOCK Operation
WP#
CLE
CE#
WE#
ALE
RE#
I/Ox
23h
Unlock
Block
Block
Block
add 1
add 2
add 3
Lower boundary
24h
Block
Block
Block
add 1
add 2
add 3
Upper boundary
R/B#
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Block Lock Feature
LOCK (2Ah)
By default at power-on, if LOCK is HIGH, all the blocks are locked and protected from
PROGRAM and ERASE operations. If portions of the device are unlocked using the UNLOCK (23h) command, they can be locked again using the LOCK (2Ah) command. The
LOCK command locks all of the blocks in the device. Locked blocks are write-protected
from PROGRAM and ERASE operations.
To lock all of the blocks in the device, issue the LOCK (2Ah) command.
When a PROGRAM or ERASE operation is issued to a locked block, R/B# goes LOW for
tLBSY. The PROGRAM or ERASE operation does not complete. Any READ STATUS command reports bit 7 as 0, indicating that the block is protected.
The LOCK (2Ah) command is disabled if LOCK is LOW at power-on or if the device is
locked tight.
Figure 61: LOCK Operation
CLE
CE#
WE#
I/Ox
2Ah
LOCK command
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Block Lock Feature
LOCK TIGHT (2Ch)
The LOCK TIGHT (2Ch) command prevents locked blocks from being unlocked and also prevents unlocked blocks from being locked. When this command is issued, the UNLOCK (23h) and LOCK (2Ah) commands are disabled. This provides an additional level
of protection against inadvertent PROGRAM and ERASE operations to locked blocks.
To implement LOCK TIGHT in all of the locked blocks in the device, verify that WP# is
HIGH and then issue the LOCK TIGHT (2Ch) command.
When a PROGRAM or ERASE operation is issued to a locked block that has also been
locked tight, R/B# goes LOW for tLBSY. The PROGRAM or ERASE operation does not
complete. The READ STATUS (70h) command reports bit 7 as 0, indicating that the
block is protected. PROGRAM and ERASE operations complete successfully to blocks
that were not locked at the time the LOCK TIGHT command was issued.
After the LOCK TIGHT command is issued, the command cannot be disabled via a software command. The only ways to disable the lock tight status is to power cycle the device. When the lock tight status is disabled, all of the blocks become locked, the same as
if the LOCK (2Ah) command had been issued.
The LOCK TIGHT (2Ch) command is disabled if LOCK is LOW at power-on.
Figure 62: LOCK TIGHT Operation
LOCK
WP#
CLE
CE#
WE#
I/Ox
2Ch
LOCK TIGHT
command
R/B#
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Block Lock Feature
Figure 63: PROGRAM/ERASE Issued to Locked Block
t
LBSY
R/B#
I/Ox
PROGRAM or ERASE
Add ress/data input
CONFIRM
70h
Locked block
60h
READ STATUS
BLOCK LOCK READ STATUS (7Ah)
The BLOCK LOCK READ STATUS (7Ah) command is used to determine the protection
status of individual blocks. The address cycles have the same format, as shown below,
and the invert area bit should be set LOW. On the falling edge of RE# the I/O pins output
the block lock status register, which contains the information on the protection status
of the block.
Table 23: Block Lock Status Register Bit Definitions
Block Lock Status Register Definitions
I/O[7:3]
I/O2 (Lock#)
I/O1 (LT#)
I/O0 (LT)
Block is locked tight
X
0
0
1
Block is locked
X
0
1
0
Block is unlocked, and device is locked tight
X
1
0
1
Block is unlocked, and device is not locked tight
X
1
1
0
Figure 64: BLOCK LOCK READ STATUS
CLE
CE#
WE#
tWHR
ALE
RE#
I/Ox
7Ah
BLOCK LOCK
READ STATUS
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Add 1
Add 2
Add 3
Status
Block address
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Block Lock Feature
Figure 65: BLOCK LOCK Flowchart
Power-up
Power-up with
LOCK HIGH
Power-up with
LOCK LOW
(default)
Entire NAND Flash
array locked
BLOCK LOCK function
disabled
LOCK TIGHT Cmd
with WP# and
LOCK HIGH
Entire NAND Flash
array locked tight
UNLOCK Cmd with
invert area bit = 1
UNLOCK Cmd with
invert area bit = 0
WP# LOW
>100ns or
LOCK Cmd
WP# LOW
>100ns or
LOCK Cmd
Unlocked range
Locked range
Locked range
Unlocked range
UNLOCK Cmd with
invert area bit = 0
UNLOCK Cmd with invert area bit = 1
Unlocked range
UNLOCK Cmd
with invert area
bit = 1
UNLOCK Cmd with invert area bit = 0
Locked range
LOCK TIGHT Cmd
with WP# and
LOCK HIGH
LOCK TIGHT Cmd
with WP# and
LOCK HIGH
Unlocked range
Locked tight range
Locked tight range
Unlocked range
Unlocked range
Locked-tight range
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
One-Time Programmable (OTP) Operations
This Micron NAND Flash device offers a protected, one-time programmable NAND
Flash memory area. Thirty full pages (2112 bytes per page) of OTP data are available on
the device, and the entire range is guaranteed to be good. The OTP area is accessible
only through the OTP commands. Customers can use the OTP area any way they
choose; typical uses include programming serial numbers or other data for permanent
storage.
The OTP area leaves the factory in an unwritten state (all bits are 1s). Programming or
partial-page programming enables the user to program only 0 bits in the OTP area. The
OTP area cannot be erased, whether it is protected or not. Protecting the OTP area prevents further programming of that area.
Micron provides a unique way to program and verify data before permanently protecting it and preventing future changes. The OTP area is only accessible while in OTP operation mode. To set the device to OTP operation mode, issue the SET FEATURE (EFh)
command to feature address 90h and write 01h to P1, followed by three cycles of 00h to
P2-P4. For parameters to enter OTP mode, see Features Operations.
When the device is in OTP operation mode, all subsequent PAGE READ (00h-30h) and
PROGRAM PAGE (80h-10h) commands are applied to the OTP area. The OTP area is assigned to page addresses 02h-1Fh. To program an OTP page, issue the PROGRAM PAGE
(80h-10h) command. The pages must be programmed in the ascending order. Similarly,
to read an OTP page, issue the PAGE READ (00h-30h) command.
Protecting the OTP is done by entering OTP protect mode. To set the device to OTP protect mode, issue the SET FEATURE (EFh) command to feature address 90h and write
03h to P1, followed by three cycles of 00h to P2-P4.
To determine whether the device is busy during an OTP operation, either monitor R/B#
or use the READ STATUS (70h) command.
To exit OTP operation or protect mode, write 00h to P1 at feature address 90h.
Legacy OTP Commands
For legacy OTP commands, OTP DATA PROGRAM (A0h-10h), OTP DATA PROTECT
(A5h-10h), and OTP DATA READ (AFh-30h), refer to the MT29F4GxxAxC data sheet.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
OTP DATA PROGRAM (80h-10h)
The OTP DATA PROGRAM (80h-10h) command is used to write data to the pages within
the OTP area. An entire page can be programmed at one time, or a page can be partially
programmed up to eight times. Only the OTP area allows up to eight partial-page programs. The rest of the blocks support only four partial-page programs. There is no
ERASE operation for OTP pages.
PROGRAM PAGE enables programming into an offset of an OTP page using two bytes of
the column address (CA[12:0]). The command is compatible with the RANDOM DATA
INPUT (85h) command. The PROGRAM PAGE command will not execute if the OTP
area has been protected.
To use the PROGRAM PAGE command, issue the 80h command. Issue n address cycles.
The first two address cycles are the column address. For the remaining cycles, select a
page in the range of 02h-00h through 1Fh-00h. Next, write from 1–2112 bytes of data.
After data input is complete, issue the 10h command. The internal control logic automatically executes the proper programming algorithm and controls the necessary timing for programming and verification.
R/B# goes LOW for the duration of the array programming time (tPROG). The READ
STATUS (70h) command is the only valid command for reading status in OTP operation
mode. Bit 5 of the status register reflects the state of R/B#. When the device is ready,
read bit 0 of the status register to determine whether the operation passed or failed (see
Status Operations). Each OTP page can be programmed to 8 partial-page programming.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
RANDOM DATA INPUT (85h)
After the initial OTP data set is input, additional data can be written to a new column
address with the RANDOM DATA INPUT (85h) command. The RANDOM DATA INPUT
command can be used any number of times in the same page prior to the OTP PAGE
WRITE (10h) command being issued.
Figure 66: OTP DATA PROGRAM (After Entering OTP Operation Mode)
CLE
CE#
tWC
WE#
tWB
tPROG
ALE
RE#
I/Ox
Col
add 1
80h
Col
add 2
OTP DATA INPUT
command
OTP
page1
OTP address1
00h
00h
DIN
n
DIN
m
1 up to m bytes
serial input
10h
70h
PROGRAM
command
READ STATUS
command
Status
R/B#
x8 device: m = 2112 bytes
x16 device: m = 1056 words
OTP data written
(following good status confirmation)
Don’t Care
Note:
1. The OTP page must be within the 02h–1Fh range.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
Figure 67: OTP DATA PROGRAM Operation with RANDOM DATA INPUT (After Entering OTP Operation Mode)
CLE
CE#
tWC
tADL
tADL
WE#
tWB
tPROG
ALE
RE#
I/Ox
80h
Col
add1
OTP
Col
add2 page1
00h
00h
SERIAL DATA
INPUT command
DIN
Col
Col
85h
add1 add2
n+1
Serial input RANDOM DATA Column address
INPUT command
DIN
n
DIN
10h
n+1
Serial input
PROGRAM
command
DIN
n
70h
Status
READ STATUS
command
R/B#
Don‘t Care
OTP DATA PROTECT (80h-10)
The OTP DATA PROTECT (80h-10h) command is used to prevent further programming
of the pages in the OTP area. To protect the OTP area, the target must be in OTP operation mode.
To protect all data in the OTP area, issue the 80h command. Issue n address cycles including the column address, OTP protect page address and block address; the column
and block addresses are fixed to 0. Next, write 00h data for the first byte location and
issue the 10h command. R/B# goes LOW for the duration of the array programming
time, tPROG.
After the data is protected, it cannot be programmed further. When the OTP area is protected, the pages within the area are no longer programmable and cannot be unprotected.
The READ STATUS (70h) command is the only valid command for reading status in OTP
operation mode. The RDY bit of the status register will reflect the state of R/B#. Use of
the READ STATUS ENHANCED (78h) command is prohibited.
When the target is ready, read the FAIL bit of the status register to determine if the operation passed or failed.
If the OTP DATA PROTECT (80h-10h) command is issued after the OTP area has already
been protected, R/B# goes LOW for tOBSY. After tOBSY, the status register is set to 60h.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
Figure 68: OTP DATA PROTECT Operation (After Entering OTP Protect Mode)
CLE
CE#
tWC
WE#
tWB
tPROG
ALE
RE#
I/Ox
Col
00h
80h
OTP DATA
PROTECT command
Col
00h
OTP
page
00h
00h
DIN
OTP address
10h
70h
PROGRAM
command
READ STATUS
command
R/B#
Status
OTP data protected1
Don’t Care
Note:
1. OTP data is protected following a good status confirmation.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
OTP DATA READ (00h-30h)
To read data from the OTP area, set the device to OTP operation mode, then issue the
PAGE READ (00h-30h) command. Data can be read from OTP pages within the OTP area
whether the area is protected or not.
To use the PAGE READ command for reading data from the OTP area, issue the 00h
command, and then issue five address cycles: for the first two cycles, the column address; and for the remaining address cycles, select a page in the range of 02h-00h-00h
through 1Fh-00h-00h. Lastly, issue the 30h command. The PAGE READ CACHE MODE
command is not supported on OTP pages.
R/B# goes LOW (tR) while the data is moved from the OTP page to the data register. The
READ STATUS (70h) command is the only valid command for reading status in OTP operation mode. Bit 5 of the status register reflects the state of R/B# (see Status Operations).
Normal READ operation timings apply to OTP read accesses. Additional pages within
the OTP area can be selected by repeating the OTP DATA READ command.
The PAGE READ command is compatible with the RANDOM DATA OUTPUT (05h-E0h)
command.
Only data on the current page can be read. Pulsing RE# outputs data sequentially.
Figure 69: OTP DATA READ
CLE
CE#
WE#
ALE
tR
RE#
I/Ox
00h
Col
add 1
Col
add 2
OTP
page1
00h
00h
OTP address
DOUT
n
30h
DOUT
n+1
DOUT
m
Busy
R/B#
Don’t Care
Note:
1. The OTP page must be within the 02h–1Fh range.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
One-Time Programmable (OTP) Operations
Figure 70: OTP DATA READ with RANDOM DATA READ Operation
CLE
tCLR
CE#
WE#
tWB
tAR
tWHR
ALE
tREA
tRC
RE#
tRR
I/Ox
00h
Col
add 1
Col
add 2
OTP
page1
00h
00h
DOUT
n
30h
DOUT
n+1
05h
tR
Column addressn
Col
add 1
Col
add 2
E0h
DOUT
m
DOUT
m+1
Column addressm
Busy
R/B#
Don’t Care
Note:
1. The OTP page must be within the range 02h–1Fh.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Two-Plane Operations
Two-Plane Operations
Each NAND Flash logical unit (LUN) is divided into multiple physical planes. Each
plane contains a cache register and a data register independent of the other planes. The
planes are addressed via the low-order block address bits. Specific details are provided
in Device and Array Organization.
Two-plane operations make better use of the NAND Flash arrays on these physical
planes by performing concurrent READ, PROGRAM, or ERASE operations on multiple
planes, significantly improving system performance. Two-plane operations must be of
the same type across the planes; for example, it is not possible to perform a PROGRAM
operation on one plane with an ERASE operation on another.
When issuing two-plane program or erase operations, use the READ STATUS (70h)
command and check whether the previous operation(s) failed. If the READ STATUS
(70h) command indicates that an error occurred (FAIL = 1 and/or FAILC = 1), use the
READ STATUS ENHANCED (78h) command to determine which plane operation failed.
Two-Plane Addressing
Two-plane commands require multiple, five-cycle addresses, one address per operational plane. For a given two-plane operation, these addresses are subject to the following requirements:
• The LUN address bit(s) must be identical for all of the issued addresses.
• The plane select bit, BA[6], must be different for each issued address.
• The page address bits, PA[5:0], must be identical for each issued address.
The READ STATUS (70h) command should be used following two-plane program page
and erase block operations on a single die (LUN).
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Two-Plane Operations
Figure 71: TWO-PLANE PAGE READ
CLE
WE#
ALE
RE#
Page address M
00h
I/Ox
Col
add 1
Col
add 2
Row
add 1
Column address J
Row
add 2
Page address M
Row
add 3
Col
add 1
00h
Col
add 2
Row
add 1
Column address J
Plane 0 address
Row
add 2
Row
add 3
30h
tR
Plane 1 address
R/B#
1
CLE
WE#
ALE
RE#
I/Ox
DOUT 0
DOUT 1
DOUT
06h
Col
add 1
Col
add 2
Row
add 1
Plane 0 data
Row
add 2
Row
add 3
Plane 1 address
E0h
DOUT 0
DOUT 1
DOUT
Plane 1 data
R/B#
1
Notes:
1. Column and page addresses must be the same.
2. The least significant block address bit, BA6, must be different for the first- and secondplane addresses.
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Two-Plane Operations
Figure 72: TWO-PLANE PAGE READ with RANDOM DATA READ
tR
R/B#
RE#
I/Ox
00h
Address (5 cycles) 00h
Address (5 cycles) 30h
Plane 0 address
Data output
Plane 1 address
05h
Address
(2 cycles)
E0h
Data output
Plane 0 data
Plane 0 data
1
R/B#
RE#
06h
I/Ox
Address (5 cycles) E0h
Data output
05h
Address
(2 cycles)
E0h
Data output
Plane 1 data
Plane 1 address
Plane 1 data
1
Figure 73: TWO-PLANE PROGRAM PAGE
tDBSY
tPROG
R/B#
I/Ox
80h
Address (5 cycles) Data
1st-plane address
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input 11h
80h
Address (5 cycles)
Data
input 10h
70h
Status
2nd-plane address
103
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Two-Plane Operations
Figure 74: TWO-PLANE PROGRAM PAGE with RANDOM DATA INPUT
tDBSY
R/B#
I/Ox
80h
Address (5 cycles)
Data
input
85h
Address (2 cycles)
Data
input
Different column
address than previous
5 address cycles, for
1st plane only
1st-plane address
11h
80h
Address (5 cycles)
Data
input
2nd-plane address
1
Unlimited number of repetitions
tPROG
R/B#
85h
I/Ox
1
Address (2 cycles)
Data
input
10h
Different column
address than previous
5 address cycles, for
2nd plane only
Unlimited number of repetitions
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Two-Plane Operations
Figure 75: TWO-PLANE PROGRAM PAGE CACHE MODE
tDBSY
tCBSY
R/B#
80h
I/Ox
Address/data input
80h
11h
1st plane
Address/data input
15h
2nd plane
1
tDBSY
tCBSY
R/B#
80h
I/Ox
Address/data input
11h
80h
1st plane
Address/data input
15h
2nd plane
1
2
tDBSY
tLPROG
R/B#
80h
I/Ox
Address/data input
11h
80h
1st plane
Address/data input
10h
2nd plane
2
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Two-Plane Operations
Figure 76: TWO-PLANE INTERNAL DATA MOVE
tR
tDBSY
R/B#
00h
I/Ox
Address (5 cycles) 00h
1st-plane source
Address (5 cycles) 35h
85h
2nd-plane source
Address (5 cycles) 11h
1st-plane destination
1
tPROG
R/B#
85h
I/Ox
Address (5 cycles) 10h
70h
Status
2nd-plane destination
1
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Two-Plane Operations
Figure 77: TWO-PLANE INTERNAL DATA MOVE with TWO-PLANE RANDOM DATA READ
tR
R/B#
RE#
I/Ox
00h Address (5 cycles) 00h Address (5 cycles) 35h
1st-plane source
Data output
2nd-plane source
06h
Data from 1st-plane source
Address (5 cycles) E0h
2nd-plane source address 1
R/B#
RE#
Data output
I/Ox
05h
Data from
2nd-plane source
1
Data output
Address (2 cycles) E0h
2nd-plane
source column address
Data from 2nd-plane source
from new column address
2
Optional
tDBSY
tPROG
R/B#
RE#
I/Ox
85h
2
Address (5 cycles) 11h
1st-plane destination
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85h
Address (5 cycles) 10h
70h
Status
2nd-plane destination
107
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Two-Plane Operations
Figure 78: TWO-PLANE INTERNAL DATA MOVE with RANDOM DATA INPUT
tR
R/B#
00h
I/Ox
Address (5 cycles)
00h
Address (5 cycles)
1st-plane source
35h
85h
2nd-plane source
Address (5 cycles)
Data
85h
Optional
1st-plane destination
Address (2 cycles)
Data
11h
Unlimited number
of repetitions
1
tPROG
tDBSY
R/B#
85h
I/Ox
Address (5 cycles)
Data
Optional
2nd-plane destination
85h
Address (2 cycles)
Data
10h
70h
Status
Unlimited number
of repetitions
1
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Two-Plane Operations
Figure 79: TWO-PLANE BLOCK ERASE
CLE
CE#
WE#
ALE
tDBSY
tBERS
R/B#
RE#
I/Ox
60h
Address input (3 cycles)
D1h
60h
1st plane
Address input (3 cycles)
D0h
70h
Status
or 78h
2nd plane
Don‘t Care
Optional
Figure 80: TWO-PLANE/MULTIPLE-DIE READ STATUS Cycle
CE#
CLE
WE#
tAR
ALE
RE#
tWHR
I/Ox
78h
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Address (3 cycles)
109
tREA
Status output
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Interleaved Die (Multi-LUN) Operations
Interleaved Die (Multi-LUN) Operations
In devices that have more than one die (LUN) per target, it is possible to improve performance by interleaving operations between the die (LUNs). An interleaved die (multiLUN) operation is one that is issued to an idle die (LUN) (RDY = 1) while another die
(LUN) is busy (RDY = 0).
Interleaved die (multi-LUN) operations are prohibited following RESET (FFh), identification (90h, ECh, EDh), and configuration (EEh, EFh) operations until ARDY =1 for all of
the die (LUNs) on the target.
During an interleaved die (multi-LUN) operation, there are two methods to determine
operation completion. The R/B# signal indicates when all of the die (LUNs) have finished their operations. R/B# remains LOW while any die (LUN) is busy. When R/B# goes
HIGH, all of the die (LUNs) are idle and the operations are complete. Alternatively, the
READ STATUS ENHANCED (78h) command can report the status of each die (LUN) individually.
If a die (LUN) is performing a cache operation, like PROGRAM PAGE CACHE (80h-15h),
then the die (LUN) is able to accept the data for another cache operation when status
register bit 6 is 1. All operations, including cache operations, are complete on a die
when status register bit 5 is 1.
During and following interleaved die (multi-LUN) operations, the READ STATUS (70h)
command is prohibited. Instead, use the READ STATUS ENHANCED (78h) command to
monitor status. This command selects which die (LUN) will report status. When twoplane commands are used with interleaved die (multi-LUN) operations, the two-plane
commands must also meet the requirements in Two-Plane Operations.
See Command Definitions for the list of commands that can be issued while other die
(LUNs) are busy.
During an interleaved die (multi-LUN) operation that involves a PROGRAM series
(80h-10h, 80h-15h) operation and a READ operation, the PROGRAM series operation
must be issued before the READ series operation. The data from the READ series operation must be output to the host before the next PROGRAM series operation is issued.
This is because the 80h command clears the cache register contents of all cache registers on all planes.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Error Management
Error Management
Each NAND Flash die (LUN) is specified to have a minimum number of valid blocks
(NVB) of the total available blocks. This means the die (LUNs) could have blocks that
are invalid when shipped from the factory. An invalid block is one that contains at least
one page that has more bad bits than can be corrected by the minimum required ECC.
Additional blocks can develop with use. However, the total number of available blocks
per die (LUN) will not fall below NVB during the endurance life of the product.
Although NAND Flash memory devices could contain bad blocks, they can be used
quite reliably in systems that provide bad block management and error-correction algorithms. This type of software environment ensures data integrity.
Internal circuitry isolates each block from other blocks, so the presence of a bad block
does not affect the operation of the rest of the NAND Flash array.
NAND Flash devices are shipped from the factory erased. The factory identifies invalid
blocks before shipping by attempting to program the bad block mark into every location in the first page of each invalid block. It may not be possible to program every location with the bad block mark. However, the first spare area location in each bad block is
guaranteed to contain the bad block mark. This method is compliant with ONFI Factory
Defect Mapping requirements. See the following table for the first spare area location
and the bad block mark.
System software should check the first spare area location on the first page of each
block prior to performing any PROGRAM or ERASE operations on the NAND Flash device. A bad block table can then be created, enabling system software to map around
these areas. Factory testing is performed under worst-case conditions. Because invalid
blocks could be marginal, it may not be possible to recover this information if the block
is erased.
Over time, some memory locations may fail to program or erase properly. In order to
ensure that data is stored properly over the life of the NAND Flash device, the following
precautions are required:
• Always check status after a PROGRAM or ERASE operation
• Under typical conditions, use the minimum required ECC (see table below)
• Use bad block management and wear-leveling algorithms
The first block (physical block address 00h) for each CE# is guaranteed to be valid
with ECC when shipped from the factory.
Table 24: Error Management Details
Description
Requirement
Minimum number of valid blocks (NVB) per LUN
4016
Total available blocks per LUN
4096
First spare area location
x8: byte 2048
x16: word 1024
Bad-block mark
x8: 00h
x16: 0000h
Minimum required ECC
4-bit ECC per 528 bytes
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Error Management
Table 24: Error Management Details (Continued)
Description
Requirement
Minimum ECC with internal ECC enabled
4-bit ECC per 516 bytes (user data) + 8
bytes (parity data)
Minimum required ECC for block 0 if PROGRAM/
ERASE cycles are less than 1000
1-bit ECC per 528 bytes
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Internal ECC and Spare Area Mapping for ECC
Internal ECC and Spare Area Mapping for ECC
Internal ECC enables 5-bit detection and 4-bit error correction in 512 bytes (x8) or 256
words (x16) of the main area and 4 bytes (x8) or 2 words (x16) of metadata I in the spare
area. The metadata II area, which consists of two bytes (x8) and one word (x16), is not
ECC protected. During the busy time for PROGRAM operations, internal ECC generates
parity bits when error detection is complete.
During READ operations the device executes the internal ECC engine (5-bit detection
and 4-bit error correction). When the READ operaton is complete, read status bit 0 must
be checked to determine whether errors larger than four bits have occurred.
Following the READ STATUS command, the device must be returned to read mode by
issuing the 00h command.
Limitations of internal ECC include the spare area, defined in the figures below, and
ECC parity areas that cannot be written to. Each ECC user area (referred to as main and
spare) must be written within one partial-page program so that the NAND device can
calculate the proper ECC parity. The number of partial-page programs within a page
cannot exceed four.
Figure 81: Spare Area Mapping (x8)
Max Byte Min Byte
Address Address ECC Protected
1FFh
000h
Yes
3FFh
200h
Yes
5FFh
400h
Yes
7FFh
600h
Yes
801h
800h
No
803h
802h
No
807h
804h
Yes
80Fh
808h
Yes
811h
810h
No
813h
812h
No
817h
814h
Yes
81Fh
818h
Yes
821h
820h
No
823h
822h
No
827h
824h
Yes
82Fh
828h
Yes
831h
830h
No
833h
832h
No
837h
834h
Yes
83Fh
838h
Yes
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Area
Main 0
Main 1
Main 2
Main 3
Spare 0
Spare 0
Spare 1
Spare 1
Spare 2
Spare 2
Spare 3
Spare 3
Description
User data
User data
User data
User data
Reserved
User metadata II
User metadata I
ECC for main/spare 0
Reserved
User metadata II
User metadata I
ECC for main/spare 1
Reserved
User metadata II
User metadata I
ECC for main/spare 2
User data
User metadata II
User metadata I
ECC for main/spare 3
113
Bad Block
Information
ECC
Parity
User Data
(Metadata)
2 bytes
8 bytes
6 bytes
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Internal ECC and Spare Area Mapping for ECC
Figure 82: Spare Area Mapping (x16)
Max word Min word
Address Address ECC Protected
0FFh
000h
Yes
1FFh
100h
Yes
2FFh
200h
Yes
3FFh
300h
Yes
400h
400h
No
401h
401h
No
403h
402h
Yes
407h
404h
Yes
408h
408h
No
409h
409h
No
40Bh
40Ah
Yes
40Fh
40Ch
Yes
410h
410h
No
411h
411h
No
413h
412h
Yes
417h
414h
Yes
418h
418h
No
419h
419h
No
41Bh
41Ah
Yes
41Fh
41Ch
Yes
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Area
Main 0
Main 1
Main 2
Main 3
Spare 0
Spare 0
Spare 1
Spare 1
Spare 2
Spare 2
Spare 3
Spare 3
Description
User data
User data
User data
User data
Reserved
User metadata II
User metadata I
ECC for main/spare 0
Reserved
User metadata II
User metadata I
ECC for main/spare 1
Reserved
User metadata II
User metadata I
ECC for main/spare 2
User data
User metadata II
User metadata I
ECC for main/spare 3
114
Bad Block
Information
ECC
Parity
User Data
(Metadata)
1 word
4 words
3 words
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications
Electrical Specifications
Stresses greater than those listed can cause permanent damage to the device. This is
stress rating only, and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not guaranteed. Exposure to absolute maximum rating conditions for extended periods can affect reliability.
Table 25: Absolute Maximum Ratings
Voltage on any pin relative to Vss
Parameter/Condition
Voltage input
Symbol
Min
Max
Unit
VIN
–0.6
2.4
V
–0.6
4.6
V
–0.6
2.4
V
–0.6
4.6
V
TSTG
–65
150
°C
–
–
5
mA
1.8V
3.3V
VCC supply voltage
1.8V
VCC
3.3V
Storage temperature
Short circuit output current, I/Os
Table 26: Recommended Operating Conditions
Parameter/Condition
Symbol
Min
Typ
Max
Unit
TA
0
–
70
°C
Operating temperature Commercial
Industrial
VCC supply voltage
1.8V
VCC
3.3V
Ground supply voltage
VSS
–40
–
85
°C
1.7
1.8
1.95
V
2.7
3.3
3.6
V
0
0
0
V
Table 27: Valid Blocks
Notes:
Parameter
Symbol
Device
Min
Max
Unit
Notes
Valid block
number
NVB
MT29F4G
4016
4096
Blocks
1, 2
MT29F8G
8032
8192
Blocks
1, 2, 3
1. Invalid blocks are blocks that contain one or more bad bits. The device may contain bad
blocks upon shipment. Additional bad blocks may develop over time; however, the total
number of available blocks will not drop below NVB during the endurance life of the
device. Do not erase or program blocks marked invalid by the factory.
2. Block 00h (the first block) is guaranteed to be valid with ECC when shipped from the
factory.
3. Each 4Gb section has a maximum of 80 invalid blocks.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications
Table 28: Capacitance
Notes 1–3 apply to all parameters and conditions
Description
Symbol
Notes:
Max
Unit
Input capacitance
CIN
10
pF
Input/output capacitance (I/O)
CIO
10
pF
1. These parameters are verified in device characterization and are not 100% tested.
2. Test conditions: TC = 25°C; f = 1 MHz; VIN = 0V.
3. Capacitance (CIN = CIO = 20pF) for MT29F8G and (CIN = CIO = 40pF) for MT29F16G.
Table 29: Test Conditions
Parameter
Value
Input pulse levels
Notes
0.0V to VCC
Input rise and fall times
1.8V
2.5ns
3.3V
5.0ns
VCC/2
Input and output timing levels
Output load
1 TTL GATE and CL = 30pF (1.8V)
1
1 TTL GATE and CL = 50pF (3.3V)
Output load
1 TTL GATE and CL = 30pF (1.8V)
1
1 TTL GATE and CL = 50pF (3.3V)
Note:
1. Verified in device characterization, not 100% tested.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – DC Characteristics and Operating
Conditions
Electrical Specifications – DC Characteristics and Operating Conditions
Table 30: DC Characteristics and Operating Conditions (3.3V)
Parameter
Conditions
Sequential READ current
tRC
=
tRC
(MIN); CE# = VIL;
IOUT = 0mA
Symbol
Min
Typ
Max
Unit
ICC1
–
25
35
mA
Notes
PROGRAM current
–
ICC2
–
25
35
mA
ERASE current
–
ICC3
–
25
35
mA
CE# = VIH;
WP# = 0V/VCC
ISB1
–
–
1
mA
Standby current (CMOS)
CE# = VCC - 0.2V;
WP# = 0V/VCC
ISB2
–
20
100
μA
Staggered power-up current
Rise time = 1ms
Line capacitance = 0.1μF
IST
–
–
10 per die
mA
VIN = 0V to VCC
ILI
–
–
±10
μA
VOUT = 0V to VCC
ILO
–
–
±10
μA
I/O[7:0], I/O[15:0],
CE#, CLE, ALE, WE#, RE#,
WP#
VIH
0.8 x VCC
–
VCC + 0.3
V
–
VIL
–0.3
–
0.2 x VCC
V
Output high voltage
IOH = –400μA
VOH
0.67 x VCC
–
–
V
3
Output low voltage
IOL = 2.1mA
VOL
–
–
0.4
V
3
Output low current
VOL = 0.4V
IOL (R/B#)
8
10
–
mA
2
Standby current (TTL)
Input leakage current
Output leakage current
Input high voltage
Input low voltage, all inputs
Notes:
1
1. Measurement is taken with 1ms averaging intervals and begins after VCC reaches
VCC(MIN).
2. IOL (R/B#) may need to be relaxed if R/B pull-down strength is not set to full.
3. VOH and VOL may need to be relaxed if I/O drive strength is not set to full.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – DC Characteristics and Operating
Conditions
Table 31: DC Characteristics and Operating Conditions (1.8V)
Parameter
Conditions
Sequential READ current
tRC
=
tRC
(MIN); CE# = VIL;
IOUT = 0mA
Symbol
Min
Typ
Max
Unit
Notes
ICC1
–
13
20
mA
1, 2
PROGRAM current
–
ICC2
–
10
20
mA
1, 2
ERASE current
–
ICC3
–
10
20
mA
1, 2
CE# = VIH;
WP# = 0V/VCC
ISB1
–
–
1
mA
Standby current (CMOS)
CE# = VCC - 0.2V;
WP# = 0V/VCC
ISB2
–
10
50
μA
Staggered power-up current
Rise time = 1ms
Line capacitance = 0.1μF
IST
–
–
10 per die
mA
VIN = 0V to VCC
ILI
–
–
±10
μA
VOUT = 0V to VCC
ILO
–
–
±10
μA
I/O[7:0], I/O[15:0],
CE#, CLE, ALE, WE#, RE#,
WP#
VIH
0.8 x VCC
–
VCC + 0.3
V
–
VIL
–0.3
–
0.2 x VCC
V
Output high voltage
IOH = –100μA
VOH
VCC - 0.1
–
–
V
4
Output low voltage
IOL = +100μA
VOL
–
–
0.1
V
4
VOL = 0.2V
IOL (R/B#)
3
4
–
mA
5
Standby current (TTL)
Input leakage current
Output leakage current
Input high voltage
Input low voltage, all inputs
Output low current (R/B#)
Notes:
3
1. Typical and maximum values are for single-plane operation only. If device supports dualplane operation, values are 20mA (TYP) and 40mA (MAX).
2. Values are for single-die operations. Values could be higher for interleaved-die operations.
3. Measurement is taken with 1ms averaging intervals and begins after VCC reaches
VCC(MIN).
4. Test conditions for VOH and VOL.
5. DC characteristics may need to be relaxed if R/B# pull-down strength is not set to full.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Characteristics and Operating
Conditions
Electrical Specifications – AC Characteristics and Operating Conditions
Table 32: AC Characteristics: Command, Data, and Address Input (3.3V)
Note 1 applies to all
Parameter
Symbol
Min
Max
Unit
Notes
ALE to data start
tADL
70
–
ns
2
ALE hold time
tALH
5
–
ns
ALE setup time
tALS
10
–
ns
CE# hold time
tCH
5
–
ns
CLE hold time
tCLH
5
–
ns
CLE setup time
tCLS
10
–
ns
CE# setup time
tCS
15
–
ns
Data hold time
tDH
5
–
ns
Data setup time
tDS
7
–
ns
WRITE cycle time
tWC
20
–
ns
2
WE# pulse width HIGH
tWH
7
–
ns
2
WE# pulse width
tWP
10
–
ns
2
WP# transition to WE# LOW
tWW
100
–
ns
Notes:
1. Operating mode timings meet ONFI timing mode 5 parameters.
2. Timing for tADL begins in the address cycle, on the final rising edge of WE#, and ends
with the first rising edge of WE# for data input.
Table 33: AC Characteristics: Command, Data, and Address Input (1.8V)
Note 1 applies to all
Parameter
Symbol
Min
Max
Unit
Notes
ALE to data start
tADL
70
–
ns
2
ALE hold time
tALH
5
–
ns
ALE setup time
tALS
10
–
ns
CE# hold time
tCH
5
–
ns
CLE hold time
tCLH
5
–
ns
CLE setup time
tCLS
10
–
ns
CE# setup time
tCS
20
–
ns
Data hold time
tDH
5
–
ns
Data setup time
tDS
10
–
ns
WRITE cycle time
tWC
25
–
ns
2
WE# pulse width HIGH
tWH
10
–
ns
2
WE# pulse width
tWP
12
–
ns
2
WP# transition to WE# LOW
tWW
100
–
ns
Notes:
1. Operating mode timings meet ONFI timing mode 4 parameters.
2. Timing for tADL begins in the address cycle on the final rising edge of WE#, and ends
with the first rising edge of WE# for data input.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Characteristics and Operating
Conditions
Table 34: AC Characteristics: Normal Operation (3.3V)
Note 1 applies to all
Parameter
Symbol
Min
tAR
10
–
ns
CE# access time
tCEA
–
25
ns
CE# HIGH to output High-Z
tCHZ
–
50
ns
CLE to RE# delay
tCLR
10
–
ns
CE# HIGH to output hold
tCOH
15
–
ns
Output High-Z to RE# LOW
tIR
0
–
ns
READ cycle time
tRC
20
–
ns
RE# access time
tREA
–
16
ns
RE# HIGH hold time
tREH
7
–
ns
tRHOH
15
–
ns
RE# HIGH to WE# LOW
tRHW
100
–
ns
RE# HIGH to output High-Z
tRHZ
–
100
ns
ALE to RE# delay
RE# HIGH to output hold
Max
Unit
tRLOH
5
–
ns
RE# pulse width
tRP
10
–
ns
Ready to RE# LOW
tRR
20
–
ns
Reset time (READ/PROGRAM/ERASE)
tRST
–
5/10/500
μs
WE# HIGH to busy
tWB
–
100
ns
tWHR
60
–
ns
RE# LOW to output hold
WE# HIGH to RE# LOW
Notes:
Notes
2
2
3
1. AC characteristics may need to be relaxed if I/O drive strength is not set to full.
2. Transition is measured ±200mV from steady-state voltage with load. This parameter is
sampled and not 100% tested.
3. The first time the RESET (FFh) command is issued while the device is idle, the device will
go busy for a maximum of 1ms. Thereafter, the device goes busy for a maximum of 5μs.
Table 35: AC Characteristics: Normal Operation (1.8V)
Note 1 applies to all
Parameter
Symbol
Min
tAR
10
–
ns
CE# access time
tCEA
–
25
ns
CE# HIGH to output High-Z
tCHZ
–
50
ns
CLE to RE# delay
tCLR
10
–
ns
CE# HIGH to output hold
tCOH
15
–
ns
Output High-Z to RE# LOW
tIR
0
–
ns
READ cycle time
tRC
25
–
ns
RE# access time
tREA
–
22
ns
RE# HIGH hold time
tREH
10
–
ns
tRHOH
15
–
ns
tRHW
100
–
ns
ALE to RE# delay
RE# HIGH to output hold
RE# HIGH to WE# LOW
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Max
Unit
Notes
2
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Characteristics and Operating
Conditions
Table 35: AC Characteristics: Normal Operation (1.8V) (Continued)
Note 1 applies to all
Parameter
RE# HIGH to output High-Z
RE# LOW to output hold
Symbol
Min
Max
Unit
Notes
tRHZ
–
65
ns
2
tRLOH
3
–
ns
RE# pulse width
tRP
12
–
ns
Ready to RE# LOW
tRR
20
–
ns
Reset time (READ/PROGRAM/ERASE)
tRST
–
5/10/500
μs
WE# HIGH to busy
tWB
–
100
ns
tWHR
80
–
ns
WE# HIGH to RE# LOW
Notes:
3
1. AC characteristics may need to be relaxed if I/O drive strength is not set to full.
2. Transition is measured ±200mV from steady-state voltage with load. This parameter is
sampled and not 100% tested.
3. The first time the RESET (FFh) command is issued while the device is idle, the device will
be busy for a maximum of 1ms. Thereafter, the device is busy for a maximum of 5μs.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – Program/Erase Characteristics
Electrical Specifications – Program/Erase Characteristics
Table 36: Program/Erase Characteristics
Parameter
Number of partial-page programs
Symbol
Typ
Max
Unit
Notes
4
cycles
1
NOP
–
BLOCK ERASE operation time
tBERS
0.7
3
ms
Busy time for PROGRAM CACHE operation
tCBSY
3
600
μs
tRCBSY
3
25
μs
Busy time for SET FEATURES and GET FEATURES operations
tFEAT
–
1
μs
Busy time for OTP DATA PROGRAM operation if OTP is protected
tOBSY
–
30
μs
Busy time for PROGRAM/ERASE on locked blocks
tLBSY
–
3
μs
PROGRAM PAGE operation time, internal ECC disabled
tPROG
200
600
μs
8
PROGRAM PAGE operation time, internal ECC enabled
tPROG_ECC
220
600
μs
3, 8
Data transfer from Flash array to data register, internal ECC
disabled
tR
–
25
μs
6, 7
Data transfer from Flash array to data register, internal ECC
enabled
tR_ECC
45
70
μs
3, 5
Busy time for OTP DATA PROGRAM operation if OTP is protected, internal ECC enabled
tOBSY_ECC
–
50
μs
Busy time for TWO-PLANE PROGRAM PAGE or TWO-PLANE
BLOCK ERASE operation
tDBSY
0.5
1
μs
Cache read busy time
Notes:
2
1. Four total partial-page programs to the same page. If ECC is enabled, then the device is
limited to one partial-page program per ECC user area, not exceeding four partial-page
programs per page.
2. tCBSY MAX time depends on timing between internal program completion and data-in.
3. Parameters are with internal ECC enabled.
4. Typical is nominal voltage and room temperature.
5. Typical tR_ECC is under typical process corner, nominal voltage, and at room temperature.
6. Data transfer from Flash array to data register with internal ECC disabled.
7. AC characteristics may need to be relaxed if I/O drive strength is not set to full.
8. Typical program time is defined as the time within which more than 50% of the pages
are programmed at nominal voltage and room temperature.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Asynchronous Interface Timing Diagrams
Figure 83: RESET Operation
CLE
CE#
tWB
WE#
tRST
R/B#
I/O[7:0]
FFh
RESET
command
Figure 84: READ STATUS Cycle
tCLR
CLE
CE#
tCLS
tCLH
tCS
tWP
tCH
WE#
tCEA
tWHR
tRP
tCHZ
tCOH
RE#
tRHZ
tDS
I/O[7:0]
tDH
tIR
tREA
tRHOH
Status
output
70h
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 85: READ STATUS ENHANCED Cycle
tCS
CE#
tCLS
tCLH
CLE
tWC
tWP
tWP
tWH
tCH
WE#
tCHZ
tCEA
tALS
tALH
tALH
tCOH
tAR
ALE
RE#
tRHZ
tDS
I/O[7:0]
tDH
tWHR
Row add 1
78h
Row add 2
tREA
tRHOH
Status output
Row add 3
Don’t Care
Figure 86: READ PARAMETER PAGE
CLE
WE#
tWB
ALE
tRC
RE#
tRR
I/O[7:0]
ECh
00h
tR or tR_ECC
tRP
P00
P10
P2550
P01
R/B#
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 87: READ PAGE
CLE
tCLR
CE#
tWC
WE#
tWB
tAR
ALE
tR
tRC
or tR_ECC
tRHZ
RE#
tRR
I/Ox
00h
Col
add 1
Col
add 2
Row
add 1
Row
add 2
Row
add 3
tRP
DOUT
N
30h
DOUT
N+1
DOUT
M
Busy
RDY
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 88: READ PAGE Operation with CE# “Don’t Care”
CLE
CE#
RE#
ALE
tR
or tR_ECC
RDY
WE#
I/Ox
00h
Address (5 cycles)
30h
Data output
tCEA
CE#
tREA
tCOH
RE#
Don’t Care
Out
I/Ox
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tCHZ
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Asynchronous Interface Timing Diagrams
Figure 89: RANDOM DATA READ
CLE
tCLR
CE#
WE#
tRHW
tWHR
ALE
tRC
tREA
RE#
I/Ox
DOUT
N-1
DOUT
N
05h
Col
add 1
Col
add 2
E0h
DOUT
M
DOUT
M+1
Column address M
RDY
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 90: READ PAGE CACHE SEQUENTIAL
CLE
tCLS
tCLS
tCLH
tCLH
tCS
tCH
tCS
tCH
CE#
tWC
WE#
tCEA
tRHW
ALE
tRC
RE#
tWB
tDH
tDS
tR
tWB
I/Ox
Col
add 1
00h
Col
add 2
Row
add 1
Column address
00h
Row
add 2
Row
add 3
tREA
tDS
tRR
30h
Dout
0
31h
Page address
M
Dout
1
Dout
tDH
31h
Page address
M
tRCBSY
RDY
Column address 0
1
CLE
tCLS
tCLH
tCS
tCH
CE#
WE#
tRHW
tRHW
tCEA
ALE
tRC
tRC
RE#
tWB
tREA
tDS
tRR
tDH
I/Ox
Dout
0
Dout
1
Dout
31h
Page address
M
tREA
Dout
0
tRCBSY
Dout
1
Dout
Page address
M+1
Dout
0
3Fh
tRCBSY
Dout
1
Dout
Page address
M+2
RDY
Column address 0
Column address 0
Column address 0
1
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Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 91: READ PAGE CACHE RANDOM
CLE
tCLS
tCLH
tCH
tCS
CE#
tWC
WE#
ALE
RE#
tDH
tWB
tDS
I/Ox
Col
add 1
00h
Row
add 1
Col
add 2
Column address
00h
Row
add 2
Row
add 3
tR
30h
Col
add 1
00h
Page address
M
Row
add 1
Col
add 2
Column address
00h
Row
add 2
Page address
N
RDY
1
CLE
tCLS
tCLH
tCS
tCH
CE#
WE#
tCEA
tRHW
ALE
tRC
tWB
RE#
tDS
tDH
I/Ox
Col
add 1
Row
add 1
Col
add 2
Column address
00h
Row
add 2
Row
add 3
Page address
N
RDY
tRR
tREA
Dout
0
31h
Dout
1
Page address
M
tRCBSY
Column address 0
1
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Dout
Dout
0
3Fh
tRCBSY
Dout
1
Dout
Page address
N
Column address 0
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 92: READ ID Operation
CLE
CE#
WE#
tAR
ALE
RE#
tWHR
I/Ox
90h
tREA
Byte 1
Byte 0
00h or 20h
Byte 2
Byte 3
Byte 4
Address, 1 cycle
Figure 93: PROGRAM PAGE Operation
CLE
CE#
tWC
tADL
WE#
tWB
tPROG
or
tWHR
tPROG_ECC
ALE
RE#
I/Ox
80h
Col
add 1
Col
add 2
Row
add 1
Row
add 2
Row
add 3
DIN
N
DIN
M
10h
70h
Status
1 up to m byte
serial Input
RDY
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 94: PROGRAM PAGE Operation with CE# “Don’t Care”
CLE
CE#
WE#
ALE
I/Ox
80h
Address (5 cycles)
Data
input
Data
input
10h
tCH
tCS
CE#
tWP
WE#
Don’t Care
Figure 95: PROGRAM PAGE Operation with RANDOM DATA INPUT
CLE
CE#
tWC
tADL
tADL
WE#
tPROG
or
tWB tPROG_ECC
tWHR
ALE
RE#
I/Ox
80h
Col
add 1
Col
add 2
Row
add 1
Row
add 2
Row
add 3
DIN
M
DIN
N
Serial input
85h
Col
add 1
Col
add 2
CHANGE WRITE Column address
COLUMN command
DIN
P
DIN
Q
Serial input
10h
70h
Status
READ STATUS
command
RDY
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 96: PROGRAM PAGE CACHE
CLE
CE#
tADL
tWC
WE#
tWB tCBSY
tWB tLPROG
tWHR
ALE
RE#
I/Ox
80h
Row Row Row
Col
Col
add 1 add 2 add 1 add 2 add 3
Din
N
Din
M
15h
80h
Col
Col Row Row Row
add 1 add 2 add 1 add 2 add 3
Din
N
Din
M
10h
70h
Status
Serial input
RDY
Last page - 1
Last page
Don’t Care
Figure 97: PROGRAM PAGE CACHE Ending on 15h
CLE
CE#
tWC
tADL
tADL
WE#
tWHR
tWHR
ALE
RE#
I/Ox
80h
Col Row Row Row
Col
add 1 add 2 add 1 add 2 add 3
Din
Din
N
M
Serial input
15h
70h
Status
80h
Col Row Row Row Din
Col
add 1 add 2 add 1 add 2 add 3 N
Last page – 1
Din
M
15h
70h
Status
70h
Status
Last page
Poll status until:
I/O6 = 1, Ready
To verify successful completion of the last 2 pages:
I/O5 = 1, Ready
I/O0 = 0, Last page PROGRAM successful
I/O1 = 0, Last page – 1 PROGRAM successful
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 98: INTERNAL DATA MOVE
CLE
CE#
tADL
tWC
WE#
tWB tPROG
tWB
tWHR
ALE
RE#
I/Ox
tR
Col
add 1
00h
Col
add 2
Row
add 1
Row
add 2
Row
add 3
35h
(or 30h)
85h
Col
Row Row Row
Col
add 1 add 2 add 1 add 2 add 3
Data
1
Data
N
10h
Status
70h
READ STATUS
Busy command
Busy
RDY
Data Input
Optional
Don’t Care
Figure 99: INTERNAL DATA MOVE (85h-10h) with Internal ECC Enabled
tR_ECC
tPROG_ECC
R/B#
I/O[7:0]
00h
Address
(5 cycles)
35h
Source address
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70h
Status
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
DOUT
85h
DOUT is optional
133
Address
(5 cycles)
10h
Destination address
70h
Status
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Asynchronous Interface Timing Diagrams
Figure 100: INTERNAL DATA MOVE (85h-10h) with Random Data Input with Internal ECC Enabled
tR_ECC
tPROG_ECC
R/B#
I/O[7:0]
00h
Address
(5 cycles)
35h
70h
Source address
Status
DOUT
00h
SR bit 0 = 0 READ successful
SR bit 1 = 0 READ error
85h
DOUT is optional
Address
(5 cycles) Data 85h
Address
(2 cycles) Data 10h
70h
Destination address
Column address 1, 2
(Unlimitted repetitions are possible)
Figure 101: ERASE BLOCK Operation
CLE
CE#
t
WC
WE#
t
t
WB
WHR
ALE
RE#
t
I/O[7:0]
60h
Row
add 1
Row
add 2
Row
add 3
BERS
D0h
70h
Row address
RDY
Status
READ STATUS
command
Busy
I/O0 = 0, Pass
I/O0 = 1, Fail
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
2Gb: x16, x32 Mobile LPDDR SDRAM
2Gb: x16, x32 Mobile LPDDR SDRAM
Features
• VDD/VDDQ = 1.70–1.95V
• Bidirectional data strobe per byte of data (DQS)
• Internal, pipelined double data rate (DDR)
architecture; two data accesses per clock cycle
• Differential clock inputs (CK and CK#)
• Commands entered on each positive CK edge
• DQS edge-aligned with data for READs; center-aligned with data for WRITEs
• 4 internal banks for concurrent operation
• Data masks (DM) for masking write data; one mask per byte
• Programmable burst lengths (BL): 2, 4, 8, or 16
• Concurrent auto precharge option is supported
• Auto refresh and self refresh modes
• 1.8V LVCMOS-compatible inputs
• Temperature-compensated self refresh (TCSR)
• Partial-array self refresh (PASR)
• Deep power-down (DPD)
• Status read register (SRR)
• Selectable output drive strength (DS)
• Clock stop capability
• 64ms refresh; 32ms for the automotive temperature range
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
2Gb: x16, x32 Mobile LPDDR SDRAM
Table 37: Configuration Addressing – 2Gb
Architecture
128 Meg x 16
64 Meg x 32
Configuration
32 Meg x 16 x 4
banks
16 Meg x 32 x 4
banks
Refresh count
Row addressing
Column addressing
Reduced Page-Size
Option 128 Meg x 16
Reduced Page-Size
Option 64 Meg x 32
32 Meg x 16 x 4 banks
16 Meg x 32 x 4 banks
8K
8K
8K
8K
16K A[13:0]
16K A[13:0]
32K A[14:0]
32K A[14:0]
2K A11, A[9:0]
1K A[9:0]
1K A[9:0]
512K A[8:0]
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
2Gb: x16, x32 Mobile LPDDR SDRAM
General Description
The 2Gb Mobile low-power DDR SDRAM is a high-speed CMOS, dynamic random-access memory containing 2,147,483,648 bits. It is internally configured as a quad-bank
DRAM. Each of the x16’s 536,870,912-bit banks is organized as 16,384 rows by 2048 columns by 16 bits. Each of the x32’s 536,870,912-bit banks is organized as 16,384 rows by
1024 columns by 32 bits. In the reduced page-size (LG) option, each of the x32's
536,870,912-bit banks is organized as 32,768 rows by 512 columns by 32 bits. In the reduced page-size (R4) option, each of the x16's 536,870,912-bit banks is organized as
32,768 rows by 1024 columns x 16 bits.
Note:
1. Throughout this data sheet, various figures and text refer to DQs as “DQ.” DQ should
be interpreted as any and all DQ collectively, unless specifically stated otherwise. Additionally, the x16 is divided into 2 bytes: the lower byte and the upper byte. For the lower
byte (DQ[7:0]), DM refers to LDM and DQS refers to LDQS. For the upper byte
(DQ[15:8]), DM refers to UDM and DQS refers to UDQS. The x32 is divided into 4 bytes.
For DQ[7:0], DM refers to DM0 and DQS refers to DQS0. For DQ[15:8], DM refers to
DM1 and DQS refers to DQS1. For DQ[23:16], DM refers to DM2 and DQS refers to
DQS2. For DQ[31:24], DM refers to DM3 and DQS refers to DQS3.
2. Complete functionality is described throughout the document; any page or diagram
may have been simplified to convey a topic and may not be inclusive of all requirements.
3. Any specific requirement takes precedence over a general statement.
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Functional Block Diagrams
Functional Block Diagrams
Figure 102: Functional Block Diagram (x16)
CKE
CK#
CK
WE#
CAS#
RAS#
Command
decode
CS#
Control
logic
Bank 3
Bank 2
Bank 1
Refresh
counter
Standard mode
register
Extended mode
register
Bank 0
rowaddress
latch
and
decoder
Rowaddress
Mux
Bank 0
memory
array
Data
16
32
Read
latch
Sense amplifiers
16
MUX
DRVRS
16
2
DQS
generator
DQ[15:0]
COL 0
I/O gating
DM mask logic
2
Address
BA0, BA1
Address
register
2
CK
32
Bank
control
logic
2
DQS
Input
registers
32
Column
decoder
Columnaddress
counter/
latch
Write
FIFO
and
drivers
CK
out
CK
in
LDQS,
UDQS
2
Mask
2
2
2
16
16
16
16
4
32
RCVRS
16
LDM,
UDM
Data
CK
2
COL 0
1
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Functional Block Diagrams
Figure 103: Functional Block Diagram (x32)
CKE
CK#
CK
WE#
CAS#
RAS#
Command
decode
CS#
Control
logic
Bank 3
Bank 2
Bank 1
Refresh
counter
Standard mode
register
Extended mode
register
Bank 0
rowaddress
latch
and
decoder
Rowaddress
MUX
Bank 0
memory
array
Data
32
64
Read
latch
Sense amplifiers
32
MUX
DRVRS
32
2
DQS
generator
DQ[31:0]
COL 0
I/O gating
DM mask logic
2
Address,
BA0, BA1
Address
register
2
CK
64
Bank
control
logic
DQS
Input
registers
4
4
4
4
32
32
Mask
64
Column
decoder
Columnaddress
counter/
latch
Write
FIFO
and
drivers
CK
out
CK
in
DQS0
DQS1
DQS2
DQS3
4
8
64
RCVRS
32
32
32
Data
CK
DM0
DM1
DM2
DM3
4
COL 0
1
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications
Electrical Specifications
Stresses greater than those listed may cause permanent damage to the device. This is a
stress rating only, and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect
reliability.
Table 38: Absolute Maximum Ratings
Note 1 applies to all parameters in this table
Parameter
Symbol
Min
Max
Unit
VDD/VDDQ supply voltage relative to VSS
VDD/VDDQ
–1.0
2.4
V
Voltage on any pin relative to VSS
VIN
–0.5
2.4 or (VDDQ + 0.3V),
whichever is less
V
Storage temperature (plastic)
TSTG
–55
150
˚C
Note:
1. VDD and VDDQ must be within 300mV of each other at all times. VDDQ must not exceed
VDD.
Table 39: AC/DC Electrical Characteristics and Operating Conditions
Notes 1–5 apply to all parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Parameter/Condition
Symbol
Min
Max
Unit
Notes
Supply voltage
VDD
1.70
1.95
V
6, 7
I/O supply voltage
VDDQ
1.70
1.95
V
6, 7
Input voltage high
VIH
0.8 × VDDQ
VDDQ + 0.3
V
8, 9
Input voltage low
VIL
–0.3
0.2 × VDDQ
V
8, 9
VIN
–0.3
VDDQ + 0.3
V
10
DC input differential voltage
VID(DC)
0.4 × VDDQ
VDDQ + 0.6
V
10, 11
AC input differential voltage
VID(AC)
0.6 × VDDQ
VDDQ + 0.6
V
10, 11
VIX
0.4 × VDDQ
0.6 × VDDQ
V
10, 12
DC input high voltage
VIH(DC)
0.7 × VDDQ
VDDQ + 0.3
V
8, 9, 13
DC input low voltage
VIL(DC)
–0.3
0.3 × VDDQ
V
8, 9, 13
AC input high voltage
VIH(AC)
0.8 × VDDQ
VDDQ + 0.3
V
8, 9, 13
AC input low voltage
VIL(AC)
–0.3
0.2 × VDDQ
V
8, 9, 13
DC output high voltage: Logic 1 (IOH = –0.1mA)
VOH
0.9 × VDDQ
–
V
DC output low voltage: Logic 0 (IOL = 0.1mA)
VOL
–
0.1 × VDDQ
V
II
–1
1
μA
Address and command inputs
Clock inputs (CK, CK#)
DC input voltage
AC differential crossing voltage
Data inputs
Data outputs
Leakage current
Input leakage current
Any input 0V ≤ VIN ≤ VDD
(All other pins not under test = 0V)
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Electrical Specifications
Table 39: AC/DC Electrical Characteristics and Operating Conditions (Continued)
Notes 1–5 apply to all parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Parameter/Condition
Symbol
Min
Output leakage current
(DQ are disabled; 0V ≤ VOUT ≤ VDDQ)
IOZ
Max
Unit
–1.5
1.5
μA
Notes
Operating temperature
Commercial
TA
0
70
˚C
Wireless
TA
–25
85
˚C
Industrial
TA
–40
85
˚C
Automotive
TA
–40
105
˚C
Notes:
1. All voltages referenced to VSS.
2. All parameters assume proper device initialization.
3. Tests for AC timing, IDD, and electrical AC and DC characteristics may be conducted at
nominal supply voltage levels, but the related specifications and device operation are
guaranteed for the full voltage range specified.
4. Outputs measured with equivalent load; transmission line delay is assumed to be very
small:
50
50
I/O
I/O
10pF
20pF
Full drive strength
Half drive strength
5. Timing and IDD tests may use a VIL-to-VIH swing of up to 1.5V in the test environment,
but input timing is still referenced to VDDQ/2 (or to the crossing point for CK/CK#). The
output timing reference voltage level is VDDQ/2.
6. Any positive glitch must be less than one-third of the clock cycle and not more than
+200mV or 2.0V, whichever is less. Any negative glitch must be less than one-third of the
clock cycle and not exceed either –150mV or +1.6V, whichever is more positive.
7. VDD and VDDQ must track each other and VDDQ must be less than or equal to VDD.
8. To maintain a valid level, the transitioning edge of the input must:
8a. Sustain a constant slew rate from the current AC level through to the target AC level, VIL(AC) Or VIH(AC).
8b. Reach at least the target AC level.
8c. After the AC target level is reached, continue to maintain at least the target DC level, VIL(DC) or VIH(DC).
9. VIH overshoot: VIHmax = VDDQ + 1.0V for a pulse width ≤3ns and the pulse width cannot
be greater than one-third of the cycle rate. VIL undershoot: VILmin = –1.0V for a pulse
width ≤3ns and the pulse width cannot be greater than one-third of the cycle rate.
10. CK and CK# input slew rate must be ≥1 V/ns (2 V/ns if measured differentially).
11. VID is the magnitude of the difference between the input level on CK and the input level on CK#.
12. The value of VIX is expected to equal VDDQ/2 of the transmitting device and must track
variations in the DC level of the same.
13. DQ and DM input slew rates must not deviate from DQS by more than 10%. 50ps must
be added to tDS and tDH for each 100 mV/ns reduction in slew rate. If slew rate exceeds
4 V/ns, functionality is uncertain.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications
Table 40: Capacitance (x16, x32)
Notes 1 and 2 apply to all the parameters in this table
Parameter
Symbol
Min
Max
Unit
Input capacitance: CK, CK#
CCK
1.0
2.0
pF
Delta input capacitance: CK, CK#
CDCK
0
0.25
pF
Input capacitance: command and address
CI
1.0
2.0
pF
Delta input capacitance: command and address
CDI
– 0.5
0.5
pF
Input/output capacitance: DQ, DQS, DM
CIO
1.25
2.5
pF
Delta input/output capacitance: DQ, DQS, DM
CDIO
– 0.6
0.6
pF
Notes:
Notes
3
3
4
1. This parameter is sampled. VDD/VDDQ = 1.70–1.95V, f = 100 MHz, TA = 25˚C, VOUT(DC) =
VDDQ/2, VOUT (peak-to-peak) = 0.2V. DM input is grouped with I/O pins, reflecting the
fact that they are matched in loading.
2. This parameter applies to die devices only (does not include package capacitance).
3. The input capacitance per pin group will not differ by more than this maximum amount
for any given device.
4. The I/O capacitance per DQS and DQ byte/group will not differ by more than this maximum amount for any given device.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Electrical Specifications – IDD Parameters
Table 41: IDD Specifications and Conditions, –25°C to +85°C (x16)
Notes 1–5 apply to all the parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Max
Parameter/Condition
Symbol
-5
-54
-6
-75
Unit Notes
Operating 1 bank active precharge current: tRC = tRC (MIN); tCK
= tCK (MIN); CKE is HIGH; CS is HIGH between valid commands;
Address inputs are switching every 2 clock cycles; Data bus inputs are stable
IDD0
75
75
75
70
mA
6
Precharge power-down standby current: All banks idle; CKE is
LOW; CS is HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2P
900
900
900
900
μA
7, 8
Precharge power-down standby current: Clock stopped; All
banks idle; CKE is LOW; CS is HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2PS
900
900
900
900
μA
7
Precharge nonpower-down standby current: All banks idle;
CKE = HIGH; CS = HIGH; tCK = tCK (MIN); Address and control
inputs are switching; Data bus inputs are stable
IDD2N
15
15
15
12
mA
9
Precharge nonpower-down standby current: Clock stopped; All
banks idle; CKE = HIGH; CS = HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2NS
9
9
8
8
mA
9
Active power-down standby current: 1 bank active; CKE = LOW;
CS = HIGH; tCK = tCK (MIN); Address and control inputs are
switching; Data bus inputs are stable
IDD3P
5
5
5
5
mA
8
Active power-down standby current: Clock stopped; 1 bank active; CKE = LOW; CS = HIGH; CK = LOW; CK# = HIGH; Address
and control inputs are switching; Data bus inputs are stable
IDD3PS
5
5
5
5
mA
Active nonpower-down standby: 1 bank active; CKE = HIGH; CS
= HIGH; tCK = tCK (MIN); Address and control inputs are switching; Data bus inputs are stable
IDD3N
17
17
16
15
mA
6
Active nonpower-down standby: Clock stopped; 1 bank active;
CKE = HIGH; CS = HIGH; CK = LOW; CK# = HIGH; Address and
control inputs are switching; Data bus inputs are stable
IDD3NS
14
14
13
12
mA
6
Operating burst read: 1 bank active; BL = 4; tCK = tCK (MIN);
Continuous READ bursts; Iout = 0mA; Address inputs are
switching every 2 clock cycles; 50% data changing each burst
IDD4R
90
90
90
90
mA
6
Operating burst write: 1 bank active; BL = 4; tCK = tCK (MIN);
Continuous WRITE bursts; Address inputs are switching; 50%
data changing each burst
IDD4W
90
90
90
90
mA
6
Auto refresh: Burst refresh; CKE = HIGH; Address and control inputs are switching; Data
bus inputs are stable
tRFC
= 138ns
IDD5
170
170
170
170
mA
10
tRFC
= tREFI
IDD5A
12
12
12
12
mA
10, 11
IDD8
10
10
10
10
μA
7, 13
Deep power-down current: Address and control balls are stable; Data bus inputs are stable
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Table 42: IDD Specifications and Conditions, –25°C to +85°C (x32)
Notes 1–5 apply to all the parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Max
Parameter/Condition
Symbol
-5
-54
-6
-75
Unit Notes
Operating 1 bank active precharge current: tRC = tRC (MIN); tCK
= tCK (MIN); CKE is HIGH; CS is HIGH between valid commands;
Address inputs are switching every 2 clock cycles; Data bus inputs are stable
IDD0
75
75
75
70
mA
6
Precharge power-down standby current: All banks idle; CKE is
LOW; CS is HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2P
900
900
900
900
μA
7, 8
Precharge power-down standby current: Clock stopped; All
banks idle; CKE is LOW; CS is HIGH, CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2PS
900
900
900
900
μA
7
Precharge nonpower-down standby current: All banks idle; CKE
= HIGH; CS = HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2N
15
15
15
12
mA
9
Precharge nonpower-down standby current: Clock stopped; All
banks idle; CKE = HIGH; CS = HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2NS
9
9
8
8
mA
9
Active power-down standby current: 1 bank active; CKE = LOW;
CS = HIGH; tCK = tCK (MIN); Address and control inputs are
switching; Data bus inputs are stable
IDD3P
5
5
5
5
mA
8
Active power-down standby current: Clock stopped; 1 bank active; CKE = LOW; CS = HIGH; CK = LOW; CK# = HIGH; Address
and control inputs are switching; Data bus inputs are stable
IDD3PS
5
5
5
5
mA
Active nonpower-down standby: 1 bank active; CKE = HIGH; CS
= HIGH; tCK = tCK (MIN); Address and control inputs are switching; Data bus inputs are stable
IDD3N
17
17
16
15
mA
6
Active nonpower-down standby: Clock stopped; 1 bank active;
CKE = HIGH; CS = HIGH; CK = LOW; CK# = HIGH; Address and
control inputs are switching; Data bus inputs are stable
IDD3NS
14
14
13
12
mA
6
Operating burst read: 1 bank active; BL = 4; CL = 3; tCK = tCK
(MIN); Continuous READ bursts; Iout = 0mA; Address inputs are
switching every 2 clock cycles; 50% data changing each burst
IDD4R
90
90
90
90
mA
6
Operating burst write: One bank active; BL = 4; tCK = tCK
(MIN); Continuous WRITE bursts; Address inputs are switching;
50% data changing each burst
IDD4W
90
90
90
90
mA
6
Auto refresh: Burst refresh; CKE = HIGH; Address and control inputs are switching; Data
bus inputs are stable
tRFC
= 138ns
IDD5
170
170
170
170
mA
10
tRFC
= tREFI
IDD5A
12
12
12
12
mA
10, 11
IDD8
10
10
10
10
μA
7, 13
Deep power-down current: Address and control pins are stable;
Data bus inputs are stable
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Table 43: IDD Specifications and Conditions, –40°C to +105°C (x16)
Notes 1–5 apply to all the parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Max
Parameter/Condition
Symbol
-5
-54
-6
-75
Unit Notes
(MIN);
Operating 1 bank active precharge current:
= tCK (MIN); CKE is HIGH; CS is HIGH between valid commands;
Address inputs are switching every 2 clock cycles; Data bus inputs are stable
IDD0
100
100
80
70
mA
6
Precharge power-down standby current: All banks idle; CKE is
LOW; CS is HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2P
1500
1500
1500
1500
μA
7, 8
Precharge power-down standby current: Clock stopped; All
banks idle; CKE is LOW; CS is HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2PS
1500
1500
1500
1500
μA
7
Precharge nonpower-down standby current: All banks idle;
CKE = HIGH; CS = HIGH; tCK = tCK (MIN); Address and control
inputs are switching; Data bus inputs are stable
IDD2N
19
19
19
16
mA
9
Precharge nonpower-down standby current: Clock stopped; All
banks idle; CKE = HIGH; CS = HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2NS
13
13
12
12
mA
9
Active power-down standby current: 1 bank active; CKE = LOW;
CS = HIGH; tCK = tCK (MIN); Address and control inputs are
switching; Data bus inputs are stable
IDD3P
9
9
9
9
mA
8
Active power-down standby current: Clock stopped; 1 bank active; CKE = LOW; CS = HIGH; CK = LOW; CK# = HIGH; Address
and control inputs are switching; Data bus inputs are stable
IDD3PS
9
9
9
9
mA
Active nonpower-down standby: 1 bank active; CKE = HIGH; CS
= HIGH; tCK = tCK (MIN); Address and control inputs are switching; Data bus inputs are stable
IDD3N
21
21
20
19
mA
6
Active nonpower-down standby: Clock stopped; 1 bank active;
CKE = HIGH; CS = HIGH; CK = LOW; CK# = HIGH; Address and
control inputs are switching; Data bus inputs are stable
IDD3NS
18
18
17
15
mA
6
Operating burst read: 1 bank active; BL = 4; tCK = tCK (MIN);
Continuous READ bursts; Iout = 0mA; Address inputs are
switching every 2 clock cycles; 50% data changing each burst
IDD4R
130
125
115
105
mA
6
Operating burst write: 1 bank active; BL = 4; tCK = tCK (MIN);
Continuous WRITE bursts; Address inputs are switching; 50%
data changing each burst
IDD4W
130
125
115
105
mA
6
tRC
Auto refresh: Burst refresh; CKE = HIGH; Address and control inputs are switching; Data
bus inputs are stable
= tRC
tCK
tRFC
= 138ns
IDD5
170
170
170
170
mA
10
tRFC
tREFI
IDD5A
13
13
13
13
mA
10, 11
IDD8
15
15
15
15
μA
7, 13
=
Deep power-down current: Address and control balls are stable; Data bus inputs are stable
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Table 44: IDD Specifications and Conditions, –40°C to +105°C (x32)
Notes 1–5 apply to all the parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Max
Parameter/Condition
Symbol
-5
-54
-6
-75
Unit Notes
(MIN);
Operating 1 bank active precharge current:
= tCK (MIN); CKE is HIGH; CS is HIGH between valid commands;
Address inputs are switching every 2 clock cycles; Data bus inputs are stable
IDD0
100
100
80
70
mA
6
Precharge power-down standby current: All banks idle; CKE is
LOW; CS is HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2P
1500
1500
1500
1500
μA
7, 8
Precharge power-down standby current: Clock stopped; All
banks idle; CKE is LOW; CS is HIGH, CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2PS
1500
1500
1500
1500
μA
7
Precharge nonpower-down standby current: All banks idle; CKE
= HIGH; CS = HIGH; tCK = tCK (MIN); Address and control inputs
are switching; Data bus inputs are stable
IDD2N
19
19
19
16
mA
9
Precharge nonpower-down standby current: Clock stopped; All
banks idle; CKE = HIGH; CS = HIGH; CK = LOW, CK# = HIGH; Address and control inputs are switching; Data bus inputs are stable
IDD2NS
13
13
12
12
mA
9
Active power-down standby current: 1 bank active; CKE = LOW;
CS = HIGH; tCK = tCK (MIN); Address and control inputs are
switching; Data bus inputs are stable
IDD3P
9
9
9
9
mA
8
Active power-down standby current: Clock stopped; 1 bank active; CKE = LOW; CS = HIGH; CK = LOW; CK# = HIGH; Address
and control inputs are switching; Data bus inputs are stable
IDD3PS
9
9
9
9
mA
Active nonpower-down standby: 1 bank active; CKE = HIGH; CS
= HIGH; tCK = tCK (MIN); Address and control inputs are switching; Data bus inputs are stable
IDD3N
21
21
20
19
mA
6
Active nonpower-down standby: Clock stopped; 1 bank active;
CKE = HIGH; CS = HIGH; CK = LOW; CK# = HIGH; Address and
control inputs are switching; Data bus inputs are stable
IDD3NS
18
18
17
15
mA
6
Operating burst read: 1 bank active; BL = 4; CL = 3; tCK = tCK
(MIN); Continuous READ bursts; Iout = 0mA; Address inputs are
switching every 2 clock cycles; 50% data changing each burst
IDD4R
150
145
140
120
mA
6
Operating burst write: One bank active; BL = 4; tCK = tCK
(MIN); Continuous WRITE bursts; Address inputs are switching;
50% data changing each burst
IDD4W
150
145
140
120
mA
6
tRC
Auto refresh: Burst refresh; CKE = HIGH; Address and control inputs are switching; Data
bus inputs are stable
= tRC
tCK
tRFC
= 138ns
IDD5
170
170
170
170
mA
10
tRFC
tREFI
IDD5A
13
13
13
13
mA
10, 11
IDD8
15
15
15
15
μA
7, 13
=
Deep power-down current: Address and control pins are stable;
Data bus inputs are stable
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Table 45: IDD6 Specifications and Conditions
Notes 1–5, 7, and 12 apply to all the parameters/conditions in this table; VDD/VDDQ = 1.70–1.95V
Parameter/Condition
Symbol
Self refresh:
CKE = LOW; tCK = tCK (MIN); Address and control inputs
are stable; Data bus inputs are stable
Notes:
Value
Units
n/a14
μA
2000
μA
Full array, 45˚C
900
μA
1/2 array, 85˚C
1450
μA
1/2 array, 45˚C
700
μA
1/4 array, 85˚C
1230
μA
Full array, 105˚C
Full array, 85˚C
IDD6
1/4 array, 45˚C
600
μA
1/8 array, 85˚C
1090
μA
1/8 array, 45˚C
575
μA
1/16 array, 85˚C
1020
μA
1/16 array, 45˚C
550
μA
1. All voltages referenced to VSS.
2. Tests for IDD characteristics may be conducted at nominal supply voltage levels, but the
related specifications and device operation are guaranteed for the full voltage range
specified.
3. Timing and IDD tests may use a VIL-to-VIH swing of up to 1.5V in the test environment,
but input timing is still referenced to VDDQ/2 (or to the crossing point for CK/CK#). The
output timing reference voltage level is VDDQ/2.
4. IDD is dependent on output loading and cycle rates. Specified values are obtained with
minimum cycle time with the outputs open.
5. IDD specifications are tested after the device is properly initialized and values are averaged at the defined cycle rate.
6. MIN (tRC or tRFC) for IDD measurements is the smallest multiple of tCK that meets the
minimum absolute value for the respective parameter. tRASmax for IDD measurements is
the largest multiple of tCK that meets the maximum absolute value for tRAS.
7. Measurement is taken 500ms after entering into this operating mode to provide settling
time for the tester.
8. VDD must not vary more than 4% if CKE is not active while any bank is active.
9. IDD2N specifies DQ, DQS, and DM to be driven to a valid high or low logic level.
10. CKE must be active (HIGH) during the entire time a REFRESH command is executed.
From the time the AUTO REFRESH command is registered, CKE must be active at each
rising clock edge until tRFC later.
11. This limit is a nominal value and does not result in a fail. CKE is HIGH during REFRESH
command period (tRFC (MIN)) else CKE is LOW (for example, during standby).
12. Values for IDD6 85˚C are guaranteed for the entire temperature range. All other IDD6 values are estimated.
13. Typical values at 25˚C, not a maximum value.
14. Self refresh is not supported for AT (85˚C to 105˚C) operation.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – IDD Parameters
Figure 104: Typical Self Refresh Current vs. Temperature
1600
1500
Full Array
1400
1/2 Array
1300
1/4 Array
1/8 Array
1200
1/16 Array
Current [μA]
1100
1000
900
800
700
600
500
400
300
200
100
0
–45
–35
–25
–15
–5
5
15
25
35
45
55
65
75
85
Temperature °C
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Operating Conditions
Electrical Specifications – AC Operating Conditions
Table 46: Electrical Characteristics and Recommended AC Operating Conditions
Notes 1–9 apply to all the parameters in this table; VDD/VDDQ = 1.70–1.95V
-5
-54
Parameter
Access window of
DQ from CK/CK#
CL = 3
-6
-75
Symbol
Min
Max
Min
Max
Min
Max
Min
Max
Unit
tAC
2.0
5.0
2.0
5.0
2.0
5.0
2.0
6.0
ns
2.0
6.5
2.0
6.5
2.0
6.5
2.0
6.5
tCK
5.0
–
5.4
–
6
–
7.5
–
12
–
12
–
12
–
12
–
CK high-level width
tCH
0.45
0.55
0.45
0.55
0.45
0.55
0.45
0.55
tCK
CK low-level width
tCL
0.45
0.55
0.45
0.55
0.45
0.55
0.45
0.55
tCK
CKE minimum pulse width
(high and low)
tCKE
1
–
1
–
1
–
1
–
tCK
11
Auto precharge write recovery + precharge time
tDAL
–
–
–
–
–
–
–
–
–
12
DQ and DM input hold
time relative to DQS (fast
slew rate)
tDH
f
0.48
–
0.54
–
0.6
–
0.8
–
ns
13, 14,
15
DQ and DM input hold
time relative to DQS (slow
slew rate)
tDH
s
0.58
–
0.64
–
0.7
–
0.9
–
ns
DQ and DM input setup
time relative to DQS (fast
slew rate)
tDS
f
0.48
–
0.54
–
0.6
–
0.8
–
ns
DQ and DM input setup
time relative to DQS (slow
slew rate)
tDS
s
0.58
–
0.64
–
0.7
–
0.9
–
ns
tDIPW
1.8
–
1.9
–
2.1
–
1.8
–
ns
tDQSCK
2.0
5.0
2.0
5.0
2.0
5.0
2.0
6.0
ns
2.0
6.5
2.0
6.5
2.0
6.5
2.0
6.5
ns
Clock cycle time
CL = 2
Notes
CL = 3
CL = 2
DQ and DM input pulse
width (for each input)
Access window of
DQS from CK/CK#
CL = 3
CL = 2
ns
DQS input high pulse
width
tDQSH
0.4
0.6
0.4
0.6
0.4
0.6
0.4
0.6
tCK
DQS input low pulse
width
tDQSL
0.4
0.6
0.4
0.6
0.4
0.6
0.4
0.6
tCK
DQS–DQ skew, DQS to last
DQ valid, per group, per
access
tDQSQ
–
0.4
–
0.45
–
0.45
–
0.6
ns
WRITE command to first
DQS latching transition
tDQSS
0.75
1.25
0.75
1.25
0.75
1.25
0.75
1.25
tCK
DQS falling edge from CK
rising – hold time
tDSH
0.2
–
0.2
–
0.2
–
0.2
–
tCK
DQS falling edge to CK
rising – setup time
tDSS
0.2
–
0.2
–
0.2
–
0.2
–
tCK
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10
13, 14,
15
16
13, 17
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Operating Conditions
Table 46: Electrical Characteristics and Recommended AC Operating Conditions (Continued)
Notes 1–9 apply to all the parameters in this table; VDD/VDDQ = 1.70–1.95V
-5
-54
Parameter
-6
-75
Symbol
Min
Max
Min
Max
Min
Max
Min
Max
Data valid output window
(DVW)
n/a
tQH
tDQSQ
tQH
tDQSQ
tQH
tDQSQ
tQH
tDQSQ
Half-clock period
tHP
tCH,
-
–
tCL
Data-out High-Z
window from
CK/CK#
CL = 3
tHZ
CL = 2
-
tCH,
tCH,
–
tCL
-
–
tCL
tCH,
-
Unit
Notes
ns
17
–
ns
18
19, 20
tCL
–
5.0
–
5.0
–
5.5
–
6.0
ns
–
6.5
–
6.5
–
6.5
–
6.5
ns
Data-out Low-Z window
from CK/CK#
tLZ
1.0
–
1.0
–
1.0
–
1.0
–
ns
19
Address and control input
hold time (fast slew rate)
tIH
F
0.9
–
1.0
–
1.1
–
1.3
–
ns
15, 21
Address and control input
hold time (slow slew rate)
tIH
S
1.1
–
1.2
–
1.3
–
1.5
–
ns
Address and control input
setup time (fast slew rate)
tIS
F
0.9
–
1.0
–
1.1
–
1.3
–
ns
Address and control input
setup time (slow slew
rate)
tIS
S
1.1
–
1.2
–
1.3
–
1.5
–
ns
Address and control input
pulse width
tIPW
2.3
–
2.5
–
2.6
–
–
ns
LOAD MODE REGISTER
command cycle time
tMRD
–
tCK
–
ns
DQ–DQS hold, DQS to first
DQ to go nonvalid, per access
tIS
+
15, 21
16
tIH
tQH
2
tHP
–
-
–
tQHS
2
tHP
–
-
2
tHP
–
tQHS
–
-
–
tQHS
2
tHP
-
13, 17
tQHS
Data hold skew factor
tQHS
–
0.5
–
0.5
–
0.65
–
0.75
ns
ACTIVE-to-PRECHARGE
command
tRAS
40
70,000
42
70,000
42
70,000
45
70,000
ns
22
ACTIVE to ACTIVE/ACTIVE
to AUTO REFRESH command period
tRC
55
–
58.2
–
60
–
67.5
–
ns
23
Active to read or write delay
tRCD
15
–
16.2
–
18
–
22.5
–
ns
Refresh period
tREF
–
64
–
64
–
64
–
64
ms
29
Average periodic refresh
interval: 64Mb, 128Mb,
and 256Mb (x32)
tREFI
–
15.6
–
15.6
–
15.6
–
15.6
μs
29
Average periodic refresh
interval: 256Mb, 512Mb,
1Gb, 2Gb
tREFI
–
7.8
–
7.8
–
7.8
–
7.8
μs
29
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Operating Conditions
Table 46: Electrical Characteristics and Recommended AC Operating Conditions (Continued)
Notes 1–9 apply to all the parameters in this table; VDD/VDDQ = 1.70–1.95V
-5
-54
Parameter
-6
-75
Symbol
Min
Max
Min
Max
Min
Max
Min
Max
Unit
AUTO REFRESH command
period
tRFC
72
–
72
–
72
–
72
–
ns
PRECHARGE command period
tRP
15
–
16.2
–
18
–
22.5
–
ns
DQS read preamble CL = 3
tRPRE
0.9
1.1
0.9
1.1
0.9
1.1
0.9
1.1
tCK
CL = 2
tRPRE
0.5
1.1
0.5
1.1
0.5
1.1
0.5
1.1
tCK
DQS read postamble
tRPST
0.4
0.6
0.4
0.6
0.4
0.6
0.4
0.6
tCK
Active bank a to active
bank b command
tRRD
10
–
10.8
–
12
–
15
–
ns
Read of SRR to next valid
command
tSRC
CL + 1
–
CL + 1
–
CL + 1
–
CL + 1
–
tCK
SRR to read
tSRR
2
–
2
–
2
–
2
–
tCK
Internal temperature sensor valid temperature output enable
tTQ
2
–
2
–
2
–
2
–
ms
tWPRE
0.25
–
0.25
–
0.25
–
0.25
–
tCK
tWPRES
0
–
0
–
0
–
0
–
ns
24, 25
tWPST
0.4
0.6
0.4
0.6
0.4
0.6
0.4
0.6
tCK
26
tWR
15
–
15
–
15
–
15
–
ns
27
DQS write preamble
DQS write preamble setup
time
DQS write postamble
Write recovery time
Internal WRITE-to-READ
command delay
Exit power-down mode to
first valid command
Exit self refresh to first
valid command
Notes:
tWTR
2
–
2
–
1
–
1
–
tCK
tXP
2
–
2
–
1
–
1
–
tCK
tXSR
112.5
–
112.5
–
112.5
–
112.5
–
ns
Notes
28
1. All voltages referenced to VSS.
2. All parameters assume proper device initialization.
3. Tests for AC timing and electrical AC and DC characteristics may be conducted at nominal supply voltage levels, but the related specifications and device operation are guaranteed for the full voltage ranges specified.
4. The circuit shown below represents the timing reference load used in defining the relevant timing parameters of the device. It is not intended to be either a precise representation of the typical system environment or a depiction of the actual load presented by
a production tester. System designers will use IBIS or other simulation tools to correlate
the timing reference load to system environment. Specifications are correlated to production test conditions (generally a coaxial transmission line terminated at the tester
electronics). For the half-strength driver with a nominal 10pF load, parameters tAC and
tQH are expected to be in the same range. However, these parameters are not subject to
production test but are estimated by design/characterization. Use of IBIS or other simu-
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Electrical Specifications – AC Operating Conditions
lation tools for system design validation is suggested.
50
50
I/O
I/O
10pF
20pF
Full drive strength
Half drive strength
5. The CK/CK# input reference voltage level (for timing referenced to CK/CK#) is the point
at which CK and CK# cross; the input reference voltage level for signals other than
CK/CK# is VDDQ/2.
6. A CK and CK# input slew rate ≥1 V/ns (2 V/ns if measured differentially) is assumed for
all parameters.
7. All AC timings assume an input slew rate of 1 V/ns.
8. CAS latency definition: with CL = 2, the first data element is valid at (tCK + tAC) after the
clock at which the READ command was registered; for CL = 3, the first data element is
valid at (2 × tCK + tAC) after the first clock at which the READ command was registered.
9. Timing tests may use a VIL-to-VIH swing of up to 1.5V in the test environment, but input
timing is still referenced to VDDQ/2 or to the crossing point for CK/CK#. The output timing reference voltage level is VDDQ/2.
10. Clock frequency change is only permitted during clock stop, power-down, or self refresh
mode.
11. In cases where the device is in self refresh mode for tCKE, tCKE starts at the rising edge
of the clock and ends when CKE transitions HIGH.
t
12. DAL = (tWR/tCK) + (tRP/tCK): for each term, if not already an integer, round up to the
next highest integer.
13. Referenced to each output group: for x16, LDQS with DQ[7:0]; and UDQS with DQ[15:8].
For x32, DQS0 with DQ[7:0]; DQS1 with DQ[15:8]; DQS2 with DQ[23:16]; and DQS3 with
DQ[31:24].
14. DQ and DM input slew rates must not deviate from DQS by more than 10%. If the
DQ/DM/DQS slew rate is less than 1.0 V/ns, timing must be derated: 50ps must be added
to tDS and tDH for each 100 mV/ns reduction in slew rate. If the slew rate exceeds 4 V/ns,
functionality is uncertain.
15. The transition time for input signals (CAS#, CKE, CS#, DM, DQ, DQS, RAS#, WE#, and addresses) are measured between VIL(DC) to VIH(AC) for rising input signals and VIH(DC) to
VIL(AC) for falling input signals.
16. These parameters guarantee device timing but are not tested on each device.
17. The valid data window is derived by achieving other specifications: tHP (tCK/2), tDQSQ,
and tQH (tHP - tQHS). The data valid window derates directly proportional with the clock
duty cycle and a practical data valid window can be derived. The clock is provided a
maximum duty cycle variation of 45/55. Functionality is uncertain when operating beyond a 45/55 ratio.
18. tHP (MIN) is the lesser of tCL (MIN) and tCH (MIN) actually applied to the device CK and
CK# inputs, collectively.
19. tHZ and tLZ transitions occur in the same access time windows as valid data transitions.
These parameters are not referenced to a specific voltage level, but specify when the
device output is no longer driving (tHZ) or begins driving (tLZ).
20. tHZ (MAX) will prevail over tDQSCK (MAX) + tRPST (MAX) condition.
21. Fast command/address input slew rate ≥1 V/ns. Slow command/address input slew rate
≥0.5 V/ns. If the slew rate is less than 0.5 V/ns, timing must be derated: tIS has an additional 50ps per each 100 mV/ns reduction in slew rate from the 0.5 V/ns. tIH has 0ps added, therefore, it remains constant. If the slew rate exceeds 4.5 V/ns, functionality is uncertain.
22. READs and WRITEs with auto precharge must not be issued until tRAS (MIN) can be satisfied prior to the internal PRECHARGE command being issued.
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Electrical Specifications – AC Operating Conditions
23. DRAM devices should be evenly addressed when being accessed. Disproportionate accesses to a particular row address may result in reduction of the product lifetime.
24. This is not a device limit. The device will operate with a negative value, but system performance could be degraded due to bus turnaround.
25. It is recommended that DQS be valid (HIGH or LOW) on or before the WRITE command.
The case shown (DQS going from High-Z to logic low) applies when no WRITEs were
previously in progress on the bus. If a previous WRITE was in progress, DQS could be
HIGH during this time, depending on tDQSS.
26. The maximum limit for this parameter is not a device limit. The device will operate with
a greater value for this parameter, but system performance (bus turnaround) will degrade accordingly.
27. At least 1 clock cycle is required during tWR time when in auto precharge mode.
28. Clock must be toggled a minimum of two times during the tXSR period.
29. For the Automotive Temperature parts, tREF = tREF /2 and tREF I = tREF I/2 .
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Output Drive Characteristics
Output Drive Characteristics
Table 47: Target Output Drive Characteristics (Full Strength)
Notes 1–2 apply to all values; characteristics are specified under best and worst process variations/conditions
Pull-Down Current (mA)
Pull-Up Current (mA)
Voltage (V)
Min
Max
Min
Max
0.00
0.00
0.00
0.00
0.00
0.10
2.80
18.53
–2.80
–18.53
0.20
5.60
26.80
–5.60
–26.80
0.30
8.40
32.80
–8.40
–32.80
0.40
11.20
37.05
–11.20
–37.05
0.50
14.00
40.00
–14.00
–40.00
0.60
16.80
42.50
–16.80
–42.50
0.70
19.60
44.57
–19.60
–44.57
0.80
22.40
46.50
–22.40
–46.50
0.85
23.80
47.48
–23.80
–47.48
0.90
23.80
48.50
–23.80
–48.50
0.95
23.80
49.40
–23.80
–49.40
1.00
23.80
50.05
–23.80
–50.05
1.10
23.80
51.35
–23.80
–51.35
1.20
23.80
52.65
–23.80
–52.65
1.30
23.80
53.95
–23.80
–53.95
1.40
23.80
55.25
–23.80
–55.25
1.50
23.80
56.55
–23.80
–56.55
1.60
23.80
57.85
–23.80
–57.85
1.70
23.80
59.15
–23.80
–59.15
1.80
–
60.45
–
–60.45
1.90
–
61.75
–
–61.75
Notes:
1. Based on nominal impedance of 25Ω (full strength) at VDDQ/2.
2. The full variation in driver current from minimum to maximum, due to process, voltage,
and temperature, will lie within the outer bounding lines of the I-V curves.
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Output Drive Characteristics
Table 48: Target Output Drive Characteristics (Three-Quarter Strength)
Notes 1–3 apply to all values; characteristics are specified under best and worst process variations/conditions
Pull-Down Current (mA)
Pull-Up Current (mA)
Voltage (V)
Min
Max
Min
Max
0.00
0.00
0.00
0.00
0.00
0.10
1.96
12.97
–1.96
–12.97
0.20
3.92
18.76
–3.92
–18.76
0.30
5.88
22.96
–5.88
–22.96
0.40
7.84
25.94
–7.84
–25.94
0.50
9.80
28.00
–9.80
–28.00
0.60
11.76
29.75
–11.76
–29.75
0.70
13.72
31.20
–13.72
–31.20
0.80
15.68
32.55
–15.68
–32.55
0.85
16.66
33.24
–16.66
–33.24
0.90
16.66
33.95
–16.66
–33.95
0.95
16.66
34.58
–16.66
–34.58
1.00
16.66
35.04
–16.66
–35.04
1.10
16.66
35.95
–16.66
–35.95
1.20
16.66
36.86
–16.66
–36.86
1.30
16.66
37.77
–16.66
–37.77
1.40
16.66
38.68
–16.66
–38.68
1.50
16.66
39.59
–16.66
–39.59
1.60
16.66
40.50
–16.66
–40.50
1.70
16.66
41.41
–16.66
–41.41
1.80
–
42.32
–
–42.32
1.90
–
43.23
–
–43.23
Notes:
1. Based on nominal impedance of 37Ω (three-quarter drive strength) at VDDQ/2.
2. The full variation in driver current from minimum to maximum, due to process, voltage,
and temperature, will lie within the outer bounding lines of the I-V curves.
3. Contact factory for availability of three-quarter drive strength.
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Output Drive Characteristics
Table 49: Target Output Drive Characteristics (One-Half Strength)
Notes 1–3 apply to all values; characteristics are specified under best and worst process variations/conditions
Pull-Down Current (mA)
Pull-Up Current (mA)
Voltage (V)
Min
Max
Min
Max
0.00
0.00
0.00
0.00
0.00
0.10
1.27
8.42
–1.27
–8.42
0.20
2.55
12.30
–2.55
–12.30
0.30
3.82
14.95
–3.82
–14.95
0.40
5.09
16.84
–5.09
–16.84
0.50
6.36
18.20
–6.36
–18.20
0.60
7.64
19.30
–7.64
–19.30
0.70
8.91
20.30
–8.91
–20.30
0.80
10.16
21.20
–10.16
–21.20
0.85
10.80
21.60
–10.80
–21.60
0.90
10.80
22.00
–10.80
–22.00
0.95
10.80
22.45
–10.80
–22.45
1.00
10.80
22.73
–10.80
–22.73
1.10
10.80
23.21
–10.80
–23.21
1.20
10.80
23.67
–10.80
–23.67
1.30
10.80
24.14
–10.80
–24.14
1.40
10.80
24.61
–10.80
–24.61
1.50
10.80
25.08
–10.80
–25.08
1.60
10.80
25.54
–10.80
–25.54
1.70
10.80
26.01
–10.80
–26.01
1.80
–
26.48
–
–26.48
1.90
–
26.95
–
–26.95
Notes:
1. Based on nominal impedance of 55Ω (one-half drive strength) at VDDQ/2.
2. The full variation in driver current from minimum to maximum, due to process, voltage,
and temperature, will lie within the outer bounding lines of the I-V curves.
3. The I-V curve for one-quarter drive strength is approximately 50% of one-half drive
strength.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Functional Description
Functional Description
The Mobile LPDDR SDRAM uses a double data rate architecture to achieve high-speed
operation. The double data rate architecture is essentially a 2n-prefetch architecture,
with an interface designed to transfer two data words per clock cycle at the I/O. Single
read or write access for the device consists of a single 2n-bit-wide, one-clock-cycle data
transfer at the internal DRAM core and two corresponding n-bit-wide, one-half-clockcycle data transfers at the I/O.
A bidirectional data strobe (DQS) is transmitted externally, along with data, for use in
data capture at the receiver. DQS is a strobe transmitted by the device during READs
and by the memory controller during WRITEs. DQS is edge-aligned with data for READs
and center-aligned with data for WRITEs. The x16 device has two data strobes, one for
the lower byte and one for the upper byte; the x32 device has four data strobes, one per
byte.
The LPDDR device operates from a differential clock (CK and CK#); the crossing of CK
going HIGH and CK# going LOW will be referred to as the positive edge of CK. Commands (address and control signals) are registered at every positive edge of CK. Input
data is registered on both edges of DQS, and output data is referenced to both edges of
DQS, as well as to both edges of CK.
Read and write accesses to the device are burst-oriented; accesses start at a selected location and continue for a programmed number of locations in a programmed sequence. Accesses begin with the registration of an ACTIVE command, followed by a
READ or WRITE command. The address bits registered coincident with the ACTIVE
command are used to select the bank and row to be accessed. The address bits registered coincident with the READ or WRITE command are used to select the starting column location for the burst access.
The device provides for programmable READ or WRITE burst lengths of 2, 4, 8, or 16. An
auto precharge function can be enabled to provide a self-timed row precharge that is
initiated at the end of the burst access.
As with standard DDR SDRAM, the pipelined, multibank architecture of LPDDR supports concurrent operation, thereby providing high effective bandwidth by hiding row
precharge and activation time.
An auto refresh mode is provided, along with a power-saving power-down mode. Deep
power-down mode is offered to achieve maximum power reduction by eliminating the
power of the memory array. Data will not be retained after the device enters deep power-down mode.
Two self refresh features, temperature-compensated self refresh (TCSR) and partial-array self refresh (PASR), offer additional power savings. TCSR is controlled by the automatic on-chip temperature sensor. PASR can be customized using the extended mode
register settings. The two features can be combined to achieve even greater power savings.
The DLL that is typically used on standard DDR devices is not necessary on LPDDR devices. It has been omitted to save power.
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Commands
Commands
A quick reference for available commands is provided in Table 50 and Table 51
(page 159), followed by a written description of each command. Three additional truth
tables (Table 52 (page 165), Table 53 (page 167), and Table 54 (page 169)) provide CKE
commands and current/next state information.
Table 50: Truth Table – Commands
CKE is HIGH for all commands shown except SELF REFRESH and DEEP POWER-DOWN; all states and sequences not shown
are reserved and/or illegal
Name (Function)
CS#
RAS# CAS#
WE#
Address
Notes
DESELECT (NOP)
H
X
X
X
X
1
NO OPERATION (NOP)
L
H
H
ACTIVE (select bank and activate row)
L
L
H
H
X
1
H
Bank/row
2
READ (select bank and column, and start READ burst)
L
H
L
H
Bank/column
3
WRITE (select bank and column, and start WRITE burst)
L
H
L
L
Bank/column
3
BURST TERMINATE or DEEP POWER-DOWN (enter deep
power-down mode)
L
H
H
L
X
4, 5
PRECHARGE (deactivate row in bank or banks)
L
L
H
L
Code
6
AUTO REFRESH (refresh all or single bank) or SELF REFRESH (enter self refresh mode)
L
L
L
H
X
7, 8
LOAD MODE REGISTER
L
L
L
L
Op-code
9
Notes:
1. DESELECT and NOP are functionally interchangeable.
2. BA0–BA1 provide bank address and A[0:I] provide row address (where I = the most significant address bit for each configuration).
3. BA0–BA1 provide bank address; A[0:I] provide column address (where I = the most significant address bit for each configuration); A10 HIGH enables the auto precharge feature (nonpersistent); A10 LOW disables the auto precharge feature.
4. Applies only to READ bursts with auto precharge disabled; this command is undefined
and should not be used for READ bursts with auto precharge enabled and for WRITE
bursts.
5. This command is a BURST TERMINATE if CKE is HIGH and DEEP POWER-DOWN if CKE is
LOW.
6. A10 LOW: BA0–BA1 determine which bank is precharged.
A10 HIGH: all banks are precharged and BA0–BA1 are “Don’t Care.”
7. This command is AUTO REFRESH if CKE is HIGH, SELF REFRESH if CKE is LOW.
8. Internal refresh counter controls row addressing; in self refresh mode all inputs and I/Os
are “Don’t Care” except for CKE.
9. BA0–BA1 select the standard mode register, extended mode register, or status register.
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Commands
Table 51: DM Operation Truth Table
Name (Function)
Notes:
DM
DQ
Notes
Write enable
L
Valid
1, 2
Write inhibit
H
X
1, 2
1. Used to mask write data; provided coincident with the corresponding data.
2. All states and sequences not shown are reserved and/or illegal.
DESELECT
The DESELECT function (CS# HIGH) prevents new commands from being executed by
the device. Operations already in progress are not affected.
NO OPERATION
The NO OPERATION (NOP) command is used to instruct the selected device to perform
a NOP. This prevents unwanted commands from being registered during idle or wait
states. Operations already in progress are not affected.
LOAD MODE REGISTER
The mode registers are loaded via inputs A[0:n]. See mode register descriptions in
Standard Mode Register and Extended Mode Register. The LOAD MODE REGISTER
command can only be issued when all banks are idle, and a subsequent executable
command cannot be issued until tMRD is met.
ACTIVE
The ACTIVE command is used to activate a row in a particular bank for a subsequent
access. The values on the BA0 and BA1 inputs select the bank, and the address provided
on inputs A[0:n] selects the row. This row remains active for accesses until a PRECHARGE command is issued to that bank. A PRECHARGE command must be issued before opening a different row in the same bank.
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Commands
Figure 105: ACTIVE Command
CK#
CK
CKE
HIGH
CS#
RAS#
CAS#
WE#
Address
Row
BA0, BA1
Bank
Don’t Care
READ
The READ command is used to initiate a burst read access to an active row. The values
on the BA0 and BA1 inputs select the bank; the address provided on inputs A[I:0] (where
I = the most significant column address bit for each configuration) selects the starting
column location. The value on input A10 determines whether auto precharge is used. If
auto precharge is selected, the row being accessed will be precharged at the end of the
READ burst; if auto precharge is not selected, the row will remain open for subsequent
accesses.
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Commands
Figure 106: READ Command
CK#
CK
CKE HIGH
CS#
RAS#
CAS#
WE#
Address
Column
EN AP
A10
DIS AP
BA0, BA1
Bank
Don’t Care
Note:
1. EN AP = enable auto precharge; DIS AP = disable auto precharge.
WRITE
The WRITE command is used to initiate a burst write access to an active row. The values
on the BA0 and BA1 inputs select the bank; the address provided on inputs A[I:0] (where
I = the most significant column address bit for each configuration) selects the starting
column location. The value on input A10 determines whether auto precharge is used. If
auto precharge is selected, the row being accessed will be precharged at the end of the
WRITE burst; if auto precharge is not selected, the row will remain open for subsequent
accesses. Input data appearing on the DQ is written to the memory array, subject to the
DM input logic level appearing coincident with the data. If a given DM signal is registered LOW, the corresponding data will be written to memory; if the DM signal is registered HIGH, the corresponding data inputs will be ignored, and a WRITE will not be
executed to that byte/column location.
If a WRITE or a READ is in progress, the entire data burst must be complete prior to
stopping the clock (see Clock Change Frequency (page 219)). A burst completion for
WRITEs is defined when the write postamble and tWR or tWTR are satisfied.
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Commands
Figure 107: WRITE Command
CK#
CK
CKE
HIGH
CS#
RAS#
CAS#
WE#
Address
Column
EN AP
A10
DIS AP
BA0, BA1
Bank
Don’t Care
Note:
1. EN AP = enable auto precharge; DIS AP = disable auto precharge.
PRECHARGE
The PRECHARGE command is used to deactivate the open row in a particular bank or
the open row in all banks. The bank(s) will be available for a subsequent row access a
specified time (tRP) after the PRECHARGE command is issued. Input A10 determines
whether one or all banks will be precharged, and in the case where only one bank is precharged, inputs BA0 and BA1 select the bank. Otherwise, BA0 and BA1 are treated as
“Don’t Care.” After a bank has been precharged, it is in the idle state and must be activated prior to any READ or WRITE commands being issued to that bank.
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Commands
Figure 108: PRECHARGE Command
CK#
CK
CKE
HIGH
CS#
RAS#
CAS#
WE#
Address
All banks
A10
Single bank
BA0, BA1
Bank
Don’t Care
Note:
1. If A10 is HIGH, bank address becomes “Don’t Care.”
BURST TERMINATE
The BURST TERMINATE command is used to truncate READ bursts with auto precharge disabled. The most recently registered READ command prior to the BURST TERMINATE command will be truncated, as described in READ Operation. The open page
from which the READ was terminated remains open.
AUTO REFRESH
AUTO REFRESH is used during normal operation of the device and is analogous to
CAS#-BEFORE-RAS# (CBR) REFRESH in FPM/EDO DRAM. The AUTO REFRESH command is nonpersistent and must be issued each time a refresh is required.
Addressing is generated by the internal refresh controller. This makes the address bits a
“Don’t Care” during an AUTO REFRESH command.
For improved efficiency in scheduling and switching between tasks, some flexibility in
the absolute refresh interval is provided. The auto refresh period begins when the AUTO
REFRESH command is registered and ends tRFC later.
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Commands
SELF REFRESH
The SELF REFRESH command is used to place the device in self refresh mode; self refresh mode is used to retain data in the memory device while the rest of the system is
powered down. When in self refresh mode, the device retains data without external
clocking. The SELF REFRESH command is initiated like an AUTO REFRESH command,
except that CKE is disabled (LOW). After the SELF REFRESH command is registered, all
inputs to the device become “Don’t Care” with the exception of CKE, which must remain LOW.
Micron recommends that, prior to self refresh entry and immediately upon self refresh
exit, the user perform a burst auto refresh cycle for the number of refresh rows. Alternatively, if a distributed refresh pattern is used, this pattern should be immediately resumed upon self refresh exit.
DEEP POWER-DOWN
The DEEP POWER-DOWN (DPD) command is used to enter DPD mode, which achieves
maximum power reduction by eliminating the power to the memory array. Data will not
be retained when the device enters DPD mode. The DPD command is the same as a
BURST TERMINATE command with CKE LOW.
Figure 109: DEEP POWER-DOWN Command
CK#
CK
CKE
CS#
RAS#
CAS#
WE#
Address
BA0, BA1
Don’t Care
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Truth Tables
Truth Tables
Table 52: Truth Table – Current State Bank n – Command to Bank n
Notes 1–6 apply to all parameters in this table
Current State
CS#
RAS# CAS# WE#
Any
Idle
Row active
Read (auto precharge disabled)
Write (auto precharge disabled)
Command/Action
Notes
H
X
X
X
DESELECT (NOP/continue previous operation)
L
H
H
H
NO OPERATION (NOP/continue previous operation)
L
L
H
H
ACTIVE (select and activate row)
L
L
L
H
AUTO REFRESH
L
L
L
L
LOAD MODE REGISTER
7
L
H
L
H
READ (select column and start READ burst)
10
L
H
L
L
WRITE (select column and start WRITE burst)
10
L
L
H
L
PRECHARGE (deactivate row in bank or banks)
8
L
H
L
H
READ (select column and start new READ burst)
L
H
L
L
WRITE (select column and start WRITE burst)
L
L
H
L
PRECHARGE (truncate READ burst, start PRECHARGE)
8
L
H
H
L
BURST TERMINATE
9
L
H
L
H
READ (select column and start READ burst)
L
H
L
L
WRITE (select column and start new WRITE burst)
L
L
H
L
PRECHARGE (truncate WRITE burst, start PRECHARGE)
Notes:
7
10
10, 12
10, 11
10
8, 11
1. This table applies when CKEn - 1 was HIGH, CKEn is HIGH and after tXSR has been met (if
the previous state was self refresh), after tXP has been met (if the previous state was
power-down), or after a full initialization (if the previous state was deep power-down).
2. This table is bank-specific, except where noted (for example, the current state is for a
specific bank and the commands shown are supported for that bank when in that state).
Exceptions are covered in the notes below.
3. Current state definitions:
Idle: The bank has been precharged, and tRP has been met.
Row active: A row in the bank has been activated, and tRCD has been met. No data
bursts/accesses and no register accesses are in progress.
Read: A READ burst has been initiated with auto precharge disabled and has not yet terminated or been terminated.
Write: A WRITE burst has been initiated with auto precharge disabled and has not yet
terminated or been terminated.
4. The states listed below must not be interrupted by a command issued to the same bank.
COMMAND INHIBIT or NOP commands, or supported commands to the other bank,
must be issued on any clock edge occurring during these states. Supported commands to
any other bank are determined by that bank’s current state.
Precharging: Starts with registration of a PRECHARGE command and ends when tRP is
met. After tRP is met, the bank will be in the idle state.
Row activating: Starts with registration of an ACTIVE command and ends when tRCD is
met. After tRCD is met, the bank will be in the row active state.
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Truth Tables
Read with auto-precharge enabled: Starts with registration of a READ command with
auto precharge enabled and ends when tRP has been met. After tRP is met, the bank will
be in the idle state.
Write with auto-precharge enabled: Starts with registration of a WRITE command with
auto precharge enabled and ends when tRP has been met. After tRP is met, the bank
will be in the idle state.
5. The states listed below must not be interrupted by any executable command; DESELECT
or NOP commands must be applied on each positive clock edge during these states.
Refreshing: Starts with registration of an AUTO REFRESH command and ends when tRFC
is met. After tRFC is met, the device will be in the all banks idle state.
Accessing mode register: Starts with registration of a LOAD MODE REGISTER command
and ends when tMRD has been met. After tMRD is met, the device will be in the all
banks idle state.
Precharging all: Starts with registration of a PRECHARGE ALL command and ends when
is met. After tRP is met, all banks will be in the idle state.
All states and sequences not shown are illegal or reserved.
Not bank-specific; requires that all banks are idle, and bursts are not in progress.
May or may not be bank-specific; if multiple banks need to be precharged, each must be
in a valid state for precharging.
Not bank-specific; BURST TERMINATE affects the most recent READ burst, regardless of
bank.
READs or WRITEs listed in the Command/Action column include READs or WRITEs with
auto precharge enabled and READs or WRITEs with auto precharge disabled.
Requires appropriate DM masking.
A WRITE command can be applied after the completion of the READ burst; otherwise, a
BURST TERMINATE must be used to end the READ burst prior to asserting a WRITE command.
tRP
6.
7.
8.
9.
10.
11.
12.
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Truth Tables
Table 53: Truth Table – Current State Bank n – Command to Bank m
Notes 1–6 apply to all parameters in this table
Current State
CS#
RAS# CAS#
WE#
Any
Command/Action
Notes
H
X
X
X
DESELECT (NOP/continue previous operation)
L
H
H
H
NO OPERATION (NOP/continue previous operation)
Idle
X
X
X
X
Any command supported to bank m
Row activating,
active, or precharging
L
L
H
H
ACTIVE (select and activate row)
L
H
L
H
READ (select column and start READ burst)
L
H
L
L
WRITE (select column and start WRITE burst)
L
L
H
L
PRECHARGE
L
L
H
H
ACTIVE (select and activate row)
L
H
L
H
READ (select column and start new READ burst)
L
H
L
L
WRITE (select column and start WRITE burst)
L
L
H
L
PRECHARGE
L
L
H
H
ACTIVE (select and activate row)
L
H
L
H
READ (select column and start READ burst)
L
H
L
L
WRITE (select column and start new WRITE burst)
L
L
H
L
PRECHARGE
L
L
H
H
ACTIVE (select and activate row)
L
H
L
H
READ (select column and start new READ burst)
L
H
L
L
WRITE (select column and start WRITE burst)
L
L
H
L
PRECHARGE
L
L
H
H
ACTIVE (select and activate row)
L
H
L
H
READ (select column and start READ burst)
L
H
L
L
WRITE (select column and start new WRITE burst)
L
L
H
L
PRECHARGE
Notes:
1. This table applies when CKEn - 1 was HIGH, CKEn is HIGH and after tXSR has been met (if
the previous state was self refresh), after tXP has been met (if the previous state was
power-down) or after a full initialization (if the previous state was deep power-down).
2. This table describes alternate bank operation, except where noted (for example, the current state is for bank n and the commands shown are those supported for issue to bank
m, assuming that bank m is in such a state that the given command is supported). Exceptions are covered in the notes below.
3. Current state definitions:
Read (auto precharge disabled)
Write (auto precharge disabled)
Read (with auto
precharge)
Write (with auto
precharge)
7
7
Idle: The bank has been precharged, and tRP has been met.
Row active: A row in the bank has been activated, and tRCD has been met. No data
bursts/accesses and no register accesses are in progress.
Read: A READ burst has been initiated and has not yet terminated or been terminated.
Write: A WRITE burst has been initiated and has not yet terminated or been terminated.
3a. Both the read with auto precharge enabled state or the write with auto precharge
enabled state can be broken into two parts: the access period and the precharge period.
For read with auto precharge, the precharge period is defined as if the same burst was
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Truth Tables
executed with auto precharge disabled and then followed with the earliest possible
PRECHARGE command that still accesses all of the data in the burst. For write with auto
precharge, the precharge period begins when tWR ends, with tWR measured as if auto
precharge was disabled. The access period starts with registration of the command and
ends when the precharge period (or tRP) begins. This device supports concurrent auto
precharge such that when a read with auto precharge is enabled or a write with auto
precharge is enabled, any command to other banks is supported, as long as that command does not interrupt the read or write data transfer already in process. In either
case, all other related limitations apply (i.e., contention between read data and write
data must be avoided).
3b. The minimum delay from a READ or WRITE command (with auto precharge enabled)
to a command to a different bank is summarized below.
From
Command
Minimum Delay
(with Concurrent Auto
Precharge)
To Command
WRITE with
Auto Precharge
READ or READ with auto precharge
WRITE or WRITE with auto precharge
PRECHARGE
ACTIVE
[1 + (BL/2)] tCK + tWTR
(BL/2) tCK
1 tCK
1 tCK
READ with
Auto Precharge
READ or READ with auto precharge
WRITE or WRITE with auto precharge
PRECHARGE
ACTIVE
(BL/2) × tCK
[CL + (BL/2)] tCK
1 tCK
1 tCK
4. AUTO REFRESH and LOAD MODE REGISTER commands can only be issued when all
banks are idle.
5. All states and sequences not shown are illegal or reserved.
6. Requires appropriate DM masking.
7. A WRITE command can be applied after the completion of the READ burst; otherwise, a
BURST TERMINATE must be used to end the READ burst prior to asserting a WRITE command.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Truth Tables
Table 54: Truth Table – CKE
Notes 1–4 apply to all parameters in this table
Current State
CKEn - 1 CKEn
COMMANDn
ACTIONn
Notes
Active power-down
L
L
X
Maintain active power-down
Deep power-down
L
L
X
Maintain deep power-down
Precharge power-down
L
L
X
Maintain precharge power-down
Self refresh
L
L
X
Maintain self refresh
Active power-down
L
H
DESELECT or NOP
Exit active power-down
5
Deep power-down
L
H
DESELECT or NOP
Exit deep power-down
6
Precharge power-down
L
H
DESELECT or NOP
Exit precharge power-down
Self refresh
L
H
DESELECT or NOP
Exit self refresh
Bank(s) active
H
L
DESELECT or NOP
Active power-down entry
All banks idle
H
L
BURST TERMINATE
Deep power-down entry
All banks idle
H
L
DESELECT or NOP
Precharge power-down entry
All banks idle
H
L
AUTO REFRESH
Self refresh entry
H
H
See Table 53 (page 167)
H
H
See Table 53 (page 167)
Notes:
5, 7
1. CKEn is the logic state of CKE at clock edge n; CKEn - 1 was the state of CKE at the previous clock edge.
2. Current state is the state of the DDR SDRAM immediately prior to clock edge n.
3. COMMANDn is the command registered at clock edge n, and ACTIONn is a result of
COMMANDn.
4. All states and sequences not shown are illegal or reserved.
5. DESELECT or NOP commands should be issued on each clock edge occurring during the
tXP or tXSR period.
6. After exiting deep power-down mode, a full DRAM initialization sequence is required.
7. The clock must toggle at least two times during the tXSR period.
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State Diagram
State Diagram
Figure 110: Simplified State Diagram
Power
applied
Power
on
Self
refresh
DPDX
PRE
Deep
powerdown
PREALL
SRR
Idle:
all banks
precharged
LMR
LMR
EMR
READ
SRR
DPD
LMR
READ
SREFX
SREF
Auto
refresh
AREF
CKEL
CKEH
Active
powerdown
Precharge
powerdown
ACT
CKEH
CKEL
Row
active
Burst
terminate
READ
WRITE
BST
WRITE
WRITE A
READ
READ A
READ
WRITING
READING
WRITE
WRITE A
WRITING
PRE
READ A
WRITE A
PRE
READ A
PRE
PRE
READING
Precharging
Automatic sequence
Command sequence
ACT = ACTIVE
AREF = AUTO REFRESH
BST = BURST TERMINATE
CKEH = Exit power-down
CKEL = Enter power-down
DPD = Enter deep power-down
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DPDX = Exit deep power-down
EMR = LOAD EXTENDED MODE REGISTER
LMR = LOAD MODE REGISTER
PRE = PRECHARGE
PREALL = PRECHARGE all banks
READ = READ w/o auto precharge
170
READ A = READ w/ auto precharge
SREF = Enter self refresh
SREFX = Exit self refresh
SRR = STATUS REGISTER READ
WRITE = WRITE w/o auto precharge
WRITE A = WRITE w/ auto precharge
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Initialization
Initialization
Prior to normal operation, the device must be powered up and initialized in a predefined manner. Using initialization procedures other than those specified will result in
undefined operation.
If there is an interruption to the device power, the device must be re-initialized using
the initialization sequence described below to ensure proper functionality of the device.
To properly initialize the device, this sequence must be followed:
1. The core power (VDD) and I/O power (VDDQ) must be brought up simultaneously.
It is recommended that V DD and V DDQ be from the same power source, or V DDQ
must never exceed V DD. Standard initialization requires that CKE be asserted
HIGH (see Figure 111 (page 172)). Alternatively, initialization can be completed
with CKE LOW provided that CKE transitions HIGH tIS prior to T0 (see Figure 112
(page 173)).
2. When power supply voltages are stable and the CKE has been driven HIGH, it is
safe to apply the clock.
3. When the clock is stable, a 200μs minimum delay is required by the Mobile LPDDR
prior to applying an executable command. During this time, NOP or DESELECT
commands must be issued on the command bus.
4. Issue a PRECHARGE ALL command.
5. Issue NOP or DESELECT commands for at least tRP time.
6. Issue an AUTO REFRESH command followed by NOP or DESELECT commands
for at least tRFC time. Issue a second AUTO REFRESH command followed by NOP
or DESELECT commands for at least tRFC time. Two AUTO REFRESH commands
must be issued. Typically, both of these commands are issued at this stage as described above.
7. Using the LOAD MODE REGISTER command, load the standard mode register as
desired.
8. Issue NOP or DESELECT commands for at least tMRD time.
9. Using the LOAD MODE REGISTER command, load the extended mode register to
the desired operating modes. Note that the sequence in which the standard and
extended mode registers are programmed is not critical.
10. Issue NOP or DESELECT commands for at least tMRD time.
After steps 1–10 are completed, the device has been properly initialized and is ready to
receive any valid command.
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Initialization
Figure 111: Initialize and Load Mode Registers
((
))
VDD
((
))
VDDQ
T1
T0
CK#
((
))
((
))
CK
LVCMOS
HIGH LEVEL
CKE
((
))
((
))
Command1
((
))
((
))
tCH
tIS
NOP2
tCL
Ta0
Tb0
Tc0
Td0
Te0
Tf0
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
tIH
NOP
PRE
tCK
((
))
((
))
AR
((
))
((
))
AR
((
))
((
))
LMR
((
))
((
))
LMR
((
))
((
))
ACT3
((
))
((
))
DM
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
Address
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
A10
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
BA0, BA1
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
DQS
((
))
High-Z
((
))
((
))
((
))
((
))
((
))
((
))
DQ
((
))
High-Z
((
))
((
))
((
))
((
))
((
))
((
))
tRFC4
tRFC4
tMRD4
((
))
((
))
tIS
All banks
tIS
T = 200μs
tIH
tRP4
Power-up: VDD and CK stable
Notes:
((
))
((
))
Op-code
((
))
((
))
Row
((
))
((
))
((
))
((
))
Op-code
((
))
((
))
Row
((
))
((
))
((
))
((
))
BA0 = L,
BA1 = H
((
))
((
))
Bank
((
))
((
))
tIH
Op-code
tIS
((
))
((
))
tIH
Op-code
tIS
((
))
((
))
NOP3
tIH
BA0 = L,
BA1 = L
Load standard
mode register
tMRD4
Load extended
mode register
Don’t Care
1. PRE = PRECHARGE command; LMR = LOAD MODE REGISTER command; AR = AUTO REFRESH command; ACT = ACTIVE command.
2. NOP or DESELECT commands are required for at least 200μs.
3. Other valid commands are possible.
4. NOPs or DESELECTs are required during this time.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Initialization
Figure 112: Alternate Initialization with CKE LOW
((
))
VDD
((
))
VDDQ
T1
T0
CK#
((
))
((
))
CK
tCH
tCL
Ta0
Tb0
Tc0
Td0
Te0
Tf0
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
((
))
tIS
CKE
1
Command
LVCMOS
LOW level
2
NOP
((
))
((
))
((
))
((
))
tIS
tIH
NOP
PRE
((
))
((
))
AR
((
))
((
))
AR
((
))
((
))
LMR
((
))
((
))
LMR
((
))
((
))
ACT3
((
))
((
))
NOP3
T = 200μs
Don’t Care
Power up: VDD and CK stable
Notes:
1. PRE = PRECHARGE command; LMR = LOAD MODE REGISTER command; AR = AUTO REFRESH command; ACT = ACTIVE command.
2. NOP or DESELECT commands are required for at least 200μs.
3. Other valid commands are possible.
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Standard Mode Register
Standard Mode Register
The standard mode register bit definition enables the selection of burst length, burst
type, CAS latency (CL), and operating mode, as shown in Figure 113. Reserved states
should not be used as this may result in setting the device into an unknown state or
cause incompatibility with future versions of LPDDR devices. The standard mode register is programmed via the LOAD MODE REGISTER command (with BA0 = 0 and BA1 =
0) and will retain the stored information until it is programmed again, until the device
goes into deep power-down mode, or until the device loses power.
Reprogramming the mode register will not alter the contents of the memory, provided it
is performed correctly. The mode register must be loaded when all banks are idle and
no bursts are in progress, and the controller must wait tMRD before initiating the subsequent operation. Violating any of these requirements will result in unspecified operation.
Figure 113: Standard Mode Register Definition
BA1 BA0 An ... A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0
n + 2 n + 1 n ... 10 9 8
Operating Mode
0 0
7
6 5 4 3 2 1 0
CAS Latency BT Burst Length
Standard mode register (Mx)
Burst Length
Mn + 2 Mn + 1 Mode Register Definition
0
0
Standard mode register
0
1
Status register
0
0
1
0
Extended mode register
0
1
1
Reserved
0
M2 M1 M0
M3 = 0
M3 = 1
0
Reserved
Reserved
0
1
2
2
1
0
4
4
0
1
1
8
8
1
0
0
16
16
1
0
1
Reserved
Reserved
0
0
0
0
0
Normal operation
1
1
0
Reserved
Reserved
–
–
–
–
–
All other states reserved
1
1
1
Reserved
Reserved
Mn
... M10 M9 M8 M7 Operating Mode
M6 M5 M4
0
Note:
Address bus
0
0
Burst Type
CAS Latency
M3
Reserved
0
Sequential
1
Interleaved
0
0
1
Reserved
0
1
0
2
0
1
1
3
1
0
0
Reserved
1
0
1
Reserved
1
1
0
Reserved
1
1
1
Reserved
1. The integer n is equal to the most significant address bit.
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Standard Mode Register
Burst Length
Read and write accesses to the device are burst-oriented, and the burst length (BL) is
programmable. The burst length determines the maximum number of column locations that can be accessed for a given READ or WRITE command. Burst lengths of 2, 4,
8, or 16 locations are available for both sequential and interleaved burst types.
When a READ or WRITE command is issued, a block of columns equal to the burst
length is effectively selected. All accesses for that burst take place within this block,
meaning that the burst will wrap when a boundary is reached. The block is uniquely selected by A[i:1] when BL = 2, by A[i:2] when BL = 4, by A[i:3] when BL = 8, and by A[i:4]
when BL = 16, where Ai is the most significant column address bit for a given configuration. The remaining (least significant) address bits are used to specify the starting location within the block. The programmed burst length applies to both READ and WRITE
bursts.
Burst Type
Accesses within a given burst can be programmed to be either sequential or interleaved
via the standard mode register.
The ordering of accesses within a burst is determined by the burst length, the burst
type, and the starting column address.
Table 55: Burst Definition Table
Burst
Length
Order of Accesses Within a Burst
Starting Column Address
2
Type = Interleaved
0
0-1
0-1
1
1-0
1-0
A0
4
8
16
Type = Sequential
A3
A1
A0
0
0
0-1-2-3
0-1-2-3
0
1
1-2-3-0
1-0-3-2
1
0
2-3-0-1
2-3-0-1
1
1
3-0-1-2
3-2-1-0
A2
A1
A0
0
0
0
0-1-2-3-4-5-6-7
0-1-2-3-4-5-6-7
0
0
1
1-2-3-4-5-6-7-0
1-0-3-2-5-4-7-6
0
1
0
2-3-4-5-6-7-0-1
2-3-0-1-6-7-4-5
0
1
1
3-4-5-6-7-0-1-2
3-2-1-0-7-6-5-4
1
0
0
4-5-6-7-0-1-2-3
4-5-6-7-0-1-2-3
1
0
1
5-6-7-0-1-2-3-4
5-4-7-6-1-0-3-2
1
1
0
6-7-0-1-2-3-4-5
6-7-4-5-2-3-0-1
7-0-1-2-3-4-5-6
7-6-5-4-3-2-1-0
1
1
1
A2
A1
A0
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Standard Mode Register
Table 55: Burst Definition Table (Continued)
Burst
Length
Order of Accesses Within a Burst
Starting Column Address
Type = Sequential
Type = Interleaved
0
0
0
0
0-1-2-3-4-5-6-7-8-9-A-B-C-D-E-F
0-1-2-3-4-5-6-7-8-9-A-B-C-D-E-F
0
0
0
1
1-2-3-4-5-6-7-8-9-A-B-C-D-E-F-0
1-0-3-2-5-4-7-6-9-8-B-A-D-C-F-E
0
0
1
0
2-3-4-5-6-7-8-9-A-B-C-D-E-F-0-1
2-3-0-1-6-7-4-5-A-B-8-9-E-F-C-D
0
0
1
1
3-4-5-6-7-8-9-A-B-C-D-E-F-0-1-2
3-2-1-0-7-6-5-4-B-A-9-8-F-E-D-C
0
1
0
0
4-5-6-7-8-9-A-B-C-D-E-F-0-1-2-3
4-5-6-7-0-1-2-3-C-D-E-F-8-9-A-B
0
1
0
1
5-6-7-8-9-A-B-C-D-E-F-0-1-2-3-4
5-4-7-6-1-0-3-2-D-C-F-E-9-8-B-A
0
1
1
0
6-7-8-9-A-B-C-D-E-F-0-1-2-3-4-5
6-7-4-5-2-3-0-1-E-F-C-D-A-B-8-9
0
1
1
1
7-8-9-A-B-C-D-E-F-0-1-2-3-4-5-6
7-6-5-4-3-2-1-0-F-E-D-C-B-A-9-8
1
0
0
0
8-9-A-B-C-D-E-F-0-1-2-3-4-5-6-7
8-9-A-B-C-D-E-F-0-1-2-3-4-5-6-7
1
0
0
1
9-A-B-C-D-E-F-0-1-2-3-4-5-6-7-8
9-8-B-A-D-C-F-E-1-0-3-2-5-4-7-6
1
0
1
0
A-B-C-D-E-F-0-1-2-3-4-5-6-7-8-9
A-B-8-9-E-F-C-D-2-3-0-1-6-7-4-5
1
0
1
1
B-C-D-E-F-0-1-2-3-4-5-6-7-8-9-A
B-A-9-8-F-E-D-C-3-2-1-0-7-6-5-4
1
1
0
0
C-D-E-F-0-1-2-3-4-5-6-7-8-9-A-B
C-D-E-F-8-9-A-B-4-5-6-7-0-1-2-3
1
1
0
1
D-E-F-0-1-2-3-4-5-6-7-8-9-A-B-C
D-C-F-E-9-8-B-A-5-4-7-6-1-0-3-2
1
1
1
0
E-F-0-1-2-3-4-5-6-7-8-9-A-B-C-D
E-F-C-D-A-B-8-9-6-7-4-5-2-3-0-1
1
1
1
1
F-0-1-2-3-4-5-6-7-8-9-A-B-C-D-E
F-E-D-C-B-A-9-8-7-6-5-4-3-2-1-0
CAS Latency
The CAS latency (CL) is the delay, in clock cycles, between the registration of a READ
command and the availability of the first output data. The latency can be set to 2 or 3
clocks, as shown in Figure 114 (page 177).
For CL = 3, if the READ command is registered at clock edge n, then the data will be
nominally available at (n + 2 clocks + tAC). For CL = 2, if the READ command is registered at clock edge n, then the data will be nominally available at (n + 1 clock + tAC).
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Standard Mode Register
Figure 114: CAS Latency
T0
T1
READ
NOP
T1n
T2
T2n
T3
T3n
CK#
CK
Command
NOP
NOP
tAC
CL - 1
CL = 2
DQS
DQ
DOUT
n
DOUT
n+1
DOUT
n+2
DOUT
n+3
T2n
T3
T3n
T0
T1
T2
READ
NOP
NOP
CK#
CK
Command
NOP
tAC
CL - 1
CL = 3
DQS
DOUT
n
DQ
Transitioning Data
DOUT
n+1
Don’t Care
Operating Mode
The normal operating mode is selected by issuing a LOAD MODE REGISTER command
with bits A[n:7] each set to zero, and bits A[6:0] set to the desired values.
All other combinations of values for A[n:7] are reserved for future use. Reserved states
should not be used because unknown operation or incompatibility with future versions
may result.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Extended Mode Register
Extended Mode Register
The EMR controls additional functions beyond those set by the mode registers. These
additional functions include drive strength, TCSR, and PASR.
The EMR is programmed via the LOAD MODE REGISTER command with BA0 = 0 and
BA1 = 1. Information in the EMR will be retained until it is programmed again, the device goes into deep power-down mode, or the device loses power.
Figure 115: Extended Mode Register
BA1 BA0 An
n+ 2 n+ 1 n
1
0
En + 2 En + 1
0
0
0
1
1
0
1
1
En
0
–
Mode Register Definition
Standard mode register
Status register
Extended mode register
Reserved
...
0
–
E10 E9
0
0
–
–
Notes:
E8
0
–
E7–E0
Valid
–
... A10 A9 A8 A7 A6 A5 A4 A3 A2 A1
9
... 10
Operation
E7
0
0
0
0
1
1
1
1
8
7
E6
0
0
1
1
0
0
1
1
E5
0
1
0
1
0
1
0
1
6
DS
5
4
3
TCSR1
2
1
PASR
A0
0
Address bus
Extended mode
register (Ex)
Drive Strength
Full strength
1/2 strength
1/4 strength
3/4 strength
3/4 strength
Reserved
Reserved
Reserved
Normal AR operation
All other states reserved
E2
0
0
0
0
1
1
1
1
E1
0
0
1
1
0
0
1
1
E0
0
1
0
Partial-Array Self Refresh Coverage
Full array
1/2 array
1
0
1
0
1
Reserved
Reserved
1/8 array
1/4 array
1/16 array
Reserved
1. On-die temperature sensor is used in place of TCSR. Setting these bits will have no effect.
2. The integer n is equal to the most significant address bit.
Temperature-Compensated Self Refresh
This device includes a temperature sensor that is implemented for automatic control of
the self refresh oscillator. Programming the temperature-compensated self refresh
(TCSR) bits will have no effect on the device. The self refresh oscillator will continue to
refresh at the optimal factory-programmed rate for the device temperature.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Extended Mode Register
Partial-Array Self Refresh
For further power savings during self refresh, the partial-array self refresh (PASR) feature
enables the controller to select the amount of memory to be refreshed during self refresh. The refresh options include:
•
•
•
•
•
Full array: banks 0, 1, 2, and 3
One-half array: banks 0 and 1
One-quarter array: bank 0
One-eighth array: bank 0 with row address most significant bit (MSB) = 0
One-sixteenth array: bank 0 with row address MSB = 0 and row address MSB - 1 = 0
READ and WRITE commands can still be issued to the full array during standard operation, but only the selected regions of the array will be refreshed during self refresh. Data
in regions that are not selected will be lost.
Output Drive Strength
Because the device is designed for use in smaller systems that are typically point-topoint connections, an option to control the drive strength of the output buffers is provided. Drive strength should be selected based on the expected loading of the memory
bus. The output driver settings are 25Ω����Ω, and 55Ω internal impedance for full, threequarter, and one-half drive strengths, respectively.
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Status Read Register
Status Read Register
The status read register (SRR) is used to read the manufacturer ID, revision ID, refresh
multiplier, width type, and density of the device, as shown in Figure 117 (page 181). The
SRR is read via the LOAD MODE REGISTER command with BA0 = 1 and BA1 = 0. The
sequence to perform an SRR command is as follows:
1. The device must be properly initialized and in the idle or all banks precharged
state.
2. Issue a LOAD MODE REGISTER command with BA[1:0] = 01 and all address pins
set to 0.
3. Wait tSRR; only NOP or DESELECT commands are supported during the tSRR
time.
4. Issue a READ command.
5. Subsequent commands to the device must be issued tSRC after the SRR READ
command is issued; only NOP or DESELECT commands are supported during
tSRC.
SRR output is read with a burst length of 2. SRR data is driven to the outputs on the first
bit of the burst, with the output being “Don’t Care” on the second bit of the burst.
Figure 116: Status Read Register Timing
T0
T1
T2
T3
T4
T5
T6
T8
CK#
CK
tSRR
Command
PRE1
LMR
NOP
tSRC
NOP2
READ
NOP
NOP
NOP
Valid
tRP
Address
0
BA0 = 1
BA1 = 0
BA0, BA1
&/� ���
DQS
Note 5
SRR
out4
DQ
Don’t Care
Notes:
Transitioning Data
1. All banks must be idle prior to status register read.
2. NOP or DESELECT commands are required between the LMR and READ commands
(tSRR), and between the READ and the next VALID command (tSRC).
3. CAS latency is predetermined by the programming of the mode register. CL = 3 is shown
as an example only.
4. Burst length is fixed to 2 for SRR regardless of the value programmed by the mode register.
5. The second bit of the data-out burst is a “Don’t Care.”
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Status Read Register
Figure 117: Status Register Definition
DQ31...DQ16 DQ15 DQ14 DQ13 DQ12 DQ11 DQ10 DQ9 DQ8 DQ7 DQ6 DQ5 DQ4 DQ3 DQ2 DQ1
S31..S16 S15 S14 S13 S12 S11 S10 S9 S8
31..16
15 14 13 12 11 10 9
8
Type Width Refresh Rate
Density
Reserved1
S15 S14 S13
0
0
0
0
1
0
1
0
0
S12
0
1
0
1
1
1
1
1
0
0
1
0
1
0
1
1
1
128Mb
256Mb
512Mb
1Gb
2Gb
Reserved
Reserved
Reserved
LPDDR
LPDDR2
S10
0
0
0
S9
0
0
1
S8
0
1
0
0
1
1
1
1
0
0
1
1
0
1
0
1
1
1
S7 S6 S5 S4 S3 S2 S1 S0
0
7
6
5
4
3
2
1
Revision ID
Manufacturer ID
Density
Device Type
S11
0
1
Device Width
16 bits
32 bits
Refresh Multiplier2
Reserved
Reserved
S7
Reserved
2X
1X
Reserved
0.25X
Reserved
Notes:
DQ0
0
S6
0
S5
0
S4
0
...
...
...
...
X
X
X
X
I/O bus (CLK L->H edge)
Status register
S3
0
0
0
S2
0
0
0
S1
0
0
1
S0
0
1
0
0
0
0
0
0
1
1
1
1
0
0
1
1
0
1
0
0
1
1
1
1
1
0
0
1
1
0
0
0
0
1
1
0
1
0
1
1
1
0
0
Reserved
1
1
1
1
1
1
0
1
1
1
0
1
Reserved
Reserved
Micron
Manufacturer ID
Reserved
Samsung
Infineon
Elpida
Reserved
Reserved
Reserved
Reserved
Winbond
ESMT
NVM
Reserved
Revision ID
The manufacturer’s revision number starts at ‘0000’
and increments by ‘0001’ each time a change in the
specification (AC timings or feature set), IBIS (pullup or pull-down characteristics), or process occurs.
1. Reserved bits should be set to 0 for future compatibility.
2. Refresh multiplier is based on the memory device on-board temperature sensor. Required average periodic refresh interval = tREFI × multiplier.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Bank/Row Activation
Bank/Row Activation
Before any READ or WRITE commands can be issued to a bank within the device, a row
in that bank must be opened. This is accomplished via the ACTIVE command, which
selects both the bank and the row to be activated (see the ACTIVE Command figure).
After a row is opened with the ACTIVE command, a READ or WRITE command can be
issued to that row, subject to the tRCD specification.
A subsequent ACTIVE command to a different row in the same bank can only be issued
after the previous active row has been precharged. The minimum time interval between
successive ACTIVE commands to the same bank is defined by tRC.
A subsequent ACTIVE command to another bank can be issued while the first bank is
being accessed, which results in a reduction of total row access overhead. The minimum time interval between successive ACTIVE commands to different banks is defined
by tRRD.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
READ Operation
READ burst operations are initiated with a READ command, as shown in Figure 106
(page 161). The starting column and bank addresses are provided with the READ command, and auto precharge is either enabled or disabled for that burst access. If auto
precharge is enabled, the row being accessed is precharged at the completion of the
burst. For the READ commands used in the following illustrations, auto precharge is
disabled.
During READ bursts, the valid data-out element from the starting column address will
be available following the CL after the READ command. Each subsequent data-out element will be valid nominally at the next positive or negative clock edge. Figure 118
(page 184) shows general timing for each possible CL setting.
DQS is driven by the device along with output data. The initial LOW state on DQS is
known as the read preamble; the LOW state coincident with the last data-out element is
known as the read postamble. The READ burst is considered complete when the read
postamble is satisfied.
Upon completion of a burst, assuming no other commands have been initiated, the DQ
will go to High-Z. A detailed explanation of tDQSQ (valid data-out skew), tQH (data-out
window hold), and the valid data window is depicted in Figure 125 (page 191) and Figure 126 (page 192). A detailed explanation of tDQSCK (DQS transition skew to CK) and
tAC (data-out transition skew to CK) is depicted in Figure 127 (page 193).
Data from any READ burst can be truncated by a READ or WRITE command to the
same or alternate bank, by a BURST TERMINATE command, or by a PRECHARGE command to the same bank, provided that the auto precharge mode was not activated.
Data from any READ burst can be concatenated with or truncated with data from a subsequent READ command. In either case, a continuous flow of data can be maintained.
The first data element from the new burst either follows the last element of a completed
burst or the last desired data element of a longer burst that is being truncated. The new
READ command should be issued x cycles after the first READ command, where x
equals the number of desired data element pairs (pairs are required by the 2n-prefetch
architecture). This is shown in Figure 119 (page 185).
A READ command can be initiated on any clock cycle following a previous READ command. Nonconsecutive read data is shown in Figure 120 (page 186). Full-speed random
read accesses within a page (or pages) can be performed as shown in Figure 121
(page 187).
Data from any READ burst can be truncated with a BURST TERMINATE command, as
shown in Figure 122 (page 188). The BURST TERMINATE latency is equal to the READ
(CAS) latency; for example, the BURST TERMINATE command should be issued x cycles after the READ command, where x equals the number of desired data element pairs
(pairs are required by the 2n-prefetch architecture).
Data from any READ burst must be completed or truncated before a subsequent WRITE
command can be issued. If truncation is necessary, the BURST TERMINATE command
must be used, as shown in Figure 123 (page 189). A READ burst can be followed by, or
truncated with, a PRECHARGE command to the same bank, provided that auto precharge was not activated. The PRECHARGE command should be issued x cycles after
the READ command, where x equals the number of desired data element pairs. This is
shown in Figure 124 (page 190). Following the PRECHARGE command, a subsequent
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
command to the same bank cannot be issued until tRP is met. Part of the row precharge
time is hidden during the access of the last data elements.
Figure 118: READ Burst
CK#
T0
T1
READ
NOP
T1n
T2
T2n
T3
T3n
T4
T5
NOP
NOP
T4
T5
NOP
NOP
CK
Command
Address
NOP
NOP
Bank a, Col n
CL = 2
DQS
DQ
CK#
DOUT n1
T0
T1
T2
READ
NOP
NOP
DOUT n + 1
DOUT n + 2
T2n
T3
DOUT n + 3
T3n
CK
Command
Address
NOP
Bank a, Col n
CL = 3
DQS
DQ
DOUT n
DOUT n + 1
DOUT n + 2
DOUT n + 3
Don’t Care
Notes:
Transitioning Data
1. DOUT n = data-out from column n.
2. BL = 4.
3. Shown with nominal tAC, tDQSCK, and tDQSQ.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
Figure 119: Consecutive READ Bursts
T0
T1
Command
READ
NOP
Address
Bank,
Col n
T1n
T2
T2n
T3
T3n
T4
T4n
T5
T5n
CK#
CK
READ
NOP
NOP
NOP
Bank,
Col b
CL = 2
DQS
DQ
DOUT
n1
DOUT
n+1
T2n
T0
T1
T2
Command
READ
NOP
READ
Address
Bank,
Col n
DOUT
n+2
DOUT
n+3
DOUT
b
T3
T3n
T4
DOUT
b+1
T4n
DOUT
b+2
T5
DOUT
b+3
T5n
CK#
CK
NOP
NOP
NOP
Bank,
Col b
CL = 3
DQS
DOUT
n
DQ
DOUT
n+1
DOUT
n+2
Don’t Care
Notes:
DOUT
n+3
DOUT
b
DOUT
b+1
Transitioning Data
1. DOUTn (or b) = data-out from column n (or column b).
2. BL = 4, 8, or 16 (if 4, the bursts are concatenated; if 8 or 16, the second burst interrupts
the first).
3. Shown with nominal tAC, tDQSCK, and tDQSQ.
4. Example applies only when READ commands are issued to same device.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
Figure 120: Nonconsecutive READ Bursts
T0
T1
Command
READ
NOP
Address
Bank,
Col n
T1n
T2
T2n
T3
T3n
T4
T4n
T5
T5n
T6
CK#
CK
NOP
READ
NOP
NOP
NOP
Bank,
Col b
CL = 2
CL = 2
DQS
DOUT
n1
DQ
T0
T1
Command
READ
NOP
Address
Bank,
Col n
T1n
T2
DOUT
n+1
T2n
DOUT
n+2
DOUT
n+3
T3
T3n
DOUT
b
T4
T4n
T5
DOUT
b+1
T5n
DOUT
b+2
T6
CK#
CK
NOP
READ
NOP
NOP
NOP
Bank,
Col b
CL = 3
CL = 3
DQS
DOUT
n
DQ
Notes:
1.
2.
3.
4.
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DOUT
n+1
DOUT
n+3
DOUT
b
Don’t Care
Transitioning Data
DOUT
n+2
DOUTn (or b) = data-out from column n (or column b).
BL = 4, 8, or 16 (if burst is 8 or 16, the second burst interrupts the first).
Shown with nominal tAC, tDQSCK, and tDQSQ.
Example applies when READ commands are issued to different devices or nonconsecutive READs.
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READ Operation
Figure 121: Random Read Accesses
T0
T1
T1n
T2
T2n
T3
Command
READ
READ
READ
READ
Address
Bank,
Col n
Bank,
Col x
Bank,
Col b
Bank,
Col g
T3n
T4
T4n
T5
T5n
CK#
CK
NOP
NOP
CL = 2
DQS
DQ
T0
T1
T1n
DOUT
n1
DOUT
n+1
T2
T2n
DOUT
x
DOUT
x+1
DOUT
b
T3
T3n
T4
DOUT
b+1
T4n
DOUT
g
T5
DOUT
g+1
T5n
CK#
CK
Command
READ
READ
READ
READ
Address
Bank,
Col n
Bank,
Col x
Bank,
Col b
Bank,
Col g
NOP
NOP
CL = 3
DQS
DOUT
n
DQ
DOUT
n+1
DOUT
x
Don’t Care
Notes:
1.
2.
3.
4.
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DOUT
x+1
DOUT
b
DOUT
b+1
Transitioning Data
DOUTn (or x, b, g) = data-out from column n (or column x, column b, column g).
BL = 2, 4, 8, or 16 (if 4, 8, or 16, the following burst interrupts the previous).
READs are to an active row in any bank.
Shown with nominal tAC, tDQSCK, and tDQSQ.
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READ Operation
Figure 122: Terminating a READ Burst
T0
T1
Command
READ1
BST2
Address
Bank a,
Col n
T1n
T2
T2n
T3
T4
T5
NOP
NOP
NOP
T4
T5
NOP
NOP
CK#
CK
NOP
CL = 2
DQS
DOUT
n
DQ3
T0
DOUT
n+1
T1
T2
T2n
BST2
NOP
T3
T3n
CK#
CK
Command
READ1
Address
Bank a,
Col n
NOP
CL = 3
DQS
DOUT
n
DQ3
DOUT
n+1
Don’t Care
Notes:
1.
2.
3.
4.
5.
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Transitioning Data
BL = 4, 8, or 16.
BST = BURST TERMINATE command; page remains open.
DOUTn = data-out from column n.
Shown with nominal tAC, tDQSCK, and tDQSQ.
CKE = HIGH.
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READ Operation
Figure 123: READ-to-WRITE
T0
T1
T1n
T2
T2n
T3
T3n
T4
T4n
T5
T5n
CK#
CK
Command
Address
READ1
BST2
WRITE1
NOP
Bank,
Col n
NOP
NOP
Bank,
Col b
tDQSS
CL = 2
(NOM)
DQS
DOUT
n
DOUT
n+1
T1
T2
T2n
BST2
NOP
DQ3,4
DIN
b
DIN
b+1
DIN
b+2
DIN
b+3
T4
T4n
T5
T5n
DM
T0
T3
T3n
CK#
CK
Command
Address
READ1
WRITE1
NOP
Bank,
Col n
NOP
Bank,
Col b
tDQSS
CL = 3
(NOM)
DQS
DOUT
n
DQ3,4
DOUT
n+1
DIN
b
DIN
b+1
DM
Don’t Care
Notes:
Transitioning Data
1. BL = 4 in the cases shown (applies for bursts of 8 and 16 as well; if BL = 2, the BST command shown can be NOP).
2. BST = BURST TERMINATE command; page remains open.
3. DOUTn = data-out from column n.
4. DINb = data-in from column b.
5. Shown with nominal tAC, tDQSCK, and tDQSQ.
6. CKE = HIGH.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
Figure 124: READ-to-PRECHARGE
T0
T1
T1n
T2
T2n
T3
T3n
T4
T5
NOP
ACT3
CK#
CK
Command
READ1
Address
Banka,
Col n
PRE2
NOP
NOP
Bank a,
(a or all)
Bank a,
Row
tRP
CL = 2
DQS
DQ4
T0
T1
T1n
DOUT
n
DOUT
n+1
DOUT
n+2
T2
T2n
T3
DOUT
n+3
T3n
T4
T5
NOP
ACT3
CK#
CK
Command
READ1
Address
Banka,
Col n
PRE2
NOP
NOP
Bank a,
(a or all)
Bank a,
Row
tRP
CL = 3
DQS
DOUT
n
DQ4
DOUT
n+1
DOUT
n+2
Don’t Care
Notes:
1.
2.
3.
4.
5.
6.
7.
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DOUT
n+3
Transitioning Data
BL = 4, or an interrupted burst of 8 or 16.
PRE = PRECHARGE command.
ACT = ACTIVE command.
DOUTn = data-out from column n.
Shown with nominal tAC, tDQSCK, and tDQSQ.
READ-to-PRECHARGE equals 2 clocks, which enables 2 data pairs of data-out.
A READ command with auto precharge enabled, provided tRAS (MIN) is met, would
cause a precharge to be performed at x number of clock cycles after the READ command, where x = BL/2.
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READ Operation
Figure 125: Data Output Timing – tDQSQ, tQH, and Data Valid Window (x16)
CK#
CK
T1
T2
tHP1
T2n
tHP1
T3
tHP1
tDQSQ2
tHP1
T3n
tHP1
tDQSQ2
T4
tHP1
tDQSQ2
tDQSQ2
LDQS3
tQH5
tQH5
tQH5
Lower Byte
DQ (Last data valid)4
DQ4
DQ4
DQ4
DQ4
DQ4
DQ4
DQ (First data no longer valid)4
tQH5
DQ (Last data valid)4
T2
T2n
T3
T3n
DQ (First data no longer valid)4
T2
T2n
T3
T3n
DQ[7:0] and LDQS, collectively6
T2
T2n
T3
T3n
Data valid
window
Data valid
window
Data valid
window
Data valid
window
tDQSQ2
tDQSQ2
tDQSQ2
tDQSQ2
UDQS3
tQH5
tQH5
tQH5
Upper Byte
DQ (Last data valid)7
DQ7
DQ7
DQ7
DQ7
DQ7
DQ7
DQ (First data no longer valid)7
tQH5
DQ (Last data valid)7
T2
T2n
DQ (First data no longer valid)7
T2
T2n
collectively6
T2
T2n
T3
T3n
Data valid
window
Data valid
window
Data valid
window
Data valid
window
DQ[15:8] and UDQS,
Notes:
T3
T3
T3n
T3n
1. tHP is the lesser of tCL or tCH clock transition collectively when a bank is active.
2. tDQSQ is derived at each DQS clock edge and is not cumulative over time and begins
with DQS transition and ends with the last valid DQ transition.
3. DQ transitioning after DQS transitions define the tDQSQ window. LDQS defines the lower byte and UDQS defines the upper byte.
4. DQ0, DQ1, DQ2, DQ3, DQ4, DQ5, DQ6, or DQ7.
5. tQH is derived from tHP: tQH = tHP - tQHS.
6. The data valid window is derived for each DQS transitions and is defined as tQH - tDQSQ.
7. DQ8, DQ9, DQ10, DQ11, DQ12, DQ13, DQ14, or DQ15.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
Figure 126: Data Output Timing – tDQSQ, tQH, and Data Valid Window (x32)
CK#
CK
T1
T2
tHP1
tHP1
T2n
tHP1
T3
tHP1
T3n
T4
tHP1
tHP1
tDQSQ2,3
tDQSQ2,3
tDQSQ2,3
tDQSQ2,3
tQH5
tQH5
tQH5
tQH5
DQS0/DQS1/DQS2/DQS3
T2n
T3
T3n
DQ (First data no longer valid)
T2
T2n
T3
T3n
DQ and DQS, collectively6,7
T2
T2n
T3
T3n
Data valid
window
Data valid
window
Data valid
window
Data valid
window
Notes:
Byte 3
T2
Byte 2
DQ (Last data valid)
Byte 1
Byte 0
DQ (Last data valid)4
DQ4
DQ4
DQ4
DQ4
DQ4
DQ4
DQ (First data no longer valid)4
1. tHP is the lesser of tCL or tCH clock transition collectively when a bank is active.
2. DQ transitioning after DQS transitions define the tDQSQ window.
3. tDQSQ is derived at each DQS clock edge and is not cumulative over time; it begins with
DQS transition and ends with the last valid DQ transition.
4. Byte 0 is DQ[7:0], byte 1 is DQ[15:8], byte 2 is DQ[23:16], byte 3 is DQ[31:24].
5. tQH is derived from tHP: tQH = tHP - tQHS.
6. The data valid window is derived for each DQS transition and is tQH - tDQSQ.
7. DQ[7:0] and DQS0 for byte 0; DQ[15:8] and DQS1 for byte 1; DQ[23:16] and DQS2 for
byte 2; DQ[31:23] and DQS3 for byte 3.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
READ Operation
Figure 127: Data Output Timing – tAC and tDQSCK
T0
T1
T2
NOP1
NOP1
T3
T2n
T3n
T4
T4n
T5
T5n
T6
CK#
CK
Command
READ
NOP1
NOP1
NOP1
NOP1
CL = 3
tLZ
tHZ
tDQSCK
tDQSCK
tRPRE
tRPST
DQS or LDQS/UDQS2
tLZ
All DQ values, collectively3
T2
tAC4
T2n
T3
tAC4
T3n
T4
T4n
T5
T5n
tHZ
Don’t Care
Notes:
1.
2.
3.
4.
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Commands other than NOP can be valid during this cycle.
DQ transitioning after DQS transitions define tDQSQ window.
All DQ must transition by tDQSQ after DQS transitions, regardless of tAC.
tAC is the DQ output window relative to CK and is the long-term component of DQ
skew.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
WRITE Operation
WRITE bursts are initiated with a WRITE command, as shown in Figure 107 (page 162).
The starting column and bank addresses are provided with the WRITE command, and
auto precharge is either enabled or disabled for that access. If auto precharge is enabled, the row being accessed is precharged at the completion of the burst. For the
WRITE commands used in the following illustrations, auto precharge is disabled. Basic
data input timing is shown in Figure 128 (page 195) (this timing applies to all WRITE
operations).
Input data appearing on the data bus is written to the memory array subject to the state
of data mask (DM) inputs coincident with the data. If DM is registered LOW, the corresponding data will be written; if DM is registered HIGH, the corresponding data will be
ignored, and the write will not be executed to that byte/column location. DM operation
is illustrated in Figure 129 (page 196).
During WRITE bursts, the first valid data-in element will be registered on the first rising
edge of DQS following the WRITE command, and subsequent data elements will be registered on successive edges of DQS. The LOW state of DQS between the WRITE command and the first rising edge is known as the write preamble; the LOW state of DQS
following the last data-in element is known as the write postamble. The WRITE burst is
complete when the write postamble and tWR or tWTR are satisfied.
The time between the WRITE command and the first corresponding rising edge of DQS
(tDQSS) is specified with a relatively wide range (75%–125% of one clock cycle). All
WRITE diagrams show the nominal case. Where the two extreme cases (that is, tDQSS
[MIN] and tDQSS [MAX]) might not be obvious, they have also been included. Figure 130 (page 197) shows the nominal case and the extremes of tDQSS for a burst of 4.
Upon completion of a burst, assuming no other commands have been initiated, the DQ
will remain High-Z and any additional input data will be ignored.
Data for any WRITE burst can be concatenated with or truncated by a subsequent
WRITE command. In either case, a continuous flow of input data can be maintained.
The new WRITE command can be issued on any positive edge of clock following the
previous WRITE command. The first data element from the new burst is applied after
either the last element of a completed burst or the last desired data element of a longer
burst that is being truncated. The new WRITE command should be issued x cycles after
the first WRITE command, where x equals the number of desired data element pairs
(pairs are required by the 2n-prefetch architecture).
Figure 131 (page 198) shows concatenated bursts of 4. An example of nonconsecutive
WRITEs is shown in Figure 132 (page 198). Full-speed random write accesses within a
page or pages can be performed, as shown in Figure 133 (page 199).
Data for any WRITE burst can be followed by a subsequent READ command. To follow a
WRITE without truncating the WRITE burst, tWTR should be met, as shown in Figure 134 (page 200).
Data for any WRITE burst can be truncated by a subsequent READ command, as shown
in Figure 135 (page 201). Note that only the data-in pairs that are registered prior to the
tWTR period are written to the internal array, and any subsequent data-in should be
masked with DM, as shown in Figure 136 (page 202).
Data for any WRITE burst can be followed by a subsequent PRECHARGE command. To
follow a WRITE without truncating the WRITE burst, tWR should be met, as shown in
Figure 137 (page 203).
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
Data for any WRITE burst can be truncated by a subsequent PRECHARGE command, as
shown in Figure 138 (page 204) and Figure 139 (page 205). Note that only the data-in
pairs that are registered prior to the tWR period are written to the internal array, and any
subsequent data-in should be masked with DM, as shown in Figure 138 (page 204) and
Figure 139 (page 205). After the PRECHARGE command, a subsequent command to the
same bank cannot be issued until tRP is met.
Figure 128: Data Input Timing
T01
T1
T1n
T2
T2n
T3
CK#
CK
tDSH2
tDQSS
tDSS3
tDSH2
tDSS3
tDQSL
tDQSH tWPST
DQS4
tWPRES
tWPRE
DIN
b
DQ
DM5
tDS
tDH
Transitioning Data
Notes:
1.
2.
3.
4.
Don’t Care
WRITE command issued at T0.
(MIN) generally occurs during tDQSS (MIN).
tDSS (MIN) generally occurs during tDQSS (MAX).
For x16, LDQS controls the lower byte; UDQS controls the upper byte. For x32, DQS0
controls DQ[7:0], DQS1 controls DQ[15:8], DQS2 controls DQ[23:16], and DQS3 controls
DQ[31:24].
5. For x16, LDM controls the lower byte; UDM controls the upper byte. For x32, DM0 controls DQ[7:0], DM1 controls DQ[15:8], DM2 controls DQ[23:16], and DM3 controls
DQ[31:24].
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tDSH
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
Figure 129: Write – DM Operation
T1
T0
CK#
T2
T3
T4
WRITE2
NOP1
T4n
T5
T5n
T6
T7
NOP1
NOP11
T8
CK
tIS
tIH
tIS
tIH
tCK
tCH
tCL
CKE
Command
NOP1
tIS
Address
NOP1
ACTIVE
Row
Col n
Row
tIS
BA0, BA1
PRE3
tIH
tIS
A10
NOP1
tIH
All banks
Note 4
One bank
tIH
Bank x
Bank x5
Bank x
tRCD
tDQSS
tWR
(NOM)
tRP
tRAS
DQS
tWPRE
tWPRES
DIN
n
DQ6
tDQSL
tDQSH
tWPST
DIN
n+2
DM
tDS
tDH
Don’t Care
Notes:
Transitioning Data
1. NOP commands are shown for ease of illustration; other commands may be valid at
these times.
2. BL = 4 in the case shown.
3. PRE = PRECHARGE.
4. Disable auto precharge.
5. Bank x at T8 is “Don’t Care” if A10 is HIGH at T8.
6. DINn = data-in from column n.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
Figure 130: WRITE Burst
T0
T1
T2
WRITE1,2
NOP
NOP
T2n
T3
CK#
CK
Command
Address
t DQSS
(NOM)
NOP
Bank a,
Col b
tDQSS
DQS
DIN
b
DQ3
DIN
b+2
DIN
b+1
DIN
b+3
DM
t DQSS
(MIN)
tDQSS
DQS
DQ3
DIN
b
DIN
b+1
DIN
b+2
DIN
b+3
DIN
b
DIN
b+1
DIN
b+2
DM
t DQSS
(MAX)
tDQSS
DQS
DQ3
DIN
b+3
DM
Don’t Care
Notes:
Transitioning Data
1. An uninterrupted burst of 4 is shown.
2. A10 is LOW with the WRITE command (auto precharge is disabled).
3. DINb = data-in for column b.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
Figure 131: Consecutive WRITE-to-WRITE
T0
T1
WRITE1, 2
NOP
T1n
T2
T2n
T3
T3n
T4
T4n
T5
CK#
CK
Command
Address
WRITE1, 2
Bank,
Col b
tDQSS
NOP
NOP
NOP
Bank,
Col n
(NOM)
DQS
DIN
b
DQ3
DIN
b+1
DIN
b+2
DIN
b+3
DIN
n
DIN
n+1
DIN
n+2
DIN
n+3
DM
Don’t Care
Notes:
Transitioning Data
1. Each WRITE command can be to any bank.
2. An uninterrupted burst of 4 is shown.
3. DINb (n) = data-in for column b (n).
Figure 132: Nonconsecutive WRITE-to-WRITE
T0
T1
WRITE1, 2
NOP
T1n
T2
T2n
T3
T4
T4n
T5
T5n
CK#
CK
Command
Address
WRITE1,2
NOP
Bank,
Col b
tDQSS
NOP
NOP
Bank,
Col n
(NOM)
DQS
DIN
b
DQ3
DIN
b+1
DIN
b+2
DIN
b+3
DIN
n
DIN
n+1
DIN
n+2
DIN
n+3
DM
Don’t Care
Notes:
Transitioning Data
1. Each WRITE command can be to any bank.
2. An uninterrupted burst of 4 is shown.
3. DINb (n) = data-in for column b (n).
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
WRITE Operation
Figure 133: Random WRITE Cycles
T0
T1
T1n
T2
T2n
T3
T3n
T4
WRITE1,2
WRITE1,2
WRITE1,2
WRITE1,2
WRITE1,2
Bank,
Col b
Bank,
Col x
Bank,
Col n
Bank,
Col a
Bank,
Col g
T4n
T5
T5n
CK#
CK
Command
Address
tDQSS
NOP
(NOM)
DQS
DIN
b
DQ3,4
DIN
b’
DIN
x
DIN
x’
DIN
n
DIN
n’
DIN
a
DIN
a’
DIN
g
DIN
g’
DM
Don’t Care
Notes:
1.
2.
3.
4.
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Transitioning Data
Each WRITE command can be to any bank.
Programmed BL = 2, 4, 8, or 16 in cases shown.
DINb (or x, n, a, g) = data-in for column b (or x, n, a, g).
b' (or x, n, a, g) = the next data-in following DINb (x, n, a, g) according to the programmed burst order.
199
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WRITE Operation
Figure 134: WRITE-to-READ – Uninterrupting
T0
T1
WRITE2,3
NOP
T1n
T2
T2n
T3
T4
T5
READ
NOP
T5n
T6
T6n
CK#
CK
Command1
NOP
NOP
NOP
tWTR4
Address
t DQSSnom
Bank a,
Col b
Bank a,
Col n
tDQSS
CL = 2
DQS
DIN
b
DQ5
DIN
b+2
DIN
b+1
DIN
b+3
DOUT
n
DOUT
n+1
DOUT
n
DOUT
n+1
DOUT
n
DOUT
n+1
DM
t DQSSmin
tDQSS
CL = 2
DQS
DIN
b
DQ5
DIN
b+1
DIN
b+2
DIN
b+3
DM
t DQSSmax
tDQSS
CL = 2
DQS
DIN
b
DQ5
DIN
b+1
DIN
b+2
DIN
b+3
DM
Don’t Care
Notes:
Transitioning Data
1. The READ and WRITE commands are to the same device. However, the READ and WRITE
commands may be to different devices, in which case tWTR is not required and the
READ command could be applied earlier.
2. A10 is LOW with the WRITE command (auto precharge is disabled).
3. An uninterrupted burst of 4 is shown.
4. tWTR is referenced from the first positive CK edge after the last data-in pair.
5. DINb = data-in for column b; DOUTn = data-out for column n.
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WRITE Operation
Figure 135: WRITE-to-READ – Interrupting
T0
T1
WRITE1,2
NOP
T1n
T2
T2n
T3
T4
T5
NOP
NOP
T5n
T6
T6n
CK#
CK
Command
NOP
READ
NOP
tWTR3
Address
t DQSS
(NOM)
Bank a,
Col b
Bank a,
Col n
tDQSS
CL = 3
DQS4
DIN
b
DQ5
DIN
b+1
DOUT
n
DOUT
n+1
DM
t DQSS
(MIN)
tDQSS
CL = 3
DQS4
DIN
b
DQ5
DIN
b+1
DOUT
n
DOUT
n+1
DM
t DQSS
(MAX)
tDQSS
CL = 3
DQS4
DIN
b
DQ5
DIN
b+1
DOUT
n
DOUT
n+1
DM
Don’t Care
Notes:
1.
2.
3.
4.
5.
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Transitioning Data
An interrupted burst of 4 is shown; 2 data elements are written.
A10 is LOW with the WRITE command (auto precharge is disabled).
tWTR is referenced from the first positive CK edge after the last data-in pair.
DQS is required at T2 and T2n (nominal case) to register DM.
DINb = data-in for column b; DOUTn = data-out for column n.
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WRITE Operation
Figure 136: WRITE-to-READ – Odd Number of Data, Interrupting
T0
T1
WRITE2
NOP
T1n
T2
T2n
T3
T4
T5
NOP
NOP
T5n
T6
T6n
CK#
CK
Command1
NOP
READ
NOP
tWTR3
Address
t DQSS
(NOM)
Bank a,
Col b
Bank a,
Col b
tDQSS
CL = 3
DQS4
DIN
b
DQ5
DOUT
n
DOUT
n+1
DM
t DQSS
(MIN)
tDQSS
CL = 3
DQS4
DIN
b
DQ5
DOUT
n
DOUT
n+1
DM
t DQSS
(MAX)
tDQSS
CL = 3
DQS4
DOUT
n
DIN
b
DQ5
DOUT
n+1
DM
Don’t Care
Notes:
1.
2.
3.
4.
5.
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Transitioning Data
An interrupted burst of 4 is shown; 1 data element is written, 3 are masked.
A10 is LOW with the WRITE command (auto precharge is disabled).
tWTR is referenced from the first positive CK edge after the last data-in pair.
DQS is required at T2 and T2n (nominal case) to register DM.
DINb = data-in for column b; DOUTn = data-out for column n.
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WRITE Operation
Figure 137: WRITE-to-PRECHARGE – Uninterrupting
T0
T1
T1n
WRITE2,4
NOP
T2
T2n
T3
T4
T5
T6
NOP
NOP
PRE3,4
NOP
CK#
CK
Command1
NOP
tWR5
Address
t DQSS
(NOM)
�
Bank a,
Col b
Bank
(a or all)
tDQSS
DQS
DIN
b
DQ6
DIN
b+1
DIN
b+2
DIN
b+3
DM
t DQSS
(MIN)
tDQSS
DQS
DIN
b
DQ6
DIN
b+1
DIN
b+2
DIN
b+3
DIN
b
DIN
b+1
DIN
b+2
DM
t DQSS
tDQSS
(MAX)
DQS
DQ6
DIN
b+3
DM
Don’t Care
Notes:
Transitioning Data
1.
2.
3.
4.
An uninterrupted burst 4 of is shown.
A10 is LOW with the WRITE command (auto precharge is disabled).
PRE = PRECHARGE.
The PRECHARGE and WRITE commands are to the same device. However, the PRECHARGE and WRITE commands can be to different devices; in this case, tWR is not required and the PRECHARGE command can be applied earlier.
5. tWR is referenced from the first positive CK edge after the last data-in pair.
6. DINb = data-in for column b.
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WRITE Operation
Figure 138: WRITE-to-PRECHARGE – Interrupting
CK#
T0
T1
T1n
WRITE2
NOP
T2
T2n
T3
T3n
T4
T4n
T5
T6
NOP
NOP
CK
Command1
NOP
NOP
PRE3
tWR4
Bank a,
Col b
Address
t DQSS
(NOM)
Bank
(a or all)
tDQSS
DQS5
DIN
b
DQ6
DIN
b+1
DM
t DQSS
(MIN)
tDQSS
DQS5
DIN
b
DQ6
DIN
b+1
DM
t DQSS
(MAX)
tDQSS
DQS5
DIN
b
DQ6
DIN
b+1
DM
Don’t Care
Notes:
1.
2.
3.
4.
5.
6.
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Transitioning Data
An interrupted burst of 8 is shown; two data elements are written.
A10 is LOW with the WRITE command (auto precharge is disabled).
PRE = PRECHARGE.
tWR is referenced from the first positive CK edge after the last data-in pair.
DQS is required at T4 and T4n to register DM.
DINb = data-in for column b.
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WRITE Operation
Figure 139: WRITE-to-PRECHARGE – Odd Number of Data, Interrupting
CK#
T0
T1
WRITE2
NOP
T1n
T2
T2n
T3
T3n
T4
T4n
T5
T6
PRE3
NOP
CK
Command1
NOP
NOP
NOP
tWR4
Address
t DQSS
(NOM)
Bank a,
Col b
Bank
(a or all)
tDQSS
DQS5, 6
DIN
b
DQ7
DM6
t DQSS
(MIN)
tDQSS
DQS5, 6
DIN
b
DQ7
DM6
t DQSS
(MAX)
tDQSS
DQS5, 6
DIN
b
DQ7
DM6
Don’t Care
Notes:
1.
2.
3.
4.
5.
6.
7.
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Transitioning Data
An interrupted burst of 8 is shown; one data element is written.
A10 is LOW with the WRITE command (auto precharge is disabled).
PRE = PRECHARGE.
tWR is referenced from the first positive CK edge after the last data-in pair.
DQS is required at T4 and T4n to register DM.
If a burst of 4 is used, DQS and DM are not required at T3, T3n, T4, and T4n.
DINb = data-in for column b.
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PRECHARGE Operation
PRECHARGE Operation
The PRECHARGE command is used to deactivate the open row in a particular bank or
the open row in all banks. The bank(s) will be available for a subsequent row access
some specified time (tRP) after the PRECHARGE command is issued. Input A10 determines whether one or all banks will be precharged, and in the case where only one bank
is precharged (A10 = LOW), inputs BA0 and BA1 select the bank. When all banks are precharged (A10 = HIGH), inputs BA0 and BA1 are treated as “Don’t Care.” After a bank has
been precharged, it is in the idle state and must be activated prior to any READ or
WRITE commands being issued to that bank. A PRECHARGE command will be treated
as a NOP if there is no open row in that bank (idle state), or if the previously open row is
already in the process of precharging.
Auto Precharge
Auto precharge is a feature that performs the same individual bank PRECHARGE function described previously, without requiring an explicit command. This is accomplished
by using A10 to enable auto precharge in conjunction with a specific READ or WRITE
command. A precharge of the bank/row that is addressed with the READ or WRITE
command is automatically performed upon completion of the READ or WRITE burst.
Auto precharge is nonpersistent; it is either enabled or disabled for each individual
READ or WRITE command.
Auto precharge ensures that the precharge is initiated at the earliest valid stage within a
burst. This earliest valid stage is determined as if an explicit PRECHARGE command
was issued at the earliest possible time without violating tRAS (MIN), as described for
each burst type in Table 53 (page 167). The READ with auto precharge enabled state or
the WRITE with auto precharge enabled state can each be broken into two parts: the access period and the precharge period. The access period starts with registration of the
command and ends where tRP (the precharge period) begins. For READ with auto precharge, the precharge period is defined as if the same burst was executed with auto precharge disabled, followed by the earliest possible PRECHARGE command that still accesses all the data in the burst. For WRITE with auto precharge, the precharge period
begins when tWR ends, with tWR measured as if auto precharge was disabled. In addition, during a WRITE with auto precharge, at least one clock is required during tWR
time. During the precharge period, the user must not issue another command to the
same bank until tRP is satisfied.
This device supports tRAS lock-out. In the case of a single READ with auto precharge or
single WRITE with auto precharge issued at tRCD (MIN), the internal precharge will be
delayed until tRAS (MIN) has been satisfied.
Bank READ operations with and without auto precharge are shown in Figure 140
(page 208) and Figure 141 (page 210). Bank WRITE operations with and without auto
precharge are shown in Figure 142 (page 211) and Figure 143 (page 212).
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Auto Precharge
Concurrent Auto Precharge
This device supports concurrent auto precharge such that when a READ with auto precharge is enabled or a WRITE with auto precharge is enabled, any command to another
bank is supported, as long as that command does not interrupt the read or write data
transfer already in process. This feature enables the precharge to complete in the bank
in which the READ or WRITE with auto precharge was executed, without requiring an
explicit PRECHARGE command, thus freeing the command bus for operations in other
banks.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Auto Precharge
Figure 140: Bank Read – With Auto Precharge
CK#
T1
T0
T2
T3
T4
T5
T5n
T6
T6n
T7
T8
CK
tIS
tCK
tIH
tCH
tCL
CKE
tIS
Command
tIH
NOP1
ACTIVE
tIS
NOP1
READ2
NOP1
NOP1
NOP1
NOP1
ACTIVE
tIH
Address
Row
A10
Row
Col n
Row
Note 3
Row
tIS
tIS
BA0, BA1
tIH
tIH
Bank x
Bank x
Bank x
tRCD
tRP
tRAS
tRC
DM
CL = 2
Case 1: tAC (MIN) and tDQSCK (MIN)
tDQSCK
tRPRE
tRPST
(MIN)
DQS4
tLZ
tAC
(MIN)
(MIN)
DOUT
n
DQ4,5
tLZ
Case 2: tAC (MAX) and tDQSCK (MAX)
DOUT
n+1
DOUT
x
DOUT
x+1
(MIN)
tRPRE
tDQSCK
tRPST
(MAX)
DQS4
DOUT
n
DQ4,5
tAC
(MAX)
DOUT
n+1
DOUT
x
tHZ
DOUT
x+1
(MAX)
Don’t Care
Notes:
Transitioning Data
1. NOP commands are shown for ease of illustration; other commands may be valid at
these times.
2. BL = 4 in the case shown.
3. Enable auto precharge.
4. Refer to Figure 125 (page 191) and Figure 126 (page 192) for detailed DQS and DQ timing.
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Auto Precharge
5. DOUT n = data-out from column n.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Auto Precharge
Figure 141: Bank Read – Without Auto Precharge
CK#
T1
T0
T2
T3
T4
T5
T5n
READ2
NOP1
PRE3
T6
T6n
T7
T8
NOP1
ACTIVE
CK
tIS
tIH
tIS
tIH
tCK
tCH
tCL
CKE
Command
NOP1
NOP1
ACTIVE
tIS
Row
Address
Col n
tIS
A10
NOP1
tIH
Row
Row
tIH
All banks
Row
Note 4
One bank
tIS
BA0, BA1
tIH
Bank x
Bank x5
Bank x
Bank x
tRCD
tRP
tRAS6
tRC
DM
CL = 2
Case 1:
tAC
(MIN) and
tDQSCK
(MIN)
tDQSCK
tRPRE
tRPST
(MIN)
DQS7
tLZ
(MIN)
tAC
(MIN)
DOUT
n
DQ7,8
tLZ
DOUT
n+1
DOUT
n+2
DOUT
n+3
(MIN)
Case 2: tAC (MAX) and tDQSCK (MAX)
tRPRE
tDQSCK
tRPST
(MAX)
DQS7
DOUT
n
DQ7,8
tAC
(MAX)
DOUT
n+1
DOUT
n+2
DOUT
n+3
tHZ
(MAX)
Don’t Care
Notes:
Transitioning Data
1. NOP commands are shown for ease of illustration; other commands may be valid at
these times.
2. BL = 4 in the case shown.
3. PRE = PRECHARGE.
4. Disable auto precharge.
5. Bank x at T5 is “Don’t Care” if A10 is HIGH at T5.
6. The PRECHARGE command can only be applied at T5 if tRAS (MIN) is met.
7. Refer to Figure 125 (page 191) and Figure 126 (page 192) for DQS and DQ timing details.
8. DOUTn = data out from column n.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Auto Precharge
Figure 142: Bank Write – With Auto Precharge
CK#
CK
T1
T0
tIS
T2
tIH
tCK
T3
tCH
T4
T4n
T5
T5n
T6
T7
T8
tCL
CKE
tIS
Command
tIH
NOP4
NOP4
ACTIVE
tIS
WRITE2
NOP4
NOP4
NOP4
NOP4
NOP4
tIH
Address
Row
A10
Row
Col n
Note 3
tIS
BA0, BA1
tIS
tIH
tIH
Bank x
Bank x
tRCD
tDQSS
tWR
(NOM)
tRP
tRAS
DQS
tWPRE
tWPRES
tDQSL
tDQSH tWPST
DIN
b
DQ1
DM
tDS
tDH
Don’t Care
Notes:
Transitioning Data
1. NOP commands are shown for ease of illustration; other commands may be valid at
these times.
2. BL = 4 in the case shown.
3. Enable auto precharge.
4. DINn = data-out from column n.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Auto Precharge
Figure 143: Bank Write – Without Auto Precharge
CK
T1
T0
CK#
tIS
T2
tIH
tCK
T3
tCH
T4
T4n
T5
T5n
T6
T7
T8
NOP1
NOP1
PRE3
tCL
CKE
tIS
Command
tIH
NOP1
tIS
Address
NOP1
ACTIVE
WRITE2
tIH
Row
Col n
tIS
A10
Row
tIS
BA0, BA1
NOP1
NOP1
tIH
All banks
Note 4
One bank
tIH
Bank x
Bank x5
Bank x
tWR
tRCD
tRP
tRAS
tDQSS
(NOM)
DQS
tWPRES
tWPRE
tDQSL
tDQSH tWPST
DIN
b
DQ6
DM
tDS
tDH
Notes:
Don’t Care
Transitioning Data
1. NOP commands are shown for ease of illustration; other commands may be valid at
these times.
2. BL = 4 in the case shown.
3. PRE = PRECHARGE.
4. Disable auto precharge.
5. Bank x at T8 is “Don’t Care” if A10 is HIGH at T8.
6. DOUTn = data-out from column n.
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AUTO REFRESH Operation
AUTO REFRESH Operation
Auto refresh mode is used during normal operation of the device and is analogous to
CAS#-BEFORE-RAS# (CBR) REFRESH in FPM/EDO DRAM. The AUTO REFRESH command is nonpersistent and must be issued each time a refresh is required.
The addressing is generated by the internal refresh controller. This makes the address
bits a “Don’t Care” during an AUTO REFRESH command.
For improved efficiency in scheduling and switching between tasks, some flexibility in
the absolute refresh interval is provided. The auto refresh period begins when the AUTO
REFRESH command is registered and ends tRFC later.
Figure 144: Auto Refresh Mode
T0
T2
T1
T3
T4
CK#
CK
tIS
tCK
tIH
CKE
tCL
tIH
NOP 2
NOP2
PRE
Ta0
Ta1
))
((
))
Valid
tIS
Command1
tCH
((
))
((
))
NOP2
AR
))
((
))
NOP2, 3
AR4
((
))
((
))
Tb0
))
((
))
Valid
((
))
((
))
NOP2, 3
Tb1
Tb2
NOP2
ACTIVE
((
))
((
))
((
))
((
))
Row
((
))
((
))
((
))
((
))
Row
((
))
((
))
((
))
((
))
Bank
DQS6
((
))
((
))
((
))
((
))
DQ6
((
))
((
))
((
))
((
))
DM6
((
))
((
))
((
))
((
))
Address
All banks
A10
One bank
BA0, BA1
Bank(s)5
tRP
tRFC
tRFC4
Don’t Care
Notes:
1. PRE = PRECHARGE; AR = AUTO REFRESH.
2. NOP commands are shown for ease of illustration; other commands may be valid during
this time. CKE must be active during clock positive transitions.
3. NOP or COMMAND INHIBIT are the only commands supported until after tRFC time; CKE
must be active during clock positive transitions.
4. The second AUTO REFRESH is not required and is only shown as an example of two
back-to-back AUTO REFRESH commands.
5. Bank x at T1 is “Don’t Care” if A10 is HIGH at this point; A10 must be HIGH if more than
one bank is active (for example, must precharge all active banks).
6. DM, DQ, and DQS signals are all “Don’t Care”/High-Z for operations shown.
Although it is not a JEDEC requirement, CKE must be active (HIGH) during the auto refresh period to provide support for future functional features. The auto refresh period
begins when the AUTO REFRESH command is registered and ends tRFC later.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
SELF REFRESH Operation
SELF REFRESH Operation
The SELF REFRESH command can be used to retain data in the device while the rest of
the system is powered down. When in self refresh mode, the device retains data without
external clocking. The SELF REFRESH command is initiated like an AUTO REFRESH
command, except that CKE is disabled (LOW). All command and address input signals
except CKE are “Don’t Care” during self refresh.
During self refresh, the device is refreshed as defined in the extended mode register.
(see Partial-Array Self Refresh (page 179).) An internal temperature sensor adjusts the
refresh rate to optimize device power consumption while ensuring data integrity. (See
Temperature-Compensated Self Refresh (page 178).)
The procedure for exiting self refresh requires a sequence of commands. First, CK must
be stable prior to CKE going HIGH. When CKE is HIGH, the device must have NOP
commands issued for tXSR to complete any internal refresh already in progress.
During SELF REFRESH operation, refresh intervals are scheduled internally and may
vary. These refresh intervals may differ from the specified tREFI time. For this reason,
the SELF REFRESH command must not be used as a substitute for the AUTO REFRESH
command.
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Power-Down
Figure 145: Self Refresh Mode
T0
T1
CK#
CK1
tCH
tIS
tIH
tCL
tIS
tCKE
CKE1,2
tIS
Command
Ta01
Ta1
tCK
tIS
AR3
((
))
((
))
((
))
((
))
NOP
((
))
((
))
Address
((
))
((
))
((
))
((
))
DQS
((
))
((
))
((
))
((
))
DQ
((
))
((
))
((
))
((
))
DM
((
))
((
))
((
))
((
))
tRP4
Tb0
((
))
((
))
((
))
tIH
NOP
((
))
((
))
Valid
tIS
tIH
Valid
tXSR5
Enter self refresh mode
Exit self refresh mode
Don’t Care
Notes:
1. Clock must be stable, cycling within specifications by Ta0, before exiting self refresh
mode.
2. CKE must remain LOW to remain in self refresh.
3. AR = AUTO REFRESH.
4. Device must be in the all banks idle state prior to entering self refresh mode.
5. Either a NOP or DESELECT command is required for tXSR time with at least two clock
pulses.
Power-Down
Power-down is entered when CKE is registered LOW. If power-down occurs when all
banks are idle, this mode is referred to as precharge power-down; if power-down occurs
when there is a row active in any bank, this mode is referred to as active power-down.
Entering power-down deactivates all input and output buffers, including CK and CK#
and excluding CKE. Exiting power-down requires the device to be at the same voltage as
when it entered power-down and received a stable clock. Note that the power-down duration is limited by the refresh requirements of the device.
When in power-down, CKE LOW must be maintained at the inputs of the device, while
all other input signals are “Don’t Care.” The power-down state is synchronously exited
when CKE is registered HIGH (in conjunction with a NOP or DESELECT command).
NOP or DESELECT commands must be maintained on the command bus until tXP is
satisfied. See Figure 147 (page 217) for a detailed illustration of power-down mode.
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Power-Down
Figure 146: Power-Down Entry (in Active or Precharge Mode)
CK#
CK
CKE
CS#
RAS#, CAS#, WE#
Or
CS#
RAS#, CAS#, WE#
Address
BA0, BA1
Don’t Care
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Power-Down
Figure 147: Power-Down Mode (Active or Precharge)
T0
T1
T2
CK#
CK
tCK
tIS
tCH
tIS
tIH
CKE
tCKE
Ta2
Tb1
tCKE1
tXP1
tIH
Valid2
tIS
Address
Ta1
((
))
tIS
Command
tCL
Ta0
((
))
((
))
NOP
tIH
((
))
((
))
NOP
((
))
((
))
Valid
DQS
((
))
((
))
DQ
((
))
((
))
DM
((
))
((
))
Valid
Valid
Must not exceed refresh device limits
No read/write
Enter3
access in progress power-down
mode
Notes:
Exit
power-down
mode
Don’t Care
1. tCKE applies if CKE goes LOW at Ta2 (entering power-down); tXP applies if CKE remains
HIGH at Ta2 (exit power-down).
2. If this command is a PRECHARGE (or if the device is already in the idle state), then the
power-down mode shown is precharge power-down. If this command is an ACTIVE (or if
at least 1 row is already active), then the power-down mode shown is active powerdown.
3. No column accesses can be in progress when power-down is entered.
Deep Power-Down
Deep power-down (DPD) is an operating mode used to achieve maximum power reduction by eliminating power to the memory array. Data will not be retained after the device enters DPD mode.
Before entering DPD mode the device must be in the all banks idle state with no activity
on the data bus (tRP time must be met). DPD mode is entered by holding CS# and WE#
LOW with RAS# and CAS# HIGH at the rising edge of the clock while CKE is LOW. CKE
must be held LOW to maintain DPD mode. The clock must be stable prior to exiting
DPD mode. To exit DPD mode, assert CKE HIGH with either a NOP or DESELECT command present on the command bus. After exiting DPD mode, a full DRAM initialization
sequence is required.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Power-Down
Figure 148: Deep Power-Down Mode
T0
T1
CK#
Ta1
Ta2
Ta3
))
((
))
CK
tIS
tCKE
CKE
Command1
Ta01
T2 ( (
((
))
DPD2
NOP
All banks idle with no
activity on the data bus
T = 200μs
((
))
((
))
NOP
Enter deep power-down mode
PRE3
NOP
Exit deep power-down mode
Don’t Care
Notes:
1. Clock must be stable prior to CKE going HIGH.
2. DPD = deep power-down.
3. Upon exit of deep power-down mode, a full DRAM initialization sequence is required.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Clock Change Frequency
Clock Change Frequency
One method of controlling the power efficiency in applications is to throttle the clock
that controls the device. The clock can be controlled by changing the clock frequency or
stopping the clock.
The device enables the clock to change frequency during operation only if all timing parameters are met and all refresh requirements are satisfied.
The clock can be stopped altogether if there are no DRAM operations in progress that
would be affected by this change. Any DRAM operation already in process must be
completed before entering clock stop mode; this includes the following timings: tRCD,
tRP, tRFC, tMRD, tWR, and tRPST. In addition, any READ or WRITE burst in progress
must be complete. (See READ Operation and WRITE Operation.)
CKE must be held HIGH with CK = LOW and CK# = HIGH for the full duration of the
clock stop mode. One clock cycle and at least one NOP or DESELECT is required after
the clock is restarted before a valid command can be issued.
Figure 149: Clock Stop Mode
Ta1
CK#
CK
CKE
Ta2
Tb3
( (
) )
( (
) )
( (
) )
( (
) )
((
))
((
))
Command
( (
) )
( (
) )
Address
( (
) )
( (
) )
DQ, DQS
((
))
((
))
NOP1
((
))
((
))
((
))
( (
) )
2
( ( CMD
) )
CMD2
( (
) )
( (
) )
Valid
((
))
((
))
Tb4
Valid
NOP
NOP
((
))
((
))
((
))
((
))
((
))
((
))
All DRAM activities must be complete
Exit clock stop mode
Enter clock stop mode
Don’t Care
Notes:
1. Prior to Ta1, the device is in clock stop mode. To exit, at least one NOP is required before
issuing any valid command.
2. Any valid command is supported; device is not in clock suspend mode.
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168-Ball NAND Flash and LPDDR PoP (TI OMAP) MCP
Revision History
Revision History
Rev. C – 12/12
• Format correction in Features
Rev. B – 10/12
• Added new industrial temperature (IT) part numbers
• Added industrial temperature range under Features
Rev. A – 05/11
• Initial release; Preliminary status
8000 S. Federal Way, P.O. Box 6, Boise, ID 83707-0006, Tel: 208-368-3900
www.micron.com/productsupport Customer Comment Line: 800-932-4992
Micron and the Micron logo are trademarks of Micron Technology, Inc.
All other trademarks are the property of their respective owners.
This data sheet contains minimum and maximum limits specified over the power supply and temperature range set forth herein.
Although considered final, these specifications are subject to change, as further product development and data characterization sometimes occur.
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