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LMK04821, LMK04826, LMK04828
SNAS605AS – MARCH 2013 – REVISED MAY 2020
LMK0482x Ultra Low-Noise JESD204B Compliant
Clock Jitter Cleaner With Dual Loop PLLs
1 Features
2 Applications
•
•
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1
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JEDEC JESD204B Support
Ultra-Low RMS Jitter
– 88 fs RMS Jitter (12 kHz to 20 MHz)
– 91 fs RMS Jitter (100 Hz to 20 MHz)
– –162.5 dBc/Hz Noise Floor at 245.76 MHz
Up to 14 Differential Device Clocks from PLL2
– Up to 7 SYSREF Clocks
– Maximum Clock Output Frequency 3.1 GHz
– LVPECL, LVDS, HSDS, LCPECL
Programmable Outputs from PLL2
Up to 1 Buffered VCXO/Crystal Output from PLL1
– LVPECL, LVDS, 2xLVCMOS Programmable
Dual Loop PLLatinum™ PLL Architecture
PLL1
– Up to 3 Redundant Input Clocks
– Automatic and Manual Switch-Over Modes
– Hitless Switching and LOS
– Integrated Low-Noise Crystal Oscillator Circuit
– Holdover Mode When Input Clocks are Lost
PLL2
– Normalized [1 Hz] PLL Noise Floor of
–227 dBc/Hz
– Phase Detector Rate up to 155 MHz
– OSCin Frequency-Doubler
– Two Integrated Low-Noise VCOs
50% Duty Cycle Output Divides, 1 to 32
(even and odd)
Precision Digital Delay, Dynamically Adjustable
25-ps Step Analog Delay
Multi-Mode: Dual PLL, Single PLL, and Clock
Distribution
Industrial Temperature Range: –40 to 85°C
Supports 105°C PCB Temperature (Measured at
Thermal Pad)
3.15-V to 3.45-V Operation
Package: 64-Pin QFN (9.0 mm × 9.0 mm × 0.8
mm)
Wireless Infrastructure
Data Converter Clocking
Networking, SONET/SDH, DSLAM
Medical / Video / Military / Aerospace
Test and Measurement
3 Description
The LMK0482x family is the industry's highest
performance
clock
conditioner
with
JEDEC
JESD204B support.
The 14 clock outputs from PLL2 can be configured to
drive seven JESD204B converters or other logic
devices, using device and SYSREF clocks. SYSREF
can be provided using both DC and AC coupling. Not
limited to JESD204B applications, each of the 14
outputs can be individually configured as highperformance outputs for traditional clocking systems.
The high performance, combined with features such
as the ability to trade off between power or
performance, dual VCOs, dynamic digital delay,
holdover, and glitchless analog delay, make the
LMK0482x family ideal for providing flexible highperformance clocking trees.
Device Information(1)
PART
NUMBER
VCO0
FREQUENCY
VCO1 FREQUENCY
LMK04821
1930 to 2075 MHz
2920 to 3080 MHz
VCO1 Div = ÷2 to ÷8
(÷2 = 1460 to 1540 MHz)
LMK04826
1840 to 1970 MHz
2440 to 2505 MHz
LMK04828
2370 to 2630 MHz
2920 to 3080 MHz
(1) For all available packages, see the orderable addendum at
the end of the datasheet.
Simplified Schematic
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
�LMK04821, LMK04826, LMK04828
SNAS605AS – MARCH 2013 – REVISED MAY 2020
www.ti.com
Table of Contents
1
2
3
4
5
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Device Comparison Table.....................................
1
1
1
2
7
6
7
Pin Configuration and Functions ......................... 8
Specifications....................................................... 11
5.1 Device Configuration Information.............................. 7
7.1
7.2
7.3
7.4
7.5
7.6
7.7
8
Absolute Maximum Ratings ....................................
ESD Ratings............................................................
Recommended Operating Conditions.....................
Thermal Information ................................................
Electrical Characteristics.........................................
SPI Interface Timing ...............................................
Typical Characteristics – Clock Output AC
Characteristics .........................................................
11
11
11
11
12
25
26
Parameter Measurement Information ................ 28
8.1 Charge Pump Current Specification Definitions...... 28
8.2 Differential Voltage Measurement Terminology ..... 29
9
Detailed Description ............................................ 30
9.1
9.2
9.3
9.4
9.5
Overview .................................................................
Functional Block Diagram .......................................
Feature Description.................................................
Device Functional Modes........................................
Programming...........................................................
30
35
39
50
56
9.6 Register Maps ........................................................ 57
9.7 Device Register Descriptions .................................. 61
10 Applications and Implementation.................... 102
10.1
10.2
10.3
10.4
10.5
10.6
10.7
Application Information........................................
Digital Lock Detect Frequency Accuracy ............
Driving CLKin and OSCin Inputs.........................
Output Termination and Biasing .........................
Typical Applications ............................................
System Examples ..............................................
Do's and Don'ts ...................................................
102
102
103
105
107
110
113
11 Power Supply Recommendations ................... 114
11.1 Pin Connection Recommendations..................... 114
11.2 Current Consumption / Power Dissipation
Calculations............................................................ 116
12 Layout................................................................. 117
12.1 Layout Guidelines ............................................... 117
12.2 Layout Example .................................................. 118
13 Device and Documentation Support ............... 119
13.1
13.2
13.3
13.4
13.5
Device Support ..................................................
Related Links ......................................................
Trademarks .........................................................
Electrostatic Discharge Caution ..........................
Glossary ..............................................................
119
119
119
119
119
14 Mechanical, Packaging, and Orderable
Information ......................................................... 119
4 Revision History
Changes from Revision AR (December 2015) to Revision AS
Page
•
Deleted references to "LMK0482xB" and replaced with device names ................................................................................. 1
•
Updated Pin Configuration and Functions table with expanded descriptions ........................................................................ 8
•
Changed mVpp to |mV| for 10-mA HSDS VOD in Electrical Characteristics......................................................................... 22
•
Added requirements for OSCout LVPECL emitter resistors to Detailed Description ........................................................... 30
•
Changed Overview to provide more detail. .......................................................................................................................... 30
•
Changed Three PLL1 Redundant Reference Inputs to provide more detail. ....................................................................... 31
•
Changed Frequency Holdover wording for added clarity. .................................................................................................... 31
•
Moved VCO1 Divider (LMK04821 only) to within Internal VCOs. ........................................................................................ 31
•
Changed all instances of '0-delay' to 'zero-delay' and added reference to Multi-Clock Synchronization app note. ............ 33
•
Changed Figure 10 and Figure 11 to show OSCout_MUX, SYNC/SYSREF detail, and color. ........................................... 35
•
Changed Figure 13 to show distribution path reclocking, other FB_MUX targets. .............................................................. 38
•
Added SYSREF_DDLY_PD and DCLKoutX_DDLY_PD conditions for added power savings in SYNC/SYSREF.............. 39
•
Added reference to Recommended Programming Sequence.............................................................................................. 40
•
Changed _CNTH/_CNTL register values to 0, representing delay value of 16, in Table 3. ............................................... 43
•
Added timing alignment figure, alignment equations to SYSREF to Device Clock Alignment ............................................ 45
•
Added LOS register requirements to Input Clock Switching - Automatic Mode................................................................... 47
•
Merged redundant paragraph into Digital Lock Detect. ....................................................................................................... 47
•
Added note clarifying PLL1 phase detector frequency effect on PLL1_WND_SIZE in Digital Lock Detect......................... 47
•
Added holdover entry conditions and clarifications in Holdover. .......................................................................................... 48
•
Added Single-Loop Mode, Single-Loop Mode With External VCO, Distribution Mode to Device Functional Modes. ......... 50
2
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SNAS605AS – MARCH 2013 – REVISED MAY 2020
Revision History (continued)
•
Added RESET Pin to Recommended Programming Sequence........................................................................................... 56
•
Changed CLKoutX_Y_ODL, CLKoutX_Y_IDL, DCLKoutX_DIV descriptions to add more detail. ....................................... 63
•
Changed DCLKoutX_ADLY description in DCLKoutX_ADLY, DCLKoutX_ADLY_MUX, DCLKout_MUX........................... 64
•
Changed SDCLKoutY_ADLY description in SDCLKoutY_ADLY_EN, SDCLKoutY_ADLY. ................................................ 65
•
Added OSCout LVPECL format instructions in VCO_MUX, OSCout_MUX, OSCout_FMT. ............................................... 68
•
Changed SYSREF_CLR description in SYSREF_CLR, SYNC_1SHOT_EN, SYNC_POL, SYNC_EN,
SYNC_PLL2_DLD, SYNC_PLL1_DLD, SYNC_MODE to add more detail.......................................................................... 74
•
Added time alongside frequency for LOS_TIMEOUT in Table 45 ....................................................................................... 80
•
Changed LOS_EN description to clarify requirements in Table 45...................................................................................... 80
•
Changed Table 53, Table 55, Table 56 register text from "N counter" to "R divider" .......................................................... 84
•
Changed Table 57 maximum field value to match register size........................................................................................... 85
•
Changed Table 75 headers from Resistance to Capacitance. .......................................................................................... 96
•
Changed Application Information to reference current TI tools. ......................................................................................... 102
•
Changed all images in Driving CLKin and OSCin Inputs to include OSCin. ..................................................................... 103
•
Changed CLKinX_BUF_TYPE to CLKinX_TYPE in Driving CLKin and OSCin Pins With a Single-Ended Source. ......... 104
•
Added Output Termination and Biasing section. ................................................................................................................ 105
•
Changed Typical Applications to reference up-to-date tools.............................................................................................. 107
•
Added System Examples .................................................................................................................................................. 110
•
Added OSCout, LVDS/HSDS, and RESET pin recommendations to Do's and Don'ts. ..................................................... 113
•
Added Pin Connection Recommendations ........................................................................................................................ 114
•
Deleted empty column in Table 87 and redirected to TICS Pro current calculator. ........................................................... 116
•
Changed tools listed in Device Support . ........................................................................................................................... 119
Changes from Revision AQ (August 2014) to Revision AR
Page
•
Added Support for 105°C thermal pad temperature............................................................................................................... 1
•
Changed from I/O to I for pin 6 in Pin Functions table. ......................................................................................................... 8
•
Deleted programmable status pin in Description column for pin 6 in Pin Functions table. .................................................... 8
•
Changed from No connection to Do not connect for pins 7, 8, 9 in Pin Functions table. ..................................................... 9
•
Changed to Reference Clock Input Port 1 for PLL 1 for Pins 34, 35 in Pin Functions. ........................................................ 9
•
Added Reference Clock Input Port 2 for PLL1 for pins 40, 41 in Pin Functions. ................................................................ 10
•
Added ESD Ratings.............................................................................................................................................................. 11
•
Added PCB temperature in Recommended Operating Conditions. ..................................................................................... 11
•
Added Digital Input Timing in Electrical Characteristics. ..................................................................................................... 24
•
Changed Detailed block diagrams for LMK04821 and LMK04826/8. ................................................................................. 35
•
Added 6 to DCLKout0 sequence and 7 to SDCLKout1 sequence in Figure 12................................................................... 37
•
Added 6 to DCLKout0 sequence and 7 to SDCLKout1 sequence in Figure 13................................................................... 38
•
Added For each SDCLKoutY being used in SYNC/SYSREF............................................................................................... 39
•
Deleted "SDCLKoutY_PD as required per output. " in Table 1............................................................................................ 39
•
Added footnote starting SDCLKoutY_PD = 0 as... in Table 1. ............................................................................................ 39
•
Added SDCLKout1_PD = 0, SDCLKout3_PD = 0 in Setup of SYSREF Example............................................................... 40
•
Changed DLD_HOLD_CNT to HOLDOVER_DLD_CNT in Holdover Mode - Automatic Exit of Holdover . ........................ 49
•
Changed Recommended Programming Sequence. ............................................................................................................ 56
•
Added 0x171/0x172 to Register Map. ................................................................................................................................. 60
•
Added LMK04821 register setting. ....................................................................................................................................... 62
•
Revised Register 0x143 table............................................................................................................................................... 74
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Product Folder Links: LMK04821 LMK04826 LMK04828
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•
Added fixed register setting for 0x171.................................................................................................................................. 75
•
Added fixed register setting for 0x172 ................................................................................................................................. 75
•
Added LMK04821 register setting. ...................................................................................................................................... 98
•
Added LMK04821 register setting. ...................................................................................................................................... 99
•
Changed RB_PLL1_LD description. .................................................................................................................................... 99
•
Changed RB_PLL2_LD description. .................................................................................................................................... 99
Changes from Revision AP (June 2013) to Revision AQ
Page
•
Changed data sheet flow and layout to conform with new TI standards. Added, updated, or renamed the following
sections: Device Information Table, Application and Implementation; Power Supply Recommendations; Layout;
Device and Documentation Support; Mechanical, Packaging, and Ordering Information .................................................... 1
•
Added values for LMK04821 under "Features" section. ........................................................................................................ 1
•
Changed LMK04820 family to LMK0482x family. ................................................................................................................. 1
•
Added values for LMK04821 in Device Configuration Information......................................................................................... 7
•
Added holdover DAC to pin 36 description in Pin Functions. ............................................................................................... 9
•
Changed Thermal Information header from LMK0482xB to LMK0482x. ............................................................................ 11
•
Changed CLKinX_BUF_TYPE to CLKinX_TYPE in Electrical Characteristics. ................................................................... 12
•
Added values for LMK04821 under Internal VCO Specifications in Electrical Characteristics. ........................................... 15
•
Added values for LMK04821 under Noise Floor in Electrical Characteristics. ..................................................................... 16
•
Added values for LMK04821 under CLKout Closed Loop Phase Noise Specifications a Commercial Quality VCXO
in Electrical Characteristics. ................................................................................................................................................. 17
•
Added 245.76 MHz as frequency for LMK04826B phase noise data L(f)CLKout for VCO0. .................................................. 18
•
Added 245.76 MHz as frequency for LMK04826B phase noise data L(f)CLKout for VCO1. .................................................. 18
•
Added 245.76 MHz as frequency for LMK04828B phase noise data L(f)CLKout for VCO0. .................................................. 18
•
Added 245.76 MHz as frequency for LMK04828B phase noise data L(f)CLKout for VCO1. .................................................. 18
•
Added values for LMK04821 under CLKout Closed Loop Jitter Specifications a Commercial Quality VCXO. ................... 19
•
Added SDCLKoutY_HS = 0 for tsJESD204B in Electrical Characteristics. ............................................................................... 21
•
Added Propagation Delay from CLKin0 to SDCLKoutY in Electrical Characteristics........................................................... 21
•
Added footnote that LMK04821 has no DCLKoutX or SDCLKoutY outputs on at power up, only OSCout. ...................... 21
•
Changed VOH TEST CONDITIONS to = 3 or 4 and VOL TEST CONDITIONS to 3, 4, or 6 under DIGITAL OUTPUTS
(CLKin_SELX, Status_LDX, and RESET/GPO) subheading in Electrical Characteristics. .................................................. 23
•
Changed Digital Inputs (SCK, SDIO, CS*) IIH VIH = VCC min line from 5 µA to –5 µA........................................................ 24
•
Added 4 wire mode read back has same timing as SDIO pin, R/W bit = 0 is for SPI write, R/W bit = 1 is for SPI
read, W1 and W0 shall be written as 0. ............................................................................................................................... 25
•
Added LMK04821 phase noise graphs under Clock Output AC Characteristics. ................................................................ 26
•
Added link to AN-912 Application Report. ............................................................................................................................ 29
•
Changed from Glitchless Half Shift to Glitchless Half Step.................................................................................................. 33
•
Added LMK04821 detailed block diagram............................................................................................................................ 35
•
Changed block from SDCLKoutY_POL to DCLKoutX_POL in Figure 12. ........................................................................... 37
•
Added SYSREF_CLKin0_MUX block to Figure 13 image. .................................................................................................. 38
•
Changed Figure 13 to show that FB_MUX SYSREF input comes from SYSREF Divider, not SYSREF_MUX. ................. 38
•
Changed term pulsor to pulser throughout........................................................................................................................... 39
•
Changed DCLKout0_1_DIV to DCLKout0_DIV; DCLKout2_3_DIV to DCLKout2_DIV; DCLKout4_5_DIV to
DCLKout4_DIV. .................................................................................................................................................................... 40
•
Added DCLKout4_DIV = 20. ................................................................................................................................................ 40
•
Added DCLKout0_DDLY_PD = 0, DCLKout2_DDLY_PD = 0, DCLKout4_DDLY_PD = 0. ................................................. 40
•
Changed text to read, Set device clock and SYSREF divider digital delays: DCLKout0_DDLY_CNTH,
DCLKout0_DDLY_CNTL, DCLKout2_DDLY_CNTH, DCLKout2_DDLY_CNTL, DCLKout4_DDLY_CNTH,
4
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SNAS605AS – MARCH 2013 – REVISED MAY 2020
DCLKout4_DDLY_CNTL, SYSREF_DDLY. ........................................................................................................................ 40
•
Added = 1 in SYSREF Request. ......................................................................................................................................... 41
•
Changed step numbers in dynamic delay and references to steps to be correct, step 8 was duplicated. ......................... 44
•
Added note LMK04821 includes VCO1 divider on VCO1 output.. ....................................................................................... 50
•
Added note LMK04821 includes VCO1 divider on VCO1 output.. ....................................................................................... 51
•
Added R/W bit = 0 is for SPI write. R/W bit = 1 is for SPI read. ......................................................................................... 56
•
Added If using LMK04821, program register 0x174 in Recommended Programming Sequence. ..................................... 56
•
Added SYSREF_CLKin0_MUX and VCO1_DIV to register map. ........................................................................................ 58
•
Added CLKin_OVERRIDE bit to register map. .................................................................................................................... 59
•
Changed from half shift to half step...................................................................................................................................... 64
•
Changed definition of SDCLKoutY_DDLY value of 0 from Reserved to Bypass. ................................................................ 64
•
Changed from Sets the polarity of SYSREF clocks to Sets the polarity of clock on SDCLKoutY when device clock
output is selected with SDCLKoutY_MUX............................................................................................................................ 67
•
Changed Sets the polarity of the device clocks to Sets the polarity of the device clocks from the DCLKoutX outputs. ..... 67
•
Added LMK04821 DCLKoutX_FMT power on reset values as powerdown......................................................................... 67
•
Changed from SYSREF to SYSREF Divider in Source column of Register 0x13F. ........................................................... 71
•
Changed reserved to Off for CLKin1_OUT_MUX. .............................................................................................................. 76
•
Changed reserved to Off for CLKin0_OUT_MUX. .............................................................................................................. 76
•
Added CLKin_OVERRIDE bit. .............................................................................................................................................. 83
•
Added LMK04821 register 0x174 for VCO1_DIV................................................................................................................. 98
•
Deleted LMK04828 from Core line. ................................................................................................................................... 116
•
Added VCO1 Icc including VCO1 Divider for LMK04821................................................................................................... 116
•
Changed VCO1 Icc and power dissipated for LMK04828B/26B from 6 mA to 13.5 mA and 19.8 mW to 44.55 mW. ...... 116
Changes from Revision AO (March 2013) to Revision AP
Page
•
Changed datasheet title from LMK04828 to LMK0482xB ...................................................................................................... 1
•
Changed LMK04828 family to LMK04820 family. .................................................................................................................. 1
•
Changed image from LMK04828B to LMK0482xB. ............................................................................................................... 1
•
Added LMK04826 to Device Configuration Information table. ............................................................................................... 7
•
Changed - increased LMK04828B VCO0 max frequency from 2600 MHz to 2630 MHz. ..................................................... 7
•
Changed - expanded LMK04828B VCO1 frequency range from 2945 - 3005 MHz to 2920 MHz - 3080 MHz..................... 7
•
Changed Thermal Information header from LMK04828B to LMK0482xB............................................................................ 11
•
Added LMK04826 VCO Range Specification ....................................................................................................................... 15
•
Changed - increased LMK04828B VCO0 max frequency from 2600 MHz to 2630 MHz. ................................................... 15
•
Changed - expanded LMK04828B VCO1 frequency range from 2945 - 3005 MHz to 2920 MHz - 3080 MHz................... 15
•
Added LMK04826 KVCO specification. .................................................................................................................................. 15
•
Added clarification of LMK04828 specification vs LMK04826 specification for KVCO. .......................................................... 15
•
Added LMK04826 noise floor data. ...................................................................................................................................... 16
•
Changed - clarified phase noise data section header. ......................................................................................................... 17
•
Added LMK04826 phase noise data. ................................................................................................................................... 18
•
Added LMK04826 jitter data. ................................................................................................................................................ 19
•
Added LMK04826 fCLKout-startup spec. ..................................................................................................................................... 21
•
Added clarification of LMK04828 specification vs. LMK04826 specification for fCLKout-startup. ................................................ 21
•
Added LMK04826B Phase Noise Performance Graph for VCO0. ....................................................................................... 26
•
Added LMK04826B Phase Noise Performance Graph for VCO1. ....................................................................................... 26
•
Added Added PLL2 loop filter bandwidth and phase margin info to plot. ............................................................................ 27
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•
Changed LMK04828 to LMK0482xB in VCXO/Crystal Buffered Output. ............................................................................ 31
•
Changed LMK04828 to LMK0482xB in Status Pins. ........................................................................................................... 33
•
Changed image from LMK04828 to LMK0482xB................................................................................................................. 50
•
Changed - corrected value of PLL2_P selection to be 0 to correspond with register programming definition. ................... 50
•
Changed image from LMK04828 to LMK0482xB................................................................................................................. 51
•
Changed image from LMK04828 to LMK0482xB................................................................................................................. 52
•
Added LMK04826 register setting. ....................................................................................................................................... 62
•
Added LMK04826 register setting. ....................................................................................................................................... 98
•
Added LMK04826 register setting. ....................................................................................................................................... 99
6
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SNAS605AS – MARCH 2013 – REVISED MAY 2020
5 Device Comparison Table
5.1 Device Configuration Information
PART NUMBER
REFERENCE
INPUTS (1)
OSCout (BUFFERED
OSCin Clock) LVDS/
LVPECL/ LVCMOS (1)
PLL2
PROGRAMMABLE
LVDS/LVPECL/HSDS
OUTPUTS
VCO0 FREQUENCY
VCO1 FREQUENCY
VCO1_DIV = ÷2
1460 to 1540 MHz
VCO1_DIV = ÷3
974 to 1026 MHz
VCO1_DIV = ÷4
730 to 770 MHz
LMK04821
Up to 3
Up to 1
14
1930 to 2075 MHz
VCO1_DIV = ÷5
584 to 616 MHz
VCO1_DIV = ÷6
487 to 513 MHz
VCO1_DIV = ÷7
418 to 440 MHz
VCO1_DIV = ÷8
365 to 385 MHz
(1)
LMK04826
Up to 3
Up to 1
14
1840 to 1970 MHz
2440 to 2505 MHz
LMK04828
Up to 3
Up to 1
14
2370 to 2630 MHz
2920 to 3080 MHz
OSCout may also be third clock input, CLKin2.
Copyright © 2013–2020, Texas Instruments Incorporated
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6 Pin Configuration and Functions
NKD Package
64-Pin WQFN
Top View
CLKin_SEL1
SDCLKout11*
SDCLKout11
DCLKout10*
DCLKout10
Vcc11_CG3
DCLKout8*
DCLKout8
SDCLKout9*
SDCLKout9
57
56
55
54
53
52
51
50
49
SDCLKout13
60
CLKin_SEL0
SDCLKout13*
61
58
DCLKout12
62
59
Vcc12_CG0
DCLKout12*
63
Clock Group 3
64
Clock Group 0
DCLKout0
1
48
Status_LD2
DCLKout0*
2
47
Vcc10_PLL2
CPout2
SDCLKout1
3
46
SDCLKout1*
4
45
Vcc9_CP2
RESET/GPO
5
44
OSCin*
SYNC/SYSREF_REQ
6
43
OSCin
NC
7
42
Vcc8_OSCin
NC
8
41
OSCout*/CLKin2*
LLP-64
Top down view
NC
9
40
OSCout/CLKin2
Vcc1_VCO
10
39
Vcc7_OSCout
LDObyp1
11
38
CLKin0*
LDObyp2
12
37
CLKin0
SDCLKout3
13
36
Vcc6_PLL1
SDCLKout3*
14
35
CLKin1*/Fin*/FBCLKin*
DCLKout2
15
34
CLKin1/Fin/FBCLKin
DCLKout2*
16
33
Vcc5_DIG
23
24
25
26
27
28
29
30
SDCLKout5*
DCLKout4
DCLKout4*
Vcc4_CG2
DCLKout6
DCLKout6*
SDCLKout7
SDCLKout7*
32
22
SDCLKout5
CPout1
21
Vcc3_SYSREF
31
20
Status_LD1
19
SCK
18
CS*
Clock Group 1
SDIO
17
Vcc2_CG1
DAP
Clock Group 2
Pin Functions
PIN
NO.
1
I/O (1)
DCLKout0
2
DCLKout0*
3
SDCLKout1
4
SDCLKout1*
5
RESET/GPO
6
SYNC/SYSREF_REQ
(1)
(2)
8
DESCRIPTION (2)
NAME
O
Device clock output 0. Differential clock output. Part of clock group 0. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
O
SYSREF / Device clock output 1. Differential clock output. Part of clock group 0. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
I/O
Device reset input or GPO. If used as a reset input, pin polarity and nominal 160-kΩ pull-up or pull-down are controlled
by register settings. If used as an output, can be set to push-pull or open-drain.
I
Synchronization input.. Can be used to reset dividers, trigger the SYSREF pulser, or request continuous SYSREF from
the SYSREF divider. Pin polarity is controlled by register settings. Nominal 160-kΩ pulldown.
The definitions below define the I/O type for each pin.
(a) I = Input
(b) O = Output
(c) I/O = Input / Output (Configurable)
(d) P = Power Supply
(e) BP = Bypass (LDO output)
(f) G = Ground
(g) NC = No Connect
See Pin Connection Recommendations for recommended connections.
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Pin Functions (continued)
PIN
NO.
I/O (1)
DESCRIPTION (2)
NAME
7,
-
NC
8
-
NC
9
-
NC
10
Vcc1_VCO
11
LDObyp1
BP
LDO bypass. This pin must be bypassed to ground with 10-µF capacitor placed close to the pin.
12
LDObyp2
BP
LDO bypass.This pin must be bypassed to ground with a 0.1-µF capacitor placed close to the pin.
13,
SDCLKout3
O
14
SDCLKout3*
SYSREF / Device clock output 3. Differential clock output. Part of clock group 1. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
15
DCLKout2
O
16
DCLKout2*
Device clock output 2. Differential clock output. Part of clock group 1. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
17
Vcc2_CG1
P
Power supply for clock outputs 2 and 3. Decoupling capacitance requirements may change with system frequency. See
Pin Connection Recommendations for recommendations.
18
CS*
I
SPI Chip select. Active-low input. Must be pulled up externally or actively driven high when not in use.
19
SCK
I
SPI clock. Active-high input. Nominal 160-kΩ pulldown.
20
SDIO
I/O
21
Vcc3_SYSREF
22
SDCLKout5
23
SDCLKout5*
24
DCLKout4
25
DCLKout4*
26
Vcc4_CG2
27
DCLKout6
28
DCLKout6*
29
SDCLKout7
30
SDCLKout7*
31
P
Do not connect. These pins must be left floating.
Power supply for VCO LDO. Decoupling capacitance requirements may change with system frequency. See Pin
Connection Recommendations for recommendations.
SPI data. This pin can implement bidirectional I/O. As an output, this pin can be configured for open-drain or push-pull.
Open-drain output requires external pull-up. Register settings can disable the output feature of this pin. Other GPIO pins
can also be configured as SPI MISO (master-in slave-out) for traditional 4-wire SPI.
P
Power supply for SYSREF divider and SYNC. Decoupling capacitance requirements may change with system
frequency. See Pin Connection Recommendations for recommendations.
O
SYSREF / Device clock output 5. Differential clock output. Part of clock group 2. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
O
Device clock output 4. Differential clock output. Part of clock group 2. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
Power supply for clock outputs 4, 5, 6, and 7. Decoupling capacitance requirements may change with system frequency.
See Pin Connection Recommendations for recommendations.
O
Device clock output 6. Differential clock output. Part of clock group 2. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
O
SYSREF / Device clock output 7. Differential clock output. Part of clock group 2. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
Status_LD1
I/O
Programmable status pin. By default, this pin is configured as an active-high output representing the state of PLL1 lock
detect. Other status conditions and output polarity are register-selectable. This pin can be configured for open-drain or
push-pull output.
32
CPout1
O
Charge pump 1 output. This pin is connected to the external loop filter components for PLL1, and to the VCXO control
voltage pin.
33
Vcc5_DIG
P
Power supply for digital circuitry, such as SPI bus and GPIO pins. Decoupling capacitance requirements may change
with system frequency. See Pin Connection Recommendations for recommendations.
CLKin1
I
(Default) Reference clock input port 1 for PLL1. Can be configured for DC or AC coupling. Accepts single-ended or
differential clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor. Leave floating if
both pins are unused. See Driving CLKin and OSCin Inputs for single-ended termination information.
FBCLKin
I
Feedback input for external clock feedback input (zero–delay mode). Can be configured for DC or AC coupling. Accepts
single-ended or differential clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor.
Leave floating if both pins are unused. See Driving CLKin and OSCin Inputs for single-ended termination information.
Fin
I
External VCO input (external VCO mode) or Clock Distribution input (distribution mode). Can be configured for DC or
AC coupling. Accepts single-ended or differential clocks. If unused in single-ended configuration, connect to GND with a
0.1-µF capacitor. Leave floating if both pins are unused. See Driving CLKin and OSCin Inputs for single-ended
termination information.
CLKin1*
I
(Default) Reference clock input port 1 for PLL1. Can be configured for DC or AC coupling. Accepts single-ended or
differential clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor. Leave floating if
both pins are unused. See Driving CLKin and OSCin Inputs for single-ended termination information.
FBCLKin*
I
Feedback input for external clock feedback input (zero-delay mode). Can be configured for DC or AC coupling. Accepts
single-ended or differential clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor.
Leave floating if both pins are unused. See Driving CLKin and OSCin Inputs for single-ended termination information.
Fin*
I
External VCO input (external VCO mode) or Clock Distribution input (distribution mode). Can be configured for DC or
AC coupling. Accepts single-ended or differential clocks. If unused in single-ended configuration, connect to GND with a
0.1-µF capacitor. Leave floating if both pins are unused. See Driving CLKin and OSCin Inputs for single-ended
termination information.
36
Vcc6_PLL1
P
Power supply for PLL1, charge pump 1, holdover DAC. Decoupling capacitance requirements may change with system
frequency. See Pin Connection Recommendations for recommendations.
37
CLKin0
I
Reference clock input port 0 for PLL1. Can also be used as a synchronization input for SYNC/SYSREF. Can be
configured for DC or AC coupling. Accepts single-ended or differential clocks. If unused in single-ended configuration,
connect to GND with a 0.1-µF capacitor. Leave floating if both pins are unused. See Driving CLKin and OSCin Inputs for
single-ended termination information.
34
35
38
CLKin0*
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Pin Functions (continued)
PIN
NO.
39
I/O (1)
DESCRIPTION (2)
NAME
Vcc7_OSCout
P
Power supply for OSCout port and CLKin2. Decoupling capacitance requirements may change with system frequency.
See Pin Connection Recommendations for recommendations.
(Default) Buffered output of OSCin port. Defaults to LVPECL. In LVPECL output format, this pin only supports 240-Ω
emitter resistors. If unused, set output format buffer to powerdown and leave pins floating.
OSCout
CLKin2
Reference clock input port 2 for PLL1. Can be configured for DC or AC coupling. Accepts single-ended or differential
clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor. Leave floating if both pins are
unused. See Driving CLKin and OSCin Inputs for single-ended termination information. Registers must be configured to
set this pin as an input.
OSCout*
(Default) Buffered output of OSCin port. Defaults to LVPECL. In LVPECL output format, this pin only supports 240-Ω
emitter resistors. If unused, set output format buffer to powerdown and leave pins floating.
40
I/O
41
I/O
CLKin2*
Reference clock input port 2 for PLL1. Can be configured for DC or AC coupling. Accepts single-ended or differential
clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor. Leave floating if both pins are
unused. See Driving CLKin and OSCin Inputs for single-ended termination information. Registers must be configured to
set this pin as an input.
P
Power supply for OSCin. Decoupling capacitance requirements may change with system frequency. See Pin Connection
Recommendations for recommendations.
I
Feedback to PLL1, reference input to PLL2. Inputs to this pin should be AC-coupled. Accepts single-ended or differential
clocks. If unused in single-ended configuration, connect to GND with a 0.1-µF capacitor. Leave floating if both pins are
unused. See Driving CLKin and OSCin Inputs for single-ended termination information.
Vcc9_CP2
P
Power supply for PLL2 charge pump. Decoupling capacitance requirements may change with system frequency. See
Pin Connection Recommendations for recommendations.
46
CPout2
O
Charge pump 2 output. This pin is connected to the external components of the PLL2 loop filter. If an external VCO is
used, this pin is also connected to the external VCO control voltage pin. Do not route this pin near noisy signals.
47
Vcc10_PLL2
P
Power supply for PLL2. Decoupling capacitance requirements may change with system frequency. See Pin Connection
Recommendations for recommendations.
48
Status_LD2
I/O
Programmable status pin. By default, this pin is configured as an active-high output representing the state of PLL2 lock
detect. Other status conditions and output polarity are register-selectable. This pin can be configured for open-drain or
push-pull output.
49
SDCLKout9
O
50
SDCLKout9*
SYSREF / Device clock 9. Differential clock output. Part of clock group 3. To minimize noise, keep all outputs in the
clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
51
DCLKout8
O
52
DCLKout8*
Device clock output 8. Differential clock output. Part of clock group 3. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
53
Vcc11_CG3
P
Power supply for clock outputs 8, 9, 10, and 11. Decoupling capacitance requirements may change with system
frequency. See Pin Connection Recommendations for recommendations.
54
DCLKout10
O
55
DCLKout10*
Device clock output 10. Differential clock output. Part of clock group 3. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
56
SDCLKout11
O
57
SDCLKout11*
SYSREF / Device clock output 11. Differential clock output. Part of clock group 3. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
58
CLKin_SEL0
I/O
Programmable status pin. By default this pin is programmed as an active-high input with nominal 160-kΩ pulldown that
selects which CLKin is used as the reference to PLL1 in pin-select mode. If used as an input, pin polarity and nominal
160-kΩ pull-up or pull-down are controlled by register settings. If used as an output, can be set to push-pull or opendrain.
59
CLKin_SEL1
I/O
Programmable status pin. By default this pin is programmed as an active-high input with nominal 160-kΩ pulldown that
selects which CLKin is used as the reference to PLL1 in pin-select mode. If used as an input, pin polarity and nominal
160-kΩ pull-up or pull-down are controlled by register settings. If used as an output, can be set to push-pull or opendrain.
60
SDCLKout13
O
61
SDCLKout13*
SYSREF / Device clock output 13. Differential clock output. Part of clock group 0. To minimize noise, keep all outputs in
the clock group at the same frequency, or at frequencies without spurious interference. If unused, set output format
buffer to powerdown and leave pins floating.
62
DCLKout12
O
63
DCLKout12*
Device clock output 12. Differential clock output. Part of clock group 0. To minimize noise, keep all outputs in the clock
group at the same frequency, or at frequencies without spurious interference. If unused, set output format buffer to
powerdown and leave pins floating.
64
Vcc12_CG0
P
Power supply for clock outputs 0, 1, 12, and 13. Decoupling capacitance requirements may change with system
frequency. See Pin Connection Recommendations for recommendations.
-
DAP
G
Die attach pad. Connect directly to GND plane through multiple vias to minimize resistive and inductive effects and to
achieve good thermal performance. All power supply pins are referred to the DAP ground.
42
Vcc8_OSCin
43
OSCin
44
OSCin*
45
10
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
(1)
MIN
MAX
UNIT
–0.3
3.6
V
–0.3
(VCC +
0.3)
V
Lead temperature (solder 4 seconds)
260
°C
TJ
Junction temperature
150
°C
IIN
Differential input current (CLKinX/X*,
OSCin/OSCin*, FBCLKin/FBCLKin*, Fin/Fin*)
±5
mA
MSL
Moisture sensitivity level
Tstg
Storage temperature
VCC
Supply voltage
VIN
Input voltage
TL
(1)
(2)
(2)
3
–65
150
°C
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Never to exceed 3.6 V.
7.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2000
Machine Model (MM)
±150
Charged-device model (CDM), per JEDEC specification JESD22C101 (2)
±250
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. Manufacturing with
less than 500-V HBM is possible with the necessary precautions. Pins listed as ±2000 V may actually have higher performance.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. Manufacturing with
less than 250-V CDM is possible with the necessary precautions. Pins listed as ±250 V may actually have higher performance.
7.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
TJ
Junction temperature
TA
Ambient temperature
TPCB
PCB temperature (measured at thermal pad)
VCC
Supply voltage
MIN
TYP
–40
25
3.15
3.3
MAX
UNIT
125
°C
85
°C
105
°C
3.45
V
7.4 Thermal Information
LMK0482x
THERMAL METRIC (1)
NKD (WQFN)
UNIT
64 PINS
RθJA
Junction-to-ambient thermal resistance (2)
RθJC(top)
Junction-to-case (top) thermal resistance
RθJB
Junction-to-board thermal resistance (4)
(1)
(2)
(3)
(4)
(3)
24.3
°C/W
6.1
°C/W
3.5
°C/W
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report (SPRA953).
The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, High-K board, as
specified in JESD51-7, in an environment described in JESD51-2a.
The junction-to-case(top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific JEDEC-standard
test exists, but a close description can be found in the ANSI SEMI standard G30-88.
The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB
temperature, as described in JESD51-8.
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Thermal Information (continued)
LMK0482x
THERMAL METRIC (1)
NKD (WQFN)
UNIT
64 PINS
ψJT
Junction-to-top characterization parameter (5)
0.1
°C/W
ψJB
Junction-to-board characterization parameter (6)
3.5
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance (7)
0.7
°C/W
(5)
(6)
(7)
The junction-to-top characterization parameter, ΨJT, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining RθJA, using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-board characterization parameter, ΨJB estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining RθJA , using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-case(bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific
JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
7.5 Electrical Characteristics
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
1
3
mA
565
665
mA
750
MHz
CURRENT CONSUMPTION
ICC_PD
Power down supply current
ICC_CLKS
Supply current
14 HSDS 8-mA clocks enabled
PLL1 and PLL2 locked.
(1)
CLKin0/0*, CLKin1/1*, and CLKin2/2* INPUT CLOCK SPECIFICATIONS
fCLKin
Clock input frequency
SLEWCLKin
Clock input slew rate
VIDCLKin
Clock input
Differential input voltage
Figure 8
VSSCLKin
0.001
(2)
20% to 80%
(3)
Clock input
Single-ended input voltage
VCLKin
0.15
0.5
V/ns
0.125
1.55
|V|
0.25
3.1
Vpp
AC coupled to CLKinX;
CLKinX* AC coupled to ground
CLKinX_TYPE = 0 (bipolar)
0.25
2.4
Vpp
AC coupled to CLKinX;
CLKinX* AC coupled to ground
CLKinX_TYPE = 1 (MOS)
0.35
2.4
Vpp
AC coupled
Each pin AC coupled, CLKin0/1/2
CLKinX_TYPE = 0 (bipolar)
0
|mV|
Each pin AC coupled, CLKin0/1
CLKinX_TYPE = 1 (MOS)
55
|mV|
DC offset voltage between
CLKin2/CLKin2* (CLKin2* - CLKin2)
Each pin AC coupled
CLKinX_TYPE = 1 (MOS)
20
|mV|
VCLKin- VIH
High input voltage
VCLKin- VIL
Low input voltage
DC coupled to CLKinX;
CLKinX* AC coupled to ground
CLKinX_TYPE = 1 (MOS)
|VCLKinX-offset|
DC offset voltage between
CLKinX/CLKinX* (CLKinX* - CLKinX)
2.0
VCC
V
0.0
0.4
V
0.001
750
MHz
0.001
3100
MHz
FBCLKin/FBCLKin* and Fin/Fin* INPUT SPECIFICATIONS
fFBCLKin
fFin
(1)
(2)
(3)
(4)
12
Clock input frequency for
zero-delay with external feedback.
AC coupled
CLKinX_TYPE = 0 (bipolar)
Clock input frequency for
external VCO or distribution mode
(4)
AC coupled
CLKinX_TYPE = 0 (bipolar)
See the applications section of Power Supply Recommendations for Icc for specific part configuration and how to calculate Icc for a
specific design.
To meet the jitter performance listed in the subsequent sections of this data sheet, the minimum recommended slew rate for all input
clocks is 0.5 V/ns. This is especially true for single-ended clocks. Phase-noise performance begins to degrade as the clock input slew
rate is reduced. However, the device will function at slew rates down to the minimum listed. When compared to single-ended clocks,
differential clocks (LVDS, LVPECL) are less susceptible to degradation in phase-noise performance at lower slew rates, due to their
common-mode noise rejection. However, TI also recommends using the highest possible slew rate for differential clocks to achieve
optimal phase-noise performance at the device outputs.
See Differential Voltage Measurement Terminology for definition of VID and VOD voltages.
Assured by characterization. ATE tested at 2949.12 MHz.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
VFBCLKin/Fin
Single ended
Clock input voltage
SLEWFBCLKin/Fin
Slew rate on CLKin
(2)
TEST CONDITIONS
MIN
AC coupled
CLKinX_TYPE = 0 (bipolar)
0.25
AC coupled; 20% to 80%;
(CLKinX_TYPE = 0)
0.15
TYP
MAX
UNIT
2.0
Vpp
0.5
V/ns
PLL1 SPECIFICATIONS
fPD1
PLL1 phase detector frequency
ICPout1SOURCE
ICPout1SINK
PLL1 charge
Pump source current
PLL1 charge
Pump sink current
(5)
40
VCPout1 = VCC/2, PLL1_CP_GAIN = 0
50
VCPout1 = VCC/2, PLL1_CP_GAIN = 1
150
VCPout1 = VCC/2, PLL1_CP_GAIN = 2
250
…
(5)
MHz
µA
…
VCPout1 = VCC/2, PLL1_CP_GAIN = 14
1450
VCPout1 = VCC/2, PLL1_CP_GAIN = 15
1550
VCPout1=VCC/2, PLL1_CP_GAIN = 0
–50
VCPout1=VCC/2, PLL1_CP_GAIN = 1
–150
VCPout1=VCC/2, PLL1_CP_GAIN = 2
–250
…
µA
…
VCPout1=VCC/2, PLL1_CP_GAIN = 14
–1450
VCPout1=VCC/2, PLL1_CP_GAIN = 15
–1550
ICPout1%MIS
Charge pump
Sink / source mismatch
VCPout1 = VCC/2, T = 25 °C
1%
ICPout1VTUNE
Magnitude of charge pump current
variation vs. charge pump voltage
0.5 V < VCPout1 < VCC - 0.5 V
TA = 25 °C
4%
ICPout1%TEMP
Charge pump current vs. temperature
variation
ICPout1 TRI
Charge pump TRI-STATE leakage
current
PN10kHz
PLL 1/f noise at 10-kHz offset.
Normalized to 1-GHz output
frequency
PN1Hz
Normalized phase noise contribution
10%
4%
0.5 V < VCPout < VCC - 0.5 V
5
PLL1_CP_GAIN = 350 µA
–117
PLL1_CP_GAIN = 1550 µA
–118
PLL1_CP_GAIN = 350 µA
dBc/Hz
–221.5
PLL1_CP_GAIN = 1550 µA
nA
dBc/Hz
–223
PLL2 REFERENCE INPUT (OSCin) SPECIFICATIONS
(6)
fOSCin
PLL2 reference input
SLEWOSCin
PLL2 reference clock minimum slew
rate on OSCin (2)
20% to 80%
VOSCin
Input voltage for OSCin or OSCin*
AC coupled; single-ended
(unused pin AC coupled to GND)
VIDOSCin
VSSOSCin
Differential voltage swing
Figure 8
AC coupled
|VOSCin-offset|
DC offset voltage between
OSCin/OSCin* (OSCinX* - OSCinX)
Each pin AC coupled
fdoubler_max
(5)
(6)
(7)
(8)
Doubler input frequency
500
(7)
0.15
0.5
MHz
V/ns
0.2
2.4
0.2
1.55
|V|
0.4
3.1
Vpp
20
Vpp
|mV|
(8)
EN_PLL2_REF_2X = 1 ;
OSCin duty cycle 40% to 60%
155
MHz
This parameter is programmable.
FOSCin maximum frequency assured by characterization. Production tested at 122.88 MHz.
Assured by characterization. ATE tested at 122.88 MHz.
The EN_PLL2_REF_2X bit enables or disables a frequency doubler mode for the PLL2 OSCin path.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
40
MHz
CRYSTAL OSCILLATOR MODE SPECIFICATIONS
FXTAL
Crystal frequency range
Fundamental mode crystal
ESR = 200 Ω (10 to 30 MHz)
ESR = 125 Ω (30 to 40 MHz)
CIN
Input capacitance of OSCin port
–40 to 85 °C
10
1
pF
PLL2 PHASE DETECTOR and CHARGE PUMP SPECIFICATIONS
fPD2
Phase detector frequency
(7)
155
VCPout2=VCC/2, PLL2_CP_GAIN = 0
ICPoutSOURCE
ICPoutSINK
PLL2 charge pump source current
PLL2 charge pump sink current
(5)
(5)
VCPout2=VCC/2, PLL2_CP_GAIN = 1
400
VCPout2=VCC/2, PLL2_CP_GAIN = 2
1600
VCPout2=VCC/2, PLL2_CP_GAIN = 3
3200
VCPout2=VCC/2, PLL2_CP_GAIN = 0
–100
VCPout2=VCC/2, PLL2_CP_GAIN = 1
–400
VCPout2=VCC/2, PLL2_CP_GAIN = 2
–1600
VCPout2=VCC/2, PLL2_CP_GAIN = 3
–3200
ICPout2%MIS
Charge pump sink/source mismatch
ICPout2VTUNE
Magnitude of charge pump current vs. 0.5 V < VCPout2 < VCC - 0.5 V
charge pump voltage variation
TA = 25 °C
4%
ICPout2%TEMP
Charge pump current vs. temperature
variation
4%
ICPout2TRI
Charge pump leakage
PN10kHz
PLL 1/f noise at 10-kHz offset
Normalized to
1-GHz output frequency
PN1Hz
1%
0.5 V < VCPout2 < VCC - 0.5 V
(9)
.
Normalized phase noise contribution
(10)
VCPout2=VCC/2, TA = 25 °C
µA
µA
10%
10
PLL2_CP_GAIN = 400 µA
–118
PLL2_CP_GAIN = 3200 µA
–121
PLL2_CP_GAIN = 400 µA
–222.5
PLL2_CP_GAIN = 3200 µA
MHz
100
–227
nA
dBc/Hz
dBc/Hz
(9)
A specification in modeling PLL in-band phase noise is the 1/f flicker noise, LPLL_flicker(f), which is dominant close to the carrier. Flicker
noise has a 10-dB/decade slope. PN10kHz is normalized to a 10-kHz offset and a 1-GHz carrier frequency. PN10kHz = LPLL_flicker(10
kHz) - 20log(Fout / 1 GHz), where LPLL_flicker(f) is the single side band phase noise of only the flicker noise's contribution to total noise,
L(f). To measure LPLL_flicker(f), it is important to be on the 10-dB/decade slope close to the carrier. A high compare frequency and a
clean crystal are important to isolating this noise source from the total phase noise, L(f). LPLL_flicker(f) can be masked by the reference
oscillator performance if a low power or noisy source is used. The total PLL in-band phase noise performance is the sum of LPLL_flicker(f)
and LPLL_flat(f).
(10) A specification modeling PLL in-band phase noise. The normalized phase noise contribution of the PLL, LPLL_flat(f), is defined as:
PN1HZ=LPLL_flat(f) - 20log(N) - 10log(fPDX). LPLL_flat(f) is the single side band phase noise measured at an offset frequency, f, in a 1-Hz
bandwidth and fPDX is the phase-detector frequency of the synthesizer. LPLL_flat(f) contributes to the total noise, L(f).
14
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
INTERNAL VCO SPECIFICATIONS
LMK04821 VCO tuning range
fVCO
LMK04826 VCO tuning range
LMK04828 VCO tuning range
LMK04821 fine tuning sensitivity
KVCO
LMK04826 fine tuning sensitivity
LMK04828 fine tuning sensitivity
|ΔTCL|
Allowable temperature drift for
continuous lock
(12)
VCO0
1930
2075
VCO1 (11)
2920
3080
VCO0
1840
1970
VCO1
2440
2505
VCO0
2370
2630
VCO1
2920
3080
LMK04821 VCO0
12 to 20
LMK04821 VCO1
15 to 24
LMK04826 VCO0
11 to 19
LMK04826 VCO1
8 to 11
LMK04828 VCO0 at 2457.6 MHz
17 to 27
LMK04828 VCO1 at 2949.12 MHz
17 to 23
After programming for lock, no changes
to output configuration are permitted to
assure continuous lock
MHz
MHz
MHz
MHz/V
MHz/V
MHz/V
125
°C
(11) The VCO1 divider, VCO1_DIV in register 0x174, can be programmed to ÷2 to ÷8 resulting in a lower effective VCO frequency range, as
shown in Device Configuration Information.
(12) Maximum allowable temperature drift for continuous lock is how far the temperature can drift in either direction from the value it was at
the time that the 0x168 register was last programmed with PLL2_FCAL_DIS = 0, and still have the part stay in lock. The action of
programming the 0x168 register, even to the same value, activates a frequency calibration routine. This implies the part will work over
the entire frequency range, but if the temperature drifts more than the maximum allowable drift for continuous lock, then it is necessary
to reload the appropriate register to ensure it stays in lock. Regardless of what temperature the part was initially programmed at, the
temperature can never drift outside the frequency range of –40 °C to 85 °C without violating specifications.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
NOISE FLOOR
LVDS
L(f)CLKout
LMK04821, VCO0, noise floor
20-MHz offset (13)
245.76 MHz
–158.2
HSDS 6 mA
–160
HSDS 8 mA
–161
HSDS 10 mA
–161.4
LVPECL16 with 240
Ω
–161.6
LVPECL20 with 240
Ω
–162
LVPECL
161.7
LVDS
–157.1
HSDS 6 mA
–158.3
HSDS 8 mA
L(f)CLKout
L(f)CLKout
L(f)CLKout
LMK04821, VCO1, noise floor
20-MHz offset (13)
LMK04826, VCO0, noise floor
20-MHz offset (14)
LMK04826, VCO1, noise floor
20-MHz offset (14)
245.76 MHz
245.76 MHz
245.76 MHz
dBc/Hz
–159
HSDS 10 mA
–159.2
LVPECL16 with 240
Ω
–158.8
LVPECL20 with 240
Ω
–158.9
LVPECL
–158.8
LVDS
–158.1
HSDS 6 mA
–159.7
HSDS 8 mA
–160.8
HSDS 10 mA
–161.3
LVPECL16 with 240
Ω
–161.8
LVPECL20 with 240
Ω
–162.0
LCPECL
–161.7
LVDS
–157.5
HSDS 6 mA
–158.9
HSDS 8 mA
–159.8
HSDS 10 mA
–160.3
LVPECL16 with 240
Ω
–160.8
LVPECL20 with 240
Ω
–160.7
LCPECL
–160.7
dBc/Hz
dBc/Hz
dBc/Hz
(13) Data collected using a Prodyn BIB-100G balun. Loop filter is C1 = 47 pF, C2 = 3.9 nF, R2 = 620 Ω, C3 = 10 pF, R3 = 200 Ω, C4 = 10
pF, R4 = 200 Ω, PLL1_CP = 450 µA, PLL2_CP = 3.2 mA.. VCO0 PLL2 loop filter bandwidth = 288 kHz, phase margin = 72 degrees.
VCO1 Loop filter loop bandwidth = 221 kHz, phase margin = 70 degrees. CLKoutX_Y_IDL = 1, CLKoutX_Y_ODL = 0.
(14) Data collected using a Prodyn BIB-100G balun. Loop filter for PLL2 is C1 = 47 pF, C2 = 3.9 nF, R2 = 620 Ω, C3 = 10 pF, R3 = 200 Ω,
C4 = 10 pF, R4 = 200 Ω, PLL1_CP = 450 µA, PLL2_CP = 3.2 mA.. VCO0 loop filter bandwidth = 303 kHz, phase margin = 73 degrees.
VCO1 Loop filter loop bandwidth = 151 kHz, phase margin = 64 degrees. CLKoutX_Y_IDL = 1, CLKoutX_Y_ODL = 0.
16
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
NOISE FLOOR (continued)
L(f)CLKout
L(f)CLKout
LMK04828, VCO0, noise floor
20-MHz offset (15)
LMK04828, VCO1, noise floor
20-MHz offset (15)
245.76 MHz
245.76 MHz
LVDS
–156.3
HSDS 6 mA
–158.4
HSDS 8 mA
–159.3
HSDS 10 mA
–158.9
LVPECL16 with 240
Ω
–161.6
LVPECL20 with 240
Ω
–162.5
LCPECL
–162.1
LVDS
–155.7
HSDS 6 mA
–157.5
HSDS 8 mA
–158.1
HSDS 10 mA
–157.7
LVPECL16 with 240
Ω
–160.3
LVPECL20 with 240
Ω
–161.1
LCPECL
–160.8
dBc/Hz
dBc/Hz
CLKout CLOSED LOOP PHASE NOISE SPECIFICATIONS a COMMERCIAL QUALITY VCXO (16)
L(f)CLKout
LMK04821
VCO0
SSB phase noise
245.76 MHz
Offset = 1 kHz
–126.9
Offset = 10 kHz
–133.5
Offset = 100 kHz
–135.4
Offset = 1 MHz
(13)
Offset = 10 MHz
L(f)CLKout
LMK04821
VCO1
SSB phase noise
245.76 MHz
(13)
–149.8
LVDS
–158.1
HSDS 8 mA
–161.1
LVPECL16 with 240
Ω
–161.7
Offset = 1 kHz
–126.8
Offset = 10 kHz
–133.4
Offset = 100 kHz
–135.4
Offset = 1 MHz
–151.8
Offset = 10 MHz
LVDS
–157.2
HSDS 8 mA
–159.1
LVPECL16 with 240
Ω
–158.9
dBc/Hz
dBc/Hz
(15) Data collected using ADT2-1T+ balun. Loop filter is C1 = 47 pF, C2 = 3.9 nF, R2 = 620 Ω, C3 = 10 pF, R3 = 200 Ω, C4 = 10 pF, R4 =
200 Ω, PLL1_CP = 450 µA, PLL2_CP = 3.2 mA.. VCO0 loop filter bandwidth = 344 kHz, phase margin = 73 degrees. VCO1 Loop filter
loop bandwidth = 233 kHz, phase margin = 70 degrees. CLKoutX_Y_IDL = 1, CLKoutX_Y_ODL = 0.
(16) VCXO used is a 122.88-MHz Crystek CVHD-950-122.880.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CLKout CLOSED LOOP PHASE NOISE SPECIFICATIONS a COMMERCIAL QUALITY VCXO (continued)
Offset = 10 kHz
–134.8
Offset = 100 kHz
L(f)CLKout
LMK04826
VCO0
SSB phase noise
245.76 MHz
Offset = 1 MHz
(14)
Offset = 10 MHz
–135.4
LVDS
–148.2
HSDS 8 mA
LVPECL16 with 240
Ω
–148.6
LVDS
–157.8
HSDS 8 mA
–160.4
LVPECL16 with 240
Ω
–161.5
Offset = 10 kHz
–134.3
Offset = 100 kHz
L(f)CLKout
LMK04826
VCO1
SSB phase noise
245.76 MHz
Offset = 1 MHz
(14)
Offset = 10 MHz
L(f)CLKout
LMK04828
VCO0
SSB phase noise
245.76 MHz
(15)
L(f)CLKout
LMK04828
VCO1
SSB phase noise
245.76 MHz
(15)
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–152.5
HSDS 8 mA
LVPECL16 with 240
Ω
–153.6
LVDS
–157.3
HSDS 8 mA
–159.6
LVPECL16 with 240
Ω
–160.5
–124.3
Offset = 10 kHz
–134.7
Offset = 100 kHz
–136.5
Offset = 1 MHz
–148.4
LVDS
–156.4
HSDS 8 mA
–159.1
LVPECL16 with 240
Ω
–160.8
Offset = 1 kHz
–124.2
Offset = 10 kHz
–134.4
Offset = 100 kHz
–135.2
Offset = 1 MHz
Offset = 10 MHz
18
–133.7
LVDS
Offset = 1 kHz
Offset = 10 MHz
dBc/Hz
–151.5
LVDS
–159.9
HSDS 8 mA
–155.8
LVPECL16 with 240
Ω
–158.1
dBc/Hz
dBc/Hz
dBc/Hz
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CLKout CLOSED LOOP JITTER SPECIFICATIONS a COMMERCIAL QUALITY VCXO (16)
LMK04821, VCO0
fCLKout = 245.76-MHz
integrated RMS jitter (13)
JCLKout
LMK04821, VCO1
fCLKout = 245.76-MHz
integrated RMS jitter (13)
LVDS, BW = 12 kHz to 20 MHz
99
HSDS 8 mA, BW = 12 kHz to 20 MHz
94
LVPECL16 with 240 Ω,
BW = 12 kHz to 20 MHz
96
LVPECL20 with 240 Ω,
BW = 12 kHz to 20 MHz
94
LCPECL with 240 Ω,
BW = 12 kHz to 20 MHz
93
LVDS, BW = 12 kHz to 20 MHz
96
HSDS 8 mA, BW = 12 kHz to 20 MHz
90
LVPECL16 with 240 Ω,
BW = 12 kHz to 20 MHz
92
LVPECL20 with 240 Ω,
BW = 12 kHz to 20 MHz
91
fs rms
fs rms
LCPECL with 240 Ω,
BW = 12 kHz to 20 MHz
91
CLKout CLOSED LOOP JITTER SPECIFICATIONS a COMMERCIAL QUALITY VCXO (continued)
LMK04826, VCO0
fCLKout = 245.76-MHz
integrated RMS jitter (14)
JCLKout
LMK04826, VCO1
fCLKout = 245.76-MHz
integrated RMS jitter (14)
(16)
LVDS, BW = 100 Hz to 20 MHz
106
LVDS, BW = 12 kHz to 20 MHz
104
HSDS 8 mA, BW = 100 Hz to 20 MHz
99
HSDS 8 mA, BW = 12 kHz to 20 MHz
97
LVPECL16 /w 240 Ω,
BW = 100 Hz to 20 MHz
99
LVPECL16 /w 240 Ω,
BW = 12 kHz to 20 MHz
96
LCPECL /w 240 Ω,
BW = 100 Hz to 20 MHz
100
LCPECL /w 240 Ω,
BW = 12 kHz to 20 MHz
97
LVDS, BW = 100 Hz to 20 MHz
99
LVDS, BW = 12 kHz to 20 MHz
97
HSDS 8 mA, BW = 100 Hz to 20 MHz
92
HSDS 8 mA, BW = 12 kHz to 20 MHz
90
LVPECL16 /w 240 Ω,
BW = 100 Hz to 20 MHz
91
LVPECL20 /w 240 Ω,
BW = 12 kHz to 20 MHz
89
LCPECL /w 240 Ω,
BW = 100 Hz to 20 MHz
92
LCPECL /w 240 Ω,
BW = 12 kHz to 20 MHz
89
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fs rms
fs rms
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CLKout CLOSED LOOP JITTER SPECIFICATIONS a COMMERCIAL QUALITY VCXO (continued) (16)
LMK04828, VCO0
fCLKout = 245.76-MHz
integrated RMS jitter (15)
JCLKout
LMK04828, VCO1
fCLKout = 245.76-MHz
integrated RMS jitter (15)
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LVDS, BW = 100 Hz to 20 MHz
112
LVDS, BW = 12 kHz to 20 MHz
109
HSDS 8 mA, BW = 100 Hz to 20 MHz
102
HSDS 8 mA, BW = 12 kHz to 20 MHz
99
LVPECL16 /w 240 Ω,
BW = 100 Hz to 20 MHz
98
LVPECL20 /w 240 Ω,
BW = 12 kHz to 20 MHz
95
LCPECL /w 240 Ω,
BW = 100 Hz to 20 MHz
96
LCPECL /w 240 Ω,
BW = 12 kHz to 20 MHz
93
LVDS, BW = 100 Hz to 20 MHz
108
LVDS, BW = 12 kHz to 20 MHz
105
HSDS 8 mA, BW = 100 Hz to 20 MHz
98
HSDS 8 mA, BW = 12 kHz to 20 MHz
94
LVPECL16 /w 240 Ω,
BW = 100 Hz to 20 MHz
93
LVPECL20 /w 240 Ω,
BW = 12 kHz to 20 MHz
90
LCPECL /w 240 Ω,
BW = 100 Hz to 20 MHz
91
LCPECL /w 240 Ω,
BW = 12 kHz to 20 MHz
88
fs rms
fs rms
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DEFAULT POWER on RESET CLOCK OUTPUT FREQUENCY
fCLKout-startup
Default output clock frequency at
device power on (17) (18)
LMK04826
235
LMK04828
315
fOSCout
OSCout frequency
(7)
MHz
500
MHz
CLOCK SKEW and DELAY
DCLKoutX to SDCLKoutY
FCLK = 245.76 MHz, RL= 100 Ω
AC coupled (19)
Same pair, same format (20)
SDCLKoutY_MUX = 0 (device clock)
Maximum DCLKoutX or SDCLKoutY
to DCLKoutX or SDCLKoutY
FCLK = 245.76 MHz, RL= 100 Ω
AC coupled
Any pair, same format (20)
SDCLKoutY_MUX = 0 (device clock)
SYSREF to device clock setup time
base reference.
See SYSREF to Device Clock
Alignment to adjust SYSREF to
device clock setup time as required.
SDCLKoutY_MUX = 1 (SYSREF)
SYSREF_DIV = 30
SYSREF_DDLY = 8 (global)
SDCLKoutY_DDLY = 1 (2 cycles, local)
DCLKoutX_MUX = 1 (Div+DCC+HS)
DCLKoutX_DIV = 30
DCLKoutX_DDLY_CNTH = 7
DCLKoutX_DDLY_CNTL = 6
DCLKoutX_HS = 0
SDCLKoutY_HS = 0
–80
ps
tPDCLKin0_
SDCLKout1
Propagation delay from CLKin0 to
SDCLKout1
CLKin0_OUT_MUX = 0 (SYSREF mux)
SYSREF_CLKin0_MUX = 1 (CLKin0)
SDCLKout1_PD = 0
SDCLKout1_DDLY = 0 (bypass)
SDCLKout1_MUX = 1 (SR)
EN_SYNC = 1
LVPECL16 /w 240 Ω
0.65
ns
fADLYmax
Maximum analog delay frequency
DCLKoutX_MUX = 4
1536
MHz
395
|mV|
|TSKEW|
tsJESD204B
25
|ps|
50
LVDS CLOCK OUTPUTS (DCLKoutX, SDCLKoutY, and OSCout)
VOD
Differential output voltage
ΔVOD
Change in magnitude of VOD for
complementary output states
VOS
Output offset voltage
ΔVOS
Change in VOS for complementary
output states
T = 25 °C, DC measurement
AC coupled to receiver input
RL = 100-Ω differential termination
–60
1.125
60
1.25
1.375
35
mV
V
|mV|
Output rise time
20% to 80%, RL = 100 Ω, 245.76 MHz
Output fall time
80% to 20%, RL = 100 Ω
ISA
ISB
Output short circuit current - single
ended
Single-ended output shorted to GND
T = 25 °C
–24
24
mA
ISAB
Output short circuit current differential
Complimentary outputs tied together
–12
12
mA
TR / TF
180
ps
(17) OSCout oscillates at start-up at the frequency of the VCXO attached to the OSCin port.
(18) LMK04821 has no DCLKoutX or SDCLKoutY outputs which oscillate at power on. Only OSCout oscillates at power on.
(19) Equal loading and identical clock output configuration on each clock output is required for specification to be valid. Specification not valid
for delay mode.
(20) LVPECL uses a 120-Ω emitter resistor, LVDS and HSDS uses a 560-Ω shunt.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
6-mA HSDS CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
VCC 1.05
VOH
T = 25 °C, DC measurement
Termination = 50 Ω to
VCC - 1.42 V
VOL
VOD
Differential output voltage
ΔVOD
Change in VOD for complementary
output states
VCC 1.64
590
–80
|mV|
80
mVpp
8-mA HSDS CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
TR / T
F
Output rise time
245.76 MHz, 20% to 80%, RL = 100 Ω
Output fall time
245.76 MHz, 80% to 20%, RL = 100 Ω
170
VCC 1.26
VOH
T = 25 °C, DC measurement
Termination = 50 Ω to
VCC - 1.64 V
VOL
VOD
Differential output voltage
ΔVOD
Change in VOD for complementary
output states
ps
VCC
–2.06
800
–115
|mV|
115
mVpp
10-mA HSDS CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
VCC 0.99
VOH
T = 25 °C, DC measurement
Termination = 50 Ω to
VCC - 1.43 V
VOL
VCC 1.97
VOD
ΔVOD
980
Change in VOD for complementary
output states
–115
|mv|
115
mVpp
LVPECL CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
20% to 80% output rise
TR / TF
80% to 20% output fall time
RL = 100 Ω, emitter resistors = 240 Ω to
GND
DCLKoutX_TYPE = 4 or 5
(1600 or 2000 mVpp)
150
ps
VCC 1.04
V
VCC 1.80
V
1600-mVpp LVPECL CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
VOH
Output high voltage
VOL
Output low voltage
VOD
Output voltage
Figure 9
DC measurement
Termination = 50 Ω to
VCC - 2.0 V
760
|mV|
2000-mVpp LVPECL CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
VOH
Output high voltage
VOL
Output low voltage
VOD
Output voltage
Figure 9
DC measurement
Termination = 50 Ω to VCC - 2.3 V
VCC 1.09
V
VCC 2.05
V
960
|mV|
1.57
V
0.62
V
950
|mV|
LCPECL CLOCK OUTPUTS (DCLKoutX and SDCLKoutY)
VOH
Output high voltage
VOL
Output low voltage
VOD
Output voltage
Figure 9
22
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DC measurement
Termination = 50 Ω to 0.5 V
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LVCMOS CLOCK OUTPUTS (OSCout)
fCLKout
Maximum frequency
(21)
5-pF load
250
MHz
VOH
Output high voltage
1-mA load
VOL
Output low voltage
1-mA load
IOH
Output high current (source)
VCC = 3.3 V, VO = 1.65 V
28
mA
IOL
Output low current (sink)
VCC = 3.3 V, VO = 1.65 V
28
mA
DUTYCLK
Output duty cycle (22)
VCC/2 to VCC/2,
FCLK = 100 MHz, T = 25 °C
TR
Output rise time
20% to 80%, RL = 50 Ω, CL = 5 pF
400
ps
TF
Output fall time
80% to 20%, RL = 50 Ω, CL = 5 pF
400
ps
VCC 0.1
V
0.1
V
50%
DIGITAL OUTPUTS (CLKin_SELX, Status_LDX, and RESET/GPO)
VOH
VOL
High-level output voltage
IOH = –500 µA
CLKin_SELX_TYPE = 3 or 4
Status_LDX_TYPE = 3 or 4
RESET_TYPE = 3 or 4
Low-level output voltage
IOL = 500 µA
CLKin_SELX_TYPE = 3, 4, or 6
Status_LDX_TYPE = 3, 4, or 6
RESET_TYPE = 3, 4, or 6
VCC 0.4
V
0.4
V
DIGITAL OUTPUT (SDIO)
VOH
High-level output voltage
IOH = –500 µA ; During SPI read.
SDIO_RDBK_TYPE = 0
VOL
Low-level output voltage
IOL = 500 µA ; During SPI read.
SDIO_RDBK_TYPE = 0 or 1
VCC 0.4
V
0.4
V
VCC
V
0.4
V
DIGITAL INPUTS (CLKinX_SEL, RESET/GPO, SYNC, SCK, SDIO, or CS*)
VIH
High-level input voltage
VIL
Low-level input voltage
1.2
DIGITAL INPUTS (CLKinX_SEL)
IIH
IIL
High-level input current
VIH = VCC
Low-level input current
VIL = 0 V
CLKin_SELX_TYPE = 0,
(high impedance)
–5
5
CLKin_SELX_TYPE = 1 (pull-up)
–5
5
CLKin_SELX_TYPE = 2 (pull-down)
10
80
CLKin_SELX_TYPE = 0,
(high impedance)
–5
5
–40
–5
CLKin_SELX_TYPE = 2 (pull-down)
–5
5
RESET_TYPE = 2
(pull-down)
10
80
CLKin_SELX_TYPE = 1 (pull-up)
µA
µA
DIGITAL INPUT (RESET/GPO)
IIH
High-level input current
VIH = VCC
IIL
Low-level input current
VIL = 0 V
RESET_TYPE = 0 (high impedance)
RESET_TYPE = 1 (pull-up)
RESET_TYPE = 2 (pull-down)
–5
5
–40
–5
–5
5
µA
µA
DIGITAL INPUTS (SYNC)
IIH
High-level input current
VIH = VCC
IIL
Low-level input current
VIL = 0 V
25
–5
5
µA
DIGITAL INPUTS (SCK, SDIO, CS*)
(21) Assured by characterization. ATE tested to 10 MHz.
(22) Assumes OSCin has 50% input duty cycle.
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Electrical Characteristics (continued)
(3.15 V < VCC < 3.45 V, –40 °C < TA < 85 °C and TPCB ≤ 105 °C. Typical values at VCC = 3.3 V, TA = 25 °C, at the
Recommended Operating Conditions and are not assured.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
IIH
High-level input current
VIH = VCC
–5
5
µA
IIL
Low-level input current
VIL = 0
–5
5
µA
RESET pin held high for device reset
25
DIGITAL INPUT TIMING
tHIGH
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7.6 SPI Interface Timing
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tds
Setup time for SDI edge to SCLK rising edge
See Figure 1
10
ns
tdH
Hold time for SDI edge from SCLK rising edge
See Figure 1
10
ns
tSCLK
Period of SCLK
See Figure 1
50 (1)
ns
tHIGH
High width of SCLK
See Figure 1
25
ns
tLOW
Low width of SCLK
See Figure 1
25
ns
tcs
Setup time for CS* falling edge to SCLK rising edge
See Figure 1
10
ns
tcH
Hold time for CS* rising edge from SCLK rising edge
See Figure 1
30
tdv
SCLK falling edge to valid read back data
See Figure 1
(1)
ns
20
ns
20 MHz
Register programming information on the SDIO pin is clocked into a shift register on each rising edge of the SCK
signal. On the rising edge of the CS* signal, the register is sent from the shift register to the register addressed.
A slew rate of at least 30 V/µs is recommended for these signals. After programming is complete, the CS* signal
should be returned to a high state. If the SCK or SDIO lines are toggled while the VCO is in lock, as is
sometimes the case when these lines are shared with other parts, the phase noise may be degraded during this
programming.
4-wire mode read back has same timing as the SDIO pin.
R/W bit = 0 is for SPI write. R/W bit = 1 is for SPI read.
W1 and W0 are written as 0.
SDIO
(WRITE)
R/W
W1
tdS
tdH
tcS
tHIGH
W0
A12 to A0,
D7 to D2
D1
D0
SCLK
tcH
tLOW
tSCLK
SDIO
(Read)
D7 to
D2
tdV
D1
D0
Data valid only
during read
CS*
Figure 1. SPI Timing Diagram
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7.7 Typical Characteristics – Clock Output AC Characteristics
These plots show performance at frequencies beyond the point at which the part is ensured to operate, to give an idea of the
capabilities of the part. They do not imply any sort of ensured specification.
For Figure 2 through Figure 7, CLKout2_3_IDL=1; CLKout2_3_ODL=0; LVPECL20 with 240-Ω emitter resistors; DCLKout2
Frequency = 245.76 MHz; DCLKout2_MUX = 0 (Divider). For Figure 2 through Figure 5, Balun Prodyn BIB-100G. For
Figure 6 and Figure 7, Balun ADT2-1T+.
VCO_MUX = 0 (VCO0)
VCO0 = 1966.08 MHz
DCLKout2_DIV = 8
PLL2 Loop Filter Bandwidth = 288 kHz
PLL2 Phase Margin = 72°
Figure 2. LMK04821 DCLKout2 Phase Noise
VCO_MUX = 0 (VCO0)
VCO0 = 1966.08 MHz
DCLKout2_DIV = 8
PLL2 Loop Filter Bandwidth = 303 kHz
PLL2 Phase Margin = 73°
Figure 4. LMK04826 DCLKout2 Phase Noise
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VCO_MUX = 1 (VCO1)
VCO = 2949.12 MHz
DCLKout2_DIV = 6
VCO1_DIV = 0 (÷2)
PLL2 Loop Filter Bandwidth = 221 kHz
PLL2 Phase Margin = 70°
Figure 3. LMK04821 DCLKout2 Phase Noise
VCO_MUX = 1 (VCO1)
VCO = 2457.6 MHz
DCLKout2_DIV = 10
PLL2 Loop Filter Bandwidth = 151 kHz
PLL2 Phase Margin = 64°
Figure 5. LMK04826 DCLKout2 Phase Noise
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Typical Characteristics – Clock Output AC Characteristics (continued)
These plots show performance at frequencies beyond the point at which the part is ensured to operate, to give an idea of the
capabilities of the part. They do not imply any sort of ensured specification.
For Figure 2 through Figure 7, CLKout2_3_IDL=1; CLKout2_3_ODL=0; LVPECL20 with 240-Ω emitter resistors; DCLKout2
Frequency = 245.76 MHz; DCLKout2_MUX = 0 (Divider). For Figure 2 through Figure 5, Balun Prodyn BIB-100G. For
Figure 6 and Figure 7, Balun ADT2-1T+.
VCO_MUX = 0 (VCO0)
VCO0 = 2457.6 MHz
DCLKout2_DIV = 10
PLL2 Loop Filter Bandwidth = 344 kHz
PLL2 Phase Margin = 73°
Figure 6. LMK04828 DCLKout2 Phase Noise
VCO_MUX = 1 (VCO1)
VCO = 2949.12 MHz
DCLKout2_DIV = 12
PLL2 Loop Filter Bandwidth = 233 kHz
PLL2 Phase Margin = 70°
Figure 7. LMK04828 DCLKout2 Phase Noise
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8 Parameter Measurement Information
8.1 Charge Pump Current Specification Definitions
I1 = Charge Pump Sink Current at VCPout = VCC - ΔV
I2 = Charge Pump Sink Current at VCPout = VCC/2
I3 = Charge Pump Sink Current at VCPout = ΔV
I4 = Charge Pump Source Current at VCPout = VCC - ΔV
I5 = Charge Pump Source Current at VCPout = VCC/2
I6 = Charge Pump Source Current at VCPout = ΔV
ΔV = Voltage offset from the positive and negative supply rails. Defined to be 0.5 V for this device.
8.1.1 Charge Pump Output Current Magnitude Variation Vs. Charge Pump Output Voltage
8.1.2 Charge Pump Sink Current Vs. Charge Pump Output Source Current Mismatch
8.1.3 Charge Pump Output Current Magnitude Variation Vs. Ambient Temperature
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8.2 Differential Voltage Measurement Terminology
The differential voltage of a differential signal can be described by two different definitions, which can cause
confusion when reading data sheets or communicating with other engineers. This section addresses the
measurement and description of a differential signal, so that the reader can understand and distinguish between
the two different definitions.
The first definition used to describe a differential signal is the absolute value of the voltage potential between the
inverting and non-inverting signal. The symbol for this first measurement is typically VID or VOD, depending on if
an input or output voltage is being described.
The second definition used to describe a differential signal is to measure the potential of the non-inverting signal
with respect to the inverting signal. The symbol for this second measurement is VSS, and is a calculated
parameter. This signal does not exist in the IC with respect to ground; it only exists in reference to its differential
pair. VSS can be measured directly by oscilloscopes with floating references; otherwise this value can be
calculated as twice the value of VOD, as described in the first description.
Figure 8 illustrates the two different definitions side-by-side for inputs, and Figure 9 illustrates the two different
definitions side-by-side for outputs. The VID and VOD definitions show VA and VB DC levels that the non-inverting
and inverting signals toggle between with respect to ground. VSS input and output definitions show that if the
inverting signal is considered the voltage potential reference, the non-inverting signal voltage potential is now
increasing and decreasing above and below the non-inverting reference. Thus, the peak-to-peak voltage of the
differential signal can be measured.
VID and VOD are often defined as volts (V) and VSS is often defined as volts peak-to-peak (VPP).
VID Definition
VSS Definition for Input
Non-Inverting Clock
VA
2· VID
VID
VB
Inverting Clock
VID = | VA - VB |
VSS = 2· VID
GND
Figure 8. Two Different Definitions for
Differential Input Signals
VOD Definition
VSS Definition for Output
Non-Inverting Clock
VA
2· VOD
VOD
VB
Inverting Clock
VOD = | VA - VB |
VSS = 2· VOD
GND
Figure 9. Two Different Definitions for
Differential Output Signals
Refer to application note AN-912 Common Data Transmission Parameters and their Definitions (SNLA036) for
more information.
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9 Detailed Description
9.1 Overview
The LMK0482x family are multi-purpose, jitter cleaning dual-PLL circuits, with user-programmable settings to
support a flexible set of configurations for many different application requirements. PLL1 is optimized for use with
an external VCXO as the PLL oscillator, while PLL2 includes a dual-range integrated VCO and distributes the
VCO output to 7 integrated 10-bit channel dividers and a 13-bit SYSREF divider, yielding a total of 14 differential
clock outputs at up to 8 different frequencies.
The primary use case is as a dual-loop jitter cleaner (dual-loop mode), when using a reference clock with good
frequency accuracy but poor phase noise to generate ultra-low jitter output clocks. Dual-loop mode also helps to
maintain a high phase detector frequency and loop bandwidth in the clock generation PLL when the greatest
common divisor of the reference clock frequency and the output clock frequencies is small, avoiding a low phase
detector frequency that would elevate output clock phase noise.
Both PLLs can optionally be disabled. By disabling PLL1, the LMK0482x can be used as a standard single-PLL
clock generator with integrated VCO (single-loop mode). By disabling both PLLs, the LMK0482x can act as a
distribution buffer/divider, directly connecting an input reference to the clock dividers and the SYSREF divider.
The clock output dividers can also be bypassed or set to divide of 1 for distribution only mode.
In a typical dual-loop configuration, the external VCXO is connected to the PLL1 N-divider, and the integrated
VCO is connected to the N-divider directly. However, by routing the divided clock or SYSREF output of PLL2 to
the N-divider of PLL1, PLL2, or both PLLs in a family of configurations called zero-delay mode, the LMK0482x
can establish a deterministic phase relationship between reference input phase and clock output phase. Using
zero-delay mode, multiple LMK0482x can be cascaded to fan out exponentially more outputs, while maintaining
predictable input-to-output phase throughout the whole chain of devices. Zero-delay mode is supported in
singleloop and dual-loop mode, with two dual-loop configurations: nested dual-loop (feedback connected to PLL1
Ndivider) and cascaded dual-loop (feedback connected to PLL2 N-divider).
The LMK0482x may be used in JESD204B sytems by providing a device clock and SYSREF to up to 7 devices.
However, alternate (non-JESD204B) systems are also possible by programming pairs of outputs to share the
clock divider. Any mix of JESD204B and alternate systems can be supported.
9.1.1 Jitter Cleaning
The dual-loop PLL architecture of the LMK0482x family provides the lowest jitter performance over a wide range
of output frequencies and phase-noise integration bandwidths. The first-stage PLL (PLL1) is driven by an
external reference clock, and uses an external VCXO or tunable crystal to provide a frequency accurate, low
phase-noise reference clock for the second-stage frequency multiplication PLL (PLL2).
PLL1 typically uses a narrow-loop bandwidth (10 Hz to 200 Hz) to retain the frequency accuracy of the reference
clock input signal, while at the same time suppressing the higher offset frequency phase noise that the reference
clock may have accumulated along its path or from other circuits. This “cleaned” reference clock provides the
reference input to PLL2.
The low phase-noise reference provided to PLL2 allows PLL2 to operate with a wide-loop bandwidth (typically 50
kHz to 200 kHz). The loop bandwidth for PLL2 is chosen to take advantage of the superior high-offset frequency
phase-noise profile of the internal VCO, and the good low-offset frequency phase noise of the reference VCXO
or tunable crystal.
Ultra low jitter is achieved by allowing the external VCXO or crystal phase noise to dominate the final output
phase noise at low-offset frequencies, and the internal VCO phase noise to dominate the final output phase
noise at high-offset frequencies. This results in best overall phase noise and jitter performance.
9.1.2 JEDEC JESD204B Support
The LMK0482x family provides support for JEDEC JESD204B. The LMK0482x clocks up to 7 JESD204B targets
using 7 device clocks (DCLKoutX) and 7 SYSREF clocks (SDCLKoutY). Each device clock is grouped with a
SYSREF clock.
The user can reprogram SYSREF clocks to behave as extra device clocks for applications which have nonJESD204B clock requirements.
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Overview (continued)
9.1.3 Three PLL1 Redundant Reference Inputs
The LMK0482x family has up to three reference clock inputs for PLL1. They are CLKin0, CLKin1, and CLKin2.
The active clock is chosen based on CLKin_SEL_MODE. Automatic or manual switching can occur between the
inputs.
CLKin0, CLKin1, and CLKin2 each have their own PLL1 R dividers. CLKin0, CLKin1, and CLKin2 each support
differential or single-ended inputs, and support DC coupling or AC coupling. See Driving CLKin and OSCin
Inputs.
CLKin1 is shared for use as an external zero-delay feedback (FBCLKin), or for use with an external VCO (Fin).
CLKin2 is shared for use as OSCout. To use CLKin2 as an input, OSCout must be powered down. See
VCO_MUX, OSCout_MUX, OSCout_FMT.
Fast manual switching between reference clocks is possible with a external pins CLKin_SEL0 and CLKin_SEL1.
For clock distribution mode, a reference signal is applied to the Fin pins for clock distribution. CLKin0 can also be
used to distribute a SYSREF signal through the device. In this use case, CLKin0 may be re-clocked by Fin, or
can be routed directly to the SYSREF outputs.
9.1.4 VCXO/Crystal Buffered Output
CLKin2 may instead be configured as OSCout, which by default is a buffered copy of the PLL1 feedback/PLL2
reference input (OSCin). This reference input is typically a low-noise VCXO or crystal. When using a VCXO, this
output can be used to clock external devices such as microcontrollers, FPGAs, and CPLDs, before the
LMK0482x is programmed.
The OSCout buffer output type is programmable to LVDS, LVPECL, or LVCMOS. OSCout LVPECL mode only
supports 240-Ω emitter resistors.
The VCXO/crystal buffered output can be synchronized to the VCO clock distribution outputs by using cascaded
zero-delay mode. The buffered output of VCXO/crystal has a deterministic phase relationship with CLKin.
9.1.5 Frequency Holdover
When the reference inputs to PLL1 are lost, the LMK0482x family can enter holdover mode until a valid
reference clock signal is re-established. Holdover mode forces a constant DC voltage output to the control pin of
the PLL1 VCXO, ensuring minimal frequency drift while the reference inputs are absent.
9.1.6 PLL2 Integrated Loop Filter Poles
The LMK0482x family features programmable 3rd- and 4th-order loop filter poles for PLL2. These internal
resistors and capacitor values may be selected from a fixed range of values to achieve either a 3rd- or 4th-order
loop filter response. The integrated programmable resistors and capacitors compliment external components
mounted near the chip.
These integrated components can be effectively disabled by programming the integrated resistors and capacitors
to their minimum values.
9.1.7 Internal VCOs
The LMK0482x family has two internal VCOs, selected by VCO_MUX. The output of the selected VCO is routed
to the clock distribution path. This same selection is also fed back to the PLL2 phase detector through a
prescaler and N-divider.
9.1.7.1 VCO1 Divider (LMK04821 only)
The LMK04821 includes a VCO divider on the output of VCO1. The VCO1 divider can be programmed from 2 to
8.
When using a VCO1 frequency of 2949.12 MHz and a divide of 8, frequencies as low as 11.52 MHz can be
achieved. Using the VCO1_DIV limits the maximum output frequency from any output to the VCO1 frequency,
divided by VCO1_DIV value.
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Overview (continued)
When using VCO1, the output frequency from the VCO1_DIV defines the digital delay resolution.
The VCO1_DIV divider also impacts the total N divide value for PLL2 when VCO1 is selected; this should be
accounted for when selecting PLL2_N and PLL2_P value.
9.1.8 External VCO Mode
The Fin/Fin* input allows an external VCO to be used with PLL2 of the LMK0482x family.
Using an external VCO prevents the use of CLKin1 for other purposes.
9.1.9 Clock Distribution
The LMK0482x family features a total of 14 PLL2 clock outputs, driven from the internal or external VCO.
All PLL2 clock outputs have programmable output types. They can be programmed to LVPECL, LVDS, or HSDS,
or LCPECL.
If OSCout is included in the total number of clock outputs the LMK0482x family is able to distribute, then up to 15
differential clocks. OSCout may be a buffered version of OSCin, DCLKout6, DCLKout8, or SYSREF. Its output
format is programmable to LVDS, LVPECL, or LVCMOS. OSCout LVPECL mode only supports 240-Ω emitter
resistors.
The following sections discuss specific features of the clock distribution channels that allow the user to control
various aspects of the output clocks.
9.1.9.1 Device Clock Divider
Each device clock, DCLKoutX, has a single clock output divider. The divider supports a divide range of 1 to 32
(even and odd) with 50% output duty cycle, using duty cycle correction mode. The output of this divider may also
be directed to SDCLKoutY, where Y = X + 1.
9.1.9.2 SYSREF Clock Divider
The SYSREF clocks, SDCLKoutY, all share a common divider. The divider supports a divide range of 8 to 8191
(even and odd).
9.1.9.3 Device Clock Delay
The device clocks include both a analog and digital delay for phase adjustment of the clock outputs.
The analog delay allows a nominal 25-ps step size, and range from 0 to 575 ps of total delay. Enabling the
analog delay adds a nominal 500 ps of delay, in addition to the programmed value.
The digital delay allows a group of outputs to be delayed from 4 to 32 VCO cycles. The delay step can be as
small as half the period of the clock distribution path. For example, a 2-GHz VCO frequency results in 250 ps
coarse tuning steps. The coarse (digital) delay value takes effect on the clock outputs after a SYNC event.
There are two ways to use the digital delay.
1. Fixed digital delay – Allows all the outputs to have a known phase relationship upon a SYNC event. Typically
performed at startup.
2. Dynamic digital delay – Allows the phase relationships of the clocks to change while the clocks continue to
operate.
9.1.9.4 SYSREF Delay
The global SYSREF divider includes a digital delay block, which allows a global phase shift with respect to the
other clocks.
Each local SYSREF clock output includes both an analog and additional local digital delay, for unique phase
adjustment of each SYSREF clock.
The local analog delay allows for 150-ps steps.
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Overview (continued)
The local digital delay and SYSREF_HS bit allows the each individual SYSREF output to be delayed from, 1.5 to
11 VCO cycles. The delay step can be as small as half the period of the clock distribution path, by using the
DCLKoutX_HS bit. For example, a 2-GHz VCO frequency results in 250 ps coarse tuning steps.
9.1.9.5 Glitchless Half Step and Glitchless Analog Delay
The device clocks include a feature to ensure glitchless operation of the half step and analog delay operations,
when enabled.
9.1.9.6 Programmable Output Formats
For increased flexibility all LMK0482x family device and SYSREF clock outputs, DCLKoutX and SDCLKoutY, can
be programmed to an LVDS, HSDS, LVPECL, or LCPECL output type. The OSCout can be programmed to an
LVDS, LVPECL, or LVCMOS output type. OSCout LVPECL mode only supports 240-Ω emitter resistors.
Any LVPECL output type can be programmed to 1600- or 2000-mVpp amplitude levels. The 2000-mVpp
LVPECL output type is a Texas Instruments proprietary configuration that produces a 2000-mVpp differential
swing for compatibility with many data converters, and is known as 2VPECL.
LCPECL allows for DC coupling SYSREF to low-voltage converters.
9.1.9.7 Clock Output Synchronization
Using the SYNC input causes all active clock outputs to share a rising edge, as programmed by fixed digital
delay.
The SYNC event must occur for digital delay values to take effect.
9.1.10 Zero-Delay
The LMK0482x family supports two types of zero-delay.
1. Cascaded zero-delay
2. Nested zero-delay
Cascaded zero-delay mode establishes a fixed deterministic phase relationship of the phase of the PLL2 input
clock (OSCin) to the phase of a clock selected by the feedback mux. The zero-delay feedback may performed
with an internal feedback from CLKout6, CLKout8, SYSREF, or with an external feedback loop into the FBCLKin
port as selected by the FB_MUX. Because OSCin has a fixed deterministic phase relationship to the feedback
clock, OSCout will also have a fixed deterministic phase relationship to the feedback clock. In this mode, the
PLL1 input clock (CLKinX) also has a fixed deterministic phase relationship to PLL2 input clock (OSCin); this
results in a fixed deterministic phase relationship between all clocks from CLKinX to the clock outputs.
Nested zero-delay mode establishes a fixed deterministic phase relationship of the phase of the PLL1 input clock
(CLKinX) to the phase of a clock selected by the feedback mux. The zero-delay feedback may performed with an
internal feedback from CLKout6, CLKout8, SYSREF, or with an external feedback loop into the FBCLKin port as
selected by the FB_MUX.
Without using zero-delay mode, there are numerous possible fixed phase relationships from clock input to clock
output, depending on the clock output divide value. Careful selection of the zero-delay feedback value can
reduce the number of fixed phase relationships from clock input to clock output, potentially to as few as one. As
a result, zero-delay simplifies input-to-output phase guarantees, especially across multiple devices. For more
information, see the application note Multi-Clock Synchronization.
Using an external zero-delay feedback prevents the use of CLKin1 for other purposes.
9.1.11 Status Pins
The LMK0482x provides status pins, which can be monitored for feedback, or in some cases used for input
depending upon device programming. For example:
• The CLKin_SEL0 pin may be configured as an output, indicating the LOS (loss-of-signal) for CLKin0.
• The CLKin_SEL1 pin may be configured as an input, for selecting the active clock input.
• The Status_LD1 pin may indicate if the device is locked (PLL1 and PLL2 locked).
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Overview (continued)
•
The Status_LD2 pin may indicate if PLL2 is locked.
The status pins can be programmed to a variety of other outputs, including PLL divider outputs, combined PLL
lock detect signals, PLL1 Vtune railing, SPI readback, and so forth. Refer to the programming section of this data
sheet for more information.
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9.2 Functional Block Diagram
Figure 10 and Figure 11 illustrate the complete LMK0482x family block diagram.
Figure 10. Detailed LMK04821 Block Diagram
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Functional Block Diagram (continued)
Figure 11. Detailed LMK04826 and LMK04828 Block Diagram
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Functional Block Diagram (continued)
CLKoutX_Y_PD
DCLKout6/8 to FB_MUX
DCLKoutX_ADLY_PD
VCO
DDLY
(4 to 32)
DCLKoutX_HSg_PD
Divider
(1 to 32)
DCLKoutX_ADLYg_PD
HS/
DCC
DCLKout0, 2, 4, 6, 8, 10, 12
DCLKoutX
_POL
DCLKoutX_DDLY_PD
DCLKoutX
_MUX
DCLKoutX
_ADLY
_MUX
DDDLYdX_EN
DCLKoutX_
FMT
Analog
DLY
CLKoutX_Y_ODL
CLKoutX_Y_IDL
SYNC_
1SHOT_EN
SYSREF_GBL_PD
SDCLKoutY_DIS_MODE
One
Shot
SDCLKoutY
_POL
SYNC_
DISX
SDCLKoutY_PD
SYSREF/SYNC
Legend
SPI Register
Digital
DLY
SYSREF/SYNC Clock
VCO/Distribution Clock
Half
Step
Analog
DLY
SDCLKoutY
_MUX
SDCLKoutY
_ADLY_EN
SDCLKoutY_
FMT
SDCLKout1, 3, 5, 7, 9, 11, 13
SYSREF_CLR
Figure 12. Device and SYSREF Clock Output Block
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Functional Block Diagram (continued)
Figure 13. SYNC/SYSREF Clocking Paths
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9.3 Feature Description
9.3.1 SYNC/SYSREF
To properly use SYNC or SYSREF for JESD204B, it is important to understand the SYNC/SYSREF system. The
SYNC and SYSREF signals share the same clocking path, with SYNC_DISX bits used to enable the path from
SYSREF/SYNC to each divider reset port. Figure 12 illustrates the detailed diagram of a clock output block with
SYNC circuitry included.Figure 13 illustrates the interconnects and highlights some important registers used in
controlling the device for SYNC/SYSREF purposes.
To reset or synchronize a divider, the following conditions must be met:
1. SYNC_EN must be set. This ensures proper operation of the SYNC circuitry.
2. SYSREF_MUX and SYNC_MODE must be set to a proper combination to provide a valid SYNC/SYSREF
signal.
– If SYSREF block is being used, the SYSREF_PD bit must be clear.
– If the SYSREF Pulser is being used, the SYSREF_PLSR_PD bit must be clear.
– For each SDCLKoutY being used for SYSREF, respective SDCLKoutY_PD bits must be cleared.
3. SYSREF_DDLY_PD and DCLKoutX_DDLY_PD bits must be clear to power up the digital delay circuitry
during SYNC. After the SYNC event, these bits may be set to reduce power consumption.
4. The SYNC_DISX bit must be clear to allow the SYNC/SYSREF signal to reset the divider circuit. The
SYSREF_MUX register selects the SYNC source.
5. Other bits which impact the operation of SYNC, such as SYNC_1SHOT_EN, may be set as desired.
Table 1 illustrates the some possible combinations of SYSREF_MUX and SYNC_MODE.
Table 1. Some Possible SYNC Configurations
NAME
SYNC disabled
SYNC_MODE
SYSREF_MUX
0
0
OTHER
DESCRIPTION
CLKin0_OUT_MUX ≠ 0
No SYNC occurs.
Pin or SPI SYNC
1
0
CLKin0_OUT_MUX ≠ 0
Basic SYNC functionality, SYNC pin polarity is
selected by SYNC_POL.
To achieve SYNC through SPI, toggle the
SYNC_POL bit.
Differential input
SYNC
0 or 1
0 or 1
CLKin0_OUT_MUX = 0
Differential CLKin0 now operates as SYNC input.
JESD204B pulser
on pin transition.
2
2
SYSREF_PULSE_CNT
sets pulse count
Produce SYSREF_PULSE_CNT programmed
number of pulses on pin transition. SYNC_POL can
be used to cause SYNC through SPI.
JESD204B pulser
on SPI
programming.
3
2
SYSREF_PULSE_CNT
sets pulse count
Programming the SYSREF_PULSE_CNT register
starts sending the number of pulses.
Re-clocked SYNC
1
1
SYSREF operational,
SYSREF divider as
required for training frame
size.
Allows precise SYNC for n-bit frame training patterns
for non-JESD converters such as LM97600.
External SYSREF
request
0
2
SYSREF_REQ_EN = 1
Pulser powered up
When the SYNC pin is asserted, continuous SYSERF
pulses occur. Turning on and off of the pulses is
synchronized, to prevent runt pulses from occurring
on SYSREF.
Continuous
SYSREF
X
3
(1)
SYSREF_PD = 0
SYSREF_DDLY_PD = 0
SYSREF_PLSR_PD = 1
(1)
Continuous SYSREF signal. Useful for validating
phase alignment of SYSREF clocks, but not
recommended for use in low-noise applications due to
crosstalk spurs.
SDCLKoutY_PD = 0 as required per SYSREF output. This applies to any SYNC or SYSREF output on SDCLKoutY when
SDCLKoutY_MUX = 1 (SYSREF output)
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Feature Description (continued)
Table 1. Some Possible SYNC Configurations (continued)
NAME
SYNC_MODE
Direct SYSREF
distribution
SYSREF_MUX
0
0
OTHER
DESCRIPTION
CLKin0_OUT_MUX = 0
SDCLKoutY_DDLY = 0
(Local sysref DDLY
bypassed)
SYSREF_DDLY_PD = 1
SYSREF_PLSR_PD = 1
SYSREF_PD = 1.
A direct fan-out of SYSREF with no re-clocking to
clock distribution path.
9.3.2 JEDEC JESD204B
9.3.2.1 How To Enable SYSREF
Table 2 summarizes the bits needed to make SYSREF functionality operational.
Table 2. SYSREF Bits
REGIS
TER
FIELD
VALUE
DESCRIPTION
0x140
SYSREF_PD
0
Must be clear to power-up SYSREF circuitry.
0x140
SYSREF_DDLY_
PD
0
Must be clear to power-up digital delay circuitry during initial SYNC, to ensure deterministic timing.
0x143
SYNC_EN
1
Must be set to enable SYNC.
0x143
SYSREF_CLR
1→0
Do not hold local SYSREF_DDLY block in reset except at start.
Anytime SYSREF_PD = 1 because of user programming or device RESET, it is necessary to set
SYSREF_CLR for 15 clock distribution path cycles to clear the local SYSREF digital delay. After
clearing local delays, SYSREF_CLR must be cleared to allow SYSREF to operate.
Enabling JESD204B operation involves synchronizing all the clock dividers with the SYSREF divider, then
configuring the actual SYSREF functionality.
9.3.2.1.1 Setup of SYSREF Example
The following procedure is a programming example for a system operating with a 3000-MHz VCO frequency.
Use DCLKout0 and DCLKout2 to drive converters at 1500 MHz. Use DCLKout4 to drive an FPGA at 150 MHz.
Synchronize the converters and FPGA using two SYSREF pulses at 10 MHz.
1. Program registers 0x000 to 0x1fff as desired. Key to prepare for SYSREF operations (see Recommended
Programming Sequence):
a. Prepare for manual SYNC: SYNC_POL = 0, SYNC_MODE = 1, SYSREF_MUX = 0
b. Setup output dividers as per example: DCLKout0_DIV and DCLKout2_DIV = 2 for frequency of 1500
MHz. DCLKout4_DIV = 20 for frequency of 150 MHz.
c. Setup output dividers as per example: SYSREF_DIV = 300 for 10 MHz SYSREF
d. Setup SYSREF: SYSREF_PD = 0, SYSREF_DDLY_PD = 0, DCLKout0_DDLY_PD = 0,
DCLKout2_DDLY_PD = 0, DCLKout4_DDLY_PD = 0, SYNC_EN = 1, SYSREF_PLSR_PD = 0,
SYSREF_PULSE_CNT = 1 (2 pulses). SDCLKout1_PD = 0, SDCLKout3_PD = 0
e. Clear Local SYSREF DDLY: SYSREF_CLR = 1.
2. Establish deterministic phase relationships between SYSREF and the device clock for JESD204B:
a. Set device clock and SYSREF divider digital delays: DCLKout0_DDLY_CNTH, DCLKout0_DDLY_CNTL,
DCLKout2_DDLY_CNTH, DCLKout2_DDLY_CNTL, DCLKout4_DDLY_CNTH, DCLKout4_DDLY_CNTL,
SYSREF_DDLY.
b. Set device clock digital delay half steps: DCLKout0_HS, DCLKout2_HS, DCLKout4_HS.
c. Set SYSREF clock digital delay as required to achieve known phase relationships: SDCLKout1_DDLY,
SDCLKout3_DDLY, SDCLKout5_DDLY.
d. To allow SYNC to effect dividers: SYNC_DIS0 = 0, SYNC_DIS2 = 0, SYNC_DIS4 = 0,
SYNC_DISSYSREF = 0
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3.
4.
5.
6.
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e. Perform SYNC by toggling SYNC_POL = 1, then SYNC_POL = 0.
When the dividers are synchronized, disable SYNC from resetting these dividers. It is not desired for
SYSREF to reset it's own divider or the dividers of the output clocks.
a. Prevent SYSREF from affecting dividers: SYNC_DIS0 = 1, SYNC_DIS2 = 1, SYNC_DIS4 = 1,
SYNC_DISSYSREF = 1.
Release reset of local SYSREF digital delay.
a. SYSREF_CLR = 0. Note this bit needs to be set for only 15 clock distribution path cycles after
SYSREF_PD = 0.
Set SYSREF operation.
a. Allow pin SYNC event to start pulser: SYNC_MODE = 2.
b. Select pulser as SYSREF signal: SYSREF_MUX = 2.
After the procedure is complete, asserting the SYNC pin or toggling SYNC_POL results in a series of 2
SYSREF pulses.
9.3.2.1.2 SYSREF_CLR
The local digital delay of the SDCLKout is implemented as a shift buffer. To ensure no unwanted pulses occur at
this SYSREF output at startup when using SYSREF, clear the buffers by setting SYSREF_CLR = 1 for 15 VCO
clock cycles. This bit is set after a reset; thus, it must be cleared before the SYSREF output is used.
9.3.2.2 SYSREF Modes
9.3.2.2.1 SYSREF Pulser
This mode allows for the output of 1, 2, 4, or 8 SYSREF pulses for every SYNC pin event or SPI programming.
This implements the gapped periodic functionality of the JEDEC JESD204B specification.
When in SYSREF pulser mode, programming the field SYSREF_PULSE_CNT in register 0x13E results in the
pulser sending the programmed number of pulses.
9.3.2.2.2 Continuous SYSREF
This mode allows for continuous output of the SYSREF clock.
Continuous operation of SYSREF is not recommended, due to crosstalk from the SYSREF clock to device clock.
JESD204B is designed to operate with a single burst of pulses to initialize the system at startup, after which it is
theoretically not required to send another SYSREF, because the system continues to operate with deterministic
phases.
If continuous operation of SYSREF is required, consider using a SYSREF output from a non-adjacent output or
SYSREF from the OSCout pin, to minimize crosstalk.
9.3.2.2.3 SYSREF Request
This mode allows an external source to synchronously turn on or off a continuous stream of SYSREF pulses,
using the SYNC/SYSREF_REQ pin.
Set up the mode by programming SYSREF_REQ_EN = 1 and SYSREF_MUX = 2 (Pulser). The pulser does not
need to be powered for this mode of operation.
When the SYSREF_REQ pin is asserted, the SYSREF_MUX is synchronously set to continuous mode, providing
continuous pulses at the SYSREF frequency, until the SYSREF_REQ pin is unasserted and the final SYSREF
pulse completes sending synchronously.
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9.3.3 Digital Delay
Digital (coarse) delay allows a group of outputs to be delayed by 4 to 32 VCO cycles. The delay step can be as
small as half the period of the VCO cycle, by using the DCLKoutX_HS bit. There are two ways to use the digital
delay:
1. Fixed digital delay
2. Dynamic digital delay
In both delay modes, the regular clock divider is substituted with an alternative divide value. The substitute divide
value consists of two values, DCLKoutX_DDLY_CNTH and DCLKoutX_DDLY_CNTL. The minimum
_CNTH/_CNTL value is 2 and the maximum _CNTH/_CNTL value is 16. This results in a minimum alternative
divide value of 4 and a maximum of 32.
9.3.3.1 Fixed Digital Delay
Fixed digital delay value takes effect on the clock outputs after a SYNC event. As such, the outputs are LOW for
a while during the SYNC event. Applications that cannot accept clock interruption when adjusting digital delay
should use dynamic digital delay.
9.3.3.1.1 Fixed Digital Delay Example
Assuming the device already has the following initial configurations, and the application should delay DCLKout2
by one VCO cycle compared to DCLKout0:
• VCO frequency = 2949.12 MHz
• DCLKout0 = 368.64 MHz (DCLKout0_DIV = 8)
• DCLKout2 = 368.64 MHz (DCLKout2_DIV = 8)
These steps should be followed:
1. Set DCLKout0_DDLY_CNTH = 4 and DCLKout2_DDLY_CNTH = 4. First part of delay for each clock.
2. Set DCLKout0_DDLY_CNTL = 4 and DCLKout2_DDLY_CNTL = 5. Second part of delay for each clock.
3. Set DCLKout0_DDLY_PD = 0 and DCLKout2_DDLY_PD = 0. Power up the digital delay circuit.
4. Set SYNC_DIS0 = 0 and SYNC_DIS2 = 0. Allow the output to be synchronized.
5. Perform SYNC by asserting, then deasserting SYNC. Either by using SYNC_POL bit or the SYNC pin.
6. When the SYNC is complete, power down DCLKout0_DDLY_PD = 1 and/or DCLKout2_DDLY_PD = 1 to
save power.
7. Set SYNC_DIS0 = 1 and SYNC_DIS2 = 1, to prevent the outputs from being synchronized by other
SYNC/SYSREF events.
DCLKout0
368.64 MHz
No CLKout during SYNC
DCLKout2
368.64 MHz
SYNC event
1 VCO cycle delay
Figure 14. Fixed Digital Delay Example
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9.3.3.2 Dynamic Digital Delay
Dynamic digital delay allows the phase of clocks to be changed with respect to each other, with little impact to
the clock signal. This is accomplished by substituting the regular clock divider with an alternate divide value for
one cycle. This substitution occurs a number of times equal to the value programmed into the
DDLYd_STEP_CNT field for all outputs with DDLYdX_EN = 1.
• By programming a larger alternate divider (delay) value, the phase of the adjusted outputs is delayed with
respect to the other clocks.
• By programming a smaller alternate divider (delay) value, the phase of the adjusted output is advanced with
respect to the other clocks.
Table 3 shows the recommended DCLKoutX_DDLY_CNTH and DCLKoutX_DDLY_CNTL alternate divide setting
for delay by one VCO cycle. The clock output is high during the DCLKoutX_DDLY_CNTH time to permit a
continuous output clock. The clock output is low during the DCLKoutX_DDLY_CNTL time.
Table 3. Recommended DCLKoutX_DDLY_CNTH/_CNTL Values for Delay by One VCO Cycle
CLOCK DIVIDER
_CNTH
_CNTL
CLOCK DIVIDER
_CNTH
2
2
3
17
9
9
3
3
4
18
9
10
4
2
3
19
10
10
5
3
3
20
10
11
6
3
4
21
11
11
7
4
4
22
11
12
8
4
5
23
12
12
9
5
5
24
12
13
10
5
6
25
13
13
11
6
6
26
13
14
12
6
7
27
14
14
13
7
7
28
14
15
14
7
8
29
15
15
15
8
8
30
15
0 (1)
16
8
9
31
0 (1)
0 (1)
(1)
_CNTL
To achieve _CNTH/_CNTL value of 16, 0 must be programmed into the _CNTH/_CNTL field.
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9.3.3.3 Single and Multiple Dynamic Digital Delay Example
In this example, two separate adjustments are made to the device clocks. In the first adjustment, a single delay
of 1 VCO cycle occurs between DCLKout2 and DCLKout0. In the second adjustment, two delays of 1 VCO cycle
occur between DCLKout2 and DCLKout0. At this point in the example, DCLKout2 is delayed 3 VCO cycles
behind DCLKout0.
Assuming the device already has the following initial configurations:
• VCO frequency: 2949.12 MHz
• DCLKout0 = 368.64 MHz, DCLKout0_DIV = 8
• DCLKout2 = 368.64 MHz, DCLKout2_DIV = 8
The following steps illustrate the example above:
1. Set DCLKout2_DDLY_CNTH = 4. First part of delay for DCLKout2.
2. Set DCLKout2_DDLY_CNTL = 5. Second part of delay for DCLKout2.
3. Set DCLKout2_DDLY_PD = 0. Enable the digital delay for DCLKout2.
4. Set DDLYd2_EN = 1. Enable dynamic digital delay for DCLKout2.
5. Set SYNC_DIS0 = 1 and SYNC_DIS2 = 0. Sync should be disabled to DCLKout0, but not DCLKout2.
6. Set SYNC_MODE = 3. Enable SYNC event from SPI write to the DDLYd_STEP_CNT register.
7. Set SYNC_MODE = 2, SYSREF_MUX = 2. Setup proper SYNC settings.
8. Set DDLYd_STEP_CNT = 1. This begins the first adjustment.
Before step 8 DCLKout2 clock edge is aligned with DCLKout0.
After step 8, DCLKout2 counts four VCO cycles high and then five VCO cycles low as programmed by
DCLKout2_DDLY_CNTH and DCLKout2_DDLY_CNTL fields, effectively delaying DCLKout2 by one VCO
cycle with respect to DCLKout0. This is the first adjustment.
9. Set DDLYd_STEP_CNT = 2. This begins the second adjustment.
Before step 9, DCLKout2 clock edge was delayed 1 VCO cycle from DCLKout0.
After step 9, DCLKout2 counts four VCO cycles high and then five VCO cycles low, as programmed by
DCLKout2_DDLY_CNTH and DCLKout2_DDLY_CNTL fields twice, delaying DCLKout2 by two VCO cycles
with respect to DCLKout0. This is the second adjustment.
VCO
2949.12 MHz
DCLKout0
368.64 MHz
DCLKout2
368.64 MHz
First
Adjustment
CNTH = 4
CNTL = 5
DCLKout2
368.64 MHz
Second
Adjustment
CNTH = 4
CNTL = 5
CNTH = 4
CNTL = 5
Figure 15. Single and Multiple Adjustment Dynamic Digital Delay Example
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9.3.4 SYSREF to Device Clock Alignment
To ensure proper JESD204B operation, the timing relationship between the SYSREF and the device clock must
be adjusted for optimum setup and hold time as shown in
Added timing alignment figure, alignment equations to SYSREF to Device Clock Alignment . The global SYSREF
digital delay (SYSREF_DDLY). local SYSREF digital delay (SDCLKoutY_DDLY), local SYSREF half step
(SDCLKoutY_HS), and local SYSREF analog delay (SDCLKoutY_ADLY, SDCLKoutY_ADLY_EN) can be
adjusted to provide the required setup and hold time between SYSREF and device clock. It is also possible to
adjust the device clock digital delay (DCLKoutX_DDLY_CNTH, DCLKoutX_DDLY_CNTL), device clock half step
(DCLKoutX_HS), device clock analog delay (DCLKoutX_ADLY, DCLKoutX_ADLY_EN), and device clock muxes
(DCLKoutX_MUX, DCLKoutX_ADLY_MUX) to adjust phase with respect to SYSREF.
Figure 16. SYSREF to Device Clock Timing Alignment
Depending on the settings for DCLKoutX and the SYSREF divider, some adjustment may be needed to correctly
align DCLKoutX to SDCLKoutY. Equation 1 and Equation 2 predict the relative DCLKoutX to SDCLKoutY delay:
DELAYDCLK = DCLKoutX_DDLY_CNTH + DCLKoutX_DDLY_CNTL
DELAYSDCLK = SYSREF_DDLY + SDCLKoutY_DDLY + SYSREF_DIV_ADJUST + DCLKout_MUX_ADJUST
(1)
where
•
•
SYSREF_DIV_ADJUST = 2 IF (SYSREF_DIV % 4 < 2) ELSE 3
DCLKoutX_MUX_ADJUST = 1 IF (Duty Cycle Correction enabled) ELSE 0
(2)
For the relative delay equations, the cycle delay rather than the register value should be used, since cycle delay
does not always equal register value (example: _CNTH/_CNTL=0, delay=16). Device clock duty cycle correction
can be enabled for both digital and analog paths, either by setting DCLKoutX_MUX=1 (digital only), or by setting
DCLKoutX_MUX=3 and DCLKoutX_ADLY_MUX=1. If half step is enabled on either path, delay can be included
by subtracting 0.5 from the enabled path. As an example, if DCLKoutX_DDLY_CNTH=7,
DCLKoutX_DDLY_CNTL=6,
SYSREF_DDLY=8,
SDCLKoutY_DDLY=2
cycles,
SYSREF_DIV=30,
DCLKoutX_MUX=1, DCLKoutX_HS=0, SDCLKoutX_HS=0:
• DELAYDCLK = 7 + 6 = 13
• SYSREF_DIV_ADJUST = (30 % 4 < 2) ? 2 : 3 = 3
• DCLKoutX_MUX_ADJUST = DCC ? 1 : 0 = 0
• DELAYSDCLK = 8 + 2 + 3 + 0 = 13
To calculate the expected time delay from the first edge of DCLKoutX to the first edge of SDCLKoutY, refer to
Equation 3. Substitute the analog delays with the appropriate time values (in seconds) according to
DCLKoutX_ADLY, DCLKoutX_ADLY_MUX, DCLKout_MUX and SDCLKoutY_ADLY_EN, SDCLKoutY_ADLY.
tsJESD204B is provided in the Electrical Characteristics section for the conditions in the example above as -80 ps.
tDCLK-to-SDCLK = (FDistribution)-1 × (DELAYSDCLK - DELAYDCLK) + SDCLKoutY_ADLY - DCLKoutY_ADLY + tsJESD204B
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9.3.5 Input Clock Switching
Manual, pin select, and automatic are three kinds clock input switching modes that can be set with the
CLKin_SEL_MODE register.
The following sections describe how the active input clock is selected and what causes a switching event in the
various clock input selection modes.
9.3.5.1 Input Clock Switching - Manual Mode
When CLKin_SEL_MODE is 0, 1, or 2, then CLKin0, CLKin1, or CLKin2 respectively is always selected as the
active input clock. Manual mode also overrides the EN_CLKinX bits, such that the CLKinX buffer operates even if
EN_CLKinX = 0.
If holdover is entered in this mode, the device re-locks to the selected CLKin upon holdover exit.
9.3.5.2 Input Clock Switching - Pin Select Mode
When CLKin_SEL_MODE is 3, the pins CLKin_SEL0 and CLKin_SEL1 select which clock input is active.
Configuring Pin Select Mode
The CLKin_SEL0_TYPE must be programmed to an input value for the CLKin_SEL0 pin to function as an input
for pin select mode.
The CLKin_SEL1_TYPE must be programmed to an input value for the CLKin_SEL1 pin to function as an input
for pin select mode.
If the CLKin_SELX_TYPE is set as output, the pin input value is considered low.
The polarity of CLKin_SEL0 and CLKin_SEL1 input pins can be inverted with the CLKin_SEL_INV bit.
Table 4 defines which input clock is active depending on CLKin_SEL0 and CLKin_SEL1 state.
Table 4. Active Clock Input - Pin Select Mode, CLKin_SEL_INV = 0
PIN CLKin_SEL1
PIN CLKin_SEL0
ACTIVE CLOCK
Low
Low
CLKin0
Low
High
CLKin1
High
Low
CLKin2
High
High
Holdover
The pin select mode ignores the EN_CLKinX bits, such that the CLKinX buffer operates even if EN_CLKinX = 0.
To switch as fast as possible, keep the switchable clock input buffers enabled (EN_CLKinX = 1).
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9.3.5.3 Input Clock Switching - Automatic Mode
When CLKin_SEL_MODE is 4 and LOS_EN = 1, the active clock is selected in round-robin order of enabled
clock inputs, starting on an input clock switch event. The switching order of the clocks is CLKin0 → CLKin1 →
CLKin2 → CLKin0, and so forth.
For a clock input to be eligible to be switched through, it must be enabled using EN_CLKinX. The
LOS_TIMEOUT should also be set to a frequency below the input frequency.
To ensure LOS is valid for AC-coupled inputs, the MOS mode must be set for CLKinX and no termination is
allowed to be between the pins unless DC-blocked. For example, with an LVDS differential signal into CLKin0, no
100-Ω termination should be placed directly across CLKin0 and CLKin0* pins on the IC side of the AC coupling
capacitors. 100 Ω could instead be placed on the transmitter side of the AC coupling capacitors.
Starting Active Clock
When programming this mode, the currently active clock remains active if PLL1 lock detect is high. To ensure a
particular clock input is the active clock when starting this mode, program CLKin_SEL_MODE to the manual
mode which selects the desired clock input (CLKin0, 1, or 2). Wait for PLL1 to lock PLL1_DLD = 1, then select
this mode with CLKin_SEL_MODE = 4.
9.3.6 Digital Lock Detect
Both PLL1 and PLL2 support digital lock detect. Digital lock detect compares the phase between the reference
path (R) and the feedback path (N) of the PLL at the phase detector. When the time error(phase error) between
the two signals is less than a specified window size (ε), a lock detect count increments. When the lock detect
count reaches a user-specified value, PLL1_DLD_CNT or PLL2_DLD_CNT, lock detect is asserted (true). When
digital lock detect is true, a single phase comparison outside the specified window causes digital lock detect to
be deasserted (false). This is illustrated in Figure 17 .
NO
START
PLLX
Lock Detected = False
Lock Count = 0
NO
YES
Phase Error < g
Increment
PLLX Lock Count
PLLX Lock Count =
PLLX_DLD_CNT
YES
PLLX
Lock Detected = True
Phase Error < g
YES
NO
Figure 17. Digital Lock Detect Flowchart
This incremental lock detect count feature functions as a digital filter, to ensure that lock detect is not asserted
when the phases of R and N are within the specified tolerance for a brief time during initial phase lock.
See Digital Lock Detect Frequency Accuracy for more detailed information on programming the registers to
achieve a specified frequency accuracy in ppm with lock detect.
The digital lock detect signal can be monitored on the Status_LD1 or Status_LD2 pin. The pin may be
programmed to output the status of lock detect for PLL1, PLL2, or both PLL1 and PLL2.
The digital lock detect feature can also be used with holdover to automatically exit holdover mode. See Exiting
Holdover for more info.
NOTE
In cases where the period of the phase detector frequency approaches the value of the
default PLL1_WND_SIZE increment (40 ns), the lock detect circuit will not function with
the default value of PLL1_WND_SIZE. For PLL1 phase detector frequencies at or above
25 MHz, TI recommends setting PLL1_WND_SIZE less than or equal to 0x02 (19 ns).
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9.3.7 Holdover
Holdover mode causes PLL2 to stay locked on frequency with minimal frequency drift when an input clock
reference to PLL1 becomes invalid, when PLL1 loses lock, or when the CPout1 voltage is outside of a userspecified acceptable range. While in holdover mode, the PLL1 charge pump is TRI-STATED and a fixed tuning
voltage is set on CPout1 to operate PLL1 in open loop.
9.3.7.1 Enable Holdover
Program HOLDOVER_EN = 1 to enable holdover mode. Enabling holdover mode does not place the device in
holdover unless the relevant criteria have been met (example: PLL1 loss of lock). Program HOLDOVER_FORCE
= 1 to force the device into holdover.
Holdover mode can be configured to set the CPout1 voltage upon holdover entry, to a fixed user-defined voltage
or a tracked voltage.
9.3.7.1.1 Fixed (Manual) CPout1 Holdover Mode
By programming MAN_DAC_EN = 1, the MAN_DAC value is set on the CPout1 pin during holdover.
The user can optionally enable CPout1 voltage tracking (TRACK_EN = 1), read back the tracked DAC value,
then reprogram MAN_DAC value to a user-desired value based on information from previous DAC read backs.
This allows the most user control over the holdover CPout1 voltage, but also requires more user intervention.
9.3.7.1.2 Tracked CPout1 Holdover Mode
By programming MAN_DAC_EN = 0 and TRACK_EN = 1, the tracked voltage of CPout1 is set on the CPout1
pin during holdover. When the DAC has acquired the current CPout1 voltage, the DAC_Locked signal is set,
which may be observed on Status_LD1 or Status_LD2 pins by programming PLL1_LD_MUX or PLL2_LD_MUX,
respectively.
Updates to the DAC value for the Tracked CPout1 sub-mode occurs at the rate of the PLL1 phase detector
frequency divided by (DAC_CLK_MULT × DAC_CLK_CNTR).
The DAC update rate should be programmed for ≤ 100 kHz to ensure DAC holdover accuracy.
The ability to program slow DAC update rates, for example one DAC update per 4.08 seconds when using 1024kHz PLL1 phase-detector frequency with DAC_CLK_MULT = 16,384 and DAC_CLK_CNTR = 255, allows the
device to look-back and set CPout1 at previous "good" CPout1 tuning voltage values before the event which
caused holdover to occur.
The current voltage of DAC value can be read back using RB_DAC_VALUE; see RB_DAC_VALUE.
9.3.7.2 Entering Holdover
There are several ways to enter holdover.
• HOLDOVER_LOS_DET = 1 and a loss of active reference is detected.
• HOLDOVER_PLL1_DET = 1 and PLL1 loss of lock is detected.
• HOLDOVER_VTUNE_DET = 1 and the voltage monitored by the DAC on CPout1 is less than the value set
by DAC_TRIP_LOW, or greater than the value set by DAC_TRIP_HIGH.
• HOLDOVER_FORCE = 1.
9.3.7.3 During Holdover
PLL1 is run in open-loop mode.
• PLL1 charge pump is set to TRI-STATE.
• PLL1 DLD is deasserted.
• The HOLDOVER status is asserted.
• During holdover, if PLL2 was locked prior to entry of holdover mode, PLL2 DLD continues to be asserted.
• CPout1 voltage is set to:
– a voltage set in the MAN_DAC register (MAN_DAC_EN = 1).
– a voltage determined to be the last valid CPout1 voltage (MAN_DAC_EN = 0).
• PLL1 attempts to lock with the active clock input.
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The HOLDOVER status signal can be monitored on the Status_LD1 or Status_LD2 pin by programming the
PLL1_DLD_MUX or PLL2_DLD_MUX register to Holdover Status.
9.3.7.4 Exiting Holdover
Holdover mode can be exited in one of two ways.
• Manually, by programming the device from the host.
• Automatically, by a clock operating within a specified ppm of the current PLL1 frequency on the active clock
input.
9.3.7.5 Holdover Frequency Accuracy and DAC Performance
When in holdover mode, PLL1 runs in open loop and the DAC sets the CPout1 voltage. If fixed CPout1 mode is
used, then the output of the DAC is voltage-dependant upon the MAN_DAC register. If tracked CPout1 mode is
used, then the output of the DAC is the voltage at the CPout1 pin before holdover mode was entered. When
using tracked mode and MAN_DAC_EN = 1, during holdover the DAC value is loaded with the programmed
value in MAN_DAC, not the tracked value.
When in tracked CPout1 mode, the DAC has a worst-case tracking error of ±2 LSBs when PLL1 tuning voltage is
acquired. The step size is approximately 3.2 mV, thus the VCXO frequency error during holdover mode caused
by the DAC tracking accuracy is ±6.4 mV × Kv, where Kv is the tuning sensitivity of the VCXO in use. Thus, the
accuracy of the system when in holdover mode in ppm is:
Holdover accuracy (ppm) =
± 6.4 mV × Kv × 1e6
VCXO Frequency
(4)
Example: consider a system with a 19.2-MHz clock input, and a 153.6-MHz VCXO with a Kv of 17 kHz/V. The
accuracy of the system in holdover in ppm is:
±0.71 ppm = ±6.4 mV × 17 kHz/V × 1e6 / 153.6 MHz
(5)
It is important to account for this frequency error when determining the allowable frequency error window to
cause holdover mode to exit.
9.3.7.6 Holdover Mode - Automatic Exit of Holdover
The LMK0482x device can be programmed to automatically exit holdover mode when the frequency on the
active clock input achieves a specified accuracy. The programmable variables include PLL1_WND_SIZE and
HOLDOVER_DLD_CNT.
See Digital Lock Detect Frequency Accuracy to calculate the register values to cause holdover to automatically
exit upon reference signal recovery to within a user specified ppm error of the holdover frequency.
The time to exit holdover may vary, because the condition for automatic holdover exit is for the reference and
feedback signals to have a time/phase error less than a programmable value. Because two clock signals may be
very close in frequency but not close in phase, it may take a long time for the phases of the clocks to align
themselves within the allowable time/phase error before holdover exits.
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9.4 Device Functional Modes
The following section describes the settings to enable various modes of operation for the LMK0482x family. See
Figure 12 and Figure 13 for visual diagrams of each mode.
The LMK0482x family is a flexible device that can be configured for many different use cases. The following
simplified block diagrams show the user the different use cases of the device.
9.4.1 Dual PLL
Figure 18 illustrates the typical use case of the LMK0482x family in dual-loop mode. In dual-loop mode, the
reference to PLL1 is from CLKin0, CLKin1, or CLKin2. An external VCXO or tunable crystal is used to provide
feedback for the first PLL, and a reference to the second PLL. This first PLL cleans the jitter with the VCXO or
low-cost tunable crystal by using a narrow loop bandwidth. The VCXO or tunable crystal output may be buffered
through the OSCout port. The VCXO or tunable crystal is used as the reference to PLL2, and may be doubled
using the frequency doubler. The internal VCO drives up to seven divide/delay blocks, which drive up to 14 clock
outputs.
Hitless switching and holdover functionality are optionally available when the input reference clock is lost.
Holdover works by fixing the tuning voltage of PLL1 to the VCXO or tunable crystal.
It is also possible to use an external VCO in place of the PLL2 internal VCO. In this case, one less CLKin is
available as a reference.
LMK04821 includes VCO1 divider on VCO1 output.
PLL1
PLL2
R
N
Phase
Detector
PLL1
External VCXO
or Tunable
Crystal
External
Loop Filter
External
Loop Filter
OSCout
OSCout*
OSCin
CLKinX
CLKinX*
Up to 3
inputs
CPout1
Up to 1 OSCout
7 blocks
CPout2
R
Input
Buffer
N
Phase
Detector
PLL2
Device Clock
Divider
Digital Delay
Analog Delay
Partially
Integrated
Loop Filter
Dual
Internal
VCOs
LMK0482x
SYSREF
Digital Delay
Analog Delay
7 Device
Clocks
DCLKoutX
DCLKoutX*
7 SYSREF
or Device
Clocks
SDCLKoutY
SDCLKoutY*
1 Global SYSREF Divider
Figure 18. Simplified Functional Block Diagram for Dual-Loop Mode
Table 5. Dual-Loop Mode Register Configuration
50
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
0
OSCin
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
0
PLL2_P
FB_MUX_EN
0x13F
Enables the feedback mux
0
Disabled
FB_MUX
0x13F
Selects the output of the feedback mux
X
Don't care because FB_MUX is disabled
OSCin_PD
0x140
Powers down the OSCin port
0
Powered up
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is
directed.
2
PLL1
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is
directed.
2
PLL1
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
0 or 1
VCO 0 or VCO 1
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9.4.2 Zero-Delay Dual PLL
Figure 19 illustrates the use case of cascaded zero-delay dual-loop mode. This configuration differs from dualloop mode Figure 18 in that the feedback for PLL2 is driven by a clock output instead of the VCO output.
Figure 20 illustrates the use case of nested zero-delay dual-loop mode. This configuration is similar to the dual
PLL in Dual PLL, except that the feedback to the first PLL is driven by a clock output. This causes the clock
outputs to have deterministic phase relationship with the clock input. Because all the clock outputs can be
synchronized together, all the clock outputs can share the same deterministic phase relationship with the clock
input signal. The feedback to PLL1 can be connected internally as shown using CLKout6, CLKout8, SYSREF, or
externally using FBCLKin (CLKin1).
It is also possible to use an external VCO in place of the PLL2 internal VCO; however, because CLKin1 must be
used as Fin for the external VCO, it is unavailable as a reference to PLL1 or as external zero-delay feedback.
LMK04821 includes VCO1 divider on VCO1 output.
PLL1
PLL2
R
N
Phase
Detector
PLL1
External VCXO
or Tunable
Crystal
External
Loop Filter
OSCout
OSCout*
OSCin
CLKinX
CLKinX*
Up to 3
inputs
CPout1
Up to 1 OSCout
External
Loop Filter
CPout2
Divider
Digital Delay
Analog Delay
R
Input
Buffer
N
Phase
Detector
PLL2
Partially
Integrated
Loop Filter
Dual
Internal
VCOs
Internal or external loopback, user programmable
SDCLKoutY
SDCLKoutY*
7 SYSREF
or Device
Clocks
7 blocks
SYSREF
Analog Delay
Digital Delay
1 Global SYSREF Divider
LMK0482x
DCLKoutX
DCLKoutX*
7 Device
Clocks
Figure 19. Simplified Functional Block Diagram for Cascaded Zero-Delay Dual-Loop Mode
Table 6. Cascaded Zero-Delay Dual-Loop Mode Register Configuration
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
0
OSCin
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
1
Feedback mux
FB_MUX_EN
0x13F
Enables the feedback mux.
1
Feedback mux enabled
FB_MUX
0x13F
Selects the output of the feedback mux.
0, 1, or 2
Select between DCLKout6,
DCLKout8, SYSREF
OSCin_PD
0x140
Powers down the OSCin port.
0
Powered up
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is directed.
0
PLL1
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is directed.
0 or 2
Fin or PLL1
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
0 or 1
VCO 0 or VCO 1
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PLL1
PLL2
R
N
Phase
Detector
PLL1
External VCXO
or Tunable
Crystal
External
Loop Filter
OSCout
OSCout*
OSCin
CLKinX
CLKinX*
Up to 3
inputs
CPout1
Up to 1 OSCout
External
Loop Filter
CPout2
Divider
Digital Delay
Analog Delay
R
Input
Buffer
N
Phase
Detector
PLL2
Partially
Integrated
Loop Filter
Dual
Internal
VCOs
Internal or external loopback, user programmable
SDCLKoutY
SDCLKoutY*
7 SYSREF
or Device
Clocks
7 blocks
SYSREF
Analog Delay
Digital Delay
1 Global SYSREF Divider
LMK0482x
DCLKoutX
DCLKoutX*
7 Device
Clocks
Figure 20. Simplified Functional Block Diagram for Nested Zero-Delay Dual-Loop Mode
LMK04821 includes the VCO1 divider on the VCO1 output.
Table 7 illustrates nested zero-delay mode. This is the same as cascaded, except the clock out feedback is to
PLL1. The CLKin and CLKout have the same deterministic phase relationship, but the VCXO's phase is not
deterministic to the CLKin or CLKouts.
Table 7. Nested Zero-Delay Dual-Loop Mode Register Configuration
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
SELECTED VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
1
Feedback mux
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
0
PLL2 P
FB_MUX_EN
0x13F
Enables the feedback mux.
1
Enabled
FB_MUX
0x13F
Selects the output of the feedback mux.
0, 1, or 2
Select between DCLKout6,
DCLKout8, SYSREF
Powered up
OSCin_PD
0x140
Powers down the OSCin port.
0
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is directed.
2
PLL1
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is directed.
0 or 2
Fin or PLL1
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
0 or 1
VCO 0 or VCO 1
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9.4.3 Single-Loop Mode
Figure 21 illustrates the use case of PLL2 single loop mode. When used with a clean high frequency reference
on OSCin, performance can be comparable to (or even better than) dual-loop mode.
Figure 21. Simplified Functional Block Diagram for Single-Loop Mode
Table 8. Single-Loop Mode Register Configuration
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
SELECTED VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
X
Don't care
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
0
PLL2 P
FB_MUX_EN
0x13F
Enables the feedback mux.
0
Disabled
FB_MUX
0x13F
Selects the output of the feedback mux.
0, 1, or 2
Select between DCLKout6, DCLKout8,
SYSREF
OSCin_PD
0x140
Powers down the OSCin port.
0
Powered up
PLL1_PD
0x140
Powers down PLL1.
1
Powered down
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is
directed.
X
Don't care
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is
directed.
3
Off
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
0 or 1
VCO 0 or VCO 1
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9.4.4 Single-Loop Mode With External VCO
Adding an external VCO is possible using the CLKin1/Fin input port. The input may be single-ended or
differential. At high frequency the input impedance to Fin is low, so a resistive pad is recommended for matching.
Figure 22. Simplified Functional Block Diagram for Single-Loop Mode With External VCO
Table 9. Single-Loop Mode With External VCO Register Configuration
54
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
SELECTED VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
X
Don't care
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
0
PLL2_P
FB_MUX_EN
0x13F
Enables the feedback mux.
0
Disabled
FB_MUX
0x13F
Selects the output of the feedback mux.
X
Don't care
OSCin_PD
0x140
Powers down the OSCin port.
0
Powered up
VCO_LDO_PD
0x140
Powers down the VCO LDO.
1
Powered down
VCO_PD
0x140
Powers down the VCO.
1
Powered down
PLL1_PD
0x140
Powers down PLL1.
1
Powered down
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is
directed.
X
Don't care
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is
directed.
0
Fin
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
2
External VCO
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9.4.5 Distribution Mode
Figure 23 illustrates the use case of distribution mode. As in all other use cases, OSCin to OSCout can be used
as a buffer to OSCin or from clock distribution path via CLKout6, CLKout8, or the SYSREF divider. At high
frequency the input impedance to Fin is low, so a resistive pad is recommended for matching.
Figure 23. Simplified Functional Block Diagram for Distribution Mode
Table 10. Distribution Mode Register Configuration
FIELD
REGISTER
ADDRESS
FUNCTION
VALUE
SELECTED VALUE
PLL1_NCLK_MUX
0x13F
Selects the input to the PLL1 N divider
X
Don't care
PLL2_NCLK_MUX
0x13F
Selects the input to the PLL2 N divider
X
Don't care
FB_MUX_EN
0x13F
Enables the feedback mux.
0
Disabled
FB_MUX
0x13F
Selects the output of the feedback mux.
X
Don't care
OSCin_PD
0x140
Powers down the OSCin port.
1
Powered down
VCO_LDO_PD
0x140
Powers down the VCO LDO.
1
Powered down
VCO_PD
0x140
Powers down the VCO.
1
Powered down
PLL1_PD
0x140
Powers down PLL1.
1
Powered down
PLL2_PRE_PD
0x173
Powers down PLL2 prescaler.
1
Powered down
PLL2_PD
0x173
Powers down PLL2.
1
Powered down
CLKin0_OUT_MUX
0x147
Selects where the output of CLKin0 is
directed.
X
Don't care
CLKin1_OUT_MUX
0x147
Selects where the output of CLKin1 is
directed.
0
Fin
VCO_MUX
0x138
Selects the VCO 0, 1 or an external VCO
2
External VCO
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9.5 Programming
LMK0482x family devices are programmed using 24-bit registers. Each register consists of a 1-bit command field
(R/W), a 2-bit multi-byte field (W1, W0), a 13-bit address field (A12 to A0), and an 8-bit data field (D7 to D0). The
contents of each register is clocked in MSB first (R/W), and the LSB (D0) last. During programming, the CS*
signal is held low. The serial data is clocked in on the rising edge of the SCK signal. After the LSB is clocked in,
the CS* signal goes high to latch the contents into the shift register. TI recommends programming registers in
numeric order – for example, 0x000 to 0x1FFF – to achieve proper device operation. Each register consists of
one or more fields which control the device functionality. See Electrical Characteristics and Figure 1 for timing
details.
R/W bit = 0 is for SPI write. R/W bit = 1 is for SPI read.
W1 and W0 should be written as 0.
9.5.1 Recommended Programming Sequence
Registers are programmed in numeric order, with 0x000 being the first and 0x1FFF being the last register
programmed. The recommended programming sequence from POR involves:
1. Program register 0x000 with RESET = 1.
2. Program registers in numeric order from 0x000 to 0x165. Ensure the following register is programmed as
follows:
– 0x145 = 127 (0x7F)
3. Program register 0x171 to 0xAA and 0x172 to 0x02.
4. If using LMK04821, program register 0x174.
5. Program registers 0x17C and 0x17D as required by OPT_REG_1 and OPT_REG_2.
6. Program registers 0x166 to 0x1FFF.
When using LMK04821: Program register 0x174, bits 4:0 (VCO1_DIV) with the proper value before programming
the PLL2_N register in 0x166, 0x167, and 0x168 for proper total PLL2_N value.
Program register 0x171, 0x172, 0x17C (OPT_REG_1) and 0x17D (OPT_REG_2) before programming PLL2 in
registers: 0x166, 0x167, and 0x168, to optimize PLL2_N and VCO1 phase-noise performance over temperature.
9.5.1.1 SPI LOCK
When writing to SPI_LOCK, registers 0x1FFD, 0x1FFE, and 0x1FFF should all always be written sequentially.
9.5.1.2 SYSREF_CLR
When using SYSREF output, SYSREF local digital delay block should be cleared using SYSREF_CLR bit. See
SYSREF_CLR for more info.
9.5.1.3 RESET Pin
If the RESET pin is not used during normal operation, TI recommends programming the RESET_TYPE register
to an output setting, to prevent noise from spontaneously resetting the device.
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9.6 Register Maps
9.6.1 Register Map for Device Programming
Table 11 provides the register map for device programming. Any register can be read from the same data
address it is written to.
Table 11. LMK0482x Register Map
ADDRESS
[11:0]
DATA
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
POWER
DOWN
0x000
RESET
0
0
SPI_3WIRE
_DIS
0x002
0
0
0
0
0x003
ID_DEVICE_TYPE
0x004
ID_PROD[15:8]
0x005
ID_PROD[7:0]
0x006
ID_MASKREV
0x00C
ID_VNDR[15:8]
0x00D
0x100
ID_VNDR[7:0]
0
0x101
CLKout0_1
_ODL
CLKout0_1
_IDL
DCLKout0_DIV
DCLKout0_DDLY_CNTH
0x103
DCLKout0_DDLY_CNTL
DCLKout0_
ADLY_MUX
DCLKout0_ADLY
0x104
0
DCLKout0
_HS
SDCLKout1
_MUX
0x105
0
0
0
SDCLKout1_
ADLY_EN
0x106
DCLKout0
_ DDLY_PD
DCLKout0
_ HSg_PD
DCLKout0
_ ADLYg_PD
DCLKout0
_ADLY _PD
0x107
SDCLKout1
_POL
0x108
0
0x109
SDCLKout1_ADLY
CLKout0_1
_PD
CLKout2_3
_IDL
DCLKout2_DDLY_CNTL
0
DCLKout2
_HS
SDCLKout3
_MUX
0x10D
0
0
0
SDCLKout3
_ ADLY_EN
0x10E
DCLKout2
_ DDLY_PD
DCLKout2
_ HSg_PD
DCLKout2
_ ADLYg_PD
DCLKout2
_ADLY _PD
0x10F
SDCLKout3
_POL
0x110
0
CLKout2_3
_PD
SDCLKout3
_PD
CLKout2_FMT
DCLKout4_DIV
DCLKout4_DDLY_CNTL
DCLKout4_
ADLY_MUX
DCLKout4_ADLY
0x114
0
DCLKout4
_HS
SDCLKout5
_MUX
0x115
0
0
0
SDCLKout5
_ ADLY_EN
0x116
DCLKout4
_ DDLY_PD
DCLKout4
_ HSg_PD
DCLKout4
_ ADLYg_PD
DCLKout4
_ADLY _PD
0x117
SDCLKout5
_POL
0x118
0
CLKout6_8
_IDL
SDCLKout3_DIS_MODE
DCLKout2
_POL
DCLKout4_DDLY_CNTH
CLKout6_7
_ODL
SDCLKout3
_HS
SDCLKout3_ADLY
CLKout4_5
_IDL
CLKout5_FMT
DCLKout2_MUX
SDCLKout3_DDLY
CLKout3_FMT
0x113
CLKout0_FMT
DCLKout2_
ADLY_MUX
0x10C
0x111
SDCLKout1
_PD
DCLKout2_DIV
DCLKout2_ADLY
CLKout4_5
_ODL
SDCLKout1_DIS_MODE
DCLKout0
_POL
DCLKout2_DDLY_CNTH
0x10B
SDCLKout1
_HS
SDCLKout1_DDLY
CLKout1_FMT
CLKout2_3
_ODL
DCLKout0_MUX
DCLKout4_MUX
SDCLKout5
_HS
SDCLKout5_DDLY
SDCLKout5_ADLY
CLKout4_5
_PD
SDCLKout5_DIS_MODE
DCLKout4
_POL
SDCLKout5
_PD
CLKout4_FMT
DCLKout6_DIV
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Register Maps (continued)
Table 11. LMK0482x Register Map (continued)
ADDRESS
[11:0]
DATA
7
0x119
6
5
0
DCLKout6
_HS
SDCLKout7
_MUX
0x11D
0
0
0
SDCLKout7
_ ADLY_EN
0x11E
DCLKout6
_ DDLY_PD
DCLKout6
_ HSg_PD
DCLKout6
_ ADLYg_PD
DCLKout6
_ADLY _PD
0x11F
SDCLKout7
_POL
0x120
0
0x121
CLKout6_7
_PD
DCLKout8_DDLY_CNTL
0
DCLKout8
_HS
SDCLKout9
_MUX
0x125
0
0
0
SDCLKout9
_ ADLY_EN
0x126
DCLKout8
_ DDLY_PD
DCLKout8
_ HSg_PD
DCLKout8
_ ADLYg_PD
DCLKout8
_ADLY _PD
0x127
SDCLKout9
_POL
0x128
0
SDCLKout9_ADLY
CLKout8_9
_PD
CLKout10
_11_IDL
SDCLKout9_DIS_MODE
CLKout8_FMT
DCLKout10_DDLY_CNTL
DCLKout10
_ ADLY_MUX
0x12C
0
DCLKout10
_HS
SDCLKout11
_MUX
0x12D
0
0
0
SDCKLout11
_ ADLY_EN
0x12E
DCLKout10
_ DDLY_PD
DCLKout10
_ HSg_PD
DLCLKout10
_ ADLYg_PD
DCLKout10
_ ADLY_PD
0x12F
SDCLKout11
_POL
0x130
0
DCLKout10_MUX
SDCLKout11
_HS
SDCLKout11_DDLY
SDCLKout11_ADLY
CLKout10
_11_PD
SDCLKout11_DIS_MODE
DCLKout10
_POL
CLKout11_FMT
CLKout12
_13_IDL
SDCLKout11
_PD
CLKout10_FMT
DCLKout12_DIV
DCLKout12_DDLY_CNTH
DCLKout12_DDLY_CNTL
DCLKout12_
ADLY_MUX
DCLKout12_ADLY
0x134
0
DCLKout12
_HS
SDCLKout13
_MUX
0x135
0
0
0
SDCLKout13
_ ADLY_EN
0x136
DCLKout12
_ DDLY_PD
DCLKout12
_ HSg_PD
DCLKout12
_ ADLYg_PD
DCLKout12
_ ADLY_PD
0x137
SDCLKout13
_POL
0x138
0
0x139
0
0
0
0x13A
0
0
0
DCLKout12_MUX
SDCLKout13
_HS
SDCLKout13_DDLY
SDCLKout13_ADLY
CLKout12
_13_PD
SDCLKout13_DIS_MODE
DCLKout12
_POL
CLKout13_FMT
0
SDCLKout13
_PD
CLKout12_FMT
OSCout
_MUX
0x13B
SDCLKout9
_PD
DCLKout10_DIV
DCLKout10_ADLY
VCO_MUX
SDCLKout9
_HS
DCLKout8
_POL
CLKout9_FMT
0x133
DCLKout8_MUX
SDCLKout9_DDLY
DCLKout10_DDLY_CNTH
0x131
SDCLKout7
_PD
CLKout6_FMT
DCLKout8
_ ADLY_MUX
0x124
CLKout12
_13 _ODL
SDCLKout7_DIS_MODE
DCLKout8_DIV
DCLKout8_ADLY
0x12B
SDCLKout7
_HS
DCLKout6
_POL
DCLKout8_DDLY_CNTH
0x129
DCLKout6_MUX
SDCLKout7_ADLY
CLKout8_9
_IDL
CLKout10
_11 _ODL
0
SDCLKout7_DDLY
CLKout7
_FMT
0x123
1
DCLKout6_
ADLY_MUX
DCLKout6_ADLY
CLKout8_9
_ODL
2
DCLKout6_DDLY_CNTL
0x11C
0x13C
3
DCLKout6_DDLY_CNTH
0x11B
58
4
OSCout_FMT
0
SYSREF_
CLKin0_MUX
SYSREF_MUX
SYSREF_DIV[12:8]
SYSREF_DIV[7:0]
0
0
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SYSREF_DDLY[12:8]
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Register Maps (continued)
Table 11. LMK0482x Register Map (continued)
ADDRESS
[11:0]
DATA
7
6
5
4
0x13D
0x13E
3
2
1
0
SYSREF_DDLY[7:0]
0
0
0
0
0
PLL1_NCLK
_MUX
0
SYSREF_PULSE_CNT
0x13F
0
0
0
PLL2_NCLK
_MUX
FB_MUX
_EN
0x140
PLL1_PD
VCO_LDO_PD
VCO_PD
OSCin_PD
SYSREF_GBL
_PD
SYSREF_PD
SYSREF
_DDLY_PD
SYSREF
_PLSR_PD
0x141
DDLYd_
SYSREF_EN
DDLYd12
_EN
DDLYd10
_EN
DDLYd7_EN
DDLYd6_EN
DDLYd4_EN
DDLYd2_EN
DDLYd0_EN
0
SYNC_PLL1
_DLD
SYNC_DIS4
FB_MUX
0x142
0
0
0x143
SYSREF_DDLY
_CLR
SYNC_1SHOT
_EN
SYNC_POL
SYNC_EN
SYNC_PLL2
_DLD
0x144
SYNC
_DISSYSREF
SYNC_DIS12
SYNC_DIS10
SYNC_DIS8
SYNC_DIS6
0x145
0
1
1
1
1
1
1
1
0x146
0
0
CLKin2_EN
CLKin1_EN
CLKin0_EN
CLKin2_TYPE
CLKin1_TYPE
CLKin0_TYPE
0x147
CLKin_SEL
_POL
0x148
0
0
CLKin_SEL0_MUX
CLKin_SEL0_TYPE
0x149
0
SDIO_RDBK
_TYPE
CLKin_SEL1_MUX
CLKin_SEL1_TYPE
0x14A
0
0
RESET_MUX
0x14B
DDLYd_STEP_CNT
CLKin_SEL_MODE
LOS_TIMEOUT
LOS_EN
0x14E
TRACK_EN
DAC_CLK_CNTR
0x151
0
0
0
HOLDOVER
_ PLL1_DET
0
0
0
0
CLKin1_R[13:8]
CLKin1_R[7:0]
0
0
CLKin2_R[13:8]
CLKin2_R[7:0]
0
0
PLL1_N[13:8]
0x15A
PLL1_N[7:0]
PLL1_WND_SIZE
0
PLL1
_CP_TRI
PLL1
_CP_POL
PLL1_CP_GAIN
0
PLL1_DLD_CNT[13:8]
0x15D
PLL1_DLD_CNT[7:0]
0
0
0x15F
PLL1_R_DLY
PLL1_N_DLY
PLL1_LD_MUX
0
0
0
PLL1_LD_TYPE
0
0x161
PLL2_R[11:8]
PLL2_R[7:0]
0x162
0x163
HOLDOVER
_EN
CLKin0_R[13:8]
0x158
0x160
HOLDOVER
_HITLESS
_SWITCH
CLKin0_R[7:0]
0x156
0x15E
HOLDOVER
_VTUNE_DET
HOLDOVER_DLD_CNT[7:0]
0x154
0x15C
HOLDOVER
_LOS _DET
HOLDOVER_DLD_CNT[13:8]
0x152
0x15B
MAN_DAC[9:8]
DAC_TRIP_HIGH
CLKin
_OVERRIDE
0x159
MAN_DAC
_EN
DAC_TRIP_LOW
DAC_CLK_MULT
0
0x157
CLKin0_OUT_MUX
RESET_TYPE
HOLDOVER
_ FORCE
0
0x150
0x155
SYNC_DIS0
MAN_DAC[7:0]
0
0x14F
0x153
SYNC_DIS2
CLKin1_OUT_MUX
0x14C
0x14D
SYNC_MODE
PLL2_P
0
PLL2
_XTAL_EN
OSCin_FREQ
0
0
0
0
0x164
PLL2_N_CAL[15:8]
0x165
PLL2_N_CAL[7:0]
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PLL2
_REF_2X_EN
PLL2_N_CAL[17:16]
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Register Maps (continued)
Table 11. LMK0482x Register Map (continued)
ADDRESS
[11:0]
0x166
DATA
7
0
6
5
0
0
0
0x167
PLL2_N[15:8]
0x168
PLL2_N[7:0]
0x169
0
0x16A
0
SYSREF_REQ_
EN
PLL2_WND_SIZE
0
0
3
2
0
PLL2_FCAL
_DIS
1
PLL2
_CP_POL
PLL2_CP_GAIN
0
PLL2_N[17:16]
PLL
2_CP_TRI
1
PLL2_DLD_CNT[15:8]
0x16B
0x16C
PLL2_DLD_CNT[7:0]
0x16D
PLL2_LF_R4
PLL2_LF_R3
PLL2_LF_C4
0x16E
PLL2_LF_C3
PLL2_LD_MUX
PLL2_LD_TYPE
0x171
1
0
1
0
1
0
1
0
0x172
0
0
0
0
0
0
1
0
0x173
0
PLL2_PRE_PD
PLL2_PD
0
0
0
0
0
0x174
0
0
0
VCO1_DIV
0x17C
OPT_REG_1
0x17D
OPT_REG_2
0x182
0
0
0
0
0
RB_PLL1_
LD_LOST
RB_PLL1_LD
CLR_PLL1_
LD_LOST
0x183
0
0
0
0
0
RB_PLL2_
LD_LOST
RB_PLL2_LD
CLR_PLL2_
LD_LOST
RB_CLKin2_
SEL
RB_CLKin1_
SEL
RB_CLKin0_
SEL
X
RB_CLKin1_
LOS
RB_CLKin0_
LOS
0
RB_
HOLDOVER
X
X
X
0x184
RB_DAC_VALUE[9:8]
0x185
0x188
60
4
RB_DAC_VALUE[7:0]
0
0
X
0x1FFD
SPI_LOCK[23:16]
0x1FFE
SPI_LOCK[15:8]
0x1FFF
SPI_LOCK[7:0]
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9.7 Device Register Descriptions
The following section details the fields of each register, the power-on reset defaults, and specific descriptions of
each bit.
In some cases, similar fields are located in multiple registers. In this case, specific outputs may be designated as
X or Y. In these cases, the X represents even numbers from 0 to 12, and the Y represents odd numbers from 1
to 13. In the case where X and Y are both used in a bit name, then Y = X + 1.
9.7.1 System Functions
9.7.1.1 RESET, SPI_3WIRE_DIS
This register contains the RESET function, and a setting to disable 3-wire SPI mode.
Table 12. Register 0x000
BIT
NAME
POR
DEFAULT
7
RESET
0
0: Normal operation
1: Reset (automatically cleared)
6:5
NA
0
Reserved
4
SPI_3WIRE_DIS
0
Disable 3-wire SPI mode. 4-wire SPI mode is enabled by selecting SPI Read back in one
of the output MUX settings. For example, CLKin0_SEL_MUX.
0: 3-wire mode enabled
1: 3-wire mode disabled
3:0
NA
NA
DESCRIPTION
Reserved
9.7.1.2 POWERDOWN
This register contains the POWERDOWN function.
Table 13. Register 0x002
BIT
NAME
POR
DEFAULT
7:1
NA
0
Reserved
0
POWERDOWN
0
0: Normal operation
1: Powerdown
DESCRIPTION
9.7.1.3 ID_DEVICE_TYPE
This register contains the product device type. This is read only register.
Table 14. Register 0x003
BIT
NAME
POR
DEFAULT
7:0
ID_DEVICE_TYPE
6
DESCRIPTION
PLL product device type
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9.7.1.4 ID_PROD[15:8], ID_PROD
These registers contain the product identifier. This is a read only register.
Table 15. ID_PROD Register Configuration, ID_PROD[15:0]
MSB
LSB
0x004[7:0]
0x005[7:0]
BIT
REGISTERS
FIELD NAME
POR
DEFAULT
7:0
0x004
ID_PROD[15:8]
208
MSB of the product identifier
7:0
0x005
ID_PROD
91
LSB of the product identifier
DESCRIPTION
9.7.1.5 ID_MASKREV
This register contains the IC version identifier. This is a read only register.
Table 16. Register 0x006
POR
DEFAULT
BIT
NAME
7:0
ID_MASKREV
DESCRIPTION
36
IC version identifier for LMK04821
37
IC version identifier for LMK04826
32
IC version identifier for LMK04828
9.7.1.6 ID_VNDR[15:8], ID_VNDR
These registers contain the vendor identifier. This is a read only register.
Table 17. ID_VNDR Register Configuration, ID_VNDR[15:0]
MSB
LSB
0x00C[7:0]
0x00D[7:0]
Table 18. Registers 0x00C, 0x00D
BIT
REGISTERS
NAME
POR
DEFAULT
7:0
0x00C
ID_VNDR[15:8]
81
MSB of the vendor identifier
7:0
0x00D
ID_VNDR
4
LSB of the vendor identifier
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DESCRIPTION
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9.7.2 (0x100 - 0x138) Device Clock and SYSREF Clock Output Controls
9.7.2.1 CLKoutX_Y_ODL, CLKoutX_Y_IDL, DCLKoutX_DIV
These registers control the input and output drive level, as well as the device clock out divider values.
Table 19. Registers 0x100, 0x108, 0x110, 0x118, 0x120, 0x128, and 0x130
BIT
NAME
POR
DEFAULT
7
NA
0
Reserved
6
CLKoutX_Y_ODL
0
Output drive level. Setting this bit increases the current to the CLKoutX_Y output buffers,
which can slightly improve noise floor.
5
CLKoutX_Y_IDL
0
Input drive level. Setting this bit increases the current to the clock distribution buffer
sourcing CLKoutX_Y, which can slightly improve noise floor.
4:0
(1)
DCLKoutX_DIV
X=0→2
X=2→4
X=4→8
X=6→8
X=8→8
X = 10 → 8
X = 12 → 2
DESCRIPTION
DCLKoutX_DIV sets the divide value for the clock output; the divide may be even or odd.
Both even or odd divides output a 50% duty cycle clock if duty cycle correction (DCC) is
selected.
Divider is unused if DCLKoutX_MUX = 2 (bypass), equivalent divide of 1.
Field Value
Divider Value
0 (0x00)
32
1 (0x01)
1
(1)
2 (0x02)
2
...
...
30 (0x1E)
30
31 (0x1F)
31
Not valid if DCLKoutX_MUX = 0, divider only. Not valid if DCLKoutX_MUX = 3 (analog delay + divider) and DCLKoutX_ADLY_MUX = 0
(without duty cycle correction/halfstep).
9.7.2.2 DCLKoutX_DDLY_CNTH, DCLKoutX_DDLY_CNTL
This register controls the digital delay high and low count values for the device clock outputs.
Table 20. Registers 0x101, 0x109, 0x111, 0x119, 0x121, 0x129, 0x131
BIT
NAME
POR
DEFAULT
DESCRIPTION
Number of clock cycles the output is high when digital delay is engaged.
Field Value
7:4
DCLKoutX
_DDLY_CNTH
5
Delay Values
0 (0x00)
16
1 (0x01)
Reserved
2 (0x02)
2
...
...
15 (0x0F)
15
Number of clock cycles the output is low when dynamic digital delay is engaged.
Field Value
3:0
DCLKoutX
_DDLY_CNTL
5
Delay Values
0 (0x00)
16
1 (0x01)
Reserved
2 (0x02)
2
...
...
15 (0x0F)
15
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9.7.2.3 DCLKoutX_ADLY, DCLKoutX_ADLY_MUX, DCLKout_MUX
These registers control the analog delay properties for the device clocks.
Table 21. Registers 0x103, 0x10B, 0x113, 0x11B, 0x123, 0x12B, 0x133
BIT
POR
DEFAULT
NAME
DESCRIPTION
Device clock analog delay value. Delay step size is 25 ps. DCLKoutX_ADLY_PD = 0
(DCLK analog delay powered up) also adds a fixed 500-ps delay. Effective range is 500 ps
to 1075 ps.
7:3
DCLKoutX_ALDY
DCLKoutX_ADLY
_MUX
2
0
Field Value
Delay Value
0 (0x00)
0 ps
1 (0x01)
25 ps
2 (0x02)
50 ps
...
...
23 (0x17)
575 ps
This register selects the input to the analog delay for the device clock. Used when
DCLKoutX_MUX = 3.
0: Divided without duty cycle correction or half step. (1)
1: Divided with duty cycle correction and half step.
0
This selects the input to the device clock buffer.
Field Value
Mux Output
0 (0x0)
1:0
(1)
DCLKoutX_MUX
0
Divider only
(1)
1 (0x1)
Divider with duty cycle Correction
and half step
2 (0x2)
Bypass
3 (0x3)
Analog delay + divider
DCLKoutX_DIV = 1 is not valid when DCLKoutX_MUX = 0. DCLKoutX_DIV = 1 is valid for DCLKoutX_MUX = 1, or DCLKoutX_MUX = 3
and DCLKoutX_ADLY_MUX = 1.
9.7.2.4 DCLKoutX_HS, SDCLKoutY_MUX, SDCLKoutY_DDLY, SDCLKoutY_HS
These registers set the half step for the device clock, the SYSREF output MUX, the SYSREF clock digital delay,
and half step.
Table 22. Registers 0x104, 0x10C, 0x114, 0x11C, 0x124, 0x12C, 0x134
BIT
NAME
POR
DEFAULT
7
NA
0
Reserved
6
DCLKoutX_HS
0
Sets the device clock half step value. Half step must be zero (0) for a divide of 1.
0: 0 cycles
1: -0.5 cycles
5
SDCLKoutY_MUX
0
Sets the input the the SDCLKoutX outputs.
0: Device clock output
1: SYSREF output
DESCRIPTION
Sets the number of VCO cycles to delay the SDCLKout by.
4:1
0
64
SDCLKoutY_DDLY
SDCLKoutY_HS
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0
0
Field Value
Delay Cycles
0 (0x00)
Bypass
1 (0x01)
2
2 (0x02)
3
...
...
10 (0x0A)
11
11 to 15 (0x0B to 0x0F)
Reserved
Sets the SYSREF clock half-step value.
0: 0 cycles
1: -0.5 cycles
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9.7.2.5 SDCLKoutY_ADLY_EN, SDCLKoutY_ADLY
These registers set the analog delay parameters for the SYSREF outputs.
Table 23. Registers 0x105, 0x10D, 0x115, 0x11D, 0x125, 0x12D, 0x135
BIT
NAME
POR
DEFAULT
7:5
NA
0
Reserved
4
SDCLKoutY
_ADLY_EN
0
Enables analog delay for the SYSREF output.
0: Disabled
1: Enabled
DESCRIPTION
Sets the analog delay value for the SYSREF output. Step size is 150 ps, except first step
(600 ps). SDCLKoutY_ADLY_EN = 1 (SDCLK analog delay enabled) also adds a fixed
700-ps delay. Effective range is 700 ps to 2950 ps.
3:0
SDCLKoutY
_ADLY
0
Field Value
Delay Value
0 (0x0)
0 ps
1 (0x1)
600 ps
2 (0x2)
750 ps (+150 ps from 0x1)
3 (0x3)
900 ps (+150 ps from 0x2)
...
...
14 (0xE)
2100 ps (+150 ps from 0xD)
15 (0xF)
2250 ps (+150 ps from 0xE)
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9.7.2.6 DCLKoutX_DDLY_PD, DCLKoutX_HSg_PD, DCLKout_ADLYg_PD, DCLKout_ADLY_PD,
DCLKoutX_Y_PD, SDCLKoutY_DIS_MODE, SDCLKoutY_PD
This register controls the power-down functions for the digital delay, glitchless half step, glitchless analog delay,
analog delay, outputs, and SYSREF disable modes.
Table 24. Registers 0x106, 0x10E, 0x116, 0x11E, 0x126, 0x12E, 0x136
BIT
NAME
POR DEFAULT
DESCRIPTION
7
DCLKoutX
_DDLY_PD
0
Powerdown the device clock digital delay circuitry.
0: Enabled
1: Powerdown
6
DCLKoutX
_HSg_PD
1
Powerdown the device clock glitchless half-step feature.
0: Enabled
1: Powerdown
5
DCLKoutX
_ADLYg_PD
1
Powerdown the device clock glitchless analog delay feature.
0: Enabled, analog delay step size of one code is glitchless between values 1 to 23.
1: Powerdown
4
DCLKoutX
_ADLY_PD
1
Powerdown the device clock analog delay feature.
0: Enabled
1: Powerdown
CLKoutX_Y_PD
X_Y = 0_1 → 1
X_Y = 2_3 → 1
X_Y = 4_5 → 0
X_Y = 6_7 → 0
X_Y = 8_9 → 0
X_Y = 10_11 → 0
X_Y = 12_13 → 1
3
Powerdown the clock group defined by X and Y.
0: Enabled
1: Powerdown
Configures the output state of the SYSREF
Field Value
2:1
0
(1)
66
SDCLKoutY
_DIS_MODE
SDCLKoutY_PD
0
1
Disable Mode
0 (0x00)
Active in normal operation
1 (0x01)
If SYSREF_GBL_PD = 1, the output is a
logic low, otherwise it is active.
2 (0x02)
If SYSREF_GBL_PD = 1, the output is a
nominal Vcm voltage (1), otherwise it is
active.
3 (0x03)
Output is a nominal Vcm voltage (1)
Powerdown SDCLKoutY and set to the state defined by SDCLKoutY_DIS_MODE
If LVPECL mode is used with emitter resistors to ground, the output Vcm is ~0 V, and each pin is ~0 V.
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9.7.2.7 SDCLKoutY_POL, SDCLKoutY_FMT, DCLKoutX_POL, DCLKoutX_FMT
These registers configure the output polarity, and format.
Table 25. Registers 0x107, 0x10F, 0x117, 0x11F, 0x127, 0x12F, 0x137
BIT
7
NAME
SDCLKoutY_POL
POR
DEFAULT
DESCRIPTION
Sets the polarity of clock on SDCLKoutY when device clock output is selected with
SDCLKoutY_MUX.
0: Normal
1: Inverted
0
Sets the output format of the SYSREF clocks
6:4
3
SDCLKoutY_FMT
DCLKoutX_POL
0
Field Value
Output Format
0 (0x00)
Powerdown
1 (0x01)
LVDS
2 (0x02)
HSDS 6 mA
3 (0x03)
HSDS 8 mA
4 (0x04)
HSDS 10 mA
5 (0x05)
LVPECL 1600 mV
6 (0x06)
LVPECL 2000 mV
7 (0x07)
LCPECL
Sets the polarity of the device clocks from the DCLKoutX outputs
0: Normal
1: Inverted
0
Sets the output format of the device clocks.
2:0
DCLKoutX_FMT
LMK04821: 0
LMK04826/
LMK04828:
X=0→0
X=2→0
X=4→1
X=6→1
X=8→1
X = 10 → 1
X = 12 → 0
Field Value
Output Format
0 (0x00)
Powerdown
1 (0x01)
LVDS
2 (0x02)
HSDS 6 mA
3 (0x03)
HSDS 8 mA
4 (0x04)
HSDS 10 mA
5 (0x05)
LVPECL 1600 mV
6 (0x06)
LVPECL 2000 mV
7 (0x07)
LCPECL
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9.7.3 SYSREF, SYNC, and Device Config
9.7.3.1 VCO_MUX, OSCout_MUX, OSCout_FMT
This register selects the clock distribution source, and OSCout parameters.
Table 26. Register 0x138
BIT
NAME
POR
DEFAULT
7
NA
0
DESCRIPTION
Reserved
Selects clock distribution path source from VCO0, VCO1, or CLKin (external VCO)
6:5
4
VCO_MUX
OSCout_MUX
0
0
Field Value
VCO Selected
0 (0x00)
VCO 0
1 (0x01)
VCO 1
2 (0x02)
CLKin1 (external VCO)
3 (0x03)
Reserved
Select the source for OSCout:
0: Buffered OSCin
1: Feedback mux
Selects the output format of OSCout. When powered down, these pins may be used as
CLKin2.
3:0
(1)
68
OSCout_FMT
4
Field Value
OSCout Format
0 (0x00)
Powerdown (CLKin2)
1 (0x01)
LVDS
2 (0x02)
Reserved
3 (0x03)
Reserved
4 (0x04)
LVPECL 1600 mVpp (1)
5 (0x05)
LVPECL 2000 mVpp (1)
6 (0x06)
LVCMOS (Norm / Inv)
7 (0x07)
LVCMOS (Inv / Norm)
8 (0x08)
LVCMOS (Norm / Norm)
9 (0x09)
LVCMOS (Inv / Inv)
10 (0x0A)
LVCMOS (Off / Norm)
11 (0x0B)
LVCMOS (Off / Inv)
12 (0x0C)
LVCMOS (Norm / Off)
13 (0x0D)
LVCMOS (Inv / Off)
14 (0x0E)
LVCMOS (Off / Off)
When set to an LVPECL drive format, OSCout emitter resistors must be 240 Ω to GND.
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9.7.3.2 SYSREF_CLKin0_MUX, SYSREF_MUX
This register sets the source for the SYSREF outputs. Refer to Figure 13 and SYNC/SYSREF.
Table 27. Register 0x139
BIT
NAME
POR
DEFAULT
7:3
NA
0
DESCRIPTION
Reserved
Selects the SYSREF output from SYSREF_MUX or CLKin0 direct
2
SYSREF_
CLKin0_MUX
Field Value
0
SYSREF Source
0
SYSREF Mux
1
CLKin0 direct (from CLKin0_OUT_MUX)
Selects the SYSREF source.
1:0
SYSREF_MUX
0
Field Value
SYSREF Source
0 (0x00)
Normal SYNC
1 (0x01)
Re-clocked
2 (0x02)
SYSREF pulser
3 (0x03)
SYSREF continuous
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9.7.3.3 SYSREF_DIV[12:8], SYSREF_DIV[7:0]
These registers set the value of the SYSREF output divider.
Table 28. Registers 0x13A, 0x13B
MSB
LSB
0x13A[4:0]
0x13B[7:0]
BIT
REGISTERS
NAME
POR
DEFAULT
7:5
0x13A
NA
0
DESCRIPTION
Reserved
Divide value for the SYSREF outputs.
4:0
7:0
0x13A
SYSREF_DIV[12:8]
0x13B
SYSREF_DIV[7:0]
12
0
Field Value
Divide Value
0x00 to 0x07
Reserved
8 (0x08)
8
9 (0x09)
9
...
...
8190 (0x1FFE)
8190
8191 (0X1FFF)
8191
9.7.3.4 SYSREF_DDLY[12:8], SYSREF_DDLY[7:0]
These registers set the delay of the SYSREF digital delay value.
Table 29. SYSREF Digital Delay Register Configuration, SYSREF_DDLY[12:0]
MSB
LSB
0x13C[4:0]
0x13D[7:0]
BIT
REGISTERS
NAME
POR
DEFAULT
7:5
0x13C
NA
0
DESCRIPTION
Reserved
Sets the value of the SYSREF digital delay.
4:0
7:0
70
0x13C
0x13D
SYSREF_DDLY[12:8]
SYSREF_DDLY[7:0]
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0
8
Field Value
Delay Value
0x00 to 0x07
Reserved
8 (0x08)
8
9 (0x09)
9
...
...
8190 (0x1FFE)
8190
8191 (0X1FFF)
8191
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9.7.3.5 SYSREF_PULSE_CNT
This register sets the number of SYSREF pulses if SYSREF is not in continuous mode. See
SYSREF_CLKin0_MUX, SYSREF_MUX for further description of SYSREF's outputs.
Programming the register causes the specified number of pulses to be output if "SYSREF Pulses" is selected by
SYSREF_MUX and SYSREF functionality is powered up.
Table 30. Register 0x13E
BIT
NAME
POR
DEFAULT
7:2
NA
0
DESCRIPTION
Reserved
Sets the number of SYSREF pulses generated when not in continuous mode.
See SYSREF_CLKin0_MUX, SYSREF_MUX for more information on SYSREF modes.
Field Value
1:0
SYSREF_PULSE_CNT
3
Number of Pulses
0 (0x00)
1 pulse
1 (0x01)
2 pulses
2 (0x02)
4 pulses
3 (0x03)
8 pulses
9.7.3.6 PLL2_NCLK_MUX, PLL1_NCLK_MUX, FB_MUX, FB_MUX_EN
This register controls the feedback feature.
Table 31. Register 0x13F
BIT
NAME
POR
DEFAULT
7:5
NA
0
Reserved
4
PLL2_NCLK_MUX
0
Selects the input to the PLL2 N divider
0: PLL prescaler
1: Feedback mux
3
PLL1_NCLK_MUX
0
Selects the input to the PLL1 N delay
0: OSCin
1: Feedback mux
DESCRIPTION
When in zero-delay mode, the feedback mux selects the clock output to be fed back into
the PLL1 N divider.
2:1
0
FB_MUX
FB_MUX_EN
0
0
Field Value
Source
0 (0x00)
DCLKout6
1 (0x01)
DCLKout8
2 (0x02)
SYSREF Divider
3 (0x03)
External
When using zero-delay, FB_MUX_EN must be set to 1 to power up the feedback mux.
0: Feedback mux powered down
1: Feedback mux enabled
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9.7.3.7 PLL1_PD, VCO_LDO_PD, VCO_PD, OSCin_PD, SYSREF_GBL_PD, SYSREF_PD,
SYSREF_DDLY_PD, SYSREF_PLSR_PD
This register contains powerdown controls for OSCin and SYSREF functions.
Table 32. Register 0x140
BIT
NAME
POR
DEFAULT
7
PLL1_PD
0
Powerdown PLL1
0: Normal operation
1: Powerdown
6
VCO_LDO_PD
0
Powerdown VCO_LDO
0: Normal operation
1: Powerdown
5
VCO_PD
0
Powerdown VCO
0: Normal operation
1: Powerdown
4
OSCin_PD
0
Powerdown the OSCin port.
0: Normal operation
1: Powerdown
0
Powerdown individual SYSREF outputs depending on the setting of
SDCLKoutY_DIS_MODE for each SYSREF output. SYSREF_GBL_PD allows many
SYSREF outputs to be controlled through a single bit.
0: Normal operation
1: Activate powerdown mode
1
Powerdown the SYSREF circuitry and divider. If powered down, SYSREF output mode
cannot be used. SYNC cannot be provided either.
0: SYSREF can be used as programmed by individual SYSREF output registers.
1: Powerdown
3
2
SYSREF_GBL_PD
SYSREF_PD
DESCRIPTION
1
SYSREF_DDLY_PD
1
Powerdown the SYSREF digital delay circuitry.
0: Normal operation, SYSREF digital delay may be used. Must be powered up during
SYNC for deterministic phase relationship with other clocks.
1: Powerdown
0
SYSREF_PLSR_PD
1
Powerdown the SYSREF pulse generator.
0: Normal operation
1: Powerdown
9.7.3.8 DDLYdSYSREF_EN, DDLYdX_EN
This register enables dynamic digital delay for enabled device clocks and SYSREF when DDLYd_STEP_CNT is
programmed.
Table 33. Register 0x141
BIT
NAME
POR DEFAULT
7
DDLYd _SYSREF_EN
0
Enables dynamic digital delay on SYSREF outputs
6
DDLYd12_EN
0
Enables dynamic digital delay on DCLKout12
5
DDLYd10_EN
0
Enables dynamic digital delay on DCLKout10
4
DDLYd8_EN
0
Enables dynamic digital delay on DCLKout8
3
DDLYd6_EN
0
Enables dynamic digital delay on DCLKout6
2
DDLYd4_EN
0
Enables dynamic digital delay on DCLKout4
1
DDLYd2_EN
0
Enables dynamic digital delay on DCLKout2
0
DDLYd0_EN
0
Enables dynamic digital delay on DCLKout0
72
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DESCRIPTION
0: Disabled
1: Enabled
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9.7.3.9 DDLYd_STEP_CNT
This register sets the number of dynamic digital delay adjustments occur. Upon programming, the dynamic digital
delay adjustment begins for each clock output with dynamic digital delay enabled. Dynamic digital delay can only
be started by SPI.
Other registers must be set: SYNC_MODE = 3
Table 34. Register 0x142
BIT
NAME
POR
DEFAULT
7:4
NA
0
DESCRIPTION
Reserved
Sets the number of dynamic digital delay adjustments that occur.
3:0
DDLYd_STEP_CNT
0
Field Value
SYNC Generation
0 (0x00)
No adjust
1 (0x01)
1 step
2 (0x02)
2 steps
3 (0x03)
3 steps
...
...
14 (0x0E)
14 steps
15 (0x0F)
15 steps
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9.7.3.10 SYSREF_CLR, SYNC_1SHOT_EN, SYNC_POL, SYNC_EN, SYNC_PLL2_DLD, SYNC_PLL1_DLD,
SYNC_MODE
This register sets general SYNC parameters such as polarization, and mode. Refer to Figure 13 for block
diagram. Refer to Table 1 for using SYNC_MODE for specific SYNC use cases.
Table 35. Register 0x143
BIT
7
NAME
SYSREF_CLR
POR
DEFAULT
DESCRIPTION
1
Resets and arms the SDCLKoutY_DDLY path, allowing local digital delays to take effect
after a SYNC event. Except during the SYSREF setup procedure (see SYNC/SYSREF), this
bit should always be programmed to 0. While this bit is set, extra current is used. Refer to
Table 87.
6
SYNC_1SHOT_EN
0
SYNC one shot enables edge-sensitive SYNC.
0: SYNC is level sensitive and outputs are held in SYNC while SYNC is asserted.
1: SYNC is edge sensitive, outputs are SYNCed on rising edge of SYNC. This results in the
clock being held in SYNC for a minimum amount of time.
5
SYNC_POL
0
Sets the polarity of the SYNC pin.
0: Normal
1: Inverted
4
SYNC_EN
1
Enables the SYNC functionality.
0: Disabled
1: Enabled
3
SYNC_PLL2_DLD
0
0: Off
1: Assert SYNC until PLL2 DLD = 1
2
SYNC_PLL1_DLD
0
0: Off
1: Assert SYNC until PLL1 DLD = 1
Sets the method of generating a SYNC event.
Field Value
1:0
74
SYNC_MODE
1
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SYNC Generation
0 (0x00)
Prevents SYNC pin, SYNC_PLL1_DLD flag, or
SYNC_PLL2_DLD flag from generating a SYNC event.
1 (0x01)
SYNC event generated from SYNC pin or, if enabled, the
SYNC_PLL1_DLD flag or SYNC_PLL2_DLD flag.
2 (0x02)
For use with pulser – SYNC/SYSREF pulses are generated by
pulser block through the SYNC pin or, if enabled, the
SYNC_PLL1_DLD flag or SYNC_PLL2_DLD flag.
3 (0x03)
For use with pulser – SYNC/SYSREF pulses are generated by
pulser block when programming register 0x13E
(SYSREF_PULSE_CNT) is written to (see SYSREF Pulser).
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9.7.3.11 SYNC_DISSYSREF, SYNC_DISX
SYNC_DISX prevents a clock output from being synchronized or interrupted by a SYNC event, or when
outputting SYSREF.
Table 36. Register 0x144
BIT
NAME
POR
DEFAULT
7
SYNC_DISSYSREF
0
6
SYNC_DIS12
0
5
SYNC_DIS10
0
4
SYNC_DIS8
0
3
SYNC_DIS6
0
2
SYNC_DIS4
0
1
SYNC_DIS2
0
0
SYNC_DIS0
0
DESCRIPTION
Prevents the SYSREF clocks from becoming synchronized during a SYNC event. If
SYNC_DISSYSREF is enabled, it continues to operate normally during a SYNC event.
Prevents the device clock output from becoming synchronized during a SYNC event or
SYSREF clock. If SYNC_DIS bit for a particular output is enabled, then it continues to
operate normally during a SYNC event or SYSREF clock.
9.7.3.12 Fixed Registers (0x145, 0x171 - 0x172)
Always program this register to value 127.
Table 37. Register 0x145
BIT
NAME
POR
DEFAULT
7:0
Fixed Register
0
DESCRIPTION
Always program to 127
Always program this register to value 170.
Table 38. Register 0x171
BIT
NAME
POR
DEFAULT
7:0
Fixed Register
10 (0x0A)
DESCRIPTION
Always program to 170 (0xAA)
Always program this register to value 2.
Table 39. Register 0x172
BIT
NAME
POR
DEFAULT
7:0
Fixed Register
0
DESCRIPTION
Always program to 2 (0x02)
9.7.4 (0x146 - 0x149) CLKin Control
9.7.4.1 CLKin2_EN, CLKin1_EN, CLKin0_EN, CLKin2_TYPE, CLKin1_TYPE, CLKin0_TYPE
This register has CLKin enable and type controls.
Table 40. Register 0x146
BIT
NAME
POR
DEFAULT
7:6
NA
0
Reserved
5
CLKin2_EN
0
Enable CLKin2 to be used during auto-switching of CLKin_SEL_MODE.
0: Not enabled for auto mode
1: Enabled for auto mode
4
CLKin1_EN
1
Enable CLKin1 to be used during auto-switching of CLKin_SEL_MODE.
0: Not enabled for auto mode
1: Enabled for auto mode
DESCRIPTION
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Table 40. Register 0x146 (continued)
BIT
NAME
POR
DEFAULT
3
CLKin0_EN
1
2
CLKin2_TYPE
0
1
CLKin1_TYPE
0
DESCRIPTION
Enable CLKin0 to be used during auto-switching of CLKin_SEL_MODE.
0: Not enabled for auto mode
1: Enabled for auto mode
0: Bipolar
1: MOS
0
CLKin0_TYPE
0
There are two buffer types for CLKin0, 1, and 2: bipolar and CMOS.
Bipolar is recommended for differential inputs such as LVDS or
LVPECL. CMOS is recommended for DC-coupled single-ended
inputs.
When using bipolar, CLKinX and CLKinX* must be AC coupled.
When using CMOS, CLKinX and CLKinX* may be AC or DC coupled
if the input signal is differential. If the input signal is single-ended, the
used input may be either AC or DC coupled, and the unused input
must AC grounded (see Driving CLKin and OSCin Pins With a SingleEnded Source).
9.7.4.2 CLKin_SEL_POL, CLKin_SEL_MODE, CLKin1_OUT_MUX, CLKin0_OUT_MUX
Table 41. Register 0x147
BIT
NAME
POR
DEFAULT
7
CLKin_SEL_POL
0
DESCRIPTION
Inverts the CLKin polarity for use in pin select mode.
0: Active high
1: Active low
Sets the mode used in determining the reference for PLL1.
6:4
CLKin_SEL_MODE
3
Field Value
CLKin Mode
0 (0x00)
CLKin0 manual
1 (0x01)
CLKin1 manual
2 (0x02)
CLKin2 manual
3 (0x03)
Pin select mode
4 (0x04)
Auto mode
5 (0x05)
Reserved
6 (0x06)
Reserved
7 (0x07)
Reserved
Selects where the output of the CLKin1 buffer is directed.
3:2
CLKin1_OUT_MUX
2
Field Value
CLKin1 Destination
0 (0x00)
Fin
1 (0x01)
Feedback mux (zero-delay mode)
2 (0x02)
PLL1
3 (0x03)
Off
Selects where the output of the CLKin0 buffer is directed.
1:0
76
CLKin0_OUT_MUX
2
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Field Value
CLKin0 Destination
0 (0x00)
SYSREF mux
1 (0x01)
Reserved
2 (0x02)
PLL1
3 (0x03)
Off
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9.7.4.3 CLKin_SEL0_MUX, CLKin_SEL0_TYPE
This register has CLKin_SEL0 controls.
Table 42. Register 0x148
BIT
NAME
POR
DEFAULT
7:6
NA
0
DESCRIPTION
Reserved
This set the output value of the CLKin_SEL0 pin. This register only applies if
CLKin_SEL0_TYPE is set to an output mode
5:3
CLKin_SEL0_MUX
0
Field Value
Output Format
0 (0x00)
Logic low
1 (0x01)
CLKin0 LOS
2 (0x02)
CLKin0 selected
3 (0x03)
DAC locked
4 (0x04)
DAC low
5 (0x05)
DAC high
6 (0x06)
SPI readback
7 (0x07)
Reserved
This sets the I/O type of the CLKin_SEL0 pin.
2:0
CLKin_SEL0_TYPE
2
Field Value
Configuration
Function
0 (0x00)
Input
Input mode, see Input
Clock Switching - Pin
Select Mode for
description of input mode.
1 (0x01)
Input with pull-up resistor
2 (0x02)
Input with pull-down resistor
3 (0x03)
Output (push-pull)
4 (0x04)
Output inverted (push-pull)
5 (0x05)
Reserved
6 (0x06)
Output (open drain)
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Output modes; the
CLKin_SEL0_MUX
register for description of
outputs.
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9.7.4.4 SDIO_RDBK_TYPE, CLKin_SEL1_MUX, CLKin_SEL1_TYPE
This register has CLKin_SEL1 controls and register readback SDIO pin type.
Table 43. Register 0x149
BIT
NAME
POR
DEFAULT
7
NA
0
Reserved
6
SDIO_RDBK_TYPE
1
Sets the SDIO pin to open drain when during SPI readback in 3-wire mode.
0: Output, push-pull
1: Output, open drain.
DESCRIPTION
This set the output value of the CLKin_SEL1 pin. This register only applies if
CLKin_SEL1_TYPE is set to an output mode.
Field Value
5:3
CLKin_SEL1_MUX
0
Output Format
0 (0x00)
Logic low
1 (0x01)
CLKin1 LOS
2 (0x02)
CLKin1 selected
3 (0x03)
DAC locked
4 (0x04)
DAC low
5 (0x05)
DAC high
6 (0x06)
SPI readback
7 (0x07)
Reserved
This sets the I/O type of the CLKin_SEL1 pin.
2:0
78
CLKin_SEL1_TYPE
2
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Field Value
Configuration
0 (0x00)
Input
1 (0x01)
Input with pull-up resistor
2 (0x02)
Input with pull-down resistor
3 (0x03)
Output (push-pull)
4 (0x04)
Output inverted (push-pull)
5 (0x05)
Reserved
6 (0x06)
Output (open drain)
Function
Input mode, see Input Clock
Switching - Pin Select Mode for
description of input mode.
Output modes; see the
CLKin_SEL1_MUX register for
description of outputs.
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9.7.5 RESET_MUX, RESET_TYPE
This register contains control of the RESET pin.
Table 44. Register 0x14A
BIT
NAME
POR
DEFAUL
T
7:6
NA
0
DESCRIPTION
Reserved
This sets the output value of the RESET pin. This register only applies if RESET_TYPE is set to an
output mode.
Field Value
5:3
RESET_MUX
0
Output Format
0 (0x00)
Logic low
1 (0x01)
Reserved
2 (0x02)
CLKin2 selected
3 (0x03)
DAC locked
4 (0x04)
DAC low
5 (0x05)
DAC high
6 (0x06)
SPI readback
This sets the I/O type of the RESET pin.
2:0
RESET_TYPE
2
Field Value
Configuration
0 (0x00)
Input
Function
1 (0x01)
Input with pull-up resistor
2 (0x02)
Input with pull-down resistor
Reset mode
Reset pin high = reset
3 (0x03)
Output (push-pull)
4 (0x04)
Output inverted (push-pull)
5 (0x05)
Reserved
6 (0x06)
Output (open drain)
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Output modes; see the
RESET_MUX register for
description of outputs.
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9.7.6 (0x14B - 0x152) Holdover
9.7.6.1 LOS_TIMEOUT, LOS_EN, TRACK_EN, HOLDOVER_FORCE, MAN_DAC_EN, MAN_DAC[9:8]
This register contains the holdover functions.
Table 45. Register 0x14B
BIT
NAME
POR
DEFAULT
DESCRIPTION
This controls the amount of time in which no activity on a CLKin forces a clock switch
event.
7:6
5
LOS_TIMEOUT
LOS_EN
0
Field Value
Timeout
0 (0x00)
370 kHz (2.7 µs)
1 (0x01)
2.1 MHz (480 ns)
2 (0x02)
8.8 MHz (115 ns)
3 (0x03)
22 MHz (45 ns)
0
Enables the LOS (loss-of-signal) timeout control. Valid only for MOS clock inputs. To
ensure LOS is valid for AC-coupled inputs, no termination is allowed between CLKinX and
CLKinX* pins unless DC-blocked. For example, 100-Ω termination across CLKin0 and
CLKin0* pins on the IC side of AC coupling capacitors would invalidate the LOS detector. If
termination is required, it should be placed on the other side of the AC coupling capacitors,
away from the IC pins.
0: Disabled
1: Enabled
1
Enable the DAC to track the PLL1 tuning voltage, optionally for use in holdover mode. After
device reset, tracking starts at DAC code = 512 (midrange).
Tracking can be used to monitor PLL1 voltage in any mode.
0: Disabled
1: Enabled, only tracks when PLL1 is locked.
4
TRACK_EN
3
HOLDOVER
_FORCE
0
This bit forces holdover mode. When holdover mode is forced, if MAN_DAC_EN = 1, then
the DAC sets the programmed MAN_DAC value. Otherwise the tracked DAC value sets the
DAC voltage.
0: Disabled
1: Enabled
2
MAN_DAC_EN
1
This bit enables the manual DAC mode.
0: Automatic
1: Manual
1:0
MAN_DAC[9:8]
2
See MAN_DAC[9:8], MAN_DAC[7:0] for more information on the MAN_DAC settings.
80
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9.7.6.2 MAN_DAC[9:8], MAN_DAC[7:0]
These registers set the value of the DAC in holdover mode when used manually.
Table 46. MAN_DAC[9:0]
BIT
REGISTERS
7:2
0x14B
MSB
LSB
0x14B[1:0]
0x14C[7:0]
POR
DEFAULT
NAME
DESCRIPTION
See LOS_TIMEOUT, LOS_EN, TRACK_EN, HOLDOVER_FORCE,
MAN_DAC_EN, MAN_DAC[9:8] for information on these bits.
Sets the value of the manual DAC when in manual DAC mode.
1:0
7:0
0x14B
0x14C
MAN_DAC[9:8]
2
MAN_DAC[7:0]
0
Field Value
DAC Value
0 (0x00)
0
1 (0x01)
1
2 (0x02)
2
...
...
1022 (0x3FE)
1022
1023 (0x3FF)
1023
9.7.6.3 DAC_TRIP_LOW
This register contains the high value at which holdover mode is entered.
Table 47. Register 0x14D
BIT
NAME
POR
DEFAULT
7:6
NA
0
DESCRIPTION
Reserved
Voltage from GND at which holdover is entered if HOLDOVER_VTUNE_DET is enabled.
5:0
DAC_TRIP_LOW
0
Field Value
DAC Trip Value
0 (0x00)
1 x Vcc / 64
1 (0x01)
2 x Vcc / 64
2 (0x02)
3 x Vcc / 64
3 (0x03)
4 x Vcc / 64
...
...
61 (0x17)
62 x Vcc / 64
62 (0x18)
63 x Vcc / 64
63 (0x19)
64 x Vcc / 64
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9.7.6.4 DAC_CLK_MULT, DAC_TRIP_HIGH
This register contains the multiplier for the DAC clock counter, and the low value at which holdover mode is
entered.
Table 48. Register 0x14E
BIT
NAME
POR
DEFAULT
DESCRIPTION
This is the multiplier for the DAC_CLK_CNTR which sets the rate at which the DAC value is
tracked.
Field Value
7:6
DAC_CLK_MULT
0
DAC Multiplier Value
0 (0x00)
4
1 (0x01)
64
2 (0x02)
1024
3 (0x03)
16384
Voltage from Vcc at which holdover is entered if HOLDOVER_VTUNE_DET is enabled.
5:0
DAC_TRIP_HIGH
9.7.6.5
0
Field Value
DAC Trip Value
0 (0x00)
1 x Vcc / 64
1 (0x01)
2 x Vcc / 64
2 (0x02)
3 x Vcc / 64
3 (0x03)
4 x Vcc / 64
...
...
61 (0x17)
62 x Vcc / 64
62 (0x18)
63 x Vcc / 64
63 (0x19)
64 x Vcc / 64
DAC_CLK_CNTR
This register contains the value of the DAC when in tracked mode.
Table 49. Register 0x14F
BIT
NAME
POR
DEFAULT
DESCRIPTION
This with DAC_CLK_MULT set the rate at which the DAC is updated. The update rate (in
seconds) is = DAC_CLK_MULT * DAC_CLK_CNTR / PLL1 PDF (Hz)
7:0
82
DAC_CLK_CNTR
127
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Field Value
DAC Value
0 (0x00)
0
1 (0x01)
1
2 (0x02)
2
3 (0x03)
3
...
...
253 (0xFD)
253
254 (0xFE)
254
255 (0xFF)
255
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9.7.6.6 CLKin_OVERRIDE, HOLDOVER_PLL1_DET, HOLDOVER_LOS_DET, HOLDOVER_VTUNE_DET,
HOLDOVER_HITLESS_SWITCH, HOLDOVER_EN
This register has controls for enabling clock in switch events.
Table 50. Register 0x150
BIT
NAME
POR
DEFAULT
7
NA
0
Reserved
6
CLKin
_OVERRIDE
0
When CLKin_SEL_MODE = 0/1/2 to select a manual clock input, CLKin_OVERRIDE = 1
forces that clock input. Used with clock distribution mode for best performance.
0: Normal, no override.
1: Force select of only CLKin0/1/2, as specified by CLKin_SEL_MODE in manual mode.
5
NA
0
Reserved
4
HOLDOVER
_PLL1_DET
0
This enables the HOLDOVER when PLL1 lock detect signal transitions from high to low.
0: PLL1 DLD does not cause a clock switch event
1: PLL1 DLD causes a clock switch event
3
HOLDOVER
_LOS_DET
0
This enables HOLDOVER when PLL1 LOS signal is detected.
0: Disabled
1: Enabled
2
HOLDOVER
_VTUNE_DET
0
Enables the DAC Vtune rail detections. When the DAC achieves a specified Vtune, if this
bit is enabled, the current clock input is considered invalid and an input clock switch event
is generated.
0: Disabled
1: Enabled
1
HOLDOVER
_HITLESS
_SWITCH
1
Determines whether a clock switch event will enter holdover use hitless switching.
0: Hard Switch
1: Hitless switching (has an undefined switch time)
0
HOLDOVER_EN
1
Sets whether holdover mode can be entered when holdover conditions are met.
0: Disabled
1: Enabled
DESCRIPTION
9.7.6.7 HOLDOVER_DLD_CNT[13:8], HOLDOVER_DLD_CNT[7:0]
Table 51. HOLDOVER_DLD_CNT[13:0]
MSB
LSB
0x151[5:0]
0x152[7:0]
This register has the number of valid clocks of PLL1 PDF before holdover is exited.
Table 52. Registers 0x151 and 0x152
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x151
NA
0
DESCRIPTION
Reserved
The number of valid clocks of PLL1 PDF before holdover mode is exited.
5:0
7:0
0x151
0x152
HOLDOVER
_DLD_CNT[13:8]
HOLDOVER
_DLD_CNT[7:0]
2
0
Field Value
Count Value
0 (0x00)
0
1 (0x01)
1
2 (0x02)
2
...
...
16382 (0x3FFE)
16382
16383 (0x3FFF)
16383
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9.7.7 (0x153 - 0x15F) PLL1 Configuration
9.7.7.1 CLKin0_R[13:8], CLKin0_R[7:0]
Table 53. CLKin0_R[13:0]
MSB
LSB
0x153[5:0]
0x154[7:0]
These registers contain the value of the CLKin0 divider.
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x153
NA
0
DESCRIPTION
Reserved
The value of PLL1 R divider when CLKin0 is selected.
5:0
7:0
0x153
0x154
CLKin0_R[13:8]
CLKin0_R[7:0]
0
120
Field Value
Divide Value
0 (0x00)
Reserved
1 (0x01)
1
2 (0x02)
2
...
...
16382 (0x3FFE)
16382
16383 (0x3FFF)
16383
9.7.7.2 CLKin1_R[13:8], CLKin1_R[7:0]
Table 54. CLKin1_R[13:0]
MSB
LSB
0x155[5:0]
0x156[7:0]
These registers contain the value of the CLKin1 R divider.
Table 55. Registers 0x155 and 0x156
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x155
NA
0
DESCRIPTION
Reserved
The value of PLL1 R divider when CLKin1 is selected.
5:0
7:0
84
0x155
0x156
CLKin1_R[13:8]
CLKin1_R[7:0]
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0
150
Field Value
Divide Value
0 (0x00)
Reserved
1 (0x01)
1
2 (0x02)
2
...
...
16382 (0x3FFE)
16382
16383 (0x3FFF)
16383
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9.7.7.3 CLKin2_R[13:8], CLKin2_R[7:0]
MSB
LSB
0x157[5:0]
0x158[7:0]
These registers contain the value of the CLKin2 R divider.
Table 56. Registers 0x157 and 0x158
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x157
NA
0
DESCRIPTION
Reserved
The value of PLL1 R divider when CLKin2 is selected.
5:0
7:0
0x157
0x158
CLKin2_R[13:8]
CLKin2_R[7:0]
0
150
Field Value
Divide Value
0 (0x00)
Reserved
1 (0x01)
1
2 (0x02)
2
...
...
16382 (0x3FFE)
16382
16383 (0x3FFF)
16383
9.7.7.4 PLL1_N
Table 57. PLL1_N[13:8], PLL1_N[7:0]
PLL1_N[13:0]
MSB
LSB
0x159[5:0]
0x15A[7:0]
These registers contain the N divider value for PLL1.
Table 58. Registers 0x159 and 0x15A
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x159
NA
0
DESCRIPTION
Reserved
The value of PLL1 N divider.
5:0
7:0
0x159
0x15A
PLL1_N[13:8]
PLL1_N[7:0]
0
120
Field Value
Divide Value
0 (0x00)
Not valid
1 (0x01)
1
2 (0x02)
2
...
...
16,383 (0x3FFF)
16,383
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9.7.7.5 PLL1_WND_SIZE, PLL1_CP_TRI, PLL1_CP_POL, PLL1_CP_GAIN
This register controls the PLL1 phase detector.
Table 59. Register 0x15B
BIT
NAME
POR
DEFAULT
DESCRIPTION
PLL1_WND_SIZE sets the window size used for digital lock detect for PLL1. If the phase
error between the reference and feedback of PLL1 is less than specified time, the PLL1
lock counter increments.
7:6
5
4
PLL1_WND_SIZE
PLL1_CP_TRI
PLL1_CP_POL
3
Field Value
Definition
0 (0x00)
4 ns
1 (0x01)
9 ns
2 (0x02)
19 ns
3 (0x03)
43 ns
0
This bit allows for the PLL1 charge pump output pin, CPout1, to be placed into TRI-STATE.
0: PLL1 CPout1 is active
1: PLL1 CPout1 is at TRI-STATE
1
PLL1_CP_POL sets the charge pump polarity for PLL1. Many VCXOs use positive slope.
A positive-slope VCXO increases output frequency with increasing voltage. A negativeslope VCXO decreases output frequency with increasing voltage.
0: Negative-slope VCO/VCXO
1: Positive-slope VCO/VCXO
This bit programs the PLL1 charge pump output current level.
3:0
86
PLL1_CP_GAIN
4
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Field Value
Gain
0 (0x00)
50 µA
1 (0x01)
150 µA
2 (0x02)
250 µA
3 (0x03)
350 µA
4 (0x04)
450 µA
...
...
14 (0x0E)
1450 µA
15 (0x0F)
1550 µA
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9.7.7.6 PLL1_DLD_CNT[13:8], PLL1_DLD_CNT[7:0]
Table 60. PLL1_DLD_CNT[13:0]
MSB
LSB
0x15C[5:0]
0x15D[7:0]
This register contains the value of the PLL1 DLD counter.
Table 61. Registers 0x15C and 0x15D
BIT
REGISTERS
NAME
POR DEFAULT
7:6
0x15C
NA
0
5:0
7:0
0x15C
0x15D
DESCRIPTION
Reserved
The reference and feedback of PLL1 must be within the window of phase
error, as specified by PLL1_WND_SIZE for this many phase detector
cycles, before PLL1 digital lock detect is asserted.
PLL1_DLD
_CNT[13:8]
32
PLL1_DLD
_CNT[7:0]
0
Field Value
Delay Value
0 (0x00)
Reserved
1 (0x01)
1
2 (0x02)
2
3 (0x03)
3
...
...
16,382 (0x3FFE)
16,382
16,383 (0x3FFF)
16,383
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9.7.7.7 PLL1_R_DLY, PLL1_N_DLY
This register contains the delay value for PLL1 N and R delays.
Table 62. Register 0x15E
BIT
NAME
POR
DEFAULT
7:6
NA
0
DESCRIPTION
Reserved
Increasing delay of PLL1_R_DLY causes the outputs to lag from CLKinX. For use in zerodelay mode.
5:3
PLL1_R_DLY
0
Field Value
Gain
0 (0x00)
0 ps
1 (0x01)
205 ps
2 (0x02)
410 ps
3 (0x03)
615 ps
4 (0x04)
820 ps
5 (0x05)
1025 ps
6 (0x06)
1230 ps
7 (0x07)
1435 ps
Increasing delay of PLL1_N_DLY causes the outputs to lead from CLKinX. For use in zerodelay mode.
Field Value
2:0
88
PLL1_N_DLY
0
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Gain
0 (0x00)
0 ps
1 (0x01)
205 ps
2 (0x02)
410 ps
3 (0x03)
615 ps
4 (0x04)
820 ps
5 (0x05)
1025 ps
6 (0x06)
1230 ps
7 (0x07)
1435 ps
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9.7.7.8 PLL1_LD_MUX, PLL1_LD_TYPE
This register configures the PLL1 LD pin.
Table 63. Register 0x15F
BIT
NAME
POR
DEFAULT
DESCRIPTION
This sets the output value of the Status_LD1 pin.
Field Value
7:3
PLL1_LD_MUX
1
MUX Value
0 (0x00)
Logic low
1 (0x01)
PLL1 DLD
2 (0x02)
PLL2 DLD
3 (0x03)
PLL1 and PLL2 DLD
4 (0x04)
Holdover status
5 (0x05)
DAC locked
6 (0x06)
Reserved
7 (0x07)
SPI readback
8 (0x08)
DAC rail
9 (0x09)
DAC low
10 (0x0A)
DAC high
11 (0x0B)
PLL1_N
12 (0x0C)
PLL1_N/2
13 (0x0D)
PLL2_N
14 (0x0E)
PLL2_N/2
15 (0x0F)
PLL1_R
16 (0x10)
PLL1_R/2
17 (0x11)
PLL2_R (1)
18 (0x12)
PLL2_R/2 (1)
Sets the I/O type of the Status_LD1 pin.
2:0
(1)
PLL1_LD_TYPE
6
Field Value
TYPE
0 (0x00)
Reserved
1 (0x01)
Reserved
2 (0x02)
Reserved
3 (0x03)
Output (push-pull)
4 (0x04)
Output inverted (push-pull)
5 (0x05)
Reserved
6 (0x06)
Output (open drain)
Only valid when PLL2_LD_MUX is not set to 2 (PLL2_DLD) or 3 (PLL1 and PLL2 DLD).
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9.7.8 (0x160 - 0x16E) PLL2 Configuration
9.7.8.1 PLL2_R[11:8], PLL2_R[7:0]
Table 64. PLL2_R[11:0]
MSB
LSB
0x160[3:0]
0x161[7:0]
This register contains the value of the PLL2 R divider.
Table 65. Registers 0x160 and 0x161
BIT
REGISTERS
NAME
POR DEFAULT
7:4
0x160
NA
0
DESCRIPTION
Reserved
Valid values for the PLL2 R divider.
3:0
7:0
90
0x160
0x161
PLL2_R[11:8]
PLL2_R[7:0]
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0
2
Field Value
Divide Value
0 (0x00)
Not valid
1 (0x01)
1
2 (0x02)
2
3 (0x03)
3
...
...
4,094 (0xFFE)
4,094
4,095 (0xFFF)
4,095
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9.7.8.2 PLL2_P, OSCin_FREQ, PLL2_XTAL_EN, PLL2_REF_2X_EN
This register sets other PLL2 functions.
Table 66. Register 0x162
BIT
NAME
POR
DEFAULT
DESCRIPTION
The PLL2 N prescaler divides the output of the VCO as selected by Mode_MUX1 and is
connected to the PLL2 N divider.
7:5
PLL2_P
2
Field Value
Value
0 (0x00)
8
1 (0x01)
2
2 (0x02)
2
3 (0x03)
3
4 (0x04)
4
5 (0x05)
5
6 (0x06)
6
7 (0x07)
7
The frequency of the PLL2 reference input to the PLL2 phase detector (OSCin/OSCin* port)
must be programmed to support proper operation of the frequency calibration routine,
which locks the internal VCO to the target frequency.
Field Value
4:2
1
0
OSCin_FREQ
PLL2_XTAL_EN
PLL2_REF_2X_EN
7
OSCin Frequency
0 (0x00)
0 to 63 MHz
1 (0x01)
>63 MHz to 127 MHz
2 (0x02)
>127 MHz to 255 MHz
3 (0x03)
Reserved
4 (0x04)
>255 MHz to 500 MHz
5 (0x05) to 7(0x07)
Reserved
0
If an external crystal is being used to implement a discrete VCXO, the internal feedback
amplifier must be enabled with this bit to complete the oscillator circuit.
0: Oscillator amplifier disabled
1: Oscillator amplifier enabled
1
Enabling the PLL2 reference frequency doubler allows for higher phase-detector
frequencies on PLL2 than would normally be allowed with the given VCXO or crystal
frequency.
Higher phase-detector frequencies reduce the PLL N values, which makes the design of
wider-loop bandwidth filters possible.
0: Doubler disabled
1: Doubler enabled
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PLL2_N_CAL
PLL2_N_CAL[17:0]
PLL2 never uses zero-delay during frequency calibration. These registers contain the value of the PLL2 N divider
used with the PLL2 prescaler during calibration for cascaded zero-delay mode. When calibration is complete,
PLL2 uses the PLL2_N value. Cascaded zero-delay mode occurs when PLL2_NCLK_MUX = 1.
Table 67. Register 0x162
MSB
—
LSB
0x163[1:0]
0x164[7:0]
0x165[7:0]
Table 68. Registers 0x163, 0x164, and 0x165
BIT
REGISTERS
NAME
POR
DEFAULT
7:2
0x163
NA
0
1:0
0x163
PLL2_N
_CAL[17:16]
0
7:0
7:0
0x164
PLL2_N_CAL[15:8]
0x165
PLL2_N_CAL[7:0]
DESCRIPTION
Reserved
0
12
Field Value
Divide Value
0 (0x00)
Not valid
1 (0x01)
1
2 (0x02)
2
...
...
262,143 (0x3FFFF)
262,143
9.7.8.4 PLL2_FCAL_DIS, PLL2_N
This register disables frequency calibration and sets the PLL2 N divider value. Programming register 0x168
starts a VCO calibration routine if PLL2_FCAL_DIS = 0.
Table 69. PLL2_N[17:0]
MSB
—
LSB
0x166[1:0]
0x167[7:0]
0x168[7:0]
Table 70. Registers 0x166, 0x167, and 0x168
BIT
REGISTERS
NAME
POR
DEFAULT
7:3
0x166
NA
0
Reserved
2
0x166
PLL2_FCAL_DIS
0
This disables the PLL2 frequency calibration on programming register 0x168.
0: Frequency calibration enabled
1: Frequency calibration disabled
1:0
0x166
PLL2_N[17:16]
0
7:0
7:0
92
0x167
0x168
PLL2_N[15:8]
PLL2_N[7:0]
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0
12
DESCRIPTION
Field Value
Divide Value
0 (0x00)
Not valid
1 (0x01)
1
2 (0x02)
2
...
...
262,143 (0x3FFFF)
262,143
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9.7.8.5 PLL2_WND_SIZE, PLL2_CP_GAIN, PLL2_CP_POL, PLL2_CP_TRI
This register controls the PLL2 phase detector.
Table 71. Register 0x169
BIT
NAME
POR
DEFAULT
7
NA
0
DESCRIPTION
Reserved
PLL2_WND_SIZE sets the window size used for digital lock detect for PLL2. If the phase
error between the reference and feedback of PLL2 is less than the specified time, then the
PLL2 lock counter increments. This value must be programmed to 2 (3.7 ns).
6:5
PLL2_WND_SIZE
2
Field Value
Definition
0 (0x00)
Reserved
1 (0x01)
Reserved
2 (0x02)
3.7 ns
3 (0x03)
Reserved
This bit programs the PLL2 charge pump output current level. The table below also
illustrates the impact of the PLL2 TRISTATE bit in conjunction with PLL2_CP_GAIN.
4:3
2
PLL2_CP_GAIN
PLL2_CP_POL
3
0
Field Value
Definition
0 (0x00)
100 µA
1 (0x01)
400 µA
2 (0x02)
1600 µA
3 (0x03)
3200 µA
PLL2_CP_POL sets the charge pump polarity for PLL2. The internal VCO requires the
negative charge pump polarity to be selected. Many VCOs use positive slope.
A positive-slope VCO increases output frequency with increasing voltage. A negative-slope
VCO decreases output frequency with increasing voltage.
Field Value
Description
0
Negative-slope VCO/VCXO
1
Positive-slope VCO/VCXO
1
PLL2_CP_TRI
0
PLL2_CP_TRI TRI-STATEs the output of the PLL2 charge pump.
0: Disabled
1: TRI-STATE
0
Fixed Value
1
When programming register 0x169, this field must be set to 1.
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SYSREF_REQ_EN, PLL2_DLD_CNT
Table 72. PLL2_DLD_CNT[15:0]
MSB
LSB
0x16A[5:0]
0x16B[7:0]
This register has the value of the PLL2 DLD counter.
Table 73. Registers 0x16A and 0x16B
BIT
REGISTERS
NAME
POR
DEFAULT
7
0x16A
NA
0
Reserved
6
0x16A
SYSREF_REQ_EN
0
Enables the SYNC/SYSREF_REQ pin to force the SYSREF_MUX = 3 for
continuous pulses. When using this feature, enable the pulser and set
SYSREF_MUX = 2 (pulser).
5:0
7:0
94
0x16A
0x16B
PLL2_DLD
_CNT[13:8]
PLL2_DLD_CNT
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DESCRIPTION
The reference and feedback of PLL2 must be within the window of phase error,
as specified by PLL2_WND_SIZE for PLL2_DLD_CNT cycles, before PLL2
digital lock detect is asserted.
32
0
Field Value
Divide Value
0 (0x00)
Not valid
1 (0x01)
1
2 (0x02)
2
3 (0x03)
3
...
...
16,382 (0x3FFE)
16,382
16,383 (0x3FFF)
16,383
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9.7.8.7 PLL2_LF_R4, PLL2_LF_R3
This register controls the integrated loop filter resistors.
Table 74. Register 0x16C
BIT
NAME
POR
DEFAULT
7:6
NA
0
DESCRIPTION
Reserved
Internal loop filter components are available for PLL2, enabling either 3rd- or 4th-order loop
filters without requiring external components.
Internal loop filter resistor R4 can be set according to the following table.
5:3
PLL2_LF_R4
0
Field Value
Resistance
0 (0x00)
200 Ω
1 (0x01)
1 kΩ
2 (0x02)
2 kΩ
3 (0x03)
4 kΩ
4 (0x04)
16 kΩ
5 (0x05)
Reserved
6 (0x06)
Reserved
7 (0x07)
Reserved
Internal loop filter components are available for PLL2, enabling either 3rd- or 4th-order loop
filters without requiring external components.
Internal loop filter resistor R3 can be set according to the following table.
2:0
PLL2_LF_R3
0
Field Value
Resistance
0 (0x00)
200 Ω
1 (0x01)
1 kΩ
2 (0x02)
2 kΩ
3 (0x03)
4 kΩ
4 (0x04)
16 kΩ
5 (0x05)
Reserved
6 (0x06)
Reserved
7 (0x07)
Reserved
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9.7.8.8 PLL2_LF_C4, PLL2_LF_C3
This register controls the integrated loop filter capacitors.
Table 75. Register 0x16D
BIT
NAME
POR
DEFAULT
DESCRIPTION
Internal loop filter components are available for PLL2, enabling either 3rd- or 4th-order loop
filters without requiring external components.
Internal loop filter capacitor C4 can be set according to the following table.
7:4
PLL2_LF_C4
0
Field Value
Capacitance
0 (0x00)
10 pF
1 (0x01)
15 pF
2 (0x02)
29 pF
3 (0x03)
34 pF
4 (0x04)
47 pF
5 (0x05)
52 pF
6 (0x06)
66 pF
7 (0x07)
71 pF
8 (0x08)
103 pF
9 (0x09)
108 pF
10 (0x0A)
122 pF
11 (0x0B)
126 pF
12 (0x0C)
141 pF
13 (0x0D)
146 pF
14 (0x0E)
Reserved
15 (0x0F)
Reserved
Internal loop filter components are available for PLL2, enabling either 3rd- or 4th-order loop
filters without requiring external components.
Internal loop filter capacitor C3 can be set according to the following table.
3:0
96
PLL2_LF_C3
0
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Field Value
Capacitance
0 (0x00)
10 pF
1 (0x01)
11 pF
2 (0x02)
15 pF
3 (0x03)
16 pF
4 (0x04)
19 pF
5 (0x05)
20 pF
6 (0x06)
24 pF
7 (0x07)
25 pF
8 (0x08)
29 pF
9 (0x09)
30 pF
10 (0x0A)
33 pF
11 (0x0B)
34 pF
12 (0x0C)
38 pF
13 (0x0D)
39 pF
14 (0x0E)
Reserved
15 (0x0F)
Reserved
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9.7.8.9 PLL2_LD_MUX, PLL2_LD_TYPE
This register sets the output value of the Status_LD2 pin.
Table 76. Register 0x16E
BIT
NAME
POR
DEFAULT
DESCRIPTION
This sets the output value of the Status_LD2 pin.
Field Value
7:3
PLL2_LD_MUX
2
MUX Value
0 (0x00)
Logic low
1 (0x01)
PLL1 DLD
2 (0x02)
PLL2 DLD
3 (0x03)
PLL1 and PLL2 DLD
4 (0x04)
Holdover status
5 (0x05)
DAC locked
6 (0x06)
Reserved
7 (0x07)
SPI readback
8 (0x08)
DAC rail
9 (0x09)
DAC low
10 (0x0A)
DAC high
11 (0x0B)
PLL1_N
12 (0x0C)
PLL1_N/2
13 (0x0D)
PLL2_N
14 (0x0E)
PLL2_N/2
15 (0x0F)
PLL1_R
16 (0x10)
PLL1_R/2
17 (0x11)
PLL2_R (1)
18 (0x12)
PLL2_R/2 (1)
Sets the I/O type of the Status_LD2 pin.
2:0
(1)
PLL2_LD_TYPE
6
Field Value
TYPE
0 (0x00)
Reserved
1 (0x01)
Reserved
2 (0x02)
Reserved
3 (0x03)
Output (push-pull)
4 (0x04)
Output inverted (push-pull)
5 (0x05)
Reserved
6 (0x06)
Output (open drain)
Only valid when PLL1_LD_MUX is not set to 2 (PLL2_DLD) or 3 (PLL1 and PLL2 DLD).
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9.7.9 (0x16F - 0x1FFF) Misc Registers
9.7.9.1 PLL2_PRE_PD, PLL2_PD
Table 77. Register 0x173
BIT
NAME
7
N/A
6
PLL2_PRE_PD
5
PLL2_PD
4:0
N/A
DESCRIPTION
Reserved
Powerdown PLL2 prescaler
0: Normal operation
1: Powerdown
Powerdown PLL2
0: Normal operation
1: Powerdown
Reserved
9.7.9.2 VCO1_DIV
Sets the VCO1 VCO divider value. This divider cannot be bypassed, and has a minimum value of 2. This register
is reserved for LMK04826 and LMK04828, and should be left unprogrammed.
Table 78. Register 0x174
BIT
NAME
POR
DEFAULT
7:5
N/A
0
DESCRIPTION
Reserved
When VCO_MUX selects VCO1 for LMK04821, the clock distribution frequency is equal to
VCO1 frequency divided by this divide value. This divider is also on the PLL2 feedback
path, and impacts the PLL2 N divider value.
Unlisted field values are reserved.
4:0
VCO1_DIV
(LMK04821 only)
0
Field Value
Divide Value
0 (0x00)
2
5 (0x05)
3
10 (0x0A)
8
20 (0x14)
4
23 (0x17)
5
27 (0x1B)
7
30 (0x1E)
6
9.7.9.3 OPT_REG_1
This register must be written with the following value, depending on which LMK0482x family part is used to
optimize VCO1 phase-noise performance over temperature. This register must be written before writing register
0x168 when using VCO1.
Table 79. Register 0x17C
BIT
NAME
7:0
OPT_REG_1
98
DESCRIPTION
21: LMK04821
24: LMK04826
21: LMK04828
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9.7.9.4 OPT_REG_2
This register must be written with the following value, depending on which LMK0482x family part is used to
optimize VCO1 phase-noise performance over temperature. This register must be written before writing register
0x168 when using VCO1.
Table 80. Register 0x17D
BIT
7:0
NAME
OPT_REG_2
DESCRIPTION
51: LMK04821
119: LMK04826
51: LMK04828
9.7.9.5 RB_PLL1_LD_LOST, RB_PLL1_LD, CLR_PLL1_LD_LOST
Table 81. Register 0x182
BIT
NAME
7:3
N/A
2
RB_PLL1_LD_LOST
1
RB_PLL1_LD
0
CLR_PLL1_LD_LOST
DESCRIPTION
Reserved
This is set when PLL1 DLD edge falls. Does not set if cleared while PLL1 DLD is low.
Read back 0: PLL1 DLD is low.
Read back 1: PLL1 DLD is high.
To reset RB_PLL1_LD_LOST, write CLR_PLL1_LD_LOST with 1 and then 0.
0: RB_PLL1_LD_LOST is set on next falling PLL1 DLD edge.
1: RB_PLL1_LD_LOST is held clear (0). User must clear this bit to allow RB_PLL1_LD_LOST to
become set again.
9.7.9.6 RB_PLL2_LD_LOST, RB_PLL2_LD, CLR_PLL2_LD_LOST
Table 82. Register 0x0x183
BIT
NAME
7:3
N/A
2
RB_PLL2_LD_LOST
1
RB_PLL2_LD
PLL1_LD_MUX or PLL2_LD_MUX must select setting 2 (PLL2 DLD) for valid reading of this bit.
Read back 0: PLL2 DLD is low.
Read back 1: PLL2 DLD is high.
CLR_PLL2_LD_LOST
To reset RB_PLL2_LD_LOST, write CLR_PLL2_LD_LOST with 1 and then 0.
0: RB_PLL2_LD_LOST is set on next falling PLL2 DLD edge.
1: RB_PLL2_LD_LOST is held clear (0). User must clear this bit to allow RB_PLL2_LD_LOST to
become set again.
0
DESCRIPTION
Reserved
This is set when PLL2 DLD edge falls. Does not set if cleared while PLL2 DLD is low.
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9.7.9.7 RB_DAC_VALUE(MSB), RB_CLKinX_SEL, RB_CLKinX_LOS
This register provides read back access to CLKinX selection indicator and CLKinX LOS indicator. The 2 MSBs
are shared with the RB_DAC_VALUE. See RB_DAC_VALUE section.
Table 83. Register 0x184
BIT
NAME
DESCRIPTION
7:6
RB_DAC_VALUE[9:8]
5
RB_CLKin2_SEL
Read back 0: CLKin2 is not selected for input to PLL1.
Read back 1: CLKin2 is selected for input to PLL1.
4
RB_CLKin1_SEL
Read back 0: CLKin1 is not selected for input to PLL1.
Read back 1: CLKin1 is selected for input to PLL1.
3
RB_CLKin0_SEL
Read back 0: CLKin0 is not selected for input to PLL1.
Read back 1: CLKin0 is selected for input to PLL1.
2
N/A
1
RB_CLKin1_LOS
Read back 1: CLKin1 LOS is active.
Read back 0: CLKin1 LOS is not active.
0
RB_CLKin0_LOS
Read back 1: CLKin0 LOS is active.
Read back 0: CLKin0 LOS is not active.
See RB_DAC_VALUE section.
9.7.9.8 RB_DAC_VALUE
Contains the value of the DAC for user readback.
FIELD NAME
RB_DAC_VALUE
MSB
LSB
0x184 [7:6]
0x185 [7:0]
Table 84. Registers 0x184 and 0x185
BIT
REGISTERS
NAME
POR
DEFAULT
7:6
0x184
RB_DAC_
VALUE[9:8]
2
7:0
0x185
RB_DAC_
VALUE[7:0]
0
DESCRIPTION
DAC value is 512 on power-on reset; if PLL1 locks upon power-up, the DAC
value changes.
9.7.9.9 RB_HOLDOVER
Table 85. Register 0x188
BIT
NAME
7:5
N/A
4
RB_HOLDOVER
3:0
N/A
100
DESCRIPTION
Reserved
Read back 0: Not in HOLDOVER
Read back 1: In HOLDOVER
Reserved
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9.7.9.10 SPI_LOCK
Prevents SPI registers from being written to, except for 0x1FFD, 0x1FFE, and 0x1FFF. These registers must be
written to sequentially and in order: 0x1FFD, 0x1FFE, 0x1FFF.
These registers cannot be read back.
MSB
—
LSB
0x1FFD [7:0]
0x1FFE [7:0]
0x1FFF [7:0]
Table 86. Registers 0x1FFD, 0x1FFE, and 0x1FFF
BIT
REGISTERS
NAME
POR
DEFAULT
7:0
0x1FFD
SPI_LOCK[23:16]
0
0: Registers unlocked.
1 to 255: Registers locked
7:0
0x1FFE
SPI_LOCK[15:8]
0
0: Registers unlocked.
1 to 255: Registers locked
7:0
0x1FFF
SPI_LOCK[7:0]
83
0 to 82: Registers locked
83: Registers unlocked
84 to 256: Registers locked
DESCRIPTION
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10 Applications and Implementation
10.1 Application Information
To assist customers in frequency planning and designing loop filters, Texas Instruments provides PLLatinum Sim
(www.ti.com/tool/PLLATINUMSIM-SW) and TICS Pro (www.ti.com/tool/TICSPRO-SW).
10.2 Digital Lock Detect Frequency Accuracy
The digital lock detect circuit is used to determine PLL1 locked, PLL2 locked, and holdover exit events. A window
size and lock count register are programmed to set a ppm frequency accuracy of reference to feedback signals
of the PLL, for each event to occur. When a PLL digital lock event occurs, the PLL digital lock detect is asserted
true. When the holdover exit event occurs, the device exits holdover mode.
EVENT
PLL
WINDOW SIZE
LOCK COUNT
PLL1 locked
PLL1
PLL1_WND_SIZE
PLL1_DLD_CNT
PLL2 locked
PLL2
PLL2_WND_SIZE
PLL2_DLD_CNT
Holdover exit
PLL1
PLL1_WND_SIZE
HOLDOVER_DLD_CNT
For a digital lock detect event to occur, there must be a “lock count” number of phase-detector cycles of PLLX,
during which the time/phase error of the PLLX_R reference and PLLX_N feedback signal edges are within the
user programmable "window size." Because there must be at least "lock count" phase-detector events before a
lock event occurs, a minimum digital lock event time can be calculated as "lock count" / fPDX, where X = 1 for
PLL1 or 2 for PLL2.
By using Equation 6, values for a "lock count" and "window size" can be chosen to set the frequency accuracy
required by the system in ppm before the digital lock detect event occurs:
ppm =
1e6 × PLLX_WND_SIZE × fPDX
PLLX_DLD_CNT
(6)
The effect of the "lock count" value is that it shortens the effective lock window size by dividing the "window size"
by "lock count".
If at any time the PLLX_R reference and PLLX_N feedback signals are outside the time window set by "window
size", then the “lock count” value is reset to 0.
10.2.1 Minimum Lock Time Calculation Example
To calculate the minimum PLL2 digital lock time given a PLL2 phase-detector frequency of 40 MHz and
PLL2_DLD_CNT = 10,000: the minimum lock time of PLL2 is 10,000 / 40 MHz = 250 µs.
102
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10.3 Driving CLKin and OSCin Inputs
10.3.1 Driving CLKin and OSCin Pins With a Differential Source
Both CLKin ports can be driven by differential signals. TI recommends that the CLKin input mode be set to
bipolar (CLKinX_TYPE = 0) when using differential reference clocks. The OSCin input mode is hard-wired to
bipolar-equivalent. The LMK0482x family internally biases the input pins, thus the differential interface should be
AC coupled. The recommended circuits for driving the CLKin/OSCin pins with either LVDS or LVPECL are
shown in Figure 24 and Figure 25.
Figure 24. CLKinX and OSCin Termination for an LVDS Reference Clock Source
Figure 25. CLKinX and OSCin Termination for an LVPECL Reference Clock Source
A reference clock source that produces a differential sine wave output can drive the CLKin/OSCin pins using the
following circuit. The signal level must conform to the requirements for the CLKin/OSCin pins listed in Electrical
Characteristics.
Figure 26. CLKinX and OSCin Termination for a Differential Sinewave Reference Clock Source
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Driving CLKin and OSCin Inputs (continued)
10.3.2 Driving CLKin and OSCin Pins With a Single-Ended Source
The CLKin/OSCin pins of the LMK0482x family can be driven using a single-ended reference clock source; for
example, either a sine wave source or an LVCMOS/LVTTL source. For the CLKin pins, either AC coupling or DC
coupling may be used. For the OSCin pins, AC coupling is required. In the case of the sine wave source that is
expecting a 50-Ω load, TI recommends using AC coupling, as shown in the circuit below with a 50-Ω termination.
NOTE
The signal level must conform to the requirements for the CLKin/OSCin pins listed in
Electrical Characteristics. CLKinX_TYPE is recommended to be set to bipolar mode
(CLKinX_TYPE = 0). OSCin is hard-wired to bipolar mode.
Figure 27. CLKinX and OSCin Single-Ended Termination
If the CLKin pins are being driven with a single-ended LVCMOS/LVTTL source, either DC coupling or AC
coupling may be used. If DC coupling is used, the CLKinX_TYPE should be set to MOS buffer mode
(CLKinX_TYPE = 1), and the voltage swing of the source must meet the specifications for DC-coupled, MOSmode clock inputs given in Electrical Characteristics. If AC coupling is used, the CLKinX_TYPE should be set to
the bipolar buffer mode (CLKinX_TYPE = 0), and the voltage swing at the input pins must meet the specifications
for AC-coupled, bipolar-mode clock inputs given in Electrical Characteristics. In AC-coupled bipolar mode, some
attenuation of the clock input level may be required. A simple resistive divider circuit before the AC coupling
capacitor is sufficient.
Figure 28. DC-Coupled LVCMOS/LVTTL Reference Clock
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10.4 Output Termination and Biasing
10.4.1 LVPECL
Figure 29 shows the recommended resistor biasing configuration for the LVPECL format for both CLKout and
OSCout pins. The LVPECL emitter resistors for DCLKoutX or SDCLKoutY can be selected such that 120 Ω ≤ Re
≤ 240 Ω. When OSCout (pins 40 and 41) are configured to provide a buffered oscillator output in LVPECL
format, TI recommends setting the value of the emitter resistors for OSCout to 240 Ω. To avoid bias mismatch or
excessive loading of the bias circuitry, TI recommends connecting LVPECL outputs to the load through ACcoupling capacitors as shown.
Figure 29. LVPECL Biasing for CLKout and OSCout
10.4.2 LVDS/HSDS
Figure 30 shows the recommended resistor biasing configuration for the LVDS/HSDS format for both CLKout
and OSCout pins. When connecting an HSDS output to a load, it should be AC-coupled. In cases where the
common mode output voltage of the LMK0482x family LVDS matches the common mode input voltage of the
LVDS receiver, DC coupling can be used; however, frequently LVDS is also AC-coupled to avoid any
driver/receiver mismatch issues.
The LVDS/HSDS driver requires a DC path for current from CLKoutX to CLKoutX* and from OSCout to OSCout*
on initial startup. If a DC path for current is not present on startup, LVDS/HSDS outputs may start up with lower
amplitude than expected, and in some cases could generate runt pulses or fail to oscillate for some time after
startup. Whenever AC-coupled LVDS or HSDS is used with external termination, the 100-Ω termination should
be placed on the LMK0482x side of the AC-coupling capacitors as illustrated in Figure 30.
Figure 30. LVDS/HSDS Output Termination for OSCout and CLKout, External Receiver Termination
In cases where the termination is internal to the receiver, place 560 Ω close to the CLKoutX/X* or
OSCout/OSCout* pins, to provide a DC path for the output on startup as illustrated in Figure 31.
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Output Termination and Biasing (continued)
Figure 31. LVDS/HSDS Output Termination for OSCout and CLKout, Internal Receiver Termination
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10.5 Typical Applications
10.5.1 Design Example
This design example below highlights using the available tools to design loop filters and create a programming
map for the LMK0482x.
10.5.1.1 Design Requirements
Clocks outputs:
• 1x 245.76-MHz clock for JESD204B ADC, LVPECL.
– This clock requires the best performance in this example.
• 2x 983.04-MHz clock for JESD204B DAC, LVPECL.
• 1x 122.88-MHz clock for JESD204B FPGA block, LVDS
• 4x 10.24-MHz SYSREF for ADC (LCPECL), DAC (LVPECL), FPGA (LVDS).
• 2x 122.88-MHz clock for FPGA, LVDS
For best performance, the highest possible phase detector frequency is used at PLL2. As such, a 122.88-MHz
VCXO is used.
10.5.1.2 Detailed Design Procedure
This information is current as of the date of the release of this data sheet. Design tools receive continuous
improvements to add features and improve model accuracy. Refer to the software instructions or training for the
latest features.
10.5.1.2.1 Device Configuration and Simulation - PLLatinum Sim
Select the LMK04828 and choose the PLL and VCO to simulate. Make adjustments for more accurate
simulations depending on the application. For example:
• Enter the VCO gain of the external VCXO or possible external VCO-used device.
• Adjust the charge pump current to help with loop filter component selection. Lower charge pump currents
result in smaller components, but may increase impacts of leakage, and at the lowest values reduce PLL
phase-noise performance.
• PLLatinum Sim allows loading a custom phase noise plot for any block. Typically, a custom phase-noise plot
is entered for CLKin to match the reference phase noise to device; a phase-noise plot for the VCXO can
additionally be provided to match the performance of VCXO used. For improved accuracy in simulation and
optimum loop filter design, load these custom noise profiles for use in the application.
• The design tools return with high reference and phase-detector frequencies by default. If desired, experiment
with different reference divider settings, phase detector frequencies, and loop bandwidths. Due to the narrow
loop bandwidth used on PLL1, it is common to reduce the phase detector frequency on PLL1.
10.5.1.2.2 Device Programming
Using the PLLatinum Sim configuration, the TICS Pro software is manually updated with this information to meet
the required application. For the JESD204B outputs, place the device clocks on the DCLKoutX output, then turn
on the paired SDCLKoutY output for SYSREF output. For non-JESD204B outputs, both DCLKoutX and paired
SDCLKoutY may be driven by the device clock divider to maximize number of available outputs.
Frequency planning for assignment of outputs:
• To minimize crosstalk, perform frequency planning / CLKout assignments to keep common frequencies on
outputs close together.
• It is best to place common device clock output frequencies on outputs sharing the same Vcc group. For
example, these outputs share Vcc4_CG2. Refer to Pin Configuration and Functions to see the Vcc groupings
the clock outputs.
In this example, the 245.76-MHz ADC output requires the best performance. DCLKout2 on the LMK0482x
provides the best noise floor / performance. The 245.76 MHz is placed on DCLKout2 with 10.24-MHz SYSREF
on SDCLKout3.
• For best performance, the input and output drive level bits may be set. Best noise floor performance is
achieved with CLKout2_IDL = 1 and CLKout2_ODL = 1.
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Typical Applications (continued)
In this example, the 983.04-MHz DAC output is placed on DCLKout4 and DCLKout6, with 10.24-MHz SYSREF
on paired SDCLKout5 and SDCLKout7 outputs.
• These outputs share Vcc4_CG2.
In this example, the 122.88-MHz FPGA JESD204B output is placed on DCLKout10, with 10.24-MHz SYSREF on
paired SDCLKout11 output.
Additionally, the 122.88-MHz FPGA non-JESD204B outputs are placed on DCLKout8 and SDCLKout9.
• When frequency planning, consider PLL2 as a clock output at the phase-detector frequency. As such, these
122.88-MHz outputs have been placed on the outputs close to the PLL2 and charge pump power supplies.
The register programming can be validated live on the device, with a SPI header wired to a TI USB2ANY
programmer. When the device programming is completed as desired in the TICS Pro software, it is possible to
export the register settings by using the Export Hex Registers option in the file menu.
10.5.1.3 Application Curves
Figure 32. DCLKout0, 245.76-MHz
LVPECL20 With 240-Ω Emitter Resistors
CLKout0_1_IDL = 1, CLKout0_1_ODL = 1
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Figure 33. DCLKout2, 245.76-MHz
LVPECL20 With 240-Ω Emitter Resistors
CLKout2_3_IDL = 1, CLKout2_3_ODL = 1
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Typical Applications (continued)
Figure 34. DCLKout4, 983.04-MHz
LVPECL16 With 240-Ω Emitter Resistors
CLKout4_5_IDL = 1, CLKout4_5_ODL = 0
Figure 35. DCLKout6, 983.04-MHz
LVPECL16 With 240-Ω Emitter Resistors
CLKout6_7_IDL = 1, CLKout6_7_ODL = 0
Figure 36. DCLKout10, 122.88 MHz, LVDS
CLKout10_11_IDL = 1, CLKout10_11_ODL = 0
Figure 37. SDCLKout11, 122.88 MHz, LVDS
CLKout10_11_IDL = 1, CLKout10_11_ODL = 0
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Typical Applications (continued)
Figure 38. OSCout, 122.88 MHz, LVCMOS (Norm/Inv)
Normal Output Measured, Inverse 50-Ω Termination
Figure 39. Direct VCXO Measurement
Open Loop, Holdover Mode Set
10.6 System Examples
10.6.1 System Level Diagram
Figure 40 and Figure 41 show an LMK0482x family device with external circuitry for clocking and for power
supply to serve as a guideline for good practices when designing with the LMK0482x family. Refer to Pin
Connection Recommendations for more details on the pin connections and bypassing recommendations. Also
refer to the evaluation board in LMK04826/28 User's Guide. PCB design will also play a role in device
performance.
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System Examples (continued)
Figure 40. Example Application - System Schematic Except for Power
Figure 40 shows the primary reference clock input is at CLKin0/0*. A secondary reference clock is driving
CLKin1/1*. Both clocks are depicted as AC-coupled drivers. The VCXO attached to the OSCin/OSCin* port is
configured as an AC-coupled single-ended driver. Any of the input ports (CLKin0/0*, CLKin1/1*, CLKin2/2*,
OSCin/OSCin*) may be configured as either differential or single-ended (see Driving CLKin and OSCin Inputs).
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System Examples (continued)
The loop filter for PLL1 is configured as a 2nd-order passive filter, while the loop filter for PLL2 is configured as a
4th order passive filter (using internal 3rd and 4th order components). Typically it is not necessary to increase the
filter beyond 2nd order for PLL1. PLL2 allows software programmability of the 3rd and 4th order components
(see PLL2 Integrated Loop Filter Poles). PLLatinum Sim can be used to compute the loop filter values for optimal
phase noise.
All the LVPECL clock outputs are AC-coupled with 0.1 µF capacitors. Some LVPECL outputs are depicted with
240-Ω emitter resistors, and some are depicted with 150-Ω emitter resistors. LVPECL clock outputs can use
emitter resistors between 120 Ω and 240 Ω. OSCout LVPECL format only supports 240-Ω emitter resistors is
depicted with 240-Ω emitter resistors. The LCPECL SYSREF output is DC-coupled, with termination values
matching the conditions specified for LCPECL in the Electrical Characteristics. The non-JESD204B LVDS
outputs are AC-coupled, and include 560 Ω between the pins of the differential pair to create a DC path for
current on startup (see LVDS/HSDS). The JESD204B LVDS outputs are DC-coupled. Unused outputs are left
floating.
PCB design will influence crosstalk performance. Tightly coupled clock traces will have less crosstalk than
loosely coupled clock traces. Proximity to other clock traces will influence crosstalk.
Figure 41. Example Application - Power System Schematic
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System Examples (continued)
Figure 41 shows an example decoupling and bypassing scheme for the LMK0482x, which could apply to the
configuration shown in Figure 40. Components drawn in dotted lines are optional (see Pin Connection
Recommendations). Two power planes are used in these example designs, one for the clock outputs and one for
the PLL circuits. It is possible to reduce the number of decoupling components by tying together clock output Vcc
pins for CLKouts that share the same frequency or otherwise can tolerate potential crosstalk between outputs
with different frequencies. In the two examples, Vcc2 and Vcc11 can be tied together since no outputs are
utilized from Clock Group 0. PCB design will influence impedance to the supply. Vias and traces will increase the
impedance to the power supply. Ensure good direct return current paths.
10.7 Do's and Don'ts
•
•
•
•
•
•
VCC Pins and Decoupling: all VCC pins must always be connected.
Unused Clock Outputs: leave unused clock outputs floating and powered down.
Unused Clock Inputs: unused clock inputs can be left floating.
OSCout: When set to an LVPECL drive format, OSCout emitter resistors should be 240 Ω to GND.
Otherwise, OSCout may be treated like any other clock output.
LVDS/HSDS Outputs: Ensure that there is a DC path for current from CLKoutX to CLKoutX*, and from
OSCout to OSCout*, for all LVDS/HSDS outputs at startup. See LVDS/HSDS.
RESET Pin: If the RESET pin is used, place a capacitor on RESET pin to prevent external noise from
causing device reset. If reset functionality is not used, consider resetting GPIO as output to prevent external
noise from causing device reset.
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11 Power Supply Recommendations
11.1 Pin Connection Recommendations
11.1.1 VCC Pins and Decoupling
All Vcc pins must always be connected.
Integrated capacitance on the LMK0482x makes external high frequency decoupling capacitors ( 30 MHz, a ferrite bead may be placed and the internal capacitance is
sufficient
• If a ferrite bead is used with a low frequency output (< 30 MHz), and the output format is set to a high current
switching format such as LVPECL or LCPECL, then:
– The ferrite bead can be removed to lower the impedance to the main power supply and bypass capacitors,
or
– Localized capacitance can be placed between the ferrite bead and Vcc pin to support the switching
current.
– Note: the decoupling capacitors used between the ferrite bead and a clock group Vcc pin can permit
high frequency switching noise to couple through the capacitors into the ground plane and onto other
clock VCC pins through their decoupling capacitors. Placing unnecessary decoupling capacitances, or
placing ferrite beads with excessive impedance at high frequency (> 200 Ω) can degrade crosstalk
performance.
– If the OSCout buffer format is LVCMOS, TI recommends using a complementary output format such as
LVCMOS (Norm/Inv) to reduce switching noise and crosstalk. If only a single LVCMOS output is required,
the complementary LVCMOS output format can still be used by leaving the unused LVCMOS output
floating.
• Vcc3_SYSREF powers both the SYSREF divider and the SYNC circuitry. If SYNC is used but the SYSREF
divider is not, Vcc3_SYSREF can be connected to any other clock output supply without impacting noise
performance.
11.1.1.2 Low-Crosstalk Supplies
These supplies include Vcc1_VCO, Vcc5_DIG, and Vcc6_PLL1.
Each of these pins has internal bypass capacitance. Ferrite beads should not be needed between these pins and
the power supply. A ferrite bead can optionally before the common point connecting these supplies, in which
case a large decoupling capacitance (1 µF or more) should be used for voltage stability after the ferrite bead.
The typical application diagram in Figure 41 shows all these supply pins connected together to the power supply
with an optional ferrite bead and decoupling capacitance.
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Pin Connection Recommendations (continued)
These supplies are considered low-crosstalk supplies because they do not generate much noise. Vcc1_VCO
noise is effectively captured by the on-chip bypass capacitance, since noise from this pin is typically very high
frequency. This pin also uses a high-quality integrated LDO to minimize noise below 30 MHz. Vcc5_DIG is only
active at startup and during GPIO events, so after startup there is no continuous noise contribution from this pin.
Vcc6_PLL1 is usually low-noise as well, due to the low frequency of the PLL1 phase detector. An on-chip LDO
regulates this supply and prevents most PLL1 charge pump noise from escaping. If the PLL1 phase detector is
set to a high frequency, a ferrite bead may optionally be used on this supply. If a ferrite bead is used with this
supply, the DC resistance of this ferrite bead should be minimized to avoid voltage fluctuation at the PLL1
supply/PLL1 charge pump, and a 0.1-µF decoupling capacitor should be placed after the ferrite bead close to the
supply pin.
11.1.1.3 PLL2 Supplies
These supplies include Vcc9_CP2 and Vcc10_PLL2.
Each of these pins has an internal bypass capacitor. A ferrite bead should be placed between the power supply
and Vcc9. The DC resistance of this ferrite bead should be minimized to avoid voltage fluctuations at the PLL2
charge pump. Typically the frequency of the PLL2 phase detector is >50 MHz and an external decoupling
capacitor is not necessary. For lower PLL2 phase detector frequencies, a 0.1-µF decoupling capacitor should be
placed after the ferrite bead close to the supply pin. Use of a ferrite bead between the power supply and
Vcc10_PLL2 is optional. Normally the frequency of the dividers used by PLL2 is high enough that all noise is
well-constrained by the on-chip bypass capacitance. If a ferrite bead is used, a 0.1-µF decoupling capacitor
should be placed after the ferrite bead close to the supply pin.
11.1.1.4 Clock Input Supplies
These supplies include Vcc6_PLL1 and Vcc9_OSCin. If CLKin2 is used, Vcc7_OSCout is also included.
For Vcc6_PLL1, follow guidance in Low-Crosstalk Supplies. For Vcc9_OSCin, a ferrite bead is recommended for
VCXO frequencies above 30 MHz. Typically above 100 MHz no bypass capacitance is necessary on this pin, but
if the OSCin frequency is < 100 MHz, a 0.1-µF decoupling capacitor should be placed after the ferrite bead close
to the supply pin. Vcc7_OSCout should follow similar guidance to Vcc9 for CLKin2 above 30 MHz, and
Vcc6_PLL1 for CLKin2 below 30 MHz.
When CLKin1 is used as Fin or FBCLKin, TI recommends using CLKin2 as the source to PLL1 whenever
possible. CLKin0 and CLKin1 share Vcc6_PLL1 supply, and in cases where Fin or FBCLKin is high frequency,
CLKin0 can crosstalk to Fin/FBCLKin through Vcc6_PLL1. CLKin2 is powered from Vcc7_OSCout, and the
crosstalk between Fin/FBCLKin and CLKin2 is significantly reduced as a result.
11.1.1.5 Unused Clock Inputs/Outputs
Leave unused clock inputs and outputs floating. Set unused clock outputs to powerdown format, and disable
unused channel pairs. If the SYSREF is not used in a channel pair, SDCLKoutY_PD can be set. For maximum
power savings and noise immunity, set DCLKoutX_PD, SDCLKoutY_PD, and CLKoutX_Y_PD on all unused
channel pairs.
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11.2 Current Consumption / Power Dissipation Calculations
From Table 87, the current consumption can be calculated for any configuration. The data below is typical and
not assured.
The TICS Pro device profiles for LMK0482x family devices also include a current calculator, which performs realtime analysis of the register settings and estimates the current consumption based on which blocks are enabled.
TI strongly recommends using TICS Pro to compute the current for any device profile, as it is faster and more
flexible than manual computation using the table below. TICS Pro does not require a connection to the
LMK0482x to generate a current consumption estimate or a register file.
Table 87. Typical Current Consumption for Selected Functional Blocks
(TA = 25 °C, VCC = 3.3 V)
BLOCK
TYPICAL ICC
(mA)
POWER
DISSIPATED
in DEVICE
(mW)
PLL1 and PLL2 locked
131.5
433.95
LMK04826/LMK04828
13.5
44.55
22
72.6
CONDITION
CORE and FUNCTIONAL BLOCKS
Core
Dual loop, internal VCO0
VCO (with VCO divider for
LMK04821)
VCO1 is selected
OSCin Doubler
Doubler is enabled
3
9.9
CLKin
Any one of the CLKinX is enabled
4.9
16.17
Holdover is enabled
HOLDOVER_EN = 1
1.3
4.29
Hitless switch is enabled
HOLDOVER_HITLESS_SWI
TCH = 1
0.9
2.97
Track mode
TRACK_EN = 1
Holdover
SYNC_EN = 1
SYSREF
LMK04821
EN_PLL2_REF_2X = 1
2.5
8.25
Required for SYNC and SYSREF functionality
7.6
25.08
Enabled
SYSREF_PD = 0
27.2
89.76
Dynamic digital delay
enabled
SYSREF_DDLY_PD = 0
5
16.5
Pulser is enabled
SYSREF_PLSR_PD = 0
4.1
13.53
SYSREF pulses mode
SYSREF_MUX = 2
3
9.9
SYSREF continuous mode
SYSREF_MUX = 3
3
9.9
66.33
CLOCK GROUP
Enabled
Any one of the CLKoutX_Y_PD = 0
20.1
IDL
Any one of the CLKoutX_Y_IDL = 1
2.2
7.26
ODL
Andy one of the CLKoutX_Y_ODL = 1
3.2
10.56
Divider only
DCLKoutX_MUX = 0
13.6
44.88
Divider + DCC + HS
DCLKoutX_MUX = 1
17.7
58.41
Analog delay + divider
DCLKoutX_MUX = 3
13.6
44.88
Clock Divider
CLOCK OUTPUT BUFFERS
LVDS
100-Ω differential termination
HSDS
6
19.8
HSDS 6 mA, 100-Ω differential termination
8.8
29.04
HSDS 8 mA, 100-Ω differential termination
11.6
38.28
HSDS 10 mA, 100-Ω differential termination
19.4
64.02
100-Ω differential termination
18.5
61.05
OSCout BUFFERS
LVDS
LVCMOS
116
LVCMOS pair
150 MHz
42.6
140.58
LVCMOS single
150 MHz
27
89.1
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12 Layout
12.1 Layout Guidelines
12.1.1 Thermal Management
Power consumption of the LMK0482x family of devices can be high enough to require attention to thermal
management. For reliability and performance reasons, the die temperature should be limited to a maximum of
125°C. That is, as an estimate, TA (ambient temperature) plus device power consumption multiplied by RθJA
should not exceed 125°C.
The package of the device has an exposed pad that provides the primary heat removal path, as well as excellent
electrical grounding to a printed circuit board. To maximize the removal of heat from the package, a thermal land
pattern, including multiple vias to a ground plane, must be incorporated on the PCB within the footprint of the
package. The exposed pad must be soldered down to ensure adequate heat conduction out of the package.
7.2 mm
0.2 mm
1.46 mm
1.15 mm
Figure 42. Recommended Land and Via Pattern
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12.2 Layout Example
Figure 43. LMK0482x Layout Example
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13 Device and Documentation Support
13.1 Device Support
13.1.1 Development Support
13.1.1.1 PLLatinum Sim
Loop filter design and simulation.
For PLLatinum Sim, go to www.ti.com/tool/PLLATINUMSIM-SW.
13.1.1.2 TICS Pro
EVM programming software. Can also be used to generate register map for programming for a specific
application.
For TICS Pro, go to www.ti.com/tool/TICSPRO-SW
13.2 Related Links
The table below lists quick access links. Categories include technical documents, support and community
resources, tools and software, and quick access to sample or buy.
Table 88. Related Links
PARTS
PRODUCT FOLDER
SAMPLE & BUY
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
LMK04821
Click here
Click here
Click here
Click here
Click here
LMK04826
Click here
Click here
Click here
Click here
Click here
LMK04828
Click here
Click here
Click here
Click here
Click here
13.3 Trademarks
PLLatinum is a trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
13.4 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
13.5 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
14 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
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Product Folder Links: LMK04821 LMK04826 LMK04828
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119
�PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
LMK04821NKDR
ACTIVE
WQFN
NKD
64
1000
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04821NKD
LMK04821NKDT
ACTIVE
WQFN
NKD
64
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04821NKD
LMK04826BISQ/NOPB
ACTIVE
WQFN
NKD
64
1000
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04826BISQ
LMK04826BISQE/NOPB
ACTIVE
WQFN
NKD
64
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04826BISQ
LMK04826BISQX/NOPB
ACTIVE
WQFN
NKD
64
2000
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04826BISQ
LMK04828BISQ/NOPB
ACTIVE
WQFN
NKD
64
1000
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04828BISQ
LMK04828BISQE/NOPB
ACTIVE
WQFN
NKD
64
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04828BISQ
LMK04828BISQX/NOPB
ACTIVE
WQFN
NKD
64
2000
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
K04828BISQ
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of
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