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TPS65911
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
TPS65911 Integrated Power Management Unit Top Specification
1 Device Overview
1.1
Features
1
• Embedded Power Controller (EPC) With EEPROM
Programmability
• Two Efficient Step-Down DC-DC Converters for
Processor Cores (VDD1, VDD2)
• One Efficient Step-Down DC-DC Converter for I/O
Power (VIO)
• One Controller for External FETs (VDDCtrl)
• Dynamic Voltage Scaling (DVS) for Processor
Cores
• Eight LDO Voltage Regulators and One RTC LDO
(Supply for Internal RTC)
• One High-Speed I2C Interface for General-Purpose
Control Commands (CTL-I2C)
• Two Independent Enable Signals for Controlling
Power Resources (EN1, EN2)
– Alternatively, the EN1 and EN2 Pins can be
Used as a High-Speed I2C Interface Dedicated
for Voltage Scaling for VDD1 and VDD2
• Thermal Shutdown Protection and Hot-Die
Detection
• A Real-Time Clock (RTC) Resource With:
– Oscillator for 32.768-kHz Crystal or 32-kHz
Built-in RC Oscillator
– Date, Time, and Calendar
– Alarm Capability
1.2
• Nine Configurable GPIOs With Multiplexed Feature
Support:
– Four can be Used as Enable for External
Resources, Included in Power-Up Sequence
and Controlled by State Machine
– As GPI, GPIOs Support Logic-Level Detection
and can Generate Maskable Interrupt for
Wakeup
– Two of the GPIOs Have 10-mA Current Sink
Capability for Driving LEDs
– DC-DC Converters Switching Synchronization
Through an External 3-MHz Clock
• Two Reset Inputs:
– Cold Reset (HDRST)
– Power Initialization Reset (PWRDN) for Thermal
Reset Input
• 32-kHz Clock and Reset (NRESPWRON) for
System and an Additional Output for Reset Signal
• Watchdog
• Two ON and OFF LED Pulse Generators and One
PWM Generator
• Two Comparators for System Control, Connected
to VCCS Pin
• A JTAG and Boundary Scan (Not Accessible in
Functional Mode [Test Purpose])
Applications
Portable and Hand-Held Systems
1.3
Description
The TPS65911 device is an integrated power management IC (PMIC) available in a 98-pin 0.65-mm pitch
BGA package. The TPS65911 device is dedicated to applications powered by one Li-Ion or Li-Ion polymer
battery cell, 3-series Ni-MH cells, or a 5-V input, and applications that require multiple power rails. The
device provides three step-down converters, one controller for external FETs to support high current rail,
eight LDOs, and the device is designed to be a flexible PMIC for supporting different processors and
applications.
Two of the step-down converters provide power for dual processor cores and support dynamic voltage
scaling by a dedicated I2C interface for optimum power savings. The third converter provides power for the
I/Os and memory in the system.
The device includes eight general-purpose LDO regulators that provide a wide range of voltage and
current capabilities. Five of the LDO regulators support 1 to 3.3 V with a 100-mV step and three (LDO1,
LDO2, LDO4) support 1.0 to 3.3 V with a 50-mV step. All LDO regulators are fully controllable by the I2C
interface.
In addition to the power resources, the device contains an EPC to manage the power sequencing
requirements of systems and an RTC. Power sequencing is programmable by EEPROM.
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.
TPS65911
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
www.ti.com
Device Information (1)
PART NUMBER
PACKAGE
TPS65911 (2)
(1)
(2)
BODY SIZE (NOM)
BGA MicroStar Junior™ (98)
9.00 mm × 6.00 mm
For more information, see Section 9, Mechanical, Packaging, and Orderable Information.
Refer to the corresponding user's guide for the complete EEPROM setting before ordering.
1.4
Functional Block Diagram
Figure 1-1 shows the top-level diagram of the device.
CBB
VBACKUP
VCC7
VRTC
1.5 A at 0.6 to 2.2 V(1)
VDD1
BACKUP
VRTC (LDO) Management
and POR
AGND
SW1
AGND
OSC32KIN
GND1
Oscillator
32 kHz
OSC32KOUT
REFGND
CLK32KOUT
Real-Time Clock
(RTC)
VDDIO
0.6 V to 3.3 V
1.5 A at 0.6 to 1.5 V
VDD2
SDA_SDI
SCL_SCK
VCC1
I 2C
VFB1
(1)
VCC2
GPIO0
SW2
GPIO1
Bus Control
GPIO2
GND2
GPIO3
GPIO4
0.6 V to 3.3 V
GPIO5
GPIO6
DRVH
GPIO7
Cboost
SW
GPIO8
DRVL
2
EN1
VFB2
VBST
IC
Controller
EN2
VOUT
VFB
INT1
SLEEP
PWRON
BOOT1
C1
V5IN
Power-Control
State Machine
TRIP Rtrip
0.6 V to 1.4 V
GNDC
VIO
VCCIO
PWRHOLD
CV5IN
PWRDN
HDRST
SWIO
NRESPWRON
NRESPWRON2
GNDIO
VREF
TESTV
Analog
References
REFGND
1 to 3.3 V,
100-mV step
LDO3
LDO3
200 mA
Watchdog
1.3 A at 1.5 V
1.2 A at 1.8 V
1.1 A at 2.5 and 3.3 V
VDDIO
LDO1
320 mA
LDO1
Test Interface
1 to 3.3 V,
100-mV step
LDO2
320 mA
LDO4
LDO4
50 mA
LDO5
LDO7
300 mA
LDO5
300 mA
1 to 3.3 V,
50-mV step
LDO2
1 to 3.3 V,
50-mV step
LDO7
1 to 3.3 V,
100-mV step
VCC3
VCC4
LDO8
300 mA
VCCS
Connect to system
1.8V/3.3 V supply
VCC6
VCC5
1 to 3.3 V,
50-mV step
VFBIO
LDO8
1 to 3.3 V,
100-mV step
LDO6
1 to 3.3 V,
100-mV step
COMP
1
COMP
2
(1)
LDO6
300 mA
For details on supported levels, see the electrical characteristics for VDD1 SMPS and VDD2 SMPS, and the Power Sources table.
Figure 1-1. Top-Level Functional Block Diagram
2
Device Overview
Copyright © 2010–2018, Texas Instruments Incorporated
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Product Folder Links: TPS65911
TPS65911
www.ti.com
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Table of Contents
1
Device Overview ......................................... 1
6
Detailed Description ................................... 45
1.1
Features .............................................. 1
6.1
Overview
1.2
Applications ........................................... 1
6.2
Functional Block Diagram ........................... 46
1.3
Description ............................................ 1
6.3
Power Reference .................................... 47
1.4
Functional Block Diagram ............................ 2
6.4
Power Resources ................................... 47
2
3
4
Revision History ......................................... 3
Device Comparison Table.............................. 8
Pin Configuration and Functions ..................... 9
6.5
Embedded Power Controller (EPC) ................. 47
6.6
6.7
PWM and LED Generators ......................... 58
Dynamic Voltage Frequency Scaling and Adaptive
Voltage Scaling Operation .......................... 58
5
Specifications ........................................... 12
Pin Attributes ........................................ 10
4.1
5.1
Absolute Maximum Ratings ......................... 12
5.2
ESD Ratings
5.3
Recommended Operating Conditions ............... 13
5.4
Thermal Information ................................. 13
5.5
Electrical Characteristics: I/O Pullup and Pulldown . 14
5.6
Electrical Characteristics: Digital I/O Voltage ....... 14
5.7
5.8
Electrical Characteristics: Power Consumption ..... 16
Electrical Characteristics: Power References and
Thresholds .......................................... 17
Electrical Characteristics: Thermal Monitoring and
Shutdown ............................................ 18
5.9
........................................
12
7
............................................
45
.................................. 58
............................. 59
6.10 Backup Battery Management ....................... 62
6.11 Backup Registers ................................... 62
6.12 I2C Interface ......................................... 62
6.13 Thermal Monitoring and Shutdown ................. 64
6.14 Interrupts ............................................ 64
6.15 Register Maps ....................................... 65
Applications, Implementation, and Layout ...... 120
7.1
Application Information ............................ 120
7.2
Typical Application ................................ 120
7.3
Power Supply Recommendations ................. 131
Device and Documentation Support .............. 132
8.1
Device Support..................................... 132
8.2
Documentation Support ............................ 133
8.3
Receiving Notification of Documentation Updates. 133
8.4
Community Resources ............................. 133
8.5
Trademarks ........................................ 133
8.6
Electrostatic Discharge Caution ................... 133
8.7
Glossary............................................ 134
6.8
32-kHz RTC Clock
6.9
Real Time Clock (RTC)
5.10
Electrical Characteristics: 32-kHz RTC Clock....... 18
5.11
Electrical Characteristics: Backup Battery Charger . 19
5.12
Electrical Characteristics: VRTC LDO
5.13
Electrical Characteristics: VIO SMPS ............... 20
5.14
Electrical Characteristics: VDD1 SMPS............. 21
5.15
Electrical Characteristics: VDD2 SMPS............. 23
5.16
Electrical Characteristics: VDDCtrl SMPS .......... 25
5.17
Electrical Characteristics: LDO1 and LDO2......... 27
5.18
Electrical Characteristics: LDO3 and LDO4......... 29
5.19
Electrical Characteristics: LDO5
....................
31
Mechanical, Packaging, and Orderable
Information ............................................. 134
5.20
Electrical Characteristics: LDO6, LDO7, and LDO8
32
9.1
5.21
Timing and Switching Characteristics ............... 35
..............
8
19
9
Package Description ............................... 134
2 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision R (May 2018) to Revision S
•
Added TPS65911A to the device comparison table
Page
.............................................................................
Changes from Revision Q (March 2016) to Revision R
•
•
•
•
•
•
•
•
•
•
8
Page
Changed Device Information table to a single row reflecting all orderable devices ......................................... 2
Changed the Functional Block Diagram ........................................................................................... 2
Deleted lead temperature from the Recommended Operating Conditions table ........................................... 13
Corrected VIO output voltage from 2.2 V to 2.5 V .............................................................................. 20
Changed the VDDCtrl slew rate from 100 mV/20µs to 5 mV/µs for clarity ................................................. 25
Added SEL options for VOUT < 1 V ............................................................................................... 30
Added the Overview section ...................................................................................................... 45
Corrected VIO voltage from 2.2 V to 2.5 V ...................................................................................... 47
Corrected the SEL bits for 1 V selection for LDO1_REG and LDO2_REG ................................................. 87
Corrected the SEL bits for 0.8 V to 0.9 V options. Added the SEL bits for 0.95 V. ........................................ 90
Revision History
Copyright © 2010–2018, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: TPS65911
3
TPS65911
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
•
•
www.ti.com
Added the Applications, Implementation, and Layout section .............................................................. 120
Added specific layout recommendations, and added layout diagrams which show the routing around the device .. 129
Changes from Revision P (August 2015) to Revision Q
•
•
•
•
•
Added TPS659118 device .......................................................................................................... 1
Deleted TPS659116 device ......................................................................................................... 1
Deleted "Ordering" column from Device Comparison table ..................................................................... 8
Corrected wording in Thermal Metric column of Section 5.4 and added table note 1 ..................................... 13
Added disclaimer note to Applications, Implementation, and Layout section ............................................. 120
Changes from Revision O (March 2015) to Revision P
•
4
Page
Corrected orderable part number for TPS65911062 in the Device Comparison Table ..................................... 8
Corrected column heading from "MAX" to "UNIT" ............................................................................. 35
Changes from Revision M (May 2014) to Revision N
•
•
Page
Added TPS659114A2ZRCR device ................................................................................................ 1
Changes from Revision N (November 2014) to Revision O
•
•
Page
Page
Added TPS6591133 device ........................................................................................................ 1
Changed data sheet to TI standard format. ....................................................................................... 1
Revision History
Copyright © 2010–2018, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: TPS65911
TPS65911
www.ti.com
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Detailed Revision History
(1)
(2)
(3)
(4)
Version
Literature Number
Date
*
SWCS049
June 2010
See
Notes
(1)
A
SWCS049A
February 2011
See
(2)
.
.
B
SWCS049B
February 2011
See
(3)
C
SWCS049C
May 2011
See
(4)
.
.
TPS65911 Data Manual, SWCS049 - Initial release.
TPS65911 Data Manual, SWCS049A - Version A:
• Update Figure 1-1: LDO1, LDO2, LDO3, LDO6, and LDO7.
• Remove table, SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS
• Update Section 5.3: Adjust pin names and add exception.
• Update Table 7-2: VDDCtrl SMPS, update FET part number.
• Update: Section 5.6: Add updated BOOT1 characteristics.
• Update: Section 5.17: Update LDO1 and LDO2 characteristics.
• Update Section 5.19: Update LDO5.
• Update Section 5.20: Update LDO6, LOD7, and LDO8.
• Update Table 6-1: Update LDO1, LDO2, LDO3, LOD7, and LDO8
• Update Table 6-2: Remove SEL [6:0] selection bits.
• Update Section 6.5.3.6: Add more explanation and reorganize section.
• Add explanation to: Section 6.5.3.6, Section 6.5.3.9, Section 6.5.3.10, and Section 6.5.3.11.
• Update Section 6.12: Add Section 6.12.1.
• Update Table 6-6, Register Rest values.
• Update Register Table: Table 6-43, Table 6-44, Table 6-53, and Table 6-55.
• Update : BGA Pin column.
• Update Packaging Information.
TPS65911 Data Manual, SWCS049B - Version B:
• Update VCC6 in Section 5.1.
TPS65911 Data Manual, SWCS049C - Version C:
• Update , BGA Pins: NRESPWRON, VCC1, GND1, VCCIO, GNDIO, AGND, and AGND2.
Revision History
Copyright © 2010–2018, Texas Instruments Incorporated
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Product Folder Links: TPS65911
5
TPS65911
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
www.ti.com
Detailed Revision History (continued)
(5)
(6)
(7)
6
Version
Literature Number
Date
D
SWCS049D
July 2011
Notes
See
(5)
.
E
SWCS049E
July 2011
See
(6)
F
SWCS049F
August 2011
See
(7)
.
.
TPS65911 Data Manual, SWCS049D - Version D:
• Update Section 5.1:
• Add VBACKUP
• Voltage range on balls HDRST - Replace "VRTCMAX + 0.32 by "7"
• Update Section 5.3:
• Add VCC4 and VBACKUP
• Input voltage range on pins or balls - Remove VCC4
• Update Section 5.5: Change "HDRST programmable.." to "HDREST, PWRDN programmable.."
• Update Section 5.12: Specify Input voltage range of VCC7
• Update Section 5.13: Add discharge resistance
• Update Section 5.14:
• Add DC output voltage maximum value
• Add discharge resistance
• Update VGAIN_SEL test conditions and typ value
• Update Section 5.15:
• Add DC output voltage maximum value
• Add discharge resistance
• Update VGAIN_SEL test conditions
• Update Section 5.16: Add tablenote to Rated output current 6000 mA
• Update Section 5.21.2:
• Update introductory statement
• Add note to Figure 5-1
• Align Parameters in Table 5-3 with Figure 5-1
• Update Section 5.21.3: Add note toFigure 5-2
• Update Section 4: Add J3 to AGND in
• Update Section 6:
• Update Table 6-1: VDD1 and VDD2 voltages
• Device POWER ON enable conditions: Add additional device power enable condition
• Device SLEEP enable conditions: Replace "... keeping the SLEEP signal floating, or ..." with "... keeping the SLEEP signal in the
active polarity state, or..."
• Device reset scenarios: Replace "VCC7 < VBNPR" with " VDD7 < VBNPR and BB < VBNPR"
• Update introduction for Table 6-2
• Update Table 6-2: Remove all values in EEPROM Boot column
• Update Table 6-3:
• Remove all values in EEPROM Boot column
• Update INT_MSK_REG.VMBHI_MSK description
• Update Package Thermal Characteristics: Pin count from 96 to 98
• Update Section 6.15.1:
• Update Table 6-37, Table 6-38, Table 6-40, and Table 6-41: SEL bit description
• Update Table 6-67: Update VMBHI_IT_MSK bit description
• Update Table 6-80: Update GPIO_SEL bit description - Replace LED1 out with PWM out
TPS65911 Data Manual, SWCS049E - Version E: Update Packaging Information.
TPS65911 Data Manual, SWCS049F - Version F:
• Add Section 7.2.4.1.
• Update Table 6-67: Update bit 1, VMBHI_IT_MSK description.
• Update Section 6.5.1: Device reset scenarios: Replace "VDD7 < VBNPR" with " VCC7 < VBNPR"
• Add Ordering Information.
Revision History
Copyright © 2010–2018, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: TPS65911
TPS65911
www.ti.com
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Detailed Revision History (continued)
(8)
(9)
(10)
(11)
(12)
(13)
(14)
Version
Literature Number
Date
G
SWCS049G
October 2011
Notes
See
(8)
.
H
SWCS049H
May 2012
See
(9)
I
SWCS049I
June 2012
See
(10)
J
SWCS049J
September 2012
See
(11)
K
SWCS049K
December 2012
See
(12)
L
SWCS049L
February 2014
See
(13)
M
SWCS049M
May 2014
See
(14)
TPS65911 Data Manual, SWCS049G - Version G:
• Update Section 5.17, Section 5.18, Section 5.19, Section 5.20:
• Update turn-on time
• Update DC line regulation
• Update Section 5.13
• Update rated output current IOUTmax.
• Update Section 5.14 and Section 5.15
• Update rated output current IOUTmax.
• Update DC line regulation
• Update DC load regulation
• Update Section 5.6
• Update Related Open-Drain I/Os: GPIO2, GPIO7
• Update Section 5.16
• Add Supply Current, Internal Reference Voltage, Output discharge, Output drivers, Boot strap switch, Duty and frequency control,
softstart, current sense protection, UVLO, and thermal shutdown.
• Remove DC line regulation, DC load regulation, Transient load regulation, Overshoot/undershoot, Rated output IOUTmax, and
Conversion efficiency.
• Section 5.13 and Section 5.15 - Remove Iout = 1500 mA value
• Table 6-1 - Update VIO, VDD1, VDD2, and VDDCtrl
• Figure 1-1 - Update VIO, VDD1, and VDD2
TPS65911 Data Manual, SWCS049H - Version H:
• Update Section 5.13
• Update Rated output current description- add ILMAX bit configuration
• Update PMOS current limit (high-side) description
• Update NMOS current limit (high-side) description
• Update Figure 5-2 - CLK32KOUT out pin name (fixed typo)
• Update Figure 6-1
• Update Table 6-35, VIO_REG - Update ILMAX description
• Update Table 6-36, VDD1_REG - Update ILMAX and and TSTEP field numbers and VGAIN_SEL description
• Update Table 6-39, VDD2_REG - Update VGAIN_SEL description; align bit field numbering
• Update Table 6-43, VDDCRTL_OP_REG - Update SEL description
• Update Table 6-44, VDDCRTL_SR_REG - Update SEL description
• Update Table 5-4 - tdbPWRONF: PWRON falling-edge debouncing delay - Update unit of measure
• Update Table 5-5 - Replace tACT2SLP by tACT2SLPCK32K
• Update Figure 5-5 - Replace tdONVMBHI by tdONPWHOLD
• Update Table 5-6 - Replace tdONVMBHI by tdONPWHOLD
• Update Section 6.5.3.6 - Replace 100 µs by 100 ms
• Update Table 6-56 - Add Bit 0,1, and 3 : TURN OFF RESET to the description
• Update Table 6-57 - Add TSLOT_LENGTH: TURN OFF RESET to the description
• Update Table 6-72 - Add footnote
TPS65911 Data Manual, SWCS049I - Version I:
• Update Section 5.1 - Add VDDIO
• Update Section 5.3 - Add VDDIO
• Update Section 5.5 - Remove PWRDN
• Update - Remove PD from PWRDN
TPS65911 Data Manual, SWCS049J - Version J:
• Update Section 5.3: Fix typo on HDRST pin
• Update Section 6.15.1: Update full reset:
• Full reset: All digital logic of device is reset.
• Caused by POR (power on reset) when VCC7 < VBNPR and BB < VBNPR
TPS65911 Data Manual, SWCS049K - Version K
• Update Table 6-3 - Changed VMBCH_REG to EEPROM
TPS65911 Data Manual, SWCS049L - Version L
• Update Device Comparison Table - Added TPS659116
TPS65911 Data Manual, SWCS049M - Version M
• Update Device Comparison Table - Added TPS65911062
Revision History
Copyright © 2010–2018, Texas Instruments Incorporated
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Product Folder Links: TPS65911
7
TPS65911
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
www.ti.com
3 Device Comparison Table
DEVICE OPTION
TPS659110 (1)
DDR2
NVIDIA T30
DDR3
NVIDIA T30
N/A
DM8168, DM8167, C6A8168, C6A8167, AM3894,
AM3892
TPS659113 (1)
N/A
DM8148, DM8147, DM8146, C6A8148, C6A8147,
C6A8143, AM3874, AM3872, AM3871
TPS6591133 (1)
N/A
DM8148, DM8147, DM8146, C6A8148, C6A8147,
C6A8143, AM3874, AM3872, AM3871
TPS659114 (1)
DDR3
Freescale i.MX6
(1)
DDR3L
66AK2G02
TPS65911A (1)
DDR3L
66AK2G12
TPS659118
8
PROCESSORS
(1)
TPS659112
(1)
MEMORY SUPPORT
(DDR3 or DDR2)
Refer to the corresponding user's guide for the complete EEPROM setting before ordering.
Device Comparison Table
Copyright © 2010–2018, Texas Instruments Incorporated
Submit Documentation Feedback
Product Folder Links: TPS65911
TPS65911
www.ti.com
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
4 Pin Configuration and Functions
Figure 4-1 (top view) and Figure 4-2 (bottom view) show the 98-pin ZRC Plastic Ball-Grid Array (BGA).
Bottom view
Top view
N
AGND2
VDD
IO
LDO1
VCC6
LDO2
VCC3
PWRD
N
PWRHO
LD
N
PWRHO
LD
PWRD
N
VCC3
LDO2
VCC6
LDO1
VDD
IO
AGND2
M
AGND2
EN1
EN2
SDA_S
DI
SCL_S
CK
LDO7
LDO6
LDO8
M
LDO8
LDO6
LDO7
SCL_S
CK
SDA_S
DI
EN2
EN1
AGND2
L
VCC
IO
VCC
IO
HDRST
GPIO0
GPIO7
INT1
GPIO2
VCC4
L
VCC4
GPIO2
INT1
GPIO7
GPIO0
HDRST
VCC
IO
VCC
IO
K
SWIO
SWIO
AGND
VFB2
LDO5
K
LDO5
VFB2
AGND
SWIO
SWIO
J
GND
IO
GND
IO
AGND
BOOT1
AGND
AGND
GND2
GND2
J
GND2
GND2
AGND
H
VFB
IO
GPIO4
AGND
AGND
NRESP
WRON
SW2
SW2
H
SW2
SW2
G
VREF
REFGN
D
GPIO5
GPIO6
VCC2
VCC2
G
VCC2
VCC2
GPIO6
AGND
F
OSC32
KIN
OSC32
KOUT
GPIO1
AGND
CLK32
KOUT
VCC1
VCC1
SLEEP
F
SLEEP
VCC1
VCC1
CLK32
KOUT
E
VCCS
LDO3
AGND
AGND
PWRO
N
SW1
VCC1
E
VCC1
SW1
D
SW1
SW1
C
GND1
GND1
B
DGND
DGND
A
DGND
1
D
VCC5
C
LDO4
B
TESTV
A
GNDC
8
GPIO8
VBACK
UP
AGND
NRESP
WRON2
TRAN
GPIO3
VCC7
GNDC
7
DRVL
6
AGND
EN
VFB
VRTC
V5IN
5
VFB1
GND1
GND1
PGOOD
VOUT
SW
4
SW1
TRIP
DRVH
3
DGND
VBST
2
SW1
GPIO8
AGND
BOOT1
AGND
GND
IO
GND
IO
NRESP
WRON
AGND
AGND
GPIO4
VFB
IO
GPIO5
REFGN
D
VREF
AGND
GPIO1
OSC32
KOUT
OSC32
KIN
PWRO
N
AGND
AGND
LDO3
VCCS
VFB1
EN
AGND
VBACK
UP
VCC5
PGOOD
VFB
TRAN
NRESP
WRON2
LDO4
TRIP
VOUT
VRTC
VCC7
GPIO3
TESTV
VBST
DRVH
SW
V5IN
DRVL
GNDC
GNDC
2
3
4
5
6
7
GND1
GND1
DGND
DGND
1
SWCS049-002
8
SWCS049-003
Figure 4-1. 98-Pin ZRC BGA MicroStar™ Junior
(Top View)
Figure 4-2. 98-Pin ZRC BGA MicroStar™ Junior
(Bottom View)
Pin Configuration and Functions
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
4.1
www.ti.com
Pin Attributes
Pin Attributes
PIN
TYPE
SUPPLIES
AGND
D6, E5, E6,
F5, G4, H5,
H6, J3, J4,
J6, K3
I/O
Power
AGND
Analog ground
No
AGND2
M8, N8
I/O
Power
AGND
Analog ground
No
BOOT1
J5
I
Digital
VRTC, DGND
NO.
CLK32KOUT
DGND
A1, B1, B2
I/O
Power
DGND
DRVH
A3
O
Analog
VBST, GNDC
VDDCtrl, High-side FET driver output
DRVL
A6
O
Analog
V5IN, GNDC
VDDCtrl, FET driver output
EN
D5
I
Analog
VCC7, GNDC
Internal functional pin, leave floating
EN1
M7
I/O
Digital
VDDIO, DGND
Enable for supplies or
voltage scaling dedicated I2C clock
External PU
EN2
M6
I/O
Digital
VDDIO, DGND
Enable for supplies or
voltage scaling dedicated I2C data
External PU
GNDC
A7, A8
I/O
Power
GNDC
VDDCtrl, Controller ground
GNDIO
J7, J8
I/O
Power
VCCIO, GNDIO
VIO DCDC Power ground
No
GND1
C1, C2, D3
I/O
Power
VCC1, GND1
VDD1 DCDC Power ground
No
GND2
J1, J2
I/O
Power
VCC2, GND2
VDD2 DCDC Power ground
GPIO0
L5
I/O
Digital
VCC7, DGND
GPIO, push-pull or OD as output
OD: External PU
GPIO1
F6
I/O, OD
Digital
VRTC, DGND
GPIO or LED1 output
OD: External PU
GPIO2
L2
I/O, OD
Digital
VRTC, DGND
GPIO or DCDC clock synchronization
OD: External PU
GPIO3
B7
I/O, OD
Digital
VRTC, DGND
GPIO or LED2 output
OD: External PU
GPIO4
H7
I/O, OD
Digital
VRTC, DGND
GPIO
OD: External PU
GPIO5
G6
I/O, OD
Digital
VRTC, DGND
GPIO
OD: external PU
GPIO6
G3
I/O; OD
Digital
VRTC, DGND
GPIO
OD: External PU
GPIO7
L4
I/O, OD
Digital
VRTC, DGND
GPIO
OD: External PU
GPIO8
K5
I/O, OD
Digital
VRTC, DGND
GPIO
OD: External PU
HDRST
L6
I
Digital
VRTC, DGND
Cold reset
PD
INT1
L3
O
Digital
VDDIO, DGND
Interrupt flag
No
LDO1
N6
O
Power
VCC6, REFGND
LDO Regulator output
No
LDO2
N4
O
Power
VCC6, REFGND
LDO Regulator output
No
LDO3
E7
O
Power
VCC5, REFGND
LDO Regulator output
PD 5 µA
LDO4
C8
O
Power
VCC5, REFGND
LDO Regulator output
PD 5 µA
LDO5
K1
O
Power
VCC4, REFGND
LDO Regulator output
PD 5 µA
LDO6
M2
O
Power
VCC3, REFGND
LDO Regulator output
PD 5 µA
LDO7
M3
O
Power
VCC3, REFGND
LDO Regulator output
PD 5 µA
LDO8
M1
O
Power
VCC3, REFGND
LDO Regulator output
O
Digital
VDDIO, DGND
32-kHz clock output
No
PD disable in
ACTIVE or SLEEP
state
O
H4
VDDIO, DGND
Power-up sequence selection
F4
NRESPWRO
N
Digital
DESCRIPTION
PULLUP
PULLDOWN
I/O
NAME
Digital ground
No
No
PD 5 µA
Power off reset
PD active during
device OFF state
Second NRESPWRON output
PD active during
device OFF state.
External pullup in
ACTIVE state.
NRESPWRO
N2
C7
O, OD
Digital
VRTC, DGND
OSC32KIN
F8
I
Analog
VRTC, REFGND
32-kHz crystal oscillator
No
OSC32KOUT
F7
I
Analog
VRTC, REFGND
32-kHz crystal oscillator
No
10
Pin Configuration and Functions
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Pin Attributes (continued)
PIN
PULLUP
PULLDOWN
I/O
TYPE
SUPPLIES
DESCRIPTION
C4
O, OD
Analog
VCC7, GNDC
VDDCtrl, internal signal, leave floating
(controller trimming only)
PWRDN
N2
I
Analog
VRTC, DGND
Reset input (for example, thermal
reset)
PWRHOLD
N1
I
Digital
VRTC, DGND
Switch-on, switch off control signal or
GPI
Programmable PD
(default active)
PWRON
E4
I
Digital
VCC7, DGND
External switch-on control (ON button)
Programmable PU
(default active)
REFGND
G7
I/O
Analog
REFGND
NAME
NO.
PGOOD
Reference ground
No
SCL_SCK
M4
I/O
Digital
VDDIO, DGND
I2C bidirectional clock signal or serial
peripheral interface clock input
(multiplexed)
SDA_SDI
M5
I/O
Digital
VDDIO, DGND
I2C bidirectional data signal or serial
peripheral interface data input
(multiplexed)
SLEEP
F1
I
Digital
VDDIO, DGND
ACTIVE-SLEEP state transition control
signal
SW
A4
I
Analog
VBST, GNDC
VDDCtrl, Switch node
SWIO
K7, K8
O
Power
VCCIO, GNDIO
VIO DCDC switched output
No
SW1
D1, D2, E2
O
Power
VCC1, GND1
VDD1 DCDC switched output
No
SW2
H1, H2
O
Power
VCC2, GND2
VDD2 DCDC switched output
No
B8
O
Analog
VCC7, AGND
Analog test output (DFT)
No
TESTV
TRAN
C6
I
Analog
VCC7, GNDC
Internal functional pin, leave floating
(controller trimming only)
TRIP
B3
I
Analog
V5IN, GNDC
VDDCtrl, OCL detection threshold pin
VBACKUP
D7
I
Power
VBST
A2
VCCIO
L7, L8
VCCS
E8
VCC1
E1, F2, F3
VCC2
G1, G2
VCC3
VCC4
I
VBACKUP, AGND Backup battery input
External PU
External PU
Programmable PD
(default active)
No
VDDCtrl, supply for high-side FET
driver
Analog
VBST, GNDC
I
Power
VCCIO, GNDIO
I/O
Analog
VCC7, DGND
Input for two comparators
I
Power
VCC1, GND1
VDD1 DCDC power Input
No
I
Power
VCC2, GND2
VDD2 DCDC power Input
No
N3
I
Power
VCC3, AGND2
LDO6, LDO7, LDO8 power Input
No
L1
I
Power
VCC4, AGND2
LDO5 power Input
No
VCC5
D8
I
Power
VCC5, AGND
LDO3, LDO4 power Input
No
VCC6
N5
I
Power
VCC6, AGND2
LDO1, LDO2 power Input
No
VRTC power input and analog
references supply
No
No
VCC7
B6
I
VDDIO
N7
VFB
C5
VFBIO
VFB1
VIO DCDC power Input
No
Power
VCC7, REFGND
I
Power
VDDIO, DGND
Digital Ios supply
I
Analog
VOUT, GNDC
VDDCtrl, slew rate control capacitance
H8
I
Analog
VCC7, DGND
VIO feedback voltage
PD 5 µA
D4
I
Analog
VCC7, DGND
VDD1 feedback voltage
PD 5 µA
VFB2
K2
I
Analog
VCC7, DGND
VDD2 DCDC feedback voltage
PD 5 µA
VOUT
B4
I
Analog
VOUT, GNDC
VDDCtrl, Feedback input
VREF
G8
O
Analog
VCC7, REFGND
Band-gap voltage
VRTC
B5
O
Power
VCC7, REFGND
LDO Regulator output
V5IN
A5
I
Power
V5IN, GNDC
No
PD 5 µA
VDDCtrl, 5-V input
Pin Configuration and Functions
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5 Specifications
5.1
Absolute Maximum Ratings
Over operating free-air temperature range (unless otherwise noted) (1)
MIN
MAX
VCC1, VCC2, VCCIO, VCC3, VCC4, VCC5, VCC7, VBACKUP,
V5IN, TRIP
–0.3
7
VCC6
–0.3
3.6
VDDIO
–0.3
3.6
VBST
–0.3
37
–5
30
SW
Voltage range on
pins
Voltage range on
pins
SW1, SW2, SWIO
–0.3
7
VFB1, VFB2, VFBIO
–0.3
3.6
VOUT, VFB
–0.3
7
OSC32KIN, OSC32KOUT, BOOT1
–0.3
VRTCMAX + 0.3
SDA_SDI, SCL_SCK, EN2, EN1, SLEEP, INT1, CLK32KOUT,
NRESPWRON
–0.3
VDDIOMAX + 0.3
PWRON
–0.3
7
PWRHOLD, GPIO0
–0.3
7
GPIO1, GPIO2, GPIO3, GPIO4, GPIO5, GPIO6, GPIO7, GPIO8 (2)
–0.3
7
HDRST
–0.3
7
NRESPWRON2 (2)
–0.3
7
PWRDN (3)
–0.3
7
VCCS
UNIT
V
V
–0.3
7
Peak output current on all other pins than power resources
–5
5.0
mA
Functional junction temperature
–45
150
°C
Storage temperature, Tstg
–65
150
°C
(1)
(2)
(3)
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.
I/O supplied from VRTC, but can be driven from VCC7 or to VCC7 voltage level.
Input supplied from VRTC, but can be driven from VCC7 voltage level.
5.2
ESD Ratings
VALUE
VESD
(1)
(2)
12
Electrostatic
discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS001 (1)
±2000
Charged device model (CDM), per JESD22-C101 (2)
±500
UNIT
V
JEDEC document JEP155 statues that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP155 statues that 250-V HBM allows safe manufacturing with a standard ESD control process.
Specifications
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5.3
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Recommended Operating Conditions
Over operating free-air temperature range (unless otherwise noted) (1)
VCC1, VCC2, VCCIO, VCC5, VCC7, VCCS, VCC4,
VBACKUP
Input voltage range
NOM
MAX
2.7
3.8
5.5
VCC3
1.7
3.8
5.5
VDDIO
1.65
1.8/3.3
3.45
VCC6
1.4
3.3
3.6
V5IN
4.5
6.5
VBST
–0.1
3.45
SW ( 2.7 V
VOUT
5.5
SEL[6:0] = 0110011
VGAIN_SEL = 00,
IOUT = 0 to IOUTmax
–3%
P-channel leakage
current
(ILK_PMOS)
N-channel MOSFET
On-resistance
(RDS(ON)_NMOS)
N-channel leakage
current
(ILK_NMOS)
V
1.2
3%
0.6
SEL[6:0] = 000000: power
down
V
0
VGAIN_SEL = 10, SEL = 0101011 = 43, IOUT = 0 to
IOUTmax
–3%
2.2
3%
VGAIN_SEL = 11, SEL = 0101011 = 43, IOUT = 0 to
IOUTmax
–3%
3.3
3%
DC output maximum
voltage maximum value
P-channel MOSFET
On-resistance
(RDS(ON)_PMOS)
UNIT
1.5
Min programmable voltage,
SEL[6:0] = 0000011
DC output voltage
(VOUT)
Rated output current
(IOUTmax)
MAX
VOUT ≤ 2.7 V
Max programmable voltage,
SEL[6:0] = 1001011
DC output voltage
programmable step
(VOUTSTEP)
TYP
VGAIN_SEL = 00, 72 steps
VDD1 output voltage = (0.6 to 2.2 V)
1500
VDD1 output voltage = 3.2 V
1200
VDD1 output voltage = (1.2 V, 1.35 V, 1.5 V)
VINmin = 3 V
2000
3.3
V
12.5
mV
mA
VIN = VINmin
300
VIN = 3.8 V
250
VIN = VINmax, SW1 = 0 V
400
mΩ
2
VIN = VMIN
300
VIN = 3.8 V
250
VIN = VINmax, SW1 = VINmax
400
µA
mΩ
2
Specifications
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µA
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Electrical Characteristics: VDD1 SMPS (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
PMOS current limit
(high-side)
TEST CONDITIONS
VIN = VINmin to VINmax
MIN
TYP
MAX
1800
NMOS current limit (low- VIN = VINmin to VINmax, source current load
side)
VIN = VINmin to VINmax, sink current load
mA
1800
mA
1800
On mode, VIN = VINmin to VINmax
at IOUT = 1500 mA
VDD1 output voltage = (0.6 to 1.5 V)
20
On mode, VIN = VINmin to VINmax
at IOUT = 2000 mA
VDD1 output voltage = (1.2 V, 1.35 V, 1.5 V)
VINmin = 3 V
30
On mode, VIN = VINmin to VINmax
at IOUT = 1500 mA
VDD1 output voltage = 2.2 V
30
On mode, VIN = VINmin to VINmax
at IOUT = 1200 mA
VDD1 output voltage = 3.2 V
30
On mode, VIN = VINmin to VINmax
at IOUT = 1500 mA
VDD1 output voltage = (0.6 to 1.5 V)
20
On mode, VIN = VINmin to VINmax
at IOUT = 2000 mA
VDD1 output voltage = (1.2 V, 1.35 V, 1.5 V)
VINmin = 3 V
30
On mode, VIN = VINmin to VINmax
at IOUT = 1500 mA
VDD1 output voltage = 2.2 V
30
On mode, VIN = VINmin to VINmax
at IOUT = 1200 mA
VDD1 output voltage = 3.2 V
30
Transient load
regulation
VIN = 3.8 V, VOUT = 1.2 V
IOUT = 0 to 500 mA , Maximum slew = 100 mA/µs
IOUT = 700 mA to 1.2 A , Maximum slew = 100 mA/µs
50
Turnon time (ton) off to
on
IOUT = 200 mA
DC load regulation
DC line regulation
mV
mV
350
TSTEP[2:0] = 001
From VOUT = 0.6 V to 1.5 V
Output voltage transition
and VOUT = 1.5 V to 0.6 V TSTEP[2:0] = 011 (default)
rate
IOUT = 500 mA
TSTEP[2:0] = 111
Overshoot
µs
7.5
mV/µs
2.5
SMPS turned on
3%
Switching frequency
0.025 ×
VOUT
2.7
3
Duty cycle
VPP
3.3
MHz
100%
Minimum on time
(tON(MIN))
P-channel MOSFET
35
Discharge resistor for
power-down sequence
RDIS
30
VFB1 internal resistance
0.5
ns
50
1
Off
Ω
MΩ
1
PWM mode, IOUT = 0 mA, VIN = 3.8 V, VDD1_PSKIP = 0
22
mV
12.5
Power-save mode ripple
PFM (pulse skip mode), IOUT = 1 mA
voltage
Ground current (IQ)
UNIT
7500
Pulse skipping mode, no switching
78
Low-power (pulse skipping) mode, no switching
ST[1:0] = 11
63
Specifications
µA
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Electrical Characteristics: VDD1 SMPS (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
PWM mode, DCRL < 0.1
Ω, VOUT = 1.2 V, VIN = 3.6
V
Conversion efficiency
PFM mode, DCRL < 0.1 Ω,
VOUT = 1.2 V, VIN = 3.6 V
MIN
TYP
IOUT = 10 mA
35%
IOUT = 100 mA
78%
IOUT = 400 mA
80%
IOUT = 800 mA
74%
IOUT = 1500 mA
62%
IOUT = 1 mA
59%
IOUT = 10 mA
70%
IOUT = 400 mA
80%
MAX
UNIT
MAX
UNIT
5.15 Electrical Characteristics: VDD2 SMPS
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
Input voltage on VCC2
and VCC7 (VIN)
TEST CONDITIONS
MIN
2.7
5.5
VOUT > 2.7 V
VOUT
5.5
Max programmable voltage,
SEL[6:0] = 1001011
SEL[6:0] = 0110011
DC output voltage
(VOUT)
–3%
Min programmable voltage,
SEL[6:0] = 0000011
VGAIN_SEL = 00,
IOUT = 0 to IOUTmax
Rated output current
IOUTmax
1.2
3%
0.6
SEL[6:0] = 000000: power
down
V
0
VGAIN_SEL = 10,
SEL = 0101011 = 43
–3%
2.2
3%
VGAIN_SEL = 11, SEL =
0101011 = 43
–3%
3.3
3%
VGAIN_SEL = 00, 72 steps
VDD2 output voltage = 0.6 to 1.5 V
1500
VDD2 output voltage = 2.2 V
1200
VDD2 output voltage = 3.2 V
1200
3.3
V
12.5
mV
mA
P-channel MOSFET
VIN = VINmin
300
On-resistance
(RDS(ON)_PMOS)
VIN = 3.8 V
250
P-channel leakage
current (ILK_PMOS)
VIN = VINmax, SW2 = 0 V
N-channel MOSFET
VIN = VMIN
300
On-resistance
(RDS(ON)_NMOS)
VIN = 3.8 V
250
N-channel leakage
current (ILK_NMOS)
VIN = VINmax, SW2 = VINmax
PMOS current limit
(high-side)
VIN = VINmin to VINmax, source current load
1800
NMOS current limit (low- VIN = VINmin to VINmax, source current load
side)
VIN = VINmin to VINmax, sink current load
1800
DC load regulation
V
1.5
DC output maximum
voltage maximum value
DC output voltage
programmable step
(VOUTSTEP)
TYP
VOUT ≤ 2.7 V
mΩ
400
mΩ
2
µA
mΩ
400
mΩ
2
µA
mA
mA
1800
On mode, VIN = VINmin to VINmax at IOUT = 1500 mA
VDD2 output voltage = 0.6 to 1.5V
20
On mode, VIN = VINmin to VINmax at IOUT = 1200 mA
VDD2 output voltage = 2.2 to 3.3 V
30
mV
Specifications
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Electrical Characteristics: VDD2 SMPS (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
On mode, VIN = VINmin to VINmax at IOUT = 1500 mA
VDD2 output voltage = 0.6 to 1.5V
20
On mode, VIN = VINmin to VINmax at IOUT = 1200 mA
VDD2 output voltage = 2.2 to 3.3 V
30
Transient load
regulation
VIN = 3.8 V, VOUT = 1.2 V
IOUT = 0 to 500 mA , Maximum slew = 100 mA/µs
IOUT = 700 mA to 1.2 A , Maximum slew = 100 mA/µs
50
Turnon time (ton) Off to
on
IOUT = 200 mA
DC line regulation
mV
350
TSTEP[2:0] = 001
From VOUT = 0.6 V to 1.5 V
Output voltage transition
and VOUT = 1.5 V to 0.6 V TSTEP[2:0] = 011 (default)
rate
IOUT = 500 mA
TSTEP[2:0] = 111
Overshoot
mV/µs
2.5
3%
0.025 ×
VOUT
2.7
3
Duty cycle
VPP
3.3
MHz
100%
Minimum on time
P-Channel MOSFET
35
Discharge resistor for
power-down sequence
(RDIS)
30
VFB2 internal resistance
0.5
78
Low-power (pulse skipping) mode, no switching ST[1:0] =
11
63
PWM mode, DCRL < 50
mΩ, VOUT = 3.3 V, VIN = 5
V
PFM mode, DCRL < 50
mΩ, VOUT = 3.3 V, VIN = 5
V
Ω
MΩ
7500
PFM (pulse skipping) mode, no switching
PFM mode, DCRL < 50
mΩ, VOUT = 1.2 V, VIN =
3.6 V
50
1
PWM mode, IOUT = 0 mA, VIN = 3.8 V, VDD2_PSKIP = 0
PWM mode, DCRL < 50
mΩ, VOUT = 1.2 V, VIN =
3.6 V
ns
1
Off
24
µs
7.5
SMPS turned on
Switching frequency
Conversion efficiency
mV
12.5
Power-save mode ripple
PFM (pulse skip mode), IOUT = 1 mA
voltage
Ground current (IQ)
UNIT
IOUT = 10 mA
35%
IOUT = 100 mA
78%
IOUT = 400 mA
80%
IOUT = 800 mA
74%
IOUT = 1200 mA
66%
IOUT = 1500 mA
62%
IOUT = 1 mA
59%
IOUT = 10 mA
70%
IOUT = 400 mA
80%
IOUT = 10 mA
39%
IOUT = 100 mA
85%
IOUT = 400 mA
91%
IOUT = 800 mA
90%
IOUT = 1200 mA
86%
IOUT = 1 mA
80%
IOUT = 10 mA
82%
IOUT = 400 mA
92%
Specifications
µA
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
5.16 Electrical Characteristics: VDDCtrl SMPS
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
Input voltage for external
FETs
VIN
Input voltage V5IN
MIN
VOUT
DC output voltage
25
V
4.5
5.5
V
1.4
...
SEL[6:0] = 0110001
1.2
V
SEL[6:0] = 0000001 to
0000011
0.6
SEL[6:0] = 000000: power
down
VOUTSTEP
DC output voltage
programmable step
ton
Turnon time, off to on
From EN high to Vout = 95%
Output voltage transition
rate
From VOUT = 0.6 V to 1.4 V and VOUT = 1.4 V to 0.6 V IOUT =
500 mA
0
12.5
mV
900
µs
(1)
5
IOUT = 100 mA
mV/µs
10
IOUT = 1 A
100
IOUT = 5 A
340
Ground current, off
IQ
UNIT
...
IOUT = 0 to IOUTmax: minimum
programmable voltage
Switching frequency
MAX
3
SEL[6:0] = 1000011 to
1111111
IOUT = 0 to IOUTmax: maximum
programmable voltage
TYP
kHz
1
Ground current, no load
µA
400
500
320
500
µA
1
µA
0.603
0.6086
V
VOUT%
0.001 ×
VOUT –
0.0003%
SUPPLY CURRENT
I(V5IN)
V5IN supply current
V5IN current, TA = 25°C,
No load
V(EN) = 5 V,
V(VOUT) = 0.63 V
ISD(V5IN)
V5IN shutdown current
V5IN current,
TA = 25°C,
No load,
V(EN) = 0 V
INTERNAL REFERENCE VOLTAGE
Reference
0.5974
Mismatch of resistive
divider
Specified by design. Not production tested.
Output current
Specified by design. Not
production tested.
I(VOUT) = 10–4 × VOUT – 6 ×
10–5
(–0.0063 ×
VOUT +
0.0035)%
VOUT = 0.6 V
I(VOUT)
1.25
...
...
VOUT = 1 V
40
...
...
VOUT = 1.3875 V
µA
78.75
OUTPUT DISCHARGE
IDischg
Output discharge current
from SW pin
V(EN) = 0 V, V(SW) = 0.5 V
5
13
mA
OUTPUT DRIVERS
R(DRVH)
DRVH resistance
R(DRVL) DRVL resistance
tD
Dead time
Source, I(DRVH) = –50 mA
1.5
3
Sink, I(DRVH) = 50 mA
0.7
1.8
1
2.2
Source, I(DRVL) = –50 mA
Sink, I(DRVL) = 50 mA
Ω
0.5
1.2
DRVH-off to DRVL-on
7
17
30
DRVH-off to DRVL-on
10
22
35
0.1
0.2
V
0.01
1.5
µA
ns
BOOT STRAP SWITCH
V(FBST)
Forward voltage
V(V5IN-VBST), IF = 10 mA, TA = 25°C
Ilkg
VBST leakage current
V(VBST) = 34.5 V, V(SW) = 28 V, TA = 25°C
(1)
The output voltage is changed with 50 mV/10 µs steps
Specifications
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Electrical Characteristics: VDDCtrl SMPS (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
150
260
400
UNIT
DUTY AND FREQUENCY CONTROL
tOFF(min)
Minimum off-time
TA = 25°C
tON(min)
Minimum on-time
VIN = 28 V, VOUT = 0.6 V, TA = 25°C
Specified by design. Not production tested.
fSW
Switching frequency
TA = 25°C
ns
86
312
340
368
kHz
SOFTSTART
tss
Internal SS time
From V(EN) = high to VOUT = 95%
0.9
ms
PROTECTION: CURRENT SENSE
TRIP source current
V(TRIP) = 1 V, TA = 25°C
TRIP current temperature
coefficient
On the basis of 25°C
V(TRIP)
Current limit threshold
setting range
V(TRIP-GND) Voltage
0.2
V(TRIP) = 3 V
355
375
395
VOCL
Current limit threshold
V(TRIP) = 1.6 V
185
200
215
V(TRIP) = 0.2 V
17
25
33
V(TRIP) = 3 V
–395
–375
–355
V(TRIP) = 1.6 V
–215
–200
–185
V(TRIP) = 0.2 V
–33
–25
–17
V(TRIP)
VOCLN
Negative current limit
threshold
9
10
11
4700
Auto zero cross adjustable Positive
range
Negative
3
Wake up
Shutdown
µA
ppm/°C
3
15
–15
–3
4.2
4.38
4.5
3.7
3.93
4.1
V
mV
mV
mV
UVLO
V5IN UVLO threshold
V
THERMAL SHUTDOWN
TSDN
26
Thermal shutdown
threshold
Shutdown temperature
Specified by design. Not production tested.
145
Hysteresis
Specified by design. Not production tested.
10
Specifications
°C
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
5.17 Electrical Characteristics: LDO1 and LDO2
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
Input voltage on VCC6 (VIN)
TEST CONDITIONS
MIN
TYP
MAX
VOUT (LDO1) = 1.05 V at 320 mA
and VOUT (LDO2) = 1.05 V at 160 mA
1.4
3.6
VOUT (LDO1) = 1.2 V or 1.5 V at 100 mA
and VOUT (LDO2) = 1.2 V or 1.1 V or 1.0 V
1.7
3.6
VOUT (LDO1) = 1.5 V and VOUT (LDO1, LDO2)
= 1.8 V at 200 mA
2.1
3.6
VOUT (LDO1) = 1.8 V and VOUT (LDO2) = 1.8 V
2.7
3.6
VOUT (LDO1) = 2.7 V
3.2
3.6
VOUT (LDO1) = VOUT (LDO2) = 3.3 V
3.5
3.6
UNIT
V
LDO1
SEL[7:2] =
000100
DC output voltage (VOUT)
SEL[7:2] =
000101
ON and Low-power mode, VIN
= VINmin to VINmax (VINmax 3.6 ...
V)
SEL[7:2] =
110001
1
1.05
–3%
On mode
3%
3.3
320
Low-power mode
mA
1
Load current limitation (short-circuit
protection)
On mode, VOUT = VOUTmin – 100 mV
Dropout voltage VDO
V
3.25
SEL[7:2] =
110010
Rated output current IOUTmax
...
1000
mA
ON mode, VDO = VIN – VOUT,
VIN = 1.4 V, IOUT = IOUTmax
350
mV
DC load regulation
On mode, IOUT = IOUTmax to 0
12
mV
DC line regulation
On mode, VIN = VINmin to VINmax at IOUT =
IOUTmax
4
mV
Transient load regulation
ON mode, VIN = 1.5 V, VOUT = 1.05 V
IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5
µs
20
40
mV
Transient line regulation
On mode, VIN = 2.7 + 0.5 V to 2.7 in 30 µs,
and VIN = 2.7 to 2.7 + 0.5 V in 30 µs, IOUT =
IOUTmax
5
10
mV
Turnon time
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
30
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
50
Turnon inrush current
600
150
µs
230
300
Ripple rejection
VIN = VINDC + 100 mVpp tone,
VINDC+ = 1.8 V,
IOUT = IOUTmax / 2
LDO1 internal resistance
LDO off
ƒ = 217 Hz
70
ƒ = 20 kHz
40
600
63
On mode, IOUT = IOUTmax
Low-power mode
Off mode (max 85°C)
Ω
75
2000
22
20
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2.7
Specifications
Copyright © 2010–2018, Texas Instruments Incorporated
mA
dB
600
On mode, IOUT = 0
Ground current
450
27
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Electrical Characteristics: LDO1 and LDO2 (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LDO2
DC output voltage VOUT
Rated output current IOUTmax
On and low-power mode, VIN
= VINmin to VINmax
(VINmax = 3.6 V)
SEL[7:2] =
000100
1
SEL[7:2] =
000101
1.05
...
–3%
...
SEL[7:2] =
110001
3.25
SEL[7:2] =
110010
3.3
On mode
3%
320
Low-power mode
mA
1
Load current limitation (short-circuit
protection)
On mode, VOUT = VOUTmin – 100 mV
Dropout voltage VDO
1000
mA
ON mode, VDO = VIN – VOUT,
VIN = 1.4 V, IOUT = IOUTmax
350
mV
DC load regulation
On mode, IOUT = IOUTmax to 0
12
mV
DC line regulation
On mode, VIN = VINmin to VINmax at IOUT =
IOUTmax
4
mV
Transient load regulation
ON mode, VIN = 1.5 V, VOUT = 1.05 V
IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5
µs
20
40
mV
Transient line regulation
On mode, VIN = 2.7 + 0.5 V to 2.7 in 30 µs,
and VIN = 2.7 to 2.7 + 0.5 V in 30 µs, IOUT =
IOUTmax
5
10
mV
Turnon time
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
30
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
50
Turnon inrush current
Ripple rejection
LDO2 internal resistance
LDO off
150
µs
230
ƒ = 217 Hz
70
ƒ = 20 kHz
40
600
63
On mode, IOUT = IOUTmax
Low-power mode
Off mode (maximum 85°C)
Specifications
Ω
75
2000
22
mA
dB
600
On mode, IOUT = 0
28
600
300
VIN = VINDC + 100 mVpp tone,
VINDC+= 1.8 V,
IOUT = IOUTmax / 2
Ground current
450
V
20
µA
2.7
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
5.18 Electrical Characteristics: LDO3 and LDO4
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
Input voltage on VCC5 (VIN)
TEST CONDITIONS
MIN
TYP
MAX
VOUT (LDO3) = 1.8 V and VOUT (LDO4) = 1.8 V
or 1.1 V or 1.0 V
2.7
5.5
VOUT (LDO3) = 2.6 V and VOUT (LDO4) = 2.5 V
3.0
5.5
VOUT (LDO3) = 2.8 V
3.2
5.5
UNIT
V
LDO3
DC output voltage (VOUT)
Rated output current (IOUTmax)
On and low-power mode,
VOUT = 1.0 to 3.3 V,
VIN = VINmin to VINmax
SEL[6:2] =
00010
1
SEL[6:2] =
00011
1.1
...
SEL[6:2] =
11001
3.3
On mode
3%
200
Low-power mode
Dropout voltage (VDO)
On mode, VOUTtyp = 3.3 V, VDO = VIN – VOUT,
VIN = 3.6 V, IOUT = IOUTmax
DC load regulation
On mode, IOUT = IOUTmax to 0
DC line regulation
On mode, VIN = VINmin to VINmax at IOUT =
IOUTmax
Transient load regulation
On mode, VIN = 2.7 V, VOUTtyp = 1.8 V
IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and
IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs
Transient line regulation
On mode, VOUTtyp = 1.8V, IOUT = IOUTmax,
VIN = VINmin + 0.5 V to VINmin in 30 µs
and VIN = VINmin to VINmin + 0.5 V in 30 µs,
IOUT = IOUTmax
400
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
30
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
50
Turnon inrush current
550
650
mA
150
250
mV
10
mV
4
mV
15
22
mV
0.5
1
mV
150
µs
200
200
Ripple rejection
VIN = VINDC + 100 mVpp tone,
VINDC+ = 3.8 V,
IOUT = IOUTmax / 2
LDO3 internal resistance
LDO off
ƒ = 217 Hz
70
ƒ = 50 Hz
40
450
65
On mode, IOUT = IOUTmax
Low-power mode
Off mode
kΩ
76
2000
14
mA
dB
500
On mode, IOUT = 0
V
mA
1
On mode, VOUT = VOUTmin – 100 mV
Ground current
...
3.2
Load current limitation (short-circuit
protection)
Turnon time
–3%
SEL[6:2] =
11000
22
µA
1
LDO4
Specifications
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Electrical Characteristics: LDO3 and LDO4 (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
DC output voltage (VOUT)
TEST CONDITIONS
On and low-power mode, VIN
= VINmin to VINmax (1)
TYP
0.8
SEL[7:2] =
000001
0.85
SEL[7:2] =
000010
0.9
SEL[7:2] =
000011
0.95
SEL[7:2] =
000100
1
SEL[7:2] =
000101
1.05
...
Rated output current (IOUTmax)
MIN
SEL[7:2] =
000000
–3%
...
SEL[7:2] =
110001
3.25
SEL[7:2] =
110010
3.3
On mode
MAX
3%
50
Low-power mode
On mode, VOUT = VOUTmin – 100 mV
Dropout voltage (VDO)
On mode, VOUTtyp = 2.5 V, VDO = VIN – VOUT
VIN = 3.6 V, IOUT = IOUTmax
DC load regulation
400
500
mA
100
160
mV
On mode, IOUT = IOUTmax to 0
5
mV
DC line regulation
On mode, VIN = VINmin to VINmax at IOUT =
IOUTmax
4
mV
Transient load regulation
On mode, VIN = 2.7 V, VOUTtyp = 1.8 V
IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5
µs
6
10
mV
Transient line regulation
On mode, VIN = VINmin + 0.5 V to VINmin in 30
µs
and VIN = VINmin to VINmin + 0.5 V in 30 µs,
IOUT = IOUTmax / 2
0.2
1
mV
Turnon time
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
30
150
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of
VOUT
50
200
Ripple rejection
VIN = VINDC + 100 mVpp tone,
VINDC+= 3.8 V,
IOUT = IOUTmax / 2
LDO4 internal resistance
LDO off
70
ƒ = 50 kHz
40
30
dB
500
55
On mode, IOUT = IOUTmax
Low-power mode
Off mode
(1)
µs
ƒ = 217 Hz
On mode, IOUT = 0
Ground current
200
V
mA
1
Load current limitation (short-circuit
protection)
UNIT
kΩ
65
900
14
17
µA
1
Set DCDCCTRL_REG.TRACK=1 and disable VDD1 to achieve VOUT < 1 V.
Specifications
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SWCS049S – JUNE 2010 – REVISED AUGUST 2018
5.19 Electrical Characteristics: LDO5
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
Input voltage on VCC4
(VIN)
TEST CONDITIONS
MIN
TYP
MAX
VOUT (LDO5) = 1.8 V
2.7
5.5
VOUT (LDO5) = 2.5 V
3.2
5.5
VOUT (LDO5) = 2.8 V at Iload = 200 mA
3.2
5.5
VOUT (VAUX2) = 2.8 V at 300 mA
3.2
5.5
UNIT
V
LDO5
DC output voltage
(VOUT)
Rated output current
(IOUTmax)
Load current limitation
(short-circuit protection)
Dropout voltage (VDO)
On and low-power mode, VOUT =
1.0 V to 3.3 V,
VIN = VINmin to VINmax
SEL[6:2] = 00010
1
SEL[6:2] = 00011
1.1
...
–3%
...
SEL[6:2] = 11000
3.2
SEL[6:2] = 11001
3.3
On mode
3%
300
Low-power mode
mA
1
On mode, VOUT = VOUTmin – 100 mV
On mode, VDO = VIN – VOUT
450
550
650
VIN = 2.7 V, IOUT =
IOUTmax
500
VIN = 2.7 V, IOUT =
250 mA
400
VIN = 2.7 V, IOUT =
200 mA
300
DC load regulation
On mode, IOUT = IOUTmax to 0
DC line regulation
On mode, VIN = VINmin to VINmax at IOUTmax
V
mA
mV
15
mV
4
mV
On mode, VIN = 3.2 V, VOUTtyp = 2.8 V
Transient load regulation IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs
16
30
mV
On mode, VIN = VINmin + 0.5 V to VINmin in 30 µs
and VIN = VINmin to VINmin + 0.5 V in 30 µs,
IOUT = IOUTmax
4
12
mV
Transient line regulation
Turnon time
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
30
150
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
50
200
Turnon inrush current
Ripple rejection
200
VIN = VINDC + 100 mVpp tone,
VINDC+ = 3.8 V,
IOUT = IOUTmax / 2
ƒ = 217 Hz
70
ƒ = 20 kHz
40
LDO5 internal resistance LDO Off
450
mA
dB
60
On mode, IOUT = 0
Ground current
µs
65
On mode, IOUT = IOUTmax
Ω
76
2000
Low-power mode
14
Off mode
22
µA
1
Specifications
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5.20 Electrical Characteristics: LDO6, LDO7, and LDO8
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
Input voltage on VCC3
(VIN)
TEST CONDITIONS
MIN
TYP
MAX
VOUT (LDO6) = 1.2 V at 150 mA, VOUT (LDO7) = 1.1 V at
150 mA
and (VLDO8) = 1 V at 180 mA
1.7
5.5
VOUT (LDO7) = 1.8 V or 2 V and VOUT (LDO6) = 1.8 V
2.7
5.5
VOUT (LDO7) = 2.8 V
3.2
5.5
VOUT (LDO7) = 3.3 V
3.6
5.5
VOUT (LDO7) = 2.8 V at 250 mA
3.2
5.5
VOUT (LDO7) = 3.0 V
3.6
5.5
VOUT (LDO7) = 3.3 V at 250 mA
3.6
5.5
UNIT
V
LDO6
SEL[6:2] = 00010
1
SEL[6:2] = 00011
DC Output voltage
(VOUT)
On and low-power mode, VIN =
VINmin to VINmax
...
1.1
–3%
SEL[6:2] = 11000
SEL[6:2] = 11001
Rated output current
(IOUTmax)
Load current limitation
(short-circuit protection)
Dropout voltage (VDO)
On mode
Low-power mode
On mode, VOUT = VOUTmin – 100 mV
On mode, VDO = VIN – VOUT
450
400
VIN = 2.7 V, IOUT =
200 mA
300
VIN = 1.7 V, IOUT =
180 mA
700
VIN = 1.7 V, IOUT =
150 mA
500
VIN = 1.7 V, IOUT =
100 mA
300
15
mV
4
mV
20
32
mV
5
15
mV
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
30
150
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
50
200
µs
200
VIN = VINDC + 100 mVpp tone,
VINDC+ = 3.8 V,
IOUT = IOUTmax / 2
ƒ = 217 Hz
70
ƒ = 20 kHz
40
LDO6 internal resistance LDO off
450
65
On mode, IOUT = IOUTmax
Ω
76
2000
Low-power mode
14
Off mode
mA
dB
60
On mode, IOUT = 0
mA
mV
On mode, VIN = 2.7 V + 0.5 V to 2.7 V in 30 µs
and VIN = 2.7 V to 2.7 V + 0.5 V in 30 µs, IOUT = IOUTmax
Turnon inrush current
32
650
VIN = 2.7 V, IOUT =
250 mA
On mode, VIN = 3.2 V, VOUTtyp = 2.8 V
Transient load regulation IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs
Ground current
550
500
On mode, VIN = VINmin to VINmax at IOUT = IOUTmax
Ripple rejection
mA
VIN = 2.7 V, IOUT =
IOUTmax
DC line regulation
V
3.3
1
On mode, IOUT = IOUTmin to 0
Turnon time
3%
300
DC load regulation
Transient line regulation
...
3.2
22
µA
1
Specifications
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Electrical Characteristics: LDO6, LDO7, and LDO8 (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LDO7
SEL[6:2] = 00010
1
SEL[6:2] = 00011
DC output voltage
(VOUT)
On and low-power mode, VIN =
VINmin to VINmax
...
1.1
–3%
SEL[6:2] = 11000
SEL[6:2] = 11001
Rated output current
(IOUTmax)
Load current limitation
(short-circuit protection)
Dropout voltage (VDO)
On mode
Low-power mode
On mode, VOUT = VOUTmin – 100 mV
On mode, VDO = VIN – VOUT
450
650
VIN = 2.7 V, IOUT =
250 mA
400
VIN = 2.7 V, IOUT =
200 mA
300
VIN = 1.7 V, IOUT =
180 mA
700
VIN = 1.7 V, IOUT =
150 mA
500
VIN = 1.7 V, IOUT =
100 mA
300
On mode, IOUT = IOUTmax / 2, VIN = 2.7 + 0.5 V to 2.7 in 30
µs
and VIN = 2.7 V + 0.5 V in 30 µs, IOUT = IOUTmax / 2
15
mV
4
mV
16
25
mV
5
15
mV
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
30
150
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
50
200
Turnon inrush current
µs
200
VIN = VINDC + 100 mVpp tone,
VINDC+ = 3.8 V,
IOUT = IOUTmax / 2
ƒ = 217 Hz
70
ƒ = 20 kHz
40
LDO7 internal resistance LDO off
mA
mV
On mode, VIN = 3.6 V, VOUTtyp = 3.3 V
Transient load regulation IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs
and IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs
450
mA
dB
60
On mode, IOUT = 0
Ground current
550
500
On mode, VIN = VINmin to VINmax at IOUT = IOUTmax
Ripple rejection
mA
VIN = 2.7 V, IOUT =
IOUTmax
DC line regulation
V
3.3
1
On mode, IOUT = IOUTmax to 0
Turnon time
3%
300
DC load regulation
Transient line regulation
...
3.2
65
On mode, IOUT = IOUTmax
Ω
76
2000
Low-power mode
14
Off mode
22
µA
1
Specifications
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Electrical Characteristics: LDO6, LDO7, and LDO8 (continued)
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LDO8
SEL[6:2] = 00010
1
SEL[6:2] = 00011
DC output voltage
(VOUT)
On and low-power mode, VIN =
VINmin to VINmax
...
1.1
–3%
SEL[6:2] = 11000
SEL[6:2] = 11001
Rated output current
(IOUTmax)
Load current limitation
(short-circuit protection)
Dropout voltage (VDO)
On mode
Low-power mode
On mode, VOUT = VOUTmin – 100 mV
On mode, VDO = VIN – VOUT,
450
400
VIN = 2.7 V, IOUT =
200 mA
300
VIN = 1.7 V, IOUT =
180 mA
700
VIN = 1.7 V, IOUT =
150 mA
500
VIN = 1.7 V, IOUT =
100 mA
300
15
mV
4
mV
7
30
mV
5
15
mV
VOUT = (1 to 1.8 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
30
150
VOUT = (1.9 to 3.3 V), at IOUT = 0
measured from VOUT = 0.1 V up to 97% of VOUT
50
200
µs
200
VIN = VINDC + 100 mVpp tone,
VINDC+ = 3.8 V,
IOUT = IOUTmax / 2
ƒ = 217 Hz
70
ƒ = 20 kHz
40
LDO8 internal resistance LDO off
450
65
On mode, IOUT = IOUTmax
Ω
76
2000
Low-power mode
14
Off mode
mA
dB
60
On mode, IOUT = 0
mA
mV
On mode, IOUT = 100 mA, VIN = 2.7 V + 0.2 V to 2.7 V in
30 µs
and VIN = 2.7 V to 2.7 v + 0.2 V in 30 µs, IOUT = 100 mA
Turnon inrush current
34
650
VIN = 2.7 V, IOUT =
250 mA
On mode, VIN = 1.7 V, VOUTtyp = 1.2 V
Transient load regulation IOUT = 10 mA to 90 mA in 5 µs and IOUT = 90 mA to 10 mA
in 5 µs
Ground current
550
500
On mode, VIN = VINmin to VINmax at IOUT = IOUTmax
Ripple rejection
mA
VIN = 2.7 V, IOUT =
IOUTmax
DC line regulation
V
3.3
1
On mode, IOUT = IOUTmax to 0
Turnon time
3%
300
DC load regulation
Transient line regulation
...
3.2
22
µA
1
Specifications
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5.21 Timing and Switching Characteristics
5.21.1 I2C Timing and Switching
In Table 5-1, SDA is the SDA_SDI or EN2 signal and SCL is the SCL_SCK or EN1 signal. The input
timing requirements are given by considering a rising or falling time of 80 ns in high–speed mode (3.4
Mbps), 300 ns in fast–speed mode (400 kbps), 1000 ns in standard mode (100 kbps). Values are over the
operating free-air temperature range unless otherwise noted.
Table 5-1. Timing Requirements: I2C Interface and Control Signals
NO.
MIN
NOM
MAX
UNIT
INT1 rise and fall times
CL = 5 to 35 pF
5
10
ns
NRESPWRON rise and fall times
CL = 5 to 35 pF
5
10
ns
10
80
ns
3.4
Mbps
SLAVE HIGH–SPEED MODE
SCL/EN1 and SDA/EN2 rise and
fall time
CL = 10 to 100 pF
Data rate
I3
tsu(SDA-SCLH)
Setup time, SDA valid to SCL high
10
I4
th(SCLL-SDA)
Hold time, SDA valid from SCL low
0
ns
I7
tsu(SCLH-SDAL)
Setup time, SCL high to SDA low
160
ns
I8
th(SDAL-SCLL)
Hold time, SCL low from SDA low
160
ns
I9
tsu(SDAH-SCLH)
Setup time, SDA high to SCL high
160
ns
70
ns
SLAVE FAST MODE
SCL/EN1 and SDA/EN2 rise and
fall time
CL = 10 to 400 pF
20 +
0.1 ×
CL
Data rate
250
ns
400
Kbps
I3
tsu(SDA-SCLH)
Setup time, SDA valid to SCL high
100
I4
th(SCLL-SDA)
Hold time, SDA valid from SCL low
I7
tsu(SCLH-SDAL)
Setup time, SCL high to SDA low
0.6
µs
I8
th(SDAL-SCLL)
Hold time, SCL low from SDA low
0.6
µs
I9
tsu(SDAH-SCLH)
Setup time, SDA high to SCL high
0.6
µs
0
ns
0.9
µs
SLAVE STANDARD MODE
SCL/EN1 and SDA/EN2 rise and
fall time
CL = 10 to 400 pF
Data rate
250
ns
100
Kbps
I3
tsu(SDA-SCLH)
Setup time, SDA valid to SCL high
250
ns
I4
th(SCLL-SDA)
Hold time, SDA valid from SCL low
0
µs
I7
tsu(SCLH-SDAL)
Setup time, SCL high to SDA low
4.7
µs
I8
th(SDAL-SCLL)
Hold time, SCL low from SDA low
4
µs
I9
tsu(SDAH-SCLH)
Setup time, SDA high to SCL high
4
µs
Specifications
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In Table 5-2, SCL is the SCL_SCK or EN1 signal. The input timing requirements are given by considering
a rising or falling time of 80 ns in high–speed mode (3.4 Mbps), 300 ns in fast–speed mode (400 kbps),
1000 ns in standard mode (100 kbps). Values are over the operating free-air temperature range unless
otherwise noted.
Table 5-2. Switching Characteristics: I2C Interface and Control Signals
NO.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SLAVE HIGH–SPEED MODE
I1
tw(SCLL)
Pulse duration, SCL low
160
ns
I2
tw(SCLH)
Pulse duration, SCL high
60
ns
SLAVE FAST MODE
I1
tw(SCLL)
Pulse duration, SCL low
1.3
µs
I2
tw(SCLH)
Pulse duration, SCL high
0.6
µs
4.7
µs
4
µs
SLAVE STANDARD MODE
36
I1
tw(SCLL)
Pulse duration, SCL low
I2
tw(SCLH)
Pulse duration, SCL high
Specifications
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5.21.2 Switch-ON and Switch-OFF Sequences and Timing
This section describes an example boot sequence. Each TPS65911x device supports a dedicated
EEPROM boot sequence to match specific processor requirements. Fixed boot mode is the same in all
TPS65911x devices. Boot mode selection is described in Section 6.5.2.
tpd2
PWRHOLD
tdsON1
VIO
LDO5
tdsON2
VDD2
tdsON3
VDD1
tdsON4
LDO4
tdsON5
LDO3
LDO8
tdsON6
LDO6
i
tdsON15
tpd1
CLK32KOUT
tdsON16
NRESPWRON
NRESPWRON2
tond: Switch-on sequence
Switch-off sequence
SWCS049-004
NOTE: Figure 5-1 is for illustrative purposes only and does not describe any actual TPS65911x part number.
Figure 5-1. Boot Sequence Example With 2-ms Time Slot and Simultaneous Switch-Off of Resources
Table 5-3. Switching Characteristics for Boot Sequence Example
PARAMETER
TEST CONDITIONS
LDO5 enable delay
MIN
TYP
MAX
UNIT
66 × tCK32k =
2060
µs
tdsON1
PWRHOLD rising edge to VIO
tdsON2
VIO to VDD2 enable delay
64 × tCK32k =
2000
µs
tdsON3
VDD2 to VDD1 enable delay
64 × tCK32k =
2000
µs
tdsON4
VDD1 to LDO4 enable delay
64 × tCK32k =
2000
µs
tdsON5
LDO4 to LDO3, LDO8 enable delay
64 × tCK32k =
2000
µs
tdsON6
LDO3 to LDO6 enable delay
64 × tCK32k =
2000
µs
tdsON7
LDO6 to CLK32KOUT rising-edge
delay
9 × 64 ×
tCK32k =
18000
µs
tdsON16
CLK32KOUT to NRESPWON
NRESPWON2 rising-edge delay
64 × tCK32k =
2000
µs
tdsONT
Total switch-on delay
32
ms
tpd1
PWRHOLD falling edge to
NRESPWON
NRESPWON2 falling-edge delay
2 × tCK32k =
62.5
µs
Specifications
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Table 5-3. Switching Characteristics for Boot Sequence Example (continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tpd1b
NRESPWON falling edge to
CLK32KOUT low delay
3 × tCK32k =
92
µs
tpd2
PWRHOLD falling edge to supplies
and reference disable delay
5 × tCK32k =
154
µs
5.21.3 Power Control Timing
5.21.3.1 Device State Control Through PWRON Signal
Figure 5-2 shows the device state control through PWRON signal.
PWRON
VIO
1.8 V
CLK32KOUT
NRESPWRON
Interrupt acknowledge
INT1
Interrupt acknowledge
PWRON_IT=1
PWRON_IT=1
Internal pulse tdOINT1
PWRHOLD
t dbPWRHOLDF
t dbPWRONF
t dSONT
Switch On sequence
t dONPWHOLD
t dbPWRONF
Switch-off
sequence
SWCS049-005
A. The DEV_ON or AUTODEV_ON control bits can be used instead of the PWRHOLD signal to maintain supplies
on after a switch-on sequence.
B. The internal POWER ON enable condition pulse, tdOINT1, keeps device active until a PWRHOLD acknowledge.
C. Switch-off from PWRHOLD removal.
Figure 5-2. Device State Control Through PWRON Signal
PWRON
VIO
NRESPWRON
INT1
PWRON_IT=1
PWRON_LP_IT=1
PWRON_IT=1
PWRHOLD
t dbPWRONF
t dPWRONLP
t dPWRONLPTO
Switch-off
sequence
SWCS049-006
Figure 5-3. PWRON Long-Press Turnoff
38
Specifications
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Table 5-4 lists the power control timing characteristics.
Table 5-4. Power Control Timing Characteristics
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tdbPWRONF
PWRON falling-edge debouncing
delay
100
ms
tdbPWRONR
PWRON rising-edge debouncing
delay
3 × tCK32k =
94
µs
tdbPWRHOLD
PWRHOLD rising-edge debouncing
delay
2 × tCK32k =
63
µs
tdOINT1
INT1 (internal) power-on pulse
duration after PWRON low-level
(debounced) event
1
s
tdONPWHOL
Delay to set high PWRHOLD signal
or DEV_ON control bit after
NRESPWON released to keep on
the supplies
D
tdOINT1 –
tDSONT =
970 (1)
PWRON falling-edge to
PWRON_LP_IT
tdPWRONLP
PWRON long-press delay
tdPWRONLPT
PWROW long-press interrupt
PWRON_LP_IT to NRESPWRON
(PWRON_LP_IT) to supplies switchfalling-edge
off
O
(1)
ms
4
s
1
s
TdSONT = 30 ms, as in example boot sequence.
Specifications
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5.21.3.2 Device SLEEP State Control
t ACT2SLP
t SLP2ACT
SLEEP
VIO/VFBIO
1.8 V
Low Power mode
1.8 V
PWM mode
1.8 V
PWM mode
SWIO
LDO5
VDD2/VFB2
1.8 V
ACTIVE mode
1.8 V
ACTIVE mode
1.8 V
Low-power mode
3.3 V
Pulse skip mode
3.3 V
Pulse skip mode
3.3 V
Low-power mode
SW2
VDD1/VFB1
t dONDCDCSLP
1.2 V
PWM mode
1.2 V
PWM mode
Off
SW1
LDO4 1.8 V
ACTIVE mode
Off
LDO3
1.8 V
ACTIVE mode
Off
LDO8
1.8 V
ACTIVE mode
1.8 V
ACTIVE mode
LDO6
3.3 V
ACTIVE mode
3.3V
Low-power mode
1.8 V
ACTIVE mode
1.8 V
ACTIVE mode
1.8 V
ACTIVE mode
3.3 V
ACTIVE mode
t SLP2ACTCK32K
CLK32KOUT
t ACT2SLPCK32K
t dSLPON1
t dSLPONST
t dSLPONST
SWCS049-007
NOTE: Register programming: VIO_PSKIP = 0, VDD1_PSKIP = 0, VDD1_SETOFF = 1, LDO3_SETOFF = 1,
LDO4_SETOFF = 1, LDO8_KEEPON = 1.
Figure 5-4. Device SLEEP State Control
Table 5-5. Device SLEEP State Control Timing Characteristics
PARAMETER
tACT2SLP
SLEEP falling-edge to supply
TEST CONDITIONS
Low-power mode (SLEEP resynchronization
delay)
tACT2SLPC SLEEP falling-edge to
CLK32KOUT low
K32K
tSLP2ACT
SLEEP rising edge to supply
High-power mode
40
SLEEP rising edge to time step 1
of the turnon sequence from
SLEEP state
Specifications
TYP
2×
tCK32k =
62
156
tSLP2ACTC SLEEP rising edge to
CLK32KOUT running
K32K
tdSLPON1
MIN
tACT2SLP + 3
× tCK32k
8×
tCK32k =
250
MAX
UNIT
3×
tCK32k =
94
µs
188
µs
9×
tCK32k =
281
µs
344
tSLP2ACT + 3
× tCK32k
375
µs
281
tSLP2ACT + 1
× tCK32k
312
µs
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Table 5-5. Device SLEEP State Control Timing Characteristics (continued)
PARAMETER
tdSLPONST Turnon sequence step duration
tdSLPONDC VDD1, VDD2, or VIO turnon
delay
DC
TEST CONDITIONS
From SLEEP state
MIN
TYP
TSLOT_LENGTH[1:0]
= 00
0
TSLOT_LENGTH[1:0]
= 01
200
TSLOT_LENGTH[1:0]
= 10
500
TSLOT_LENGTH[1:0]
= 11
2000
From turnon sequence time step
MAX
µs
2 × tCK32k =
62
µs
Specifications
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UNIT
41
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5.21.3.3 Device Turnon and Turnoff With Rising and Falling Input Voltage
VMBCH threshold
VMBDCH2 threshold
VMBLO threshold
VMBHI threshold
VBNPR threshold
VCC7
1.8 V
VRTC
VBACKUP > VBNPR
VIO
1.8 V
CLK32KOUT
NRESPWRON
tdbVMBLO
Interrupt acknowledge
INT1
tdbVMBDCH
VMBHI_IT=1
PWRHOLD
td32KON
tdbVMBHI
tdSONT
Switch-off
sequence
tdONPWHOLD
Switch On sequence
SWCS049-008
A.
B.
C.
To allow power-up from first supply insertion as shown here, VMBHI_IT_MSK is set to 0.
Power-up to active state is enabled when VMBHI interrupt is not masked (VMBHI_IT_MSK in boot configuration).
The DEV_ON or AUTODEV_ON control bits can be used instead of the PWRHOLD signal to maintain supplies on
after a switch-on sequence.
Figure 5-5. Device Turnon and Turnoff With Rising and Falling Input Voltage
Table 5-6. Device Turnon Voltage With Rising Input Voltage, Timing Characteristics
MIN
td32KON
32-kHz oscillator turnon time
NOM
RC oscillator
0.1
Quartz oscillator
200
Bypass clock
0.1
MAX
ms
4 × tCK32k =
125
tdbVMBHI
VMBHI rising-edge debouncing delay
tdOINT1
INT1 power on pulse duration after VMBHI high level
(debounced) event
tdONPWHOLD
Delay to set high PWRHOLD signal or DEV_ON control bit
after NRESPWRON released in order to keep on the supplies
tdbVMBDCH
Main battery voltage = VMBDCH threshold to INT1 fallingedge delay
3 × tCK32k = 94
4 × tCK32k =
125
s
tdbVMBLO
Main battery voltage = VMBLO threshold to NRESPWRON
falling-edge delay
3 × tCK32k = 94
4 × tCK32k =
125
s
42
3 × tCK32k = 94
UNIT
1
s
tdOINT1 –
tDSONT = 970
Specifications
µs
ms
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5.21.3.4 Power Supplies State Control Through EN1 and EN2 Signals
Switch-on sequence
Switch-off sequence
Device on
NRESPWRON
tdEN
EN1
tdVEN
LDO1
tdEN
1.2 V
tdSOFF2
tdEN
EN2
tdEN
Low-power mode
1.8 V
LDO4
SWCS046-009
NOTE: Register setting: LDO1_EN1 = 1, LDO4_EN2 = 1, and LDO4_KEEPON = 1.
Figure 5-6. LDO Type Supplies State Control Through EN1 and EN2
Switch-on sequence
Switch-off sequence
Device on
NRESPWRON
tdEN
EN2
VDD2/VFB2
tdOEN
0V
tdVDDEN
tdVDDEN
3.3 V
tdSOFF2
EN1
VDD1/VFB1
1.2 V
PWM mode
tdEN
tdEN
Low-power mode
PFM (pulse skipping) mode
SW1
SWCS049-010
NOTE: Register setting: VDD2_EN2 = 1, VDD1_EN1 = 1, VDD1_KEEPON = 1, VDD1_PSKIP = 0, and SEL[6:0] = hex00 in
VDD2_SR_REG.
Figure 5-7. VDD1 and VDD2 Supplies State Control Through EN1 and EN2
Table 5-7. Supplies State Control Through EN1 and EN2 Timing Characteristics
MIN
tdEN
NRESPWRON to supply state change delay, EN1 or EN2 driven
tdOEN
tdVDDEN
NOM
MAX
UNIT
0
ms
EN1 or EN2 edge to supply state change delay
1 × tCK32k =
31
µs
EN1 or EN2 edge to VDD1 or VDD2 DCDC turnon delay
3 × tCK32k =
63
µs
Specifications
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5.21.3.5 VDD1, VDD2 Voltage Control Through EN1 and EN2 Signals
EN1
tdDVSEN
tdDVSENL
1.2 V
VDD1/VFB1
tdDVSEN
tdDVSENL
0.8 V
TSTEP[2:0]=001
TSTEP[2:0]=011
SW1
PFM (pulse skipping) mode
PWM mode
PFM (pulse
skipping) mode
PWM mode
PFM (pulse
skipping) mode
SWCS049-011
NOTE: Register setting: VDD1_EN1 = 1, SEL[6:0] = hex13 in VDD1_SR_REG
Figure 5-8. VDD1 Supply Voltage Control Through EN1
Table 5-8. VDD1 Supply Voltage Control Through EN1 Timing Characteristics
PARAMETER
tdDVSEN
EN1 (or EN2) edge to VDD1 (or
VDD2) voltage change delay
tdDVSENL
VDD1 (or VDD2) voltage settling
delay
TEST CONDITIONS
TYP
2 × tCK32k =
62
TSTEP[2:0] = 001
TSTEP[2:0] = 011 (default)
TSTEP[2:0] = 111
44
MIN
Specifications
MAX
UNIT
µs
32
0.4 / 7.5 = 53
µs
160
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6 Detailed Description
6.1
Overview
The TPS65911 device is an integrated power management IC (PMIC) available in a 98-pin 0.65-mm pitch
BGA package. It is designed for applications powered by powered by one Li-Ion or Li-Ion polymer battery
cell, 3-series Ni-MH cells, or a 5-V input supply. It provides three step-down converters, one step-down
controller with external FETs to support high current rails, eight LDOs, nine GPIOs, and EERPOMprogrammable power sequencing to support a variety of processors and system sequencing requirements.
Two of the step-down converters, VDD1 and VDD2, provide power for processor cores and support
dynamic voltage scaling using I2C interface. VDD1 and VDD2 have an output voltage range of 0.6 V to
3.3V. The converters have a 12.5-mV step size from 0.6 V to 1.5 V, and a VGAIN_SEL option to multiply
this voltage by 2 or 3, with 3.3 V maximum output voltage. The third converter, VIO, provides power for I/O
and memory. VIO has four selectable voltage outputs, 1.5 V, 1.8 V, 2.5 V, and 3.3 V.
The device includes 8 general-purpose LDOs with an output voltage range from 1 V to 3.3 V. Three of the
LDOs (LDO1, LDO2, and LDO4) support 50-mV output voltage steps, and the remaining five LDOs
(LDO3, LDO5, LDO6, LDO7, and LDO8) support 100-mV output voltage steps. The LDO voltages and
other configuration are controlled by the I2C interface.
The power-up and power-down sequences are controlled by the embedded power controller and is preprogrammed using EEPROM. The power-up and power-down sequences assign each output rail to a
sequence slot, and the delay time between slots is either 0.5 ms or 2 ms.
The device offers nine GPIOs. Four of the GPIOs (GPIO0, GPIO2, GPIO6, and GPIO7) can be configured
to enable external resources, and can be included in the power sequences. The device also includes
dedicated input and reset pins used to enable and disable the PMIC including PWRON, PWRHOLD,
HDRST, and PWRDN. The NRESPWRON pin is a dedicated power-on reset output for a processor
powered by the PMIC.
Detailed Description
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6.2
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Functional Block Diagram
CBB
VBACKUP
VCC7
VRTC
1.5 A at 0.6 to 2.2 V(1)
VDD1
BACKUP
VRTC (LDO) Management
and POR
AGND
SW1
AGND
OSC32KIN
GND1
Oscillator
32 kHz
OSC32KOUT
REFGND
CLK32KOUT
Real-Time Clock
(RTC)
VDDIO
0.6 V to 3.3 V
1.5 A at 0.6 to 1.5 V(1)
VDD2
SDA_SDI
SCL_SCK
VCC1
I 2C
VFB1
VCC2
GPIO0
SW2
GPIO1
Bus Control
GPIO2
GND2
GPIO3
GPIO4
0.6 V to 3.3 V
GPIO5
GPIO6
DRVH
GPIO7
Cboost
SW
GPIO8
DRVL
2
EN1
VFB2
VBST
IC
Controller
EN2
VOUT
VFB
INT1
SLEEP
Power-Control
State Machine
PWRON
BOOT1
C1
V5IN
TRIP Rtrip
0.6 V to 1.4 V
GNDC
VIO
VCCIO
PWRHOLD
CV5IN
PWRDN
HDRST
SWIO
NRESPWRON
NRESPWRON2
GNDIO
VREF
TESTV
Analog
References
REFGND
1 to 3.3 V,
100-mV step
LDO3
LDO3
200 mA
Watchdog
1.3 A at 1.5 V
1.2 A at 1.8 V
1.1 A at 2.5 and 3.3 V
VDDIO
LDO1
320 mA
1 to 3.3 V,
100-mV step
LDO4
50 mA
LDO5
LDO7
300 mA
LDO5
300 mA
1 to 3.3 V,
50-mV step
LDO2
1 to 3.3 V,
50-mV step
LDO7
1 to 3.3 V,
100-mV step
VCC3
VCC4
LDO8
300 mA
VCCS
Connect to system
1.8V/3.3 V supply
VCC6
LDO2
320 mA
LDO4
LDO1
Test Interface
VCC5
1 to 3.3 V,
50-mV step
VFBIO
LDO8
1 to 3.3 V,
100-mV step
LDO6
1 to 3.3 V,
100-mV step
COMP
1
COMP
2
(1)
46
LDO6
300 mA
For details on supported levels, see Section 5.14, Section 5.15, and Table 6-1.
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Power Reference
The band-gap voltage reference is filtered by using an external capacitor connected across the VREF
output and the analog ground REFGND (see Section 5.3). The VREF voltage is distributed and buffered
inside the device.
6.4
Power Resources
The power resources provided by the TPS65911 device include inductor based switched mode power
supplies (SMPSs) and linear low-dropout voltage regulators (LDOs). These supply resources provide the
required power to the external processor cores and external components, and to modules embedded in
the TPS65911 device.
Two of the integrated SMPSs and the external FET SMPS have voltage scaling capability. These SMPSs
provide independent core voltage domains to the host processor. When changing the output voltage,
VDD1 and VDD2 reach the new value through successive steps of 2.5 to 12.5 mV. The size of the voltage
step is selected by the TSTEP bit. VDDCtrl has a target slew rate of 100 mV/20 µs. New output values are
reached in successive smaller steps of N × LSB, LSB = 12.5 mV, N = 1 to 4. A suitable combination of
steps is calculated internally based on current and new target value for output voltage.
The VIO SMPS provides supply voltage for the host processor I/Os.
Table 6-1 lists the power sources provided by the TPS65911 device.
Table 6-1. Power Sources
RESOURCE
TYPE
VIO
SMPS
VDD1
SMPS
VOLTAGES
POWER
1.5 V
1300 mA
1.8 V
1200 mA
2.5 or 3.3 V
1100 mA
0.6 to 2.2 V
1500 mA
3.2 V
1200 mA
1.2 or 1.35 or 1.5 V (VINmin = 3 V)
2000 mA
0.6 ... 1.5 V in 12.5-mV steps
Programmable multiplication factor: ×2, ×3. Maximum output 3.3 V
VDD2
SMPS
0.6 to 1.5 V
1500 mA
2.2 / 3.2 V
1200 mA
0.6 ... 1.5 V in 12.5-mV steps
Programmable multiplication factor: ×2, ×3. Maximum output 3.3 V
6.5
0.6 … 1.4 V in 12.5-mV steps
External component
dependent
VDDCtrl
SMPS
LDO1
LDO
1.0–3.3 V, 0.05-V step
320 mA
LDO2
LDO
1.0–3.3 V, 0.05-V step
320 mA
LDO3
LDO
1.0–3.3 V, 0.1-V step
200 mA
LDO4
LDO
1.0–3.3 V, 0.05-V step
50 mA
LDO5
LDO
1.0–3.3 V, 0.1-V step
300 mA
LDO6
LDO
1.0–3.3 V, 0.1-V step
300 mA
LDO7
LDO
1.0–3.3 V, 0.1-V step
300 mA
LDO8
LDO
1.0–3.3 V, 0.1-V step
300 mA
Embedded Power Controller (EPC)
The EPC manages the state of the device and controls the power-up sequence.
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State Machine
The EPC supports the following states:
• NO SUPPLY: The primary battery supply voltage is not high enough to power the VRTC regulator. A
global reset is asserted in this case. Everything on the device is off.
• BACKUP: The primary battery supply voltage is high enough to enable the VRTC domain but not
enough to switch on all the resources. In this state, the VRTC regulator is in backup mode and only the
32K oscillator and RTC module are operating (if enabled). All other resources are off or under reset.
• OFF: The primary battery supply voltage is high enough to start the power-up sequence, but device
power on is not enabled. All power supplies are in the OFF state except VRTC.
• ACTIVE: Device POWER ON enable conditions are met and regulated power supplies are on or can
be enabled with full current capability.
• SLEEP: Device SLEEP enable conditions are met and some selected regulated power supplies are in
low-power mode.
Figure 6-1 shows the transitions for the state machine.
AUTODEV_ON
DEV_ON
PWRHOLD
HDRST
Pulse
generator
INT1
NRESPWRON
NO SUPPLY
TDOINT1
PWRON_LP_IT
TD
PWRON
POWER ON
ENABLE
THERM_TS
DEV_OFF
DEV_OFF_RST
HDRST
VCC7 and BB < VBNPR
PWRDN_POL
PWRDN
VCC7 > VMBHI
OFF
VCC7 < VMBLO
VCC7 and BB < VBNPR
VCC7 and BB < VBNPR
VCC7 > VMBHI
POWER ON
Enabled
And VCCS > VMBCH
SLEEPSIG_POL
SLEEP
DEV_SLP
POWER ON
disabled
BACKUP
VCC7 or BB >
VBNPR
and
VCC7 < VMBLO
SLEEP
ENABLE
INT1
ACTIVE
VCC7 < VMBLO
SLEEP
enabled
POWER ON
disabled
SLEEP
disabled
VCC7 < VMBLO
BB: Backup battery voltage
SLEEP
SWCS049-024
Copyright © 2016, Texas Instruments Incorporated
NOTE: PWRHOLD enables power-on unless the pin is programmed as GPI.
Figure 6-1. Embedded Power Control State Machine
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6.5.1.1
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Device POWER ON Enable Conditions
The device POWER ON enable conditions are as follows:
• None of the device POWER ON disable conditions are met.
• PWRON signal low level
• Or PWRHOLD signal high level
• Or DEV_ON control bit set to 1 (default inactive)
• Or interrupt flag active (default INT1 low) generates a POWER ON enable condition during a fixed
delay (tDOINT1 pulse duration defined in Section 5.21.3). Interrupt sources expected (if enabled), when
the device is off:
– RTC alarm interrupt
– First-time input voltage rising above the VMBHI threshold (depending on the boot mode used) and
input voltage > VMBCH threshold. The interrupt corresponding to this last condition is VMBCH_IT
in the INT_STS_REG register.
– Or HDRST reset release generates a POWER ON enable condition during a fixed delay tDOINT1
Interrupt flag active generates a POWER ON enable condition pulse of length tDOINT1 only when the device
is in the OFF state (when the NRESPWRON signal is low). The POWER ON enable condition pulse
occurs only if the interrupt status bit is initially low (no previous interrupt pending in the status register).
The interrupt status register must first be cleared to let the device power off during the tDOINT1 pulse
duration.
GPIO2 cannot be used to turn on the device, even if its associated interrupt is not masked. The GPIO0,
GPIO1, GPIO3, GPIO4, or GPIO5 signals can be used to turn on the device, if its associated interrupt is
not masked.
NOTE
The watchdog interrupt is not a power-on event, but can wake up the device from sleep
mode.
6.5.1.2
Device POWER ON Disable Conditions
Device POWER ON disable conditions are as follows:
• PWRON signal low level during more than the long-press delay: PWON_LP_DELAY (can be disabled
though register programming). The interrupt corresponding to this condition is PWRON_LP_IT in the
INT_STS_REG register.
• Or die temperature has reached the thermal shutdown threshold (THERM_TS = 1).
• Or DEV_OFF or DEV_OFF_RST control bit is set to 1 (DEV_OFF value is cleared when the device is
in OFF state).
NOTE
If the DEV_ON bit is set to 1, after switch-off, the device switches back on. To keep the
device off, DEV_ON must be cleared first.
6.5.1.3
Device SLEEP Enable Conditions
Device SLEEP enable conditions are as follows:
• SLEEP signal low level (default, or high level depending on the programmed polarity)
• And DEV_SLP control bit is set to 1.
• And interrupt flag inactive (default INT1 high): no nonmasked interrupt is pending.
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The SLEEP state can be controlled by programming DEV_SLP bit and keeping the SLEEP signal in the
active polarity state, or it can be controlled through the SLEEP signal setting the DEV_SLP bit to 1 after
device turnon.
6.5.1.4
Device Reset Scenarios
The device has three reset scenarios:
• Full reset: All digital logic of device is reset.
– Caused by POR (power on reset) when VCC7 < VBNPR and BB < VBNPR
• General reset: No impact on the RTC, backup registers, or interrupt status.
– Caused by PWON_LP_RST bit set high
– Or DEV_OFF_RST bit set high
– Or HDRST input set high
• Turnoff: Power reinitialization in off/backup mode.
A mapping of digital registers to these reset scenarios is described in Table 6-6.
6.5.2
BOOT Configuration, Switch-ON, and Switch-OFF Sequences
The power sequence is the automated switch-on of the devices resources when an OFF-to-ACTIVE
transition occurs. The power-on sequence has 15 sequential time slots to which resources (DC-DC
converters, LDOs, 32-kHz clock, GPIO0, GPIO2, GPIO6, GPIO7) can be assigned. The time slot length
can be selected to be 0.5 ms or 2 ms. If a resource is not assigned to any time slot, it will be in off mode
after the power-on sequence and the voltage level can be changed through the register SEL bits before
enabling the resource.
Power off disables all power resources at the same time by default. By setting the PWR_OFF_SEQ
control bit to 1, power off will follow the power-up sequence in reverse order (the first resource to be
powered on will be last to power off).
The values of VDD1, VDD2, and VDDCtrl set in the boot sequence can be selected from 16 steps. For the
whole range, 100-mV steps are available: 0.6/0.7...1.4/1.5 V. From 0.8 to 1.4 V, additional values with
50-mV step resolution can be set: 0.85/1.05...1.35 V.
For LDO1, LDO2, and LDO4 all levels from 1.0 to 3.3 V are selectable in the boot sequence with 50-mV
steps. For other LDOs, the level is selectable with 100-mV steps, from 1.0 to 3.3 V.
The device supports three boot configurations, which define the power sequence and several device
control bits. The boot configuration is selectable by the device BOOT1 pin.
BOOT1
BOOT CONFIGURATION
Floating
Test boot mode
0
Fixed boot mode
1
EEPROM boot mode
The BOOT1 input pad is disabled after the boot mode is read at power up, to save power.
Table 6-2 and Table 6-3 describe the power sequence and general control bits defined in the boot
sequence, respectively.
Fixed boot mode is the same in all devices, while EEPROM boot mode is different in each device. For a
description of EEPROM boot mode, refer to the user's guide for the selected device. For a list of user's
guides, see Section 8.2.1 or the device product folder on ti.com.
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Table 6-2. Boot Configuration: Power Sequence Control Bits
TPS65911
REGISTER
BIT
DESCRIPTION
VDD1 voltage level selection for boot.
Levels available:
VDD1_OP_REG/
VDD1_SR_REG
VDD1_REG
VGAIN_SEL
VDD1 gain selection, ×1 or ×2
VDD1 time slot selection
VDD1_PSKIP
VGAIN_SEL
DCDCCTRL_REG
VDD2_PSKIP
VIO_REG
SEL[3:2]
EEPROM
VIO_PSKIP
SEL[7:2]
SEL[6:2]
SEL[7:2]
SEL[6:2]
×1
x
VDD2 time slot selection
6
x
VDD2 pulse skip mode enable
Enable skip
x
VIO voltage selection
1.8 V
x
VIO time slot selection
4
x
Enable skip
x
Off
x
VIO pulse skip mode enable
LDO1 voltage selection
LDO2 voltage selection
LDO3 voltage selection
LDO4 voltage selection
LDO5 voltage selection
LDO5 time slot
SEL[6:2]
EEPROM
SEL[6:2]
EEPROM
CLK32KOUT pin
NRESPWRON, NRESPWRON2
pin
x
x
Off
x
1.2 V
x
7
x
LDO3 voltage: 1 V
x
Off
x
1.2 V
x
2
x
LDO5 voltage: 1 V
x
Off
x
x
Off
x
1.2 V
x
5
x
1V
x
LDO8 time slot
7
x
CLK32KOUT time slot
5
x
NRESPWRON time slot
10
x
LDO7 voltage selection
LDO7 time slot
SEL[6:2]
Off
1.05 V
LDO6 voltage: 1 V
LDO6 voltage selection
LDO6 time slot
EEPROM
LDO8_REG
VDD2 gain selection, ×1 or ×3
LDO4 time slot
EEPROM
LDO7_REG
x
LDO3 time slot
EEPROM
LDO6_REG
1.5 V
LDO2 time slot
EEPROM
LDO5_REG
x
LDO1 time slot
EEPROM
LDO4_REG
x
VDDCtrl time slot selection
SEL[7:2]
EEPROM
LDO3_REG
x
0.6/0.7/0.8/0.85/0.9/0.95/../1.35/1.4 V
EEPROM
LDO2_REG
×1
3
VDDCtrl voltage level selection for boot.
Levels available:
VDDCtrl_OP_REG/
VDDCtrl_SR_REG
LDO1_REG
x
0.6/0.7/0.8/0.85/0.9/0.95/.../1.35/1.4/1.5 V
EEPROM
DCDCCTRL_REG
1.2 V
Enable skip
VDD1 pulse skip mode enable
VDD2 voltage level selection for boot.
Levels available:
VDD2_OP_REG/
VDD2_SR_REG
VDD2_REG
EEPROM
BOOT
0.6/0.7/0.8/0.85/0.9/0.95/.../1.35/1.4/1.5 V
EEPROM
DCDCCTRL_REG
FIXED BOOT
LDO8 voltage selection
GPIO0 pin
GPIO0 time slot
1
x
GPIO2 pin
GPIO2 time slot
Off
x
GPIO6 pin
GPIO6 time slot
6
x
GPIO7 pin
GPIO7 time slot
5
x
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Table 6-3. Boot Configuration: General Control Bits
REGISTER
BIT
VRTC_REG
VRTC_OFFMASK
DEVCTRL_REG
CK32K_CTRL
DEVCTRL_REG
DEV_ON
DEVCTRL2_REG
TSLOTD
TPS65911
DESCRIPTION
0: VRTC LDO will be in low-power mode during
OFF state.
1: VRTC LDO will be in full-power mode during
OFF state.
0: Clock source is crystal/external clock.
1: Clock source is internal RC oscillator.
FIXED BOOT
EEPROM BOOT
0
x
Crystal
x
0
x
2 ms
x
1
x
1
x
0
x
1
x
1
x
0
x
1
x
0
x
Push-pull
x
1
x
Disable buffer
x
3.1 V
x
0: No impact
1: Will keep device on, in ACTIVE or SLEEP
state
Boot sequence time slot duration:
0: 0.5 ms
1: 2 ms
DEVCTRL2_REG
PWON_LP_OFF
0: Turn off device after PWRON long-press not
allowed.
1: Turn off device after PWRON long-press.
DEVCTRL2_REG
PWON_LP_RST
DEVCTRL2_REG
IT_POL
INT_MSK_REG
VMBHI_IT_MSK
0: No impact
1: Reset digital core when device is off
0: INT1 signal will be active-low.
1: INT1 signal will be active-high.
0: Device will automatically switch-on at NO
SUPPLY-to-OFF or BACKUP-to-OFF transition
(device will switch-on when supply is inserted)
1: Start-up reason required before switch-on
(VMBHI event interrupt masked)
INT_MSK3_REG
INT_MSK3_REG
INT_MSK3_REG
GPIO5_F_IT_MSK
GPIO5_R_IT_MSK
GPIO4_F_IT_MSK
INT_MSK3_REG
GPIO4_R_IT_MSK
GPIO0_REG
GPIO_ODEN
WATCHDOG_REG
WATCHDOG_EN
0: GPIO5 falling-edge detection interrupt not
masked
1: GPIO5 falling-edge detection interrupt
masked
0: GPIO5 rising-edge detection interrupt not
masked
1: GPIO5 rising-edge detection interrupt
masked
0: GPIO4 falling-edge detection interrupt not
masked
1: GPIO4 falling-edge detection interrupt
masked
0: GPIO4 rising-edge detection interrupt not
masked
1: GPIO4 rising-edge detection interrupt
masked
0: GPIO0 configured as push-pull output
1: GPIO0 configured as open-drain output
0: Watchdog disabled
52
EEPROM
VMBBUF_BYPASS
VMBCH_REG
VMBCH_SEL[5:1]
1: Watchdog enabled, periodic operation with
100 s
0: Enable input buffer for external resistive
divider
1: In single-cell system, disable buffer for low
power
Select threshold for boot gating comparator
COMP1, 2.5–3.5 V.
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Table 6-3. Boot Configuration: General Control Bits (continued)
REGISTER
BIT
DESCRIPTION
0: PWRHOLD pin is used as PWRHOLD
feature.
6.5.3
EEPROM
AUTODEV_ON
EEPROM
PWRDN_POL
1: PWRHOLD pin is GPI. After power on,
DEV_ON set high internally, no processor
action required to keep supplies.
0: PWRDN signal will be active-low.
1: PWRDN signal will be active-high.
TPS65911
FIXED BOOT
EEPROM BOOT
1, PWRHOLD
pin is GPI
x
Active-low
x
Control Signals
6.5.3.1
SLEEP
When none of the device SLEEP-disable conditions are met, a falling edge (default, or rising edge,
depending on the programmed polarity) of this signal causes an ACTIVE-to-SLEEP state transition of the
device. A rising edge (default, or falling edge, depending on the programmed polarity) causes a transition
back to the ACTIVE state. This input signal is level-sensitive and no debouncing is applied.
While the device is in the SLEEP state, predefined resources are automatically set in their low-power
mode or off. Resources can be kept in their active mode (full-load capability) by programming the
SLEEP_KEEP_LDO_ON and the SLEEP_KEEP_RES_ON registers. These registers contain 1 bit per
power resource. If the bit is set to 1, then that resource stays in active mode when the device is in the
SLEEP state.
32KCLKOUT is also included in the SLEEP_KEEP_RES_ON register and the 32-kHz clock output is
maintained in the SLEEP state if the corresponding mask bit is set.
The status (low or high) of GPO0, GPO6, GPO7, and GPO8 are also controlled by the SLEEP signal, to
allow enabling and disabling of external resources during sleep.
6.5.3.2
PWRHOLD
The PWRHOLD pin can be used as a PWRHOLD signal input or as a general purpose input (GPI). The
mode is selected by the AUTODEV_ON bit, which is part of the boot configuration. When
AUTODEV_MODE = 0, the PWRHOLD feature is selected.
Configured as PWRHOLD, when none of the device POWER ON disable conditions are met, a high level
of this signal causes an OFF-to-ACTIVE state transition of the device and a low level causes a transition
back to the OFF state.
This input signal is level-sensitive and no debouncing is applied. The rising and/or falling edge of
PWRHOLD is highlighted through an associated interrupt if interrupt is unmasked.
When AUTODEV_ON = 1, the pin is used as a GPI. As a GPI, this input can generate a maskable
interrupt from a rising or falling edge of the input. When AUTODEV_ON = 1, a rising edge of
NRESPWRON also automatically sets the DEV_ON bit to 1 to keep supplies after the switch-on
sequence, thus removing the need for the processor to set the PWRHOLD signal or the DEV_ON bit.
6.5.3.3
BOOT1
This signal determines with which processor the device is working and, hence, which power-up sequence
is needed. For more details, see Section 5.21.2. No debouncing is present on this input signal.
6.5.3.4
NRESPWRON, NRESPWRON2
The NRESPWRON signal is used as the reset to the processor and is in the VDDIO domain. It is held low
until the ACTIVE state is reached. For detailed timing, see Section 5.21.2.
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The NRESPWRON2 signal is a second reset output. It follows the state of NRESPWRON but has an
open-drain output with external pullup. The supply for the external pullup must not be activated before the
TPS65911 device is in control of the output state (that is, not earlier than during first power-up sequence
slot). In off mode, the NRESPWRON2 output has weak internal pulldown.
6.5.3.5
CLK32KOUT
This signal is the output of the 32K oscillator, which can be enabled or not during the power-on sequence,
depending on the boot mode. It can be enabled and disabled by register bit, during the ACTIVE state of
the device. The CLK32KOUT output can also be enabled or not during the SLEEP state of the device
depending on the programming of the SLEEPMASK register.
6.5.3.6
PWRON
The PWRON input is connected to an external button. If the device is in the OFF or SLEEP state, a
debounced falling edge (PWRON input low for minimum of 100 ms) causes an OFF-to-ACTIVE state or a
SLEEP-to-ACTIVE state transition of the device. If the device is in active mode, then a low level on this
signal generates an interrupt. If the PWRON signal is low for more than the PWON_TO_OFF_DELAY
delay and the corresponding interrupt is not acknowledged by the processor within 1 second, the device
goes into the OFF state. For PWRON behavior, see Figure 5-2 and Figure 5-3.
6.5.3.7
INT1
The INT1 signal (default active low) warns the host processor of any event that has occurred on the
TPS65911 device. The host processor can then poll the interrupt from the interrupt status register through
I2C to identify the interrupt source. A low level (default setting) indicates an active interrupt, highlighted in
the INT_STS_REG register. The polarity of INT1 can be set programming the IT_POL control bit. INT1
flag active is a POWER ON enable condition during a fixed delay, tDOINT1 (only), when the device is in the
OFF state (when NRESPWRON is low).
Any of the interrupt sources can be masked programming the INT_MSK_REG register. When an interrupt
is masked its corresponding interrupt status bit is still updated, but the INT1 flag is not activated. Interrupt
source masking can be used to mask a device switch-on event. Because interrupt flag active is a POWER
ON enable condition, during tDOINT1 delay, any interrupt not masked must be cleared to allow immediate
turn off of the device.
For a description of interrupt sources, see Table 6-5.
6.5.3.8
EN2 and EN1
EN2 and EN1 are the data and clock signals of the serial control interface dedicated to voltage scaling
applications.
These signals can also be programmed to be used as enable signals of one or several supplies, when the
device is on (NRESPWRON high). A resource assigned to EN2 or EN1 control automatically disables the
serial control interface.
Programming EN1_LDO_ASS_REG, EN2_LDO_REG, and SLEEP_KEEP_LDO_ON_REG registers: EN1
and EN2 signals can be used to control the turn on/off or SLEEP state of any LDO-type supplies.
Programming EN1_SMPS_ASS_REG, EN2_SMPS_ASS_REG, and SLEEP_KEEP_RES_ON registers:
EN1 and EN2 signals can be used to control the turn on/off or LOW-POWER state (PFM mode) of SMPStype supplies.
The EN2 and EN1 signals can be used to set the output voltage of VDD1 and VDD2 SMPS from a roof to
a floor value, preprogrammed in the VDD1_OP_REG, VDD2_OP_REG and VDD1_SR_REG,
VDD2_SR_REG registers.
When a supply is controlled through the EN1 or EN2 signals, its state is no longer driven by the device
SLEEP state.
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6.5.3.9
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GPIO0 to GPIO8
GPIO0, GPIO2, GPIO6, and GPIO7 can be programmed to be part of the power-up sequence and used
as enable signals for external resources.
GPIO0 is a configurable I/O in the VCC7 domain. By default, its output is push-pull, driving low. GPIO0
can also be configured as an open-drain output with external pullup.
GPIO1 through GPIO8 are configurable open-drain digital I/Os in the VRTC domain. GPIO directivity,
debouncing delay, and internal pullup can be programmed. By default, all are inputs with weak internal
pulldown; as open-drain output an external pullup is required.
GPIO0, GPIO1, and GPIO3 through GPIO5 can be used to turn on the device if the corresponding
interrupt is not masked. When configured as an input, GPIO2 cannot be used to turn on the device, even if
its associated interrupt is not masked. The GPIO interrupt is level sensitive. When an interrupt is detected,
before clearing the interrupt, it should first be disabled by masking it.
GPIO1 and GPIO3, which have current sink capability of 10 mA, can also be used to drive LEDs
connected to a 5-V supply.
GPIO2 can be used for synchronizing DC-DC converters to an external clock. Programming DCDCCKEXT
= 1, VDD1, VDD2, and VIO DCDC switching can be synchronized using a 3-MHz clock set though the
GPIO2 pin. VDD1 and VDD2 will be in-phase and VIO will be phase shifted by 180 degrees.
It is recommended not to connect noisy switching signals to GPIO4 and GPIO5.
6.5.3.10 HDRST Input
HDRST is a cold reset input for the PMIC. High level at input forces the TPS65911 device into off mode,
causing a general reset of device to the default settings. The default state is defined by the register reset
state and boot configuration. HDRST high level keeps the device in off mode. When reset is released and
HDRST input goes low, the device automatically transitions to active mode. The device is kept in active
mode for the period tDONIT1, after which another power-on enable reason is required to keep the device on.
The HDRST input is in the VRTC domain and has a weak internal pulldown, which is active by default.
6.5.3.11 PWRDN
The PWRDN input is a reset input with selectable polarity (PWRDN_POL). High(low) level at input forces
the TPS65911 device into off mode, causing a power-off reset. Off mode is maintained until PWRDN is
released and a start-up reason (for example, PWRON button press or DEV_ON = 1) is detected. An
interrupt is generated to indicate the cause for shutdown. The PWRDN input is in the VRTC domain but
can tolerate a 5-V input.
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6.5.3.12 Comparators: COMP1 and COMP2
The TPS65911 device has three comparators for system status detection/control. One comparator detects
the voltage at pin VCC7. When VCC7 > VMBHI, the comparator initiates a NO SUPPLY-to-OFF transition
and the VMBHI_IT interrupt is generated. When VCC7 < VMBLO, the comparator initiates an
ACTIVE/SLEEP/OFF-to-BACKUP transition. When both VCC7 and backup battery are below VBPNR, the
device goes to the NO SUPPLY state.
Comparators COMP1 and COMP2 detect the voltage of VCCS. Programmable comparator COMP1 is
intended for detecting if battery voltage is high enough for an OFF-to-ACTIVE transition of the TPS65911
device. For an OFF-to-ACTIVE transition VCCS must be > VMBCH (primary battery charged) and a level
below the comparator threshold prevents the power-up sequence. The threshold can be set from 2.5 to
3.5 V with 50-mV steps through VMBCH_SEL. The comparator has debouncing so that VCCS must stay
above VMBDCH (VMBCH – 0.1 V) for a debouncing period of 61 µs. The comparator can be bypassed if
the threshold selection is set to 0. The default threshold is set in the boot configuration.
In a system with a multiple-cell battery, the battery level is sensed through an external resistor divider. The
TPS65911 device has an internal buffer at the VCCS input, which must be used with the external resistive
divider.
In a single-cell system, VCCS and VCC7 are connected directly to the battery. The VCCS input buffer can
be bypassed to minimize power consumption. The buffer bypass is controlled with the VMBBUF_BYPASS
bit in the boot configuration.
COMP2 is disabled by default and can be enabled by software. The comparator trigger generates an
interrupt which is programmable on the rising (VMBCH2_H_IT) or falling edge (VMBCH2_L_IT), hence the
comparator can be used for detecting high or low battery scenarios. COMP2 generates an interrupt for the
host. In sleep mode, this creates a wake-up interrupt for the host. In off mode, the comparator trigger
generates a turnon event. In backup or no supply modes, the comparator is not active.
The COMP2 threshold can be set from 2.5 to 3.5 V with 50-mV steps. Enabling the comparator is done
through the voltage threshold selection bit VMBDCH2_SEL, which is set to 0 by default.
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6.5.3.13 Watchdog
The watchdog has two modes of operation.
In periodic operation, an interrupt is generated with a regular period defined by the WTCHDG_TIME
setting. The IC initiates WTCHDOG shutdown if the interrupt is not cleared within the period. The
watchdog interrupt WTCHDOG counter is reinitialized when NRESPWRON is low.
In interrupt mode the IC initiates WTCHDOG counter when interrupt is set pending and is cleared when
interrupt is cleared. If no interrupt is cleared before watchdog expiration within WTCHDG_TIME, the
device goes to off mode.
By default, periodic watchdog functionality is enabled with the maximum WTCHDG_TIME period.
Periodic mode:
WTCHDG_CNT
0
1
N
0
1
N
1
N
WTCHDG_IT
WTCHDG_OFF
WTCHDG_IT clearing
interrupt clearing
Interrupt mode:
WTCHDG_CNT
0
1
i
0
WTCHDG_OFF
SWCS049-013
Figure 6-2. Watchdog Signals
6.5.3.14 Tracking LDO
LDO4 has an optional mode where its output level follows that of VDD1, from 0.6 to 1.5 V, when VDD1 is
active. When VDD1 is set to off, the LDO4 output is defined by the SEL[7:2] bits in LDO4_REG, and can
be set from 0.8 to 1.5 V.
Tracking mode is enabled by setting TRACK = 1 in DCDCCTRL_REG. In initial activation, VDD1 must be
enabled and allowed to settle before enabling tracking mode. After initial activation, tracking mode can be
kept enabled while VDD1 is turned off. The value of TRACK is set to default (0) after any turnoff event.
TRACK bit
VDD1 enable
LDO4 MODE
Setting
time tON
LDO4
LDO4
LDO4
No Tracking 1 to 3.3 V
Tracking 0.6 to 1.5 V
Tracking 0.8 V to 1.5 V
(LDO4 has same
level as VDD1)
LDO4
Tracking 0.6 V
(LDO4 has same
level as VDD1)
SWCS049-019
Figure 6-3. Tracking LDO
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6.6
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PWM and LED Generators
The TPS65911 device has two LED ON/OFF signal generators, LED1 and LED2. LED1 and LED2 have
independently controllable periods from 125 ms to 8 s and ON time from 62.5 to 500 ms. Within the
period, one or two ON pulses can be generated (control bit LED1(2)_SEQ). The user must take care to
program period and ON time correctly, because no limitation on selected values is imposed. LED1 and
LED2 signals can be routed to GPIO1 and GPO3 open-drain outputs, respectively. These GPIOs have a
current sink capability of 10 mA.
The PWM generator frequency and duty cycle are set by the PWM_FREQ and PWM_DUTY_CYCLE bits,
respectively. The PWM generator signal can be connected to the GPIO3 or GPIO8 output. The PWM
generator uses the 3-MHz clock, which is not available in off mode. To enable the PWM in sleep mode,
the I2CHS_KEEPON bit must be set to 1.
6.7
Dynamic Voltage Frequency Scaling and Adaptive Voltage Scaling Operation
Dynamic voltage frequency scaling (DVFS) operation: A supply voltage value corresponding to a targeted
frequency of the digital core supplied is programmed in VDD1_OP_REG or VDD2_OP_REG registers.
The slew rate of the voltage supply reaching a new VDD1_OP_REG or VDD2_OP_REG programmed
value is limited to 12.5 mV/µs, fixed value.
Adaptative voltage scaling (AVS) operation: A supply voltage value corresponding to a supply voltage
adjustment is programmed in VDD1_SR_REG or VDD2_SR_REG registers. The supply voltage is then
intended to be tuned by the digital core supplied, based its performance self-evaluation. The slew rate of
VDD1 or VDD2 voltage supply reaching a new programmed value is programmable though the
VDD1_REG or VDD2_REG register, respectively.
A serial control interface (optional mode for EN1 and EN2 pins) can be dedicated to voltage scaling
applications, to give dedicated access to the VDD1_OP_REG, VDD1_SR_REG and VDD2_OP_REG,
VDD2_SR_REG registers.
A general-purpose serial control interface (CTL-I2C) also gives access to these registers, if the
SR_CTL_I2C_SEL control bit is set to 1 in the DEVCTRL_REG register (default inactive).
Both control interfaces are compliant with HS-I2C specification (100 Kbps, 400 Kbps, or 3.4 Mbps).
6.8
32-kHz RTC Clock
The TPS65911 device can provide a 32-kHz clock to the platform through the CLK32KOUT output, when
a crystal is connected.
Alternatively, the device can accept a square-wave 32-kHz clock signal applied to OSC32IN input
(OSC32KOUT kept floating) and gate the clock to CLK32OUT. This clock must be present for any state of
the EPC except the NO SUPPLY state. The TPS65911 device also has an internal 32-kHz RC oscillator to
decrease the BOM if an accurate clock is not needed by the system.
Default selection of a 32-kHz RC oscillator versus 32-kHz crystal oscillator or external square-wave
32-kHz clock depends on the boot configuration setting for the CK32K_CTRL bit.
Switching from the 32-kHz RC oscillator to the 32-kHz crystal oscillator or external square-wave 32-kHz
clock can also be programmed though the DEVCTRL_REG register.
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VRTC
32 kHz to
Digital Block
Biasing
and
Amplitude
Control
OSC32KIN
REFGND OSC32KOUT
Q
COSCIN
COSCOUT
SWCS049-014
Copyright © 2016, Texas Instruments Incorporated
Figure 6-4. Crystal Oscillator 32-kHz Clock
6.9
Real Time Clock (RTC)
The RTC, which is driven by the 32-kHz clock, provides the alarm and timekeeping functions. The RTC is
kept supplied when the device is in the OFF state or the BACKUP state.
The primary functions of the RTC block are:
• Time information (seconds/minutes/hours) directly in binary-coded decimal (BCD) format
• Calendar information (Day/Month/Year/Day of the week) directly in BCD code up to year 2099
• Programmable interrupts generation: The RTC can generate two interrupts: a timer interrupt
RTC_PERIOD_IT periodically (1s/1m/1h/1d period) and an alarm interrupt RTC_ALARM_IT at a
precise time of the day (alarm function). These interrupts are enabled using IT_ALARM and IT_TIMER
control bits. Periodically interrupts can be masked during the SLEEP period to avoid host interruption
and are automatically unmasked after SLEEP wakeup (using the IT_SLEEP_MASK_EN control bit).
• Oscillator frequency calibration and time correction
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32-kHz Clock
Input
32-kHz
Counter
Seconds
Frequency
Compensation
Minutes
Hours
Week
Days
Control
Days
Months
Interrupt
Alarm
Years
INT_ALARM
INT_TIMER
SWCS049-015
Copyright © 2016, Texas Instruments Incorporated
Figure 6-5. RTC Digital Section Block Diagram
6.9.1
Time Calendar Registers
All the time and calendar information is available in these dedicated registers, called TC registers. Values
of the TC registers are written in BCD format.
1. Years data ranges from 00 to 99
– Leap year = Year divisible by four (2000, 2004, 2008, 2012...)
– Common year = other years
2. Months data ranges from 01 to 12
3. Days value ranges from:
– 1 to 31 when months are 1, 3, 5, 7, 8, 10, 12
– 1 to 30 when months are 4, 6, 9, 11
– 1 to 29 when month is 2 and year is a leap year
– 1 to 28 when month is 2 and year is a common year
4. Weeks value ranges from 0 to 6
5. Hours value ranges from 00 to 23 in 24-hour mode and ranges from 1 to 12 in AM/PM mode
6. Minutes value ranges from 0 to 59
7. Seconds value ranges from 0 to 59
To modify the current time, software writes the new time into TC registers to fix the time/calendar
information. The processor can write into the TC registers without stopping the RTC. In addition, software
can stop the RTC by clearing the STOP_RTC bit of the control register and check the RUN bit of the
status to be sure that the RTC is frozen, then update the TC values, and then restart the RTC by setting
STOP_RTC bit.
Example: Time is 10H54M36S PM (PM_AM mode set), 2008 September 5, previous register values are:
Table 6-4. RTC Registers Example
60
Register
Value
SECONDS_REG
0x36
MINUTES_REG
0x54
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Table 6-4. RTC Registers Example (continued)
Register
Value
HOURS_REG
0x90
DAYS_REG
0x05
MONTHS_REG
0x09
YEARS_REG
0x08
The user can round to the nearest minute, by setting the ROUND_30S register bit. TC values are set to
the nearest minute value at the next second. The ROUND_30S bit is automatically cleared when the
rounding time is performed.
Example:
• If current time is 10H59M45S, a round operation changes time to 11H00M00S.
• If current time is 10H59M29S, a round operation changes time to 10H59M00S.
6.9.2
General Registers
Software can access the RTC_STATUS_REG and RTC_CTRL_REG registers at any time (except for the
RTC_CTRL_REG[5] bit, which must be changed only when the RTC is stopped).
6.9.3
Compensation Registers
The RTC_COMP_MSB_REG and RTC_COMP_LSB_REG registers must respect the available access
period. These registers must be updated before each compensation process. For example, software can
load the compensation value into these registers after each hour event, during an available access period.
Hours
Seconds
3
6
4
58
59
0
1
58
2
59
0
1
2
Compensation event
Hours
3
Seconds
59
4
0
1
Compensation event
SWCS046-016
Figure 6-6. RTC Compensation Scheduling
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This drift can be balanced to compensate for any inaccuracy of the 32-kHz oscillator. Software must
calibrate the oscillator frequency, calculate the drift compensation versus 1-hour time period; and then
load the compensation registers with the drift compensation value. Indeed, if the AUTO_COMP_EN bit in
the RTC_CTRL_REG is enabled, the value of COMP_REG (in twos-complement) is added to the RTC
32-kHz counter at each hour and 1 second. When COMP_REG is added to the RTC 32-kHz counter, the
duration of the current second becomes (32768 – COMP_REG)/32768s; so, the RTC can be
compensated with a 1/32768 s/hour time unit accuracy.
NOTE
The compensation is considered once written into the registers.
6.10 Backup Battery Management
The device includes a backup battery switch connecting the VRTC regulator input to a primary battery
(VCC7) or to a backup battery (VBACKUP), depending on the voltage value of the battery.
The VRTC supply can then be maintained during a BACKUP state as long as the input voltage is high
enough (> VBNPR threshold). Below the VBNPR voltage threshold, the digital core of the device is set
under reset by internal signal Power-on Reset (POR).
The backup domain functions which are always supplied from VRTC are:
• The internal 32-kHz oscillator
• Backup registers
The backup battery can be charged from the primary battery through an embedded charger. The backup
battery charge voltage and enable is controlled through BBCH_REG register programming. This register
content is maintained during the device BACKUP state.
Hence, when enabled, the backup battery charge is maintained as long as the primary battery voltage is
higher than the VMBLO threshold and the backup battery voltage.
6.11 Backup Registers
As part of the RTC, the device contains five 8-bit registers that can be used for storage by the application
firmware when the external host is powered down. These registers retain their content as long as the
VRTC is active.
6.12 I2C Interface
A general-purpose serial control interface (CTL-I2C) allows read and write access to the configuration
registers of all resources of the system.
A second serial control interface (optional mode for EN1 and EN2 pins) can be dedicated to DVFS.
Both control interfaces are compliant with the HS-I2C specification.
These interfaces support the standard slave mode (100 Kbps), fast mode (400 Kbps), and high-speed
mode (3.4 Mbps). The general-purpose I2C module using one slave hard-coded address (ID1 = 2Dh). The
voltage scaling dedicated I2C module uses one slave hard-coded address (ID0 = 12h). The master mode
is not supported.
Addressing:
The device supports seven-bit mode addressing.
It does not support the following features:
• 10-bit addressing
• General call
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6.12.1
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Access Protocols
For compatibility, the I2C interfaces in the TPS65911 device use the same read/write protocol as other TI
power ICs, based on an internal register size of 8 bits. Supported transactions are described in the
following sections.
6.12.1.1 Single Byte Access
A write access is initiated by a first byte including the address of the device (7 MSBs) and a write
command (LSB), a second byte provides the address (8 bits) of the internal register, and the third byte
represents the data to be written in the internal register, see Figure 6-7.
A
•
•
•
read access is initiated by:
A first byte, including the address of the device (7 MSBs) and a write command (LSB)
A second byte, providing the address (8 bits) of the internal register
A third byte, including again the device address (7 MSBs) and the read command (LSB)
The device replies by sending a fourth byte representing the content of the internal register (see
Figure 6-8).
DAD: Device address
S
T
A
R
T
D
A
D
6
D
A
D
5
D
A
D
3
D
A
D
4
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A
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2
D
A
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1
D
A
D
0
W
R
I
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A
C
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6
R
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7
R
A
D
5
R
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3
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2
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A
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R
A
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0
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0
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A
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1
S
T
O
P
A
C
K
RAD: Register address
DAT: Data
SCL
Master drives SDA
SDA
Slave drives SDA
SWCS049-020
2
Figure 6-7. I C Write Access Single Byte
S
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5
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4
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0
A
C
K
S
T
O
P
SCL
SDA
SWCS049-021
2
Figure 6-8. I C Read Access Single Byte
6.12.1.2 Multiple Byte Access to Several Adjacent Registers
A write access is initiated by:
• A first byte, including the address of the device (7 MSBs) and a write command (LSB)
• A second byte, providing the base address (8 bits) of the internal registers
The following N bytes represent the data to be written in the internal register starting at the base address
and incremented by one at each data byte (see Figure 6-9).
A
•
•
•
read access is initiated by:
A first byte, including the address of the device (7 MSBs) and a write command (LSB)
A second byte, providing the base address (8 bits) of the internal register
A third byte, including again the device address (7 MSBs) and the read command (LSB)
The device replies by sending a fourth byte, representing the content of the internal registers, starting at
the base address and next consecutive ones (see Figure 6-10).
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S
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www.ti.com
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D
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0
A
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K
S
T
O
P
SCL
SDA
SWCS049-022
Figure 6-9. I2C Write Access Multiple Bytes
S
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T
1
D
A
T
0
A
C
K
S
T
O
P
SCL
SDA
SWCS049-023
2
Figure 6-10. I C Read Access Multiple Bytes
6.13 Thermal Monitoring and Shutdown
A thermal protection module monitors the junction temperature of the device versus two thresholds:
• Hot-die temperature threshold
• Thermal shutdown temperature threshold
When the hot-die temperature threshold is reached, an interrupt is sent to software to close the noncritical
running tasks.
When the thermal shutdown temperature threshold is reached, the TPS65911 device is set under reset
and a transition to OFF state is initiated. Then the POWER ON enable conditions of the device are not
considered until the die temperature has decreased below the hot-die threshold. Hysteresis is applied to
the hot-die and shutdown thresholds, when detecting a falling edge of temperature, and both detections
are debounced to avoid any parasitic detection.
The TPS65911 device allows programming of four hot-die temperature thresholds to increase the flexibility
of the system.
By default, the thermal protection is enabled in ACTIVE state, but can be disabled through programming
the THERM_REG register. The thermal protection can be enabled in SLEEP state programming the
SLEEP_KEEP_RES_ON register. The thermal protection is automatically enabled during an OFF-toACTIVE state transition and is kept enabled in OFF state after a switch-off sequence caused by a thermal
shutdown event. Transition to OFF state sequence caused by a thermal shutdown event is highlighted in
the INT_STS_REG status register. Recovery from this OFF state is initiated (switch-on sequence) when
the die temperature falls below the hot-die temperature threshold.
Hot-die and thermal shutdown temperature threshold detection states can be monitored or masked by
reading or programming the THERM_REG register. The hot-die interrupt can be masked by programming
the INT_MSK_REG register.
6.14 Interrupts
Table 6-5 lists the interrupt sources.
Table 6-5. Interrupt Sources
INTERRUPT
DESCRIPTION
RTC_ALARM_IT
RTC alarm event: Occurs at programmed determinate date and time
(running in ACTIVE, OFF, and SLEEP state, default inactive)
RTC_PERIOD_IT
RTC periodic event: Occurs at programmed regular period of time (each second or minute)
(running in ACTIVE, OFF, and SLEEP state, default inactive)
64
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Table 6-5. Interrupt Sources (continued)
INTERRUPT
DESCRIPTION
HOT_DIE_IT
The embedded thermal monitoring module has detected a die temperature above the hot-die
detection threshold (running in ACTIVE and SLEEP state).
Level sensitive interrupt.
PWRHOLD_R_IT
PWRHOLD signal rising edge
PWRHOLD_F_IT
PWRHOLD signal falling-edge
PWRON_LP_IT
PWRON is low during more than the long-press delay: PWON_TO_OFF_DELAY (can be
disabled though register programming).
PWRON_IT
PWRON is low while the device is on (running in ACTIVE and SLEEP state). Level-sensitive
interrupt.
VMBHI_IT
The battery voltage rise above the VMBHI threshold: NO SUPPLY-to-OFF or BACKUP-toOFF device states transition (first battery plug or battery voltage bounce detection)
VMBDCH_IT
The battery voltage fall down below the VMBDCH threshold: the minimum operating voltage
of power supplies.
GPIO0_R_IT
GPIO_CKSYNC rising-edge detection
GPIO0_F_IT
GPIO_CKSYNC falling-edge detection
VMBCH2_H_IT
Comparator 2 input above threshold detection
VMBCH2_L_IT
Comparator 2 input below threshold detection
GPIO1_R_IT
GPIO1 rising-edge detection
GPIO1_F_IT
GPIO1 falling-edge detection
GPIO2_R_IT
GPIO2 rising-edge detection
GPIO2_F_IT
GPIO2 falling-edge detection
GPIO3_R_IT
GPIO3 rising-edge detection
GPIO3_F_IT
GPIO3 falling-edge detection
GPIO4_R_IT
GPIO4 rising-edge detection
GPIO4_F_IT
GPIO4 falling-edge detection
GPIO5_R_IT
GPIO5 rising-edge detection
GPIO5_F_IT
GPIO5 falling-edge detection
WTCHDG_IT
Watchdog interrupt
PWRDN_IT
PWRDN reset interrupt
6.15 Register Maps
6.15.1 Functional Registers
The possible device reset domains are:
• Full reset: All digital logic of device is reset.
– Caused by POR (power on reset) when VCC7 < VBNPR and BB < VBNPR
• General reset: No impact on RTC, backup registers or interrupt status.
– Caused by PWON_LP_RST bit set high or
– DEV_OFF_RST bit set high or
– HDRST input set high
• Turnoff OFF: Power reinitialization in off/backup mode.
In the following register description, the reset domain for each register is defined in the register table
heading.
NOTE
DCDCCTRL_REG and DEVCTRL2_REG have bits in two reset domains.
The comment Default value: See boot configuration indicates that bit default value is set in
boot configuration and not by the register reset value.
Detailed Description
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6.15.1.1 TPS65911_FUNC_REG Registers Mapping Summary
Table 6-6. TPS65911_FUNC_REG Register Summary (1)
Type
Register Width (Bits)
Register Reset
Address Offset
SECONDS_REG
Register Name
RW
8
0x00
0x00
MINUTES_REG
RW
8
0x00
0x01
HOURS_REG
RW
8
0x00
0x02
DAYS_REG
RW
8
0x01
0x03
MONTHS_REG
RW
8
0x01
0x04
YEARS_REG
RW
8
0x00
0x05
WEEKS_REG
RW
8
0x00
0x06
ALARM_SECONDS_REG
RW
8
0x00
0x08
ALARM_MINUTES_REG
RW
8
0x00
0x09
ALARM_HOURS_REG
RW
8
0x00
0x0A
ALARM_DAYS_REG
RW
8
0x01
0x0B
ALARM_MONTHS_REG
RW
8
0x01
0x0C
ALARM_YEARS_REG
RW
8
0x00
0x0D
RTC_CTRL_REG
RW
8
0x00
0x10
RTC_STATUS_REG
RW
8
0x80
0x11
RTC_INTERRUPTS_REG
RW
8
0x00
0x12
RTC_COMP_LSB_REG
RW
8
0x00
0x13
RTC_COMP_MSB_REG
RW
8
0x00
0x14
RTC_RES_PROG_REG
RW
8
0x27
0x15
RTC_RESET_STATUS_REG
RW
8
0x00
0x16
BCK1_REG
RW
8
0x00
0x17
BCK2_REG
RW
8
0x00
0x18
BCK3_REG
RW
8
0x00
0x19
BCK4_REG
RW
8
0x00
0x1A
BCK5_REG
RW
8
0x00
0x1B
PUADEN_REG
RW
8
0x1F
0x1C
REF_REG
RO
8
0x01
0x1D
VRTC_REG
RW
8
0x01
0x1E
VIO_REG
RW
8
0x05
0x20
VDD1_REG
RW
8
0x0D
0x21
VDD1_OP_REG
RW
8
0x33
0x22
VDD1_SR_REG
RW
8
0x33
0x23
VDD2_REG
RW
8
0x0D
0x24
VDD2_OP_REG
RW
8
0x4B
0x25
VDD2_SR_REG
RW
8
0x4B
0x26
VDDCRTL_REG
RW
8
0x00
0x27
VDDCRTL_OP_REG
RW
8
0x03
0x28
VDDCRTL_SR_REG
RW
8
0x03
0x29
LDO1_REG
RW
8
0x15
0x30
LDO2_REG
RW
8
0x15
0x31
LDO5_REG
RW
8
0x00
0x32
LDO8_REG
RW
8
0x09
0x33
LDO7_REG
RW
8
0x0D
0x34
LDO6_REG
RW
8
0x21
0x35
LDO4_REG
RW
8
0x00
0x36
(1)
66
Register reset values are for fixed boot mode.
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Table 6-6. TPS65911_FUNC_REG Register Summary(1) (continued)
Type
Register Width (Bits)
Register Reset
Address Offset
LD03_REG
Register Name
RW
8
0x00
0x37
THERM_REG
RW
8
0x0D
0x38
BBCH_REG
RW
8
0x00
0x39
DCDCCTRL_REG
RW
8
0x39
0x3E
DEVCTRL_REG
RW
8
0x0000 0014
0x3F
DEVCTRL2_REG
RW
8
0x0000 0036
0x40
SLEEP_KEEP_LDO_ON_REG
RW
8
0x00
0x41
SLEEP_KEEP_RES_ON_REG
RW
8
0x00
0x42
SLEEP_SET_LDO_OFF_REG
RW
8
0x00
0x43
SLEEP_SET_RES_OFF_REG
RW
8
0x00
0x44
EN1_LDO_ASS_REG
RW
8
0x00
0x45
EN1_SMPS_ASS_REG
RW
8
0x00
0x46
EN2_LDO_ASS_REG
RW
8
0x00
0x47
EN2_SMPS_ASS_REG
RW
8
0x00
0x48
INT_STS_REG
RW
8
0x06
0x50
INT_MSK_REG
RW
8
0xFF
0x51
INT_STS2_REG
RW
8
0xA8
0x52
INT_MSK2_REG
RW
8
0xFF
0x53
INT_STS3_REG
RW
8
0x5A
0x54
INT_MSK3_REG
RW
8
0xFF
0x55
GPIO0_REG
RW
8
0x07
0x60
GPIO1_REG
RW
8
0x08
0x61
GPIO2_REG
RW
8
0x08
0x62
GPIO3_REG
RW
8
0x08
0x63
GPIO4_REG
RW
8
0x08
0x64
GPIO5_REG
RW
8
0x08
0x65
GPIO6_REG
RW
8
0x05
0x66
GPIO7_REG
RW
8
0x05
0x67
GPIO8_REG
RW
8
0x08
0x68
WATCHDOG_REG
RW
8
0x07
0x69
VMBCH_REG
RW
8
0x1E
0x6A
VMBCH2_REG
RW
8
0x00
0x6B
LED_CTRL1_REG
RW
8
0x00
0x6C
LED_CTRL2_REG1
RW
8
0x00
0x6D
PWM_CTRL1_REG
RW
8
0x00
0x6E
PWM_CTRL2_REG
RW
8
0x00
0x6F
SPARE_REG
RW
8
0x00
0x70
VERNUM_REG
RO
8
0x00
0x80
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6.15.1.2 TPS65911_FUNC_REG Register Descriptions
Table 6-7. SECONDS_REG
Address Offset
0x00
Instance
Reset Domain: FULL RESET
Description
RTC register for seconds
Type
RW
7
Reserved
Bits
6
5
SEC1
4
3
2
1
0
SEC0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
6:4
SEC1
Second digit of seconds (range is 0 up to 5)
RW
0x0
3:0
SEC0
First digit of seconds (range is 0 up to 9)
RW
0x0
7
Table 6-8. MINUTES_REG
Address Offset
0x01
Instance
Reset Domain: FULL RESET
Description
RTC register for minutes
Type
RW
7
Reserved
Bits
5
MIN1
4
3
2
1
0
MIN0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
6:4
MIN1
Second digit of minutes (range is 0 up to 5)
RW
0x0
3:0
MIN0
First digit of minutes (range is 0 up to 9)
RW
0x0
7
68
6
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Table 6-9. HOURS_REG
Address Offset
0x02
Instance
Reset Domain: FULL RESET
Description
RTC register for hours
Type
RW
7
PM_NAM
Bits
6
Reserved
5
4
3
2
HOUR1
1
0
HOUR0
Field Name
Description
7
PM_NAM
Only used in PM_AM mode (otherwise it is set to 0)
0 is AM
1 is PM
Type
Reset
RW
0
6
Reserved
Reserved bit
RO
R returns
0s
0
5:4
HOUR1
3:0
HOUR0
Second digit of hours(range is 0 up to 2)
RW
0x0
First digit of hours (range is 0 up to 9)
RW
0x0
Table 6-10. DAYS_REG
Address Offset
0x03
Instance
Reset Domain: FULL RESET
Description
RTC register for days
Type
RW
7
6
5
Reserved
4
3
2
DAY1
1
0
DAY0
Bits
Field Name
Description
Type
Reset
7:6
Reserved
Reserved bit
RO
R returns
0s
0x0
5:4
DAY1
Second digit of days (range is 0 up to 3)
RW
0x0
3:0
DAY0
First digit of days (range is 0 up to 9)
RW
0x1
Table 6-11. MONTHS_REG
Address Offset
0x04
Instance
Reset Domain: FULL RESET
Description
RTC register for months
Type
RW
7
6
Reserved
5
4
MONTH1
3
2
1
0
MONTH0
Bits
Field Name
Description
Type
Reset
7:5
Reserved
Reserved bit
RO
R returns
0s
0x0
4
MONTH1
Second digit of months (range is 0 up to 1)
RW
0
3:0
MONTH0
First digit of months (range is 0 up to 9)
RW
0x1
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Table 6-12. YEARS_REG
Address Offset
0x05
Instance
Reset Domain: FULL RESET
Description
RTC register for day of the week
Type
RW
7
6
5
4
3
2
1
YEAR1
0
YEAR0
Bits
Field Name
Description
Type
Reset
7:4
YEAR1
Second digit of years (range is 0 up to 9)
RW
0x0
3:0
YEAR0
First digit of years (range is 0 up to 9)
RW
0x0
Table 6-13. WEEKS_REG
Address Offset
0x06
Instance
Reset Domain: FULL RESET
Description
RTC register for day of the week
Type
RW
7
6
5
Reserved
4
3
2
1
WEEK
0
Bits
Field Name
Description
Type
Reset
7:3
Reserved
Reserved bit
RO
R returns
0s
0x00
2:0
WEEK
First digit of day of the week (range is 0 up to 6)
RW
0
1
0
Table 6-14. ALARM_SECONDS_REG
Address Offset
0x08
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for seconds
Type
RW
7
Reserved
Bits
5
ALARM_SEC1
4
3
2
ALARM_SEC0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
6:4
ALARM_SEC1
Second digit of alarm programmation for seconds (range is 0 up to 5)
RW
0x0
3:0
ALARM_SEC0
First digit of alarm programmation for seconds (range is 0 up to 9)
RW
0x0
7
70
6
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Table 6-15. ALARM_MINUTES_REG
Address Offset
0x09
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for minutes
Type
RW
7
Reserved
Bits
6
5
ALARM_MIN1
4
3
2
1
0
ALARM_MIN0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
6:4
ALARM_MIN1
Second digit of alarm programmation for minutes (range is 0 up to 5)
RW
0x0
3:0
ALARM_MIN0
First digit of alarm programmation for minutes (range is 0 up to 9)
RW
0x0
7
Table 6-16. ALARM_HOURS_REG
Address Offset
0x0A
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for hours
Type
RW
7
ALARM_PM_N
AM
Bits
6
Reserved
5
4
3
ALARM_HOUR1
2
1
0
ALARM_HOUR0
Field Name
Description
7
ALARM_PM_
NAM
Only used in PM_AM mode for alarm programmation (otherwise it is set
to 0)
0 is AM
1 is PM
Type
Reset
RW
0
6
Reserved
Reserved bit
RO
R returns
0s
0
5:4
ALARM_HOUR1
3:0
ALARM_HOUR0
Second digit of alarm programmation for hours(range is 0 up to 2)
RW
0x0
First digit of alarm programmation for hours (range is 0 up to 9)
RW
0x0
Table 6-17. ALARM_DAYS_REG
Address Offset
0x0B
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for days
Type
RW
7
6
Reserved
5
4
3
2
ALARM_DAY1
1
0
ALARM_DAY0
Bits
Field Name
Description
Type
Reset
7:6
Reserved
Reserved bit
RO
R Special
0x0
5:4
ALARM_DAY1
Second digit of alarm programmation for days (range is 0 up to 3)
RW
0x0
3:0
ALARM_DAY0
First digit of alarm programmation for days (range is 0 up to 9)
RW
0x1
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Table 6-18. ALARM_MONTHS_REG
Address Offset
0x0C
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for months
Type
RW
7
6
5
4
ALARM_
MONTH1
Reserved
3
2
1
0
ALARM_MONTH0
Bits
Field Name
Description
Type
Reset
7:5
Reserved
Reserved bit
RO
R returns
0s
0x0
4
ALARM_MONTH1
Second digit of alarm programmation for months (range is 0 up to 1)
RW
0
3:0
ALARM_MONTH0
First digit of alarm programmation for months (range is 0 up to 9)
RW
0x1
Table 6-19. ALARM_YEARS_REG
Address Offset
0x0D
Instance
Reset Domain: FULL RESET
Description
RTC register for alarm programmation for years
Type
RW
7
6
5
4
3
ALARM_YEAR1
72
2
1
0
ALARM_YEAR0
Bits
Field Name
Description
Type
Reset
7:4
ALARM_YEAR1
Second digit of alarm programmation for years (range is 0 up to 9)
RW
0x0
3:0
ALARM_YEAR0
First digit of alarm programmation for years (range is 0 up to 9)
RW
0x0
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Table 6-20. RTC_CTRL_REG
Address Offset
0x10
Instance
Reset Domain: FULL RESET
Description
RTC control register:
NOTES: A dummy read of this register is necessary before each I2C read in order to update the ROUND_30S bit
value.
Type
RW
7
6
RTC_V_OPT
GET_TIME
5
SET_32_
COUNTER
4
3
2
1
0
TEST_MODE
MODE_12_24
AUTO_COMP
ROUND_30S
STOP_RTC
Bits
Field Name
Description
Type
Reset
7
RTC_V_OPT
RTC date/time register selection:
0: Read access directly to dynamic registers (SECONDS_REG,
MINUTES_REG, HOURS_REG, DAYS_REG, MONTHS_REG,
YEAR_REG, WEEKS_REG)
1: Read access to static shadowed registers: (see GET_TIME bit).
RW
0
6
GET_TIME
When writing a 1 into this register, the content of the dynamic registers
(SECONDS_REG, MINUTES_REG, HOURS_REG, DAYS_REG,
MONTHS_REG, YEAR_REG and WEEKS_REG) is transferred into
static shadowed registers. Each update of the shadowed registers needs
to be done by re-asserting GET_TIME bit to 1 (that is: reset it to 0 and
then rewrite it to 1)
RW
0
5
SET_32_COUNTER
0: No action
1: set the 32-kHz counter with COMP_REG value.
It must only be used when the RTC is frozen.
RW
0
4
TEST_MODE
0: functional mode
1: test mode (Auto compensation is enable when the 32-kHz counter
reaches at its end)
RW
0
3
MODE_12_24
0: 24 hours mode
1: 12 hours mode (PM-AM mode)
It is possible to switch between the two modes at any time without
disturbed the RTC, read or write are always performed with the current
mode.
RW
0
2
AUTO_COMP
0: No auto compensation
1: Auto compensation enabled
RW
0
1
ROUND_30S
0: No update
1: When a one is written, the time is rounded to the nearest minute.
This bit is a toggle bit, the microcontroller can only write one and RTC
clears it. If the microcontroller sets the ROUND_30S bit and then reads
it, the microcontroller will read one until rounded to the nearest value.
RW
0
0
STOP_RTC
0: RTC is frozen
1: RTC is running
RW
0
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Table 6-21. RTC_STATUS_REG
Address Offset
0x11
Instance
Reset Domain: FULL RESET
Description
RTC status register:
NOTES: A dummy read of this register is necessary before each I2C read in order to update the status register
value.
Type
RW
7
POWER_UP
74
6
ALARM
5
EVENT_1D
Bits
Field Name
Description
7
POWER_UP
6
4
EVENT_1H
3
EVENT_1M
2
EVENT_1S
1
RUN
0
Reserved
Type
Reset
Indicates that a reset occurred (bit cleared to 0 by writing 1).
POWER_UP is set by a reset, is cleared by writing one in this bit.
RW
1
ALARM
Indicates that an alarm interrupt has been generated (bit clear by writing
1).
The alarm interrupt keeps its low level, until the microcontroller write 1 in
the ALARM bit of the RTC_STATUS_REG register.
The timer interrupt is a low-level pulse (15 µs duration).
RW
0
5
EVENT_1D
One day has occurred
RO
0
4
EVENT_1H
One hour has occurred
RO
0
3
EVENT_1M
One minute has occurred
RO
0
2
EVENT_1S
One second has occurred
RO
0
1
RUN
0: RTC is frozen
1: RTC is running
This bit shows the real state of the RTC, indeed because of STOP_RTC
signal was resynchronized on 32-kHz clock, the action of this bit is
delayed.
RO
0
0
Reserved
Reserved bit
RO
R returns
0s
0
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Table 6-22. RTC_INTERRUPTS_REG
Address Offset
0x12
Instance
Reset Domain: FULL RESET
Description
RTC interrupt control register
Type
RW
7
6
5
4
IT_SLEEP_
MASK_EN
Reserved
3
2
IT_ALARM
IT_TIMER
1
0
EVERY
Bits
Field Name
Description
Type
Reset
7:5
Reserved
Reserved bit
RO
R returns
0s
0x0
4
IT_SLEEP_MASK_E
N
1: Mask periodic interrupt while the TPS65911 device is in SLEEP mode.
Interrupt event is back up in a register and occurred as soon as the
TPS65911 device is no more in SLEEP mode.
0: Normal mode, no interrupt masked
RW
0
3
IT_ALARM
Enable one interrupt when the alarm value is reached (TC ALARM
registers) by the TC registers
RW
0
2
IT_TIMER
Enable periodic interrupt
0: interrupt disabled
1: interrupt enabled
RW
0
EVERY
Interrupt period
00: each second
01: each minute
10: each hour
11: each day
RW
0x0
1:0
Table 6-23. RTC_COMP_LSB_REG
Address Offset
0x13
Instance
Reset Domain: FULL RESET
Description
RTC compensation register (LSB)
Notes: This register must be written in 2-complement.
This means that to add one 32-kHz oscillator period each hour, microcontroller needs to write FFFF into
RTC_COMP_MSB_REG and RTC_COMP_LSB_REG.
To remove one 32-kHz oscillator period each hour, microcontroller needs to write 0001 into
RTC_COMP_MSB_REG and RTC_COMP_LSB_REG.
The 7FFF value is forbidden.
Type
RW
7
6
5
4
3
RTC_COMP_LSB
2
Bits
Field Name
Description
7:0
RTC_COMP_LSB
This register contains the number of 32-kHz periods to be added into the
32-kHz counter each hour [LSB]
1
0
Type
Reset
RW
0x00
Detailed Description
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Table 6-24. RTC_COMP_MSB_REG
Address Offset
0x14
Instance
Reset Domain: FULL RESET
Description
RTC compensation register (MSB)
Notes: See RTC_COMP_LSB_REG Notes.
Type
RW
7
6
5
4
3
RTC_COMP_MSB
2
Bits
Field Name
Description
7:0
RTC_COMP_MSB
This register contains the number of 32-kHz periods to be added into the
32-kHz counter each hour [MSB]
1
0
Type
Reset
RW
0x00
Table 6-25. RTC_RES_PROG_REG
Address Offset
0x15
Instance
Reset Domain: FULL RESET
Description
RTC register containing oscillator resistance value
Type
RW
7
6
5
4
Reserved
3
2
SW_RES_PROG
1
0
Bits
Field Name
Description
Type
Reset
7:6
Reserved
Reserved bit
RO
R returns
0s
0x0
5:0
SW_RES_PROG
Value of the oscillator resistance
RW
0x27
Table 6-26. RTC_RESET_STATUS_REG
Address Offset
0x16
Instance
Reset Domain: FULL RESET
Description
RTC register for reset status
Type
RW
7
6
5
4
3
2
1
Reserved
Bits
Field Name
Description
Type
Reset
7:1
Reserved
Reserved bit
RO
R returns
0s
0x0
RESET_STATUS
This bit can only be set to one and is cleared when a manual reset or a
POR (VBAT < 2.1) occurs. If this bit is reset it means that the RTC has
lost its configuration.
RW
0
0
76
0
RESET_
STATUS
Detailed Description
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Table 6-27. BCK1_REG
Address Offset
0x17
Instance
Reset Domain: FULL RESET
Description
Backup register which can be used for storage by the application firmware when the external host is powered down.
These registers will retain their content as long as the VRTC is active.
Type
RW
7
6
5
4
3
2
1
0
BCKUP
Bits
Field Name
Description
7:0
BCKUP
Backup bit
Type
Reset
RW
0x00
Table 6-28. BCK2_REG
Address Offset
0x18
Instance
Reset Domain: FULL RESET
Description
Backup register which can be used for storage by the application firmware when the external host is powered down.
These registers will retain their content as long as the VRTC is active.
Type
RW
7
6
5
4
3
2
1
0
BCKUP
Bits
Field Name
Description
7:0
BCKUP
Backup bit
Type
Reset
RW
0x00
Table 6-29. BCK3_REG
Address Offset
0x19
Instance
Reset Domain: FULL RESET
Description
Backup register which can be used for storage by the application firmware when the external host is powered down.
These registers will retain their content as long as the VRTC is active.
Type
RW
7
6
5
4
3
2
1
0
BCKUP
Bits
Field Name
Description
7:0
BCKUP
Backup bit
Type
Reset
RW
0x00
Detailed Description
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Table 6-30. BCK4_REG
Address Offset
0x1A
Instance
Reset Domain: FULL RESET
Description
Backup register which can be used for storage by the application firmware when the external host is powered down.
These registers will retain their content as long as the VRTC is active.
Type
RW
7
6
5
4
3
2
1
0
BCKUP
Bits
Field Name
Description
7:0
BCKUP
Backup bit
Type
Reset
RW
0x00
Table 6-31. BCK5_REG
Address Offset
0x1B
Instance
Reset Domain: FULL RESET
Description
Backup register which can be used for storage by the application firmware when the external host is powered down.
These registers will retain their content as long as the VRTC is active.
Type
RW
7
6
5
4
3
2
1
0
BCKUP
78
Bits
Field Name
Description
7:0
BCKUP
Backup bit
Detailed Description
Type
Reset
RW
0x00
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Table 6-32. PUADEN_REG
Address Offset
0x1C
Instance
Reset Domain: GENERAL RESET
Description
Pullup/pulldown control register.
Type
RW
7
6
5
4
3
2
1
Reserved
I2CCTLP
I2CSRP
PWRONP
SLEEPP
PWRHOLDP
HDRSTP
Bits
Field Name
Type
Reset
RO
0
SDACTL and SCLCTL pullup control:
1: Pullup is enabled
0: Pullup is disabled
RW
0
I2CSRP
SDASR and SCLSR pullup control:
1: Pullup is enabled
0: Pullup is disabled
RW
0
4
PWRONP
PWRON pad pullup control:
1: Pullup is enabled
0: Pullup is disabled
RW
1
3
SLEEPP
SLEEP pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
PWRHOLDP
PWRHOLD pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
1
HDRSTP
HDRST pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
0
NRESPWRON2P
NRESPWRON2 pad control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
7
Reserved
6
I2CCTLP
5
Description
0
NRESPWRON
2P
Table 6-33. REF_REG
Address Offset
0x1D
Instance
Reset Domain: TURNOFF OFF RESET
Description
Reference control register
Type
RO
7
6
5
4
3
2
1
Reserved
0
ST
Bits
Field Name
Description
Type
Reset
7:2
Reserved
Reserved bit
RO
R returns
0s
0x00
1:0
ST
Reference state:
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Reserved
ST[1:0] = 11: On low power (SLEEP)
(Write access available in test mode only)
RO
0x1
Detailed Description
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Table 6-34. VRTC_REG
Address Offset
0x1E
Instance
Reset Domain: GENERAL RESET
Description
VRTC internal regulator control register
Type
RW
7
6
5
Reserved
3
VRTC_
OFFMASK
2
1
Reserved
0
ST
Bits
Field Name
Description
Type
Reset
7:4
Reserved
Reserved bit
RO
R returns
0s
0x0
3
VRTC_OFFMASK
VRTC internal regulator off mask signal:
when 1, the regulator keeps its full-load capability during device OFF
state.
when 0, the regulator will go to low-power mode during device OFF
state.
Note that VRTC is put in low-power mode when the device is on backup
even if this bit is set to 1
(Default value: See boot configuration)
RW
0
2
Reserved
Reserved bit
RO
R returns
0s
0
ST
Reference state:
ST[1:0] = 00: Reserved
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Reserved
ST[1:0] = 11: On low power (SLEEP)
(Write access available in test mode only)
RO
0x1
1:0
80
4
Detailed Description
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Table 6-35. VIO_REG
Address Offset
0x20
Instance
Reset Domain: TURNOFF OFF RESET
Description
VIO control register
Type
RW
7
6
ILMAX
5
4
Reserved
Bits
Field Name
Description
7:6
ILMAX
Select maximum load current:
when 00: 0.6 A
when 01: 1.0 A
when 10: 1.3 A
when 11: 1.3 A
5:4
Reserved
Reserved bit
3:2
SEL
1:0
ST
3
2
1
SEL
0
ST
Type
Reset
RW
0x0
RO
R returns
0s
0x0
Output voltage selection (EEPROM bits):
SEL[1:0] = 00: 1.5 V
SEL[1:0] = 01: 1.8 V
SEL[1:0] = 10: 2.5 V
SEL[1:0] = 11: 3.3 V
(Default value: See boot configuration)
RW
0x0
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Detailed Description
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Table 6-36. VDD1_REG
Address Offset
0x21
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD1 control register
Type
RW
7
6
VGAIN_SEL
82
5
ILMAX
4
3
TSTEP
2
1
0
ST
Bits
Field Name
Description
Type
Reset
7:6
VGAIN_SEL
Select output voltage multiplication factor: G (EEPROM bits):
when 00: ×1
when 01: ×1
when 10: ×2
when 11: ×3
(Default value: See boot configuration)
RW
0x0
5
ILMAX
Select maximum load current:
when 0: 1.0 A
when 1: > 1.5 A
RW
0
4:2
TSTEP
Time step: when changing the output voltage, the new value is reached
through successive 12.5-mV voltage steps (if not bypassed). The
equivalent programmable slew rate of the output voltage is then:
TSTEP[2:0] = 000: step duration is 0, step function is bypassed
TSTEP[2:0] = 001: 12.5 mV/µs (sampling 3 MHz)
TSTEP[2:0] = 010: 9.4 mV/µs (sampling 3 MHz × 3/4)
TSTEP[2:0] = 011: 7.5 mV/µs (sampling 3 MHz × 3/5) (default)
TSTEP[2:0] = 100: 6.25 mV/µs(sampling 3 MHz/2)
TSTEP[2:0] = 101: 4.7 mV/µs(sampling 3 MHz/3)
TSTEP[2:0] = 110: 3.12 mV/µs(sampling 3 MHz/4)
TSTEP[2:0] = 111: 2.5 mV/µs(sampling 3 MHz/5)
RW
0x3
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On, high-power mode
ST[1:0] = 10: Off
ST[1:0] = 11: On, low-power mode
RW
0x0
Detailed Description
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Table 6-37. VDD1_OP_REG
Address Offset
0x22
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD1 voltage selection register.
This register can be accessed by both control and voltage scaling I2C interfaces depending on SR_CTL_I2C_SEL
register bit value.
Type
RW
7
CMD
Bits
6
5
Field Name
Description
7
CMD
6:0
SEL
4
3
SEL
2
1
0
Type
Reset
when 0: VDD1_OP_REG voltage is applied
when 1: VDD1_SR_REG voltage is applied
RW
0
Output voltage (4 EEPROM bits) selection with GAIN_SEL = 00 (G = 1,
12.5 mV per LSB):
SEL[6:0] = 1001011 to 1111111: 1.5 V
...
SEL[6:0] = 0111111: 1.35 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0000001 to 0000011: 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 75 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V) × G
(Default value: See boot configuration)
Note: Vout maximum value is 3.3 V
RW
0x00
Table 6-38. VDD1_SR_REG
Address Offset
0x23
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD1 voltage selection register.
This register can be accessed by both control and voltage scaling dedicated I2C interfaces depending on
SR_CTL_I2C_SEL register bit value.
Type
RW
7
Reserved
Bits
7
6:0
6
5
4
3
SEL
2
1
0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
SEL
Output voltage selection with GAIN_SEL = 00 (G = 1, 12.5 mV per LSB):
SEL[6:0] = 1001011 to 1111111: 1.5 V
...
SEL[6:0] = 0111111: 1.35 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0000001 to 0000011: 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 75 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V) × G
(Default value: See boot configuration)
Note: Vout maximum value is 3.3 V
RW
0x00
Detailed Description
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Table 6-39. VDD2_REG
Address Offset
0x24
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD2 control register
Type
RW
7
6
VGAIN_SEL
84
5
ILMAX
4
3
TSTEP
2
1
0
ST
Bits
Field Name
Description
Type
Reset
7:6
VGAIN_SEL
Select output voltage multiplication factor (×1, ×3 included in EEPROM
bits): G
when 00: ×1
when 01: ×1
when 10: ×2
when 11: ×3
RW
0x0
5
ILMAX
Select maximum load current:
when 0: 1.0 A
when 1: > 1.5 A
RW
0
4:2
TSTEP
Time step: when changing the output voltage, the new value is reached
through successive 12.5-mV voltage steps (if not bypassed). The
equivalent programmable slew rate of the output voltage is then:
TSTEP[2:0] = 000: step duration is 0, step function is bypassed
TSTEP[2:0] = 001: 12.5 mV/µs (sampling 3 MHz)
TSTEP[2:0] = 010: 9.4 mV/µs (sampling 3 MHz × 3/4)
TSTEP[2:0] = 011: 7.5 mV/µs (sampling 3 MHz × 3/5) (default)
TSTEP[2:0] = 100: 6.25 mV/µs(sampling 3 MHz/2)
TSTEP[2:0] = 101: 4.7 mV/µs(sampling 3 MHz/3)
TSTEP[2:0] = 110: 3.12 mV/µs(sampling 3 MHz/4)
TSTEP[2:0] = 111: 2.5 mV/µs(sampling 3 MHz/5)
RW
0x1
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On, high-power mode
ST[1:0] = 10: Off
ST[1:0] = 11: On, low-power mode
RW
0x0
Detailed Description
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Table 6-40. VDD2_OP_REG
Address Offset
0x25
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD2 voltage selection register.
This register can be accessed by both control and voltage scaling dedicated I2C interfaces depending on
SR_CTL_I2C_SEL register bit value.
Type
RW
7
CMD
Bits
6
5
Field Name
Description
7
CMD
6:0
SEL
4
3
SEL
2
1
0
Type
Reset
Command:
when 0: VDD2_OP_REG voltage is applied
when 1: VDD2_SR_REG voltage is applied
RW
0
Output voltage (4 EEPROM bits) selection with GAIN_SEL = 00 (G = 1,
12.5 mV per LSB):
SEL[6:0] = 1001011 to 1111111: 1.5 V
...
SEL[6:0] = 0111111: 1.35 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0000001 to 0000011: 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 75 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V) × G
Note: Vout maximum value is 3.3 V
RW
0x00
Table 6-41. VDD2_SR_REG
Address Offset
0x26
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDD2 voltage selection register.
This register can be accessed by both control and voltage scaling dedicated I2C interfaces depending on
SR_CTL_I2C_SEL register bit value.
Type
RW
7
Reserved
Bits
7
6:0
6
5
4
3
SEL
2
1
0
Field Name
Description
Type
Reset
Reserved
Reserved bit
RO
R returns
0s
0
SEL
Output voltage (EEPROM bits) selection with GAIN_SEL = 00 (G = 1,
12.5 mV per LSB):
SEL[6:0] = 1001011 to 1111111: 1.5 V
...
SEL[6:0] = 0111111: 1.35 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0000001 to 0000011: 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 75 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V) × G
Note: Vout maximum value is 3.3 V
RW
0x00
Detailed Description
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Table 6-42. VDDCRTL_REG
Address Offset
0x27
Instance
Reset Domain: TURNOFF OFF RESET
Description
VDDCtrl, external FET controller
Type
RW
7
6
5
4
3
2
1
Reserved
0
ST
Bits
Field Name
Description
Type
Reset
7:2
Reserved
Reserved bit
RO
R returns
0s
0x00
1:0
ST
Supply state (EEPROM dependent):
ST[1:0] = 00: Off
ST[1:0] = 01: On
ST[1:0] = 10: Off
ST[1:0] = 11: On
RW
0x0
Table 6-43. VDDCRTL_OP_REG
Address Offset
0x28
Instance
Reset Domain: TURN OFF RESET
Description
VDDCtrl voltage selection register.
This register can be accessed by both control and voltage scaling dedicated I2C interfaces depending on
SR_CTL_I2C_SEL register bit value.
Type
RW
7
CMD
Bits
86
6
5
4
3
SEL
2
1
0
Field Name
Description
Type
Reset
7
CMD
Command:
when 0: VDDctrl_OP_REG voltage is applied
when 1: VDDctrl_SR_REG voltage is applied
RW
0
6:0
SEL
Output voltage (4 EEPROM bits) selection:
SEL[6:0] = 1000011 to 1111111: 1.4 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0010011: 0.8 V
...
SEL[6:0] = 0000001: 0000011 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 64 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V)
(Default value: See boot configuration)
RW
0x00
Detailed Description
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Table 6-44. VDDCRTL_SR_REG
Address Offset
0x29
Instance
Reset Domain: TURN OFF RESET
Description
VDDCtrl voltage selection register.
This register can be accessed by both control and voltage scaling dedicated I2C interfaces depending on
SR_CTL_I2C_SEL register bit value.
Type
RW
7
Reserved
Bits
6
Field Name
7
5
4
3
SEL
2
Description
SEL
0
Type
Reserved
6:0
1
Output voltage (4 EEPROM bits) selection:
SEL[6:0] = 1000011 to 1111111: 1.4 V
...
SEL[6:0] = 0110011: 1.2 V
...
SEL[6:0] = 0010011: 0.8 V
...
SEL[6:0] = 0000001: 0000011: 0.6 V
SEL[6:0] = 0000000: Off (0.0 V)
Note: from SEL[6:0] = 3 to 64 (dec)
Vout = (SEL[6:0] × 12.5 mV + 0.5625 V)
(Default value: See boot configuration)
Reset
RO
0
RW
0x03
Table 6-45. LDO1_REG
Address Offset
0x30
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO1 regulator control register
Type
RW
7
6
5
4
3
2
1
SEL
Bits
Field Name
Description
7:2
SEL
Supply voltage (EEPROM bits):
0
ST
Type
Reset
RW
0x0
RW
0x0
SEL[7:2] = 000000 to 000011: 1 V
SEL[7:2] = 000100: 1 V
SEL[7:2] = 000101: 1.05 V
...
SEL[7:2] = 110001: 3.25 V
SEL[7:2] = 110010: 3.3 V
(Default value: See boot configuration)
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
Detailed Description
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Table 6-46. LDO2_REG
Address Offset
0x31
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO2 regulator control register
Type
RW
7
6
5
4
3
2
1
SEL
0
ST
Bits
Field Name
Description
Type
Reset
7:2
SEL
Supply voltage (EEPROM bits):
SEL[7:2] = 000000 to 000011: 1 V
SEL[7:2] = 000100: 1 V
SEL[7:2] = 000101: 1.05 V
...
SEL[7:2] = 110001: 3.25 V
SEL[7:2] = 110010: 3.3 V
(Default value: See boot configuration)
RW
0x0
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Table 6-47. LDO5_REG
Address Offset
0x32
Instance
Reset Domain: TUROFF RESET
Description
LDO5 regulator control register
Type
RW
7
Reserved
Bits
7
88
6
Field Name
5
4
SEL
3
Description
Reserved
2
1
0
ST
Type
Reset
RO
R returns
0s
0
6:2
SEL
Supply voltage (EEPROM bits):
SEL[6:2] = 00000 to 00010: 1 V
SEL[6:2] = 00011: 1.1 V
...
SEL[6:2] = 11000: 3.2 V
SEL[6:2] = 11001: 3.3 V
(Default value: See boot configuration)
RW
0x00
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Detailed Description
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Table 6-48. LDO8_REG
Address Offset
0x33
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO8 regulator control register
Type
RW
7
Reserved
Bits
7
6
Field Name
5
4
SEL
3
2
1
0
ST
Description
Reserved
Type
Reset
RO
R returns
0s
0
6:2
SEL
Supply voltage (EEPROM bits):
SEL[6:2] = 00000 to 00010: 1 V
SEL[6:2] = 00011: 1.1 V
...
SEL[6:2] = 11000: 3.2 V
SEL[6:2] = 11001: 3.3 V
(Default value: See boot configuration)
RW
0x00
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Table 6-49. LDO7_REG
Address Offset
0x34
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO7 regulator control register
Type
RW
7
Reserved
Bits
7
Field Name
6
5
4
SEL
3
Description
Reserved
2
1
0
ST
Type
Reset
RO
R returns
0s
0
6:2
SEL
Supply voltage (EEPROM bits):
SEL[6:2] = 00000 to 00010: 1 V
SEL[6:2] = 00011: 1.1 V
...
SEL[6:2] = 11000: 3.2 V
SEL[6:2] = 11001: 3.3 V
(Default value: See boot configuration)
RW
0x00
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Detailed Description
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Table 6-50. LDO6_REG
Address Offset
0x35
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO6 regulator control register
Type
RW
7
Reserved
Bits
6
Field Name
7
5
4
SEL
3
2
1
0
ST
Description
Reserved
Type
Reset
RO
R returns
0s
0
6:2
SEL
Supply voltage (EEPROM bits):
SEL[6:2] = 00000 to 00010: 1 V
SEL[6:2] = 00011: 1.1 V
...
SEL[6:2] = 11000: 3.2 V
SEL[6:2] = 11001: 3.3 V
(Default value: See boot configuration)
RW
0x00
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Table 6-51. LDO4_REG
Address Offset
0x36
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO4 regulator control register
Type
RW
7
6
5
4
3
2
1
SEL
Bits
Field Name
Description
7:2
SEL
Supply voltage (EEPROM bits):
0
ST
Type
Reset
RW
0x00
RW
0x0
SEL[7:2] = 000000: 0.8 V
SEL[7:2] = 000001: 0.85 V
SEL[7:2] = 000010: 0.9 V
SEL[7:2] = 000011: 0.95 V
SEL[7:2] = 000100: 1 V
SEL[7:2] = 000101: 1.05 V
...
SEL[7:2] = 110001: 3.25 V
SEL[7:2] = 110010: 3.3 V
Applicable voltage selection
TRACK LDO 0: 1 V to 3.3 V
TRACK LDO 1: 0.8 V to 1.5 V
(Default value: See boot configuration)
1:0
90
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
Detailed Description
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Table 6-52. LDO3_REG
Address Offset
0x37
Instance
Reset Domain: TURNOFF OFF RESET
Description
LDO3 regulator control register
Type
RW
7
Reserved
Bits
7
Field Name
6
5
4
SEL
3
Description
Reserved
2
1
0
ST
Type
Reset
RO
R returns
0s
0
6:2
SEL
Supply voltage (EEPROM bits):
SEL[6:2] = 00000: 1 V
SEL[6:2] = 00001: 1 V
SEL[6:2] = 00010: 1 V
SEL[6:2] = 00011: 1.1 V
...
SEL[6:2] = 11000: 3.2 V
SEL[6:2] = 11001: 3.3 V
(Default value: See boot configuration)
RW
0x00
1:0
ST
Supply state (EEPROM bits):
ST[1:0] = 00: Off
ST[1:0] = 01: On high power (ACTIVE)
ST[1:0] = 10: Off
ST[1:0] = 11: On low power (SLEEP)
RW
0x0
Detailed Description
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Table 6-53. Therm_REG
Address Offset
0x38
Instance
Reset Domain:
bits[5:2]: GENERAL RESET
bit[0]: TURNOFF OFF RESET
Description
Thermal control register
Type
RW
7
6
Reserved
5
4
THERM_HD
THERM_TS
3
2
1
THERM_HDSEL
Reserved
0
THERM_
STATE
Bits
Field Name
Description
Type
Reset
7:6
Reserved
Reserved bit
RO
R returns
0s
0x0
5
THERM_HD
Hot die detector output:
when 0: the hot die threshold is not reached
when 1: the hot die threshold is reached
RO
0
4
THERM_TS
Thermal shutdown detector output:
when 0: the thermal shutdown threshold is not reached
when 1: the thermal shutdown threshold is reached
RO
0
THERM_HDSEL
Temperature selection for hot die detector:
when 00: Low temperature threshold
…
when 11: High temperature threshold
RW
0x3
RO
R returns
0s
0
RW
1
3:2
1
Reserved
0
THERM_STATE
Thermal shutdown module enable signal:
when 0: thermal shutdown module is disable
when 1: thermal shutdown module is enable
Table 6-54. BBCH_REG
Address Offset
0x39
Instance
Reset Domain: GENERAL RESET
Description
Backup battery charger control register
Type
RW
7
5
Reserved
4
3
2
1
BBSEL
0
BBCHEN
Bits
Field Name
Description
Type
Reset
7:3
Reserved
Reserved bit
RO
R returns
0s
0x00
2:1
BBSEL
Back up battery charge voltage selection:
BBSEL[1:0] = 00: 3.0 V
BBSEL[1:0] = 01: 2.52 V
BBSEL[1:0] = 10: 3.15 V
BBSEL[1:0] = 11: VBAT
RW
0x0
BBCHEN
Back up battery charge enable
RW
0
0
92
6
Detailed Description
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Table 6-55. DCDCCTRL_REG
Address Offset
0x3E
Instance
RESET DOMAIN:
bits [7:3]: TURNOFF OFF RESET
bits [2:0]: GENERAL RESET
Description
DCDC control register
Type
RW
7
Reserved
Bits
6
TRACK
5
VDD2_PSKIP
4
VDD1_PSKIP
3
VIO_PSKIP
2
DCDCCKEXT
1
0
DCDCCKSYNC
Field Name
Description
Type
Reset
7
Reserved
Reserved bit
RO
R returns
0s
0
6
TRACK
0 = Normal LDO operation without tracking
1 = Tracking mode: LDO4 output follows VDD1 setting when VDD1
active. See Section 6.5.3.14 for more information.
RW
0
5
VDD2_PSKIP
VDD2 pulse skip mode enable (EEPROM bit)
Default value: See boot configuration
RW
1
4
VDD1_PSKIP
VDD1 pulse skip mode enable (EEPROM bit)
Default value: See boot configuration
RW
1
3
VIO_PSKIP
VIO pulse skip mode enable (EEPROM bit)
Default value: See boot configuration
RW
1
2
DCDCCKEXT
This signal control the muxing of the GPIO2 pad:
When 0: this pad is a GPIO
When 1: this pad is used as input for an external clock used for the
synchronisation of the DCDCs
RW
0
DCDCCKSYNC
DCDC clock configuration:
DCDCCKSYNC[1:0] = 00: no synchronization of DCDC clocks
DCDCCKSYNC[1:0] = 01: DCDC synchronous clock with phase shift
DCDCCKSYNC[1:0] = 10: no synchronization of DCDC clocks
DCDCCKSYNC[1:0] = 11: DCDC synchronous clock
RW
0x1
1:0
Detailed Description
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Table 6-56. DEVCTRL_REG
Address Offset
0x3F
Instance
Reset Domain: GENERAL RESET
Bit 0,1, and 3: TURN OFF RESET
Description
Device control register
Type
RW
7
PWR_OFF_
SEQ
Bits
94
6
5
RTC_PWDN
CK32K_CTRL
Field Name
Description
7
PWR_OFF_SEQ
6
4
SR_CTL_I2C_
SEL
3
DEV_OFF_
RST
2
1
0
DEV_ON
DEV_SLP
DEV_OFF
Type
Reset
When 1, power-off will be sequential, reverse of power-on sequence (first
resource to power on will be the last to power off).
When 0, all resources disabled at the same time
RW
0
RTC_PWDN
When 1, disable the RTC digital domain (clock gating and reset of RTC
registers and logic).
This register bit is not reset in BACKUP state.
RW
0
5
CK32K_CTRL
Internal 32-kHz clock source control bit (EEPROM bit):
when 0, the internal 32-kHz clock source is the crystal oscillator or an
external 32-kHz clock in case the crystal oscillator is used in bypass
mode
when 1, the internal 32-kHz clock source is the RC oscillator.
RW
0
4
SR_CTL_I2C_SEL
Voltage scaling registers access control bit:
when 0: access to registers by voltage scaling I2C
when 1: access to registers by control I2C. The voltage scaling registers
are: VDD1_OP_REG, VDD1_SR_REG, VDD2_OP_REG,
VDD2_SR_REG, VDDCtrl_OP_REG, and VDDCtrl_SR_REG.
RW
1
3
DEV_OFF_RST
Write 1 will start an ACTIVE-to-OFF or SLEEP-to-OFF device state
transition (switch-off event) and activate reset of the digital core.
This bit is cleared in OFF state.
RW
0
2
DEV_ON
Write 1 will keep the device on (ACTIVE or SLEEP device state) (if
DEV_OFF = 0 and DEV_OFF_RST = 0).
EEPROM bit
(Default value: See boot configuration)
RW
0
1
DEV_SLP
Write 1 allows SLEEP device state (if DEV_OFF = 0 and
DEV_OFF_RST = 0).
Write 0 will start an SLEEP-to-ACTIVE device state transition (wake-up
event) (if DEV_OFF = 0 and DEV_OFF_RST = 0). This bit is cleared in
OFF state.
RW
0
0
DEV_OFF
Write 1 will start an ACTIVE-to-OFF or SLEEP-to-OFF device state
transition (switch-off event). This bit is cleared in OFF state.
RW
0
Detailed Description
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Table 6-57. DEVCTRL2_REG
Address Offset
0x40
Instance
Reset Domain: GENERAL RESET
TSLOT_LENGTH: TURN OFF RESET
Description
Device control register
Type
RW
7
Reserved
Bits
6
DCDC_SLEEP
_LVL
Field Name
5
4
TSLOT_LENGTH
3
SLEEPSIG_
POL
2
PWON_LP_
OFF
Description
1
PWON_LP_
RST
0
IT_POL
Type
Reset
RO
R returns
0s
0
7
Reserved
6
DCDC_SLEEP_LVL
When 1, DCDC output level in SLEEP mode is VDDx_SR_REG, to be
other than 0 V.
When 0, no effect
RW
0
5:4
TSLOT_LENGTH
Time slot duration programming (EEPROM bit):
When 00: 0 µs
When 01: 200 µs
When 10: 500 µs
When 11: 2 ms
(Default value: See boot configuration)
RW
0x3
3
SLEEPSIG_POL
When 1, SLEEP signal active-high
When 0, SLEEP signal active-low
RW
0
2
PWON_LP_OFF
When 1, allows device turnoff after a PWON Long Press (signal low)
(EEPROM bits).
(Default value: See boot configuration)
RW
1
1
PWON_LP_RST
When 1, allows digital core reset when the device is OFF (EEPROM bit).
(Default value: See boot configuration)
RW
0
0
IT_POL
INT1 interrupt pad polarity control signal (EEPROM bit):
When 0, active low
When 1, active high
(Default value: See boot configuration)
RW
0
Detailed Description
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Table 6-58. SLEEP_KEEP_LDO_ON_REG
Address Offset
0x41
Instance
Reset Domain: GENERAL RESET
Description
When corresponding control bit = 0 in EN1_ LDO_ASS register (default setting): Configuration Register keeping the
full load capability of LDO regulator (ACTIVE mode) during the SLEEP state of the device.
When control bit = 1, LDO regulator full load capability (ACTIVE mode) is maintained during device SLEEP state.
When control bit = 0, the LDO regulator is set or stay in low-power mode during device SLEEP state(but then
supply state can be overwritten programming ST[1:0]). Control bit value has no effect if the LDO regulator is off.
When corresponding control bit = 1 in EN1_ LDO_ASS register: Configuration Register setting the LDO regulator
state driven by SCLSR_EN1 signal low level (when SCLSR_EN1 is high the regulator is on, full power):
- the regulator is set off if its corresponding Control bit = 0 in SLEEP_KEEP_LDO_ON register (default)
- the regulator is set in low-power mode if its corresponding control bit = 1 in SLEEP_KEEP_LDO_ON register
Type
RW
7
LDO3_
KEEPON
Bits
96
6
LDO4_
KEEPON
5
LDO7_KEEPO
N
4
LDO8_
KEEPON
3
LDO5_KEEPO
N
2
LDO2_
KEEPON
1
LDO1_
KEEPON
0
LDO6_
KEEPON
Field Name
Description
Type
Reset
7
LDO3_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
6
LDO4_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
5
LDO7_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
4
LDO8_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
3
LDO5_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
2
LDO2_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
1
LDO1_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
0
LDO6_KEEPON
Setting supply state during device SLEEP state or when SCLSR_EN1 is
low
RW
0
Detailed Description
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Table 6-59. SLEEP_KEEP_RES_ON_REG
Address Offset
0x42
Instance
Description
Configuration Register keeping, during the SLEEP state of the device (but then supply state can be overwritten
programming ST[1:0]):
- the full load capability of LDO regulator (ACTIVE mode),
- The PWM mode of DCDC converter
- 32-kHz clock output
- Register access though I2C interface (keeping the internal high speed clock on)
- Die Thermal monitoring on
Control bit value has no effect if the resource is off.
Type
RW
7
THERM_
KEEPON
Bits
6
CLKOUT32K_
KEEPON
5
VRTC_
KEEPON
4
I2CHS_
KEEPON
3
Reserved
2
VDD2_
KEEPON
Field Name
Description
7
THERM_KEEPON
When 1, thermal monitoring is maintained during device SLEEP state.
When 0, thermal monitoring is turned off during device SLEEP state.
6
1
VDD1_
KEEPON
0
VIO_
KEEPON
Type
Reset
RW
0
CLKOUT32K_KEEPO When 1, CLK32KOUT output is maintained during device SLEEP state.
N
When 0, CLK32KOUT output is set low during device SLEEP state.
RW
0
5
VRTC_KEEPON
When 1, LDO regulator full load capability (ACTIVE mode) is maintained
during device SLEEP state.
When 0, the LDO regulator is set or stays in low-power mode during
device SLEEP state.
RW
0
4
I2CHS_KEEPON
When 1, high speed internal clock is maintained during device SLEEP
state.
When 0, high speed internal clock is turned off during device SLEEP
state.
RW
0
3
Reserved
RO
0
2
VDD2_KEEPON
When 1, VDD2 SMPS PWM mode is maintained during device SLEEP
state. No effect if VDD2 working mode is PFM.
When 0, VDD2 SMPS PFM mode is set during device SLEEP state.
RW
0
1
VDD1_KEEPON
When 1, VDD1 SMPS PWM mode is maintained during device SLEEP
state. No effect if VDD1 working mode is PFM.
When 0, VDD1 SMPS PFM mode is set during device SLEEP state.
RW
0
0
VIO_KEEPON
When 1, VIO SMPS PWM mode is maintained during device SLEEP
state. No effect if VIO working mode is PFM.
When 0, VIO SMPS PFM mode is set during device SLEEP state.
RW
0
Detailed Description
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Table 6-60. SLEEP_SET_LDO_OFF_REG
Address Offset
0x43
Instance
Reset Domain: GENERAL RESET
Description
Configuration Register turning-off LDO regulator during the SLEEP state of the device.
Corresponding *_KEEP_ON control bit in SLEEP_KEEP_RES_ON register should be 0 to make this *_SET_OFF
control bit effective
Type
RW
7
6
5
4
3
2
1
0
LDO3_SETOFF LDO4_SETOFF LDO7_SETOFF LDO8_SETOFF LDO5_SETOFF LDO2_SETOFF LDO1_SETOFF LDO6_SETOFF
Bits
98
Field Name
Description
Type
Reset
7
LDO3_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
6
LDO4_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
5
LDO7_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
4
LDO8_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
3
LDO5_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
2
LDO2_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
1
LDO1_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
0
LDO6_SETOFF
When 1, LDO regulator is turned off during device SLEEP state.
When 0, No effect
RW
0
Detailed Description
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Table 6-61. SLEEP_SET_RES_OFF_REG
Address Offset
0x44
Instance
Reset Domain: GENERAL RESET
Description
Configuration Register turning-off SMPS regulator during the SLEEP state of the device.
Corresponding *_KEEP_ON control bit in SLEEP_KEEP_RES_ON2 register should be 0 to make this *_SET_OFF
control bit effective. Supplies voltage expected after their wake-up (SLEEP-to-ACTIVE state transition) can also be
programmed.
Type
RW
7
DEFAULT_
VOLT
Bits
7
6:5
6
5
Reserved
4
SPARE_
SETOFF
3
VDDCTRL_
SETOFF
2
VDD2_
SETOFF
Field Name
Description
DEFAULT_VOLT
When 1, default voltages (register value after switch-on) will be applied
to all resources during SLEEP-to-ACTIVE transition.
When 0, voltages programmed before the ACTIVE-to-SLEEP state
transition will be used to turned-on supplies during SLEEP-to-ACTIVE
state transition.
Reserved
1
VDD1_
SETOFF
0
VIO_
SETOFF
Type
Reset
RW
0
RO
R returns
0s
0x0
4
SPARE_SETOFF
Spare bit
RW
0
3
VDDCTRL_SETOFF
When 1, SMPS is turned off during device SLEEP state.
When 0, No effect.
RW
0
2
VDD2_SETOFF
When 1, SMPS is turned off during device SLEEP state.
When 0, No effect.
RW
0
1
VDD1_SETOFF
When 1, SMPS is turned off during device SLEEP state.
When 0, No effect.
RW
0
0
VIO_SETOFF
When 1, SMPS is turned off during device SLEEP state.
When 0, No effect.
RW
0
Detailed Description
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Table 6-62. EN1_LDO_ASS_REG
Address Offset
0x45
Instance
Reset Domain: TURNOFF RESET
Description
Configuration Register setting the LDO regulators, driven by the multiplexed SCLSR_EN1 signal.
When control bit = 1, LDO regulator state is driven by the SCLSR_EN1 control signal and is also defined though
SLEEP_KEEP_LDO_ON register setting:
When SCLSR_EN1 is high the regulator is on,
When SCLSR_EN1 is low:
- the regulator is off if its corresponding Control bit = 0 in SLEEP_KEEP_LDO_ON register
- the regulator is working in low-power mode if its corresponding control bit = 1 in
SLEEP_KEEP_LDO_ON register
When control bit = 0 no effect: LDO regulator state is driven though registers programming and the device state
Any control bit of this register set to 1 will disable the I2C SR Interface functionality
Type
RW
7
LDO3_EN1
6
LDO4_EN1
5
LDO7_EN1
4
LDO8_EN1
3
LDO5_EN1
2
LDO2_EN1
1
LDO1_EN1
0
LDO6_EN1
Bits
Field Name
Description
Type
Reset
7
LDO3_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
6
LDO4_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
5
LDO7_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
4
LDO8_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
3
LDO5_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
2
LDO2_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
1
LDO1_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
0
LDO6_EN1
Setting supply state control though SCLSR_EN1 signal
RW
0
100
Detailed Description
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Table 6-63. EN1_SMPS_ASS_REG
Address Offset
0x46
Instance
Reset Domain: TURNOFF RESET
Description
Configuration Register setting the SMPS Supplies driven by the multiplexed SCLSR_EN1 signal.
When control bit = 1, SMPS Supply state and voltage is driven by the SCLSR_EN1 control signal and is also
defined though SLEEP_KEEP_RES_ON register setting.
When control bit = 0 no effect: SMPS Supply state is driven though registers programming and the device state.
Any control bit of this register set to 1 will disable the I2C SR Interface functionality
Type
RW
7
6
5
Reserved
Bits
Field Name
7:5
Reserved
4
SPARE_EN1
3
VDDCTRL_
EN1
2
1
0
VDD2_EN1
VDD1_EN1
VIO_EN1
Description
Type
Reset
RO
R returns
0s
0x0
4
SPARE_EN1
Spare bit
RW
0
3
VDDCTRL_EN1
When control bit = 1:
When EN1 is high the supply voltage is programmed though
VDDCtrl_OP_REG register, and it can also be programmed off.
When EN1 is low the supply voltage is programmed though
VDDCtrl_SR_REG register, and it can also be programmed off.
When control bit = 0: No effect: Supply state is driven though registers
programming and the device state
RW
0
2
VDD2_EN1
When control bit = 1:
When SCLSR_EN1 is high the supply voltage is programmed though
VDD2_OP_REG register, and it can also be programmed off.
When SCLSR_EN1 is low the supply voltage is programmed though
VDD2_SR_REG register, and it can also be programmed off.
When SCLSR_EN1 is low and SLEEP_KEEP_RES_ON = 1 the SMPS is
working in low-power mode, if not tuned off through VDD2_SR_REG
register.
When control bit = 0 No effect: Supply state is driven though registers
programming and the device state
RW
0
1
VDD1_EN1
When 1:
When SCLSR_EN1 is high the supply voltage is programmed though
VDD1_OP_REG register, and it can also be programmed off.
When SCLSR_EN1 is low the supply voltage is programmed though
VDD1_SR_REG register, and it can also be programmed off.
When SCLSR_EN1 is low and SLEEP_KEEP_RES_ON = 1 the SMPS is
working in low-power mode, if not tuned off though VDD1_SR_REG
register.
When control bit = 0 no effect: supply state is driven though registers
programming and the device state
RW
0
0
VIO_EN1
When control bit = 1, supply state is driven by the SCLSR_EN1 control
signal and is also defined though SLEEP_KEEP_RES_ON register
setting:
When SCLSR_EN1 is high the supply is on,
When SCLSR_EN1 is low:
- the supply is off (default) or the SMPS is working in low-power mode if
its corresponding control bit = 1 in SLEEP_KEEP_RES_ON register
When control bit = 0 No effect: SMPS state is driven though registers
programming and the device state
RW
0
Detailed Description
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Table 6-64. EN2_LDO_ASS_REG
Address Offset
0x47
Instance
Reset Domain: TURNOFF RESET
Description
Configuration Register setting the LDO regulators, driven by the multiplexed SDASR_EN2 signal.
When control bit = 1, LDO regulator state is driven by the SDASR_EN2 control signal and is also defined though
SLEEP_KEEP_LDO_ON register setting:
When SDASR_EN2 is high the regulator is on,
When SCLSR_EN2 is low:
- the regulator is off if its corresponding Control bit = 0 in SLEEP_KEEP_LDO_ON register
- the regulator is working in low-power mode if its corresponding control bit = 1 in SLEEP_KEEP_LDO_ON register
When control bit = 0 no effect: LDO regulator state is driven though registers programming and the device state
Any control bit of this register set to 1 will disable the I2C SR Interface functionality
Type
RW
7
LDO3_EN2
6
LDO4_EN2
5
LDO7_EN2
4
LDO8_EN2
3
LDO5_EN2
2
LDO2_EN2
1
LDO1_EN2
0
LDO6_EN2
Bits
Field Name
Description
Type
Reset
7
LDO3_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
6
LDO4_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
5
LDO7_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
4
LDO8_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
3
LDO5_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
2
LDO2_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
1
LDO1_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
0
LDO6_EN2
Setting supply state control though SDASR_EN2 signal
RW
0
102
Detailed Description
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Table 6-65. EN2_SMPS_ASS_REG
Address Offset
0x48
Instance
Reset Domain: TURNOFF RESET
Description
Configuration Register setting the SMPS Supplies driven by the multiplexed SDASR_EN2 signal.
When control bit = 1, SMPS Supply state and voltage is driven by the SDASR_EN2 control signal and is also
defined though SLEEP_KEEP_RES_ON register setting.
When control bit = 0 no effect: SMPS Supply state is driven though registers programming and the device state
Any control bit of this register set to 1 will disable the I2C SR Interface functionality
Type
RW
7
6
5
Reserved
Bits
Field Name
7:5
Reserved
4
SPARE_EN2
3
VDDCTRL_
EN2
2
1
0
VDD2_EN2
VDD1_EN2
VIO_EN2
Description
Type
Reset
RO
R returns
0s
0x0
4
SPARE_EN2
Spare bit
RW
0
3
VDDCTRL_EN2
When control bit = 1:
When EN2 is high the supply voltage is programmed though
VDDCtrl_OP_REG register, and it can also be programmed off..
When EN2 is low the supply voltage is programmed though
VDDCtrl_SR_REG register, and it can also be programmed off.
When EN2 is low and VDDCtrl_KEEPON = 1 the SMPS is working in
low-power mode, if not tuned off though VDDCtrl_SR_REG register.
When control bit = 0 no effect: Supply state is driven though registers
programming and the device state
RW
0
2
VDD2_EN2
When control bit = 1:
When SDASR_EN2 is high the supply voltage is programmed though
VDD2_OP_REG register, and it can also be programmed off.
When SDASR_EN2 is low the supply voltage is programmed though
VDD2_SR_REG register, and it can also be programmed off.
When SDASR_EN2 is low and SLEEP_KEEP_RES_ON = 1 the SMPS
is working in low-power mode, if not tuned off though VDD2_SR_REG
register.
When control bit = 0 no effect: Supply state is driven though registers
programming and the device state
RW
0
1
VDD1_EN2
When control bit = 1:
When SDASR_EN2 is high the supply voltage is programmed though
VDD1_OP_REG register, and it can also be programmed off.
When SDASR_EN2 is low the supply voltage is programmed though
VDD1_SR_REG register, and it can also be programmed off.
When SDASR_EN2 is low and SLEEP_KEEP_RES_ON = 1 the SMPS
is working in low-power mode, if not tuned off though VDD1_SR_REG
register.
When control bit = 0 no effect: supply state is driven though registers
programming and the device state
RW
0
0
VIO_EN2
When control bit = 1,
supply state is driven by the SCLSR_EN2 control signal and is also
defined though SLEEP_KEEP_RES_ON register setting:
When SDASR _EN2 is high the supply is on,
When SDASR _EN2 is low :
- the supply is off (default) or the SMPS is working in low-power mode if
its corresponding control bit = 1 in SLEEP_KEEP_RES_ON register
When control bit = 0 no effect: SMPS state is driven though registers
programming and the device state
RW
0
Detailed Description
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Table 6-66. INT_STS_REG
Address Offset
0x50
Instance
Reset Domain: FULL RESET
Description
Interrupt status register:
The interrupt status bit is set to 1 when the associated interrupt event is detected. Interrupt status bit is cleared by
writing 1.
Type
RW
7
RTC_PERIOD_
IT
Bits
104
6
RTC_ALARM_
IT
5
HOTDIE_IT
4
3
PWRHOLD_R_
PWRON_LP_IT
IT
2
1
PWRON_IT
VMBHI_IT
0
PWRHOLD_F_
IT
Field Name
Description
Type
Reset
7
RTC_PERIOD_IT
RTC period event interrupt status.
RW
W1 to Clr
0
6
RTC_ALARM_IT
RTC alarm event interrupt status.
RW
W1 to Clr
0
5
HOTDIE_IT
Hot-die event interrupt status.
RW
W1 to Clr
0
4
PWRHOLD_R_IT
Rising PWRHOLD event interrupt status.
RW
W1 to Clr
0
3
PWRON_LP_IT
PWRON Long Press event interrupt status.
RW
W1 to Clr
0
2
PWRON_IT
PWRON event interrupt status.
RW
W1 to Clr
0
1
VMBHI_IT
VBAT > VMHI event interrupt status
RW
W1 to Clr
0
0
PWRHOLD_F_IT
Falling PWRHOLD event interrupt status.
RW
W1 to Clr
0
Detailed Description
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Table 6-67. INT_MSK_REG
Address Offset
0x51
Instance
Reset Domain: GENERAL RESET
Description
Interrupt mask register:
When *_IT_MSK is set to 1, the associated interrupt is masked: INT1 signal is not activated, but *_IT interrupt
status bit is updated.
When *_IT_MSK is set to 0, the associated interrupt is enabled: INT1 signal is activated, *_IT is updated.
Type
RW
7
RTC_PERIOD_
IT_MSK
Bits
6
RTC_ALARM_
IT_MSK
Field Name
5
HOTDIE_
IT_MSK
4
PWRHOLD_R_
IT_MSK
3
PWRON_LP_
IT_MSK
2
PWRON_
IT_MSK
Description
1
VMBHI_
IT_MSK
0
PWRHOLD_F_
IT_MSK
Type
Reset
7
RTC_PERIOD_IT_MS RTC period event interrupt mask.
K
RW
1
6
RTC_ALARM_IT_MS
K
RTC alarm event interrupt mask.
RW
1
5
HOTDIE_IT_MSK
Hot die event interrupt mask.
RW
1
4
PWRHOLD_R_IT_MS PWRHOLD rising-edge event interrupt mask.
K
RW
1
3
PWRON_LP_IT_MSK PWRON Long Press event interrupt mask.
RW
1
2
PWRON_IT_MSK
PWRON event interrupt mask.
RW
1
1
VMBHI_IT_MSK
VBAT > VMBHI interrupt event mask bit
When 0, interrupt not masked. Device automatically switches on at NO
SUPPLY-to-OFF BACKUP-to-OFF transition
When 1, interrupt is masked. Device does not switch on until a start
reason is received.
(EEPROM bit. Default value: See boot configuration)
RW
1
0
PWRHOLD_F_IT_MS PWRHOLD falling-edge event interrupt mask.
K
RW
1
Detailed Description
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Table 6-68. INT_STS2_REG
Address Offset
0x52
Instance
Reset Domain: FULL RESET
Description
Interrupt status register:
The interrupt status bit is set to 1 when the associated interrupt event is detected. Interrupt status bit is cleared by
writing 1.
Type
RW
7
GPIO3_F_IT
6
GPIO3_R_IT
5
GPIO2_F_IT
Bits
Field Name
Description
7
GPIO3_F_IT
6
4
GPIO2_R_IT
3
GPIO1_F_IT
2
GPIO1_R_IT
1
GPIO0_F_IT
0
GPIO0_R_IT
Type
Reset
GPIO3 falling-edge detection interrupt status
RW
W1 to Clr
0
GPIO3_R_IT
GPIO3 rising-edge detection interrupt status
RW
W1 to Clr
0
5
GPIO2_F_IT
GPIO2 falling-edge detection interrupt status
RW
W1 to Clr
0
4
GPIO2_R_IT
GPIO2 rising-edge detection interrupt status
RW
W1 to Clr
0
3
GPIO1_F_IT
GPIO1 falling-edge detection interrupt status
RW
W1 to Clr
0
2
GPIO1_R_IT
GPIO1 rising-edge detection interrupt status
RW
W1 to Clr
0
1
GPIO0_F_IT
GPIO0 falling-edge detection interrupt status
RW
W1 to Clr
0
0
GPIO0_R_IT
GPIO0 rising-edge detection interrupt status
RW
W1 to Clr
0
Table 6-69. INT_MSK2_REG
Address Offset
0x53
Instance
Reset Domain: GENERAL RESET
Description
Interrupt mask register:
When *_IT_MSK is set to 1, the associated interrupt is masked: INT1 signal is not activated, but *_IT interrupt
status bit is updated.
When *_IT_MSK is set to 0, the associated interrupt is enabled: INT1 signal is activated, *_IT is updated.
Type
RW
7
GPIO3_F_
IT_MSK
Bits
106
6
GPIO3_R_
IT_MSK
5
GPIO2_F_
IT_MSK
4
GPIO2_R_
IT_MSK
3
GPIO1_F_
IT_MSK
2
GPIO1_R_
IT_MSK
1
GPIO0_F_
IT_MSK
0
GPIO0_R_
IT_MSK
Field Name
Description
Type
Reset
7
GPIO3_F_IT_MSK
GPIO3 falling-edge detection interrupt mask.
RW
1
6
GPIO3_R_IT_MSK
GPIO3 rising-edge detection interrupt mask.
RW
1
5
GPIO2_F_IT_MSK
GPIO2 falling-edge detection interrupt mask.
RW
1
4
GPIO2_R_IT_MSK
GPIO2 rising-edge detection interrupt mask.
RW
1
3
GPIO1_F_IT_MSK
GPIO1 falling-edge detection interrupt mask.
RW
1
2
GPIO1_R_IT_MSK
GPIO1 rising-edge detection interrupt mask.
RW
1
1
GPIO0_F_IT_MSK
GPIO0 falling-edge detection interrupt mask.
RW
1
0
GPIO0_R_IT _MSK
GPIO0 rising-edge detection interrupt mask.
RW
1
Detailed Description
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Table 6-70. INT_STS3_REG
Address Offset
0x54
Instance
Reset Domain: FULL RESET
Description
Interrupt status register:
The interrupt status bit is set to 1 when the associated interrupt event is detected. Interrupt status bit is cleared by
writing 1.
Type
RW
7
PWRDN_IT
6
VMBCH2_L_IT
5
VMBCH2_H_IT
Bits
Field Name
Description
7
PWRDN_IT
6
4
WTCHDG_IT
3
GPIO5_F_IT
2
GPIO5_R_IT
1
GPIO4_F_IT
0
GPIO4_R_IT
Type
Reset
PWRDN reset input high detected
RW
W1 to Clr
0
VMBCH2_L_IT
Comparator2 input below threshold detection interrupt status
RW
W1 to Clr
0
5
VMBCH2_H_IT
Comparator2 input above threshold detection interrupt status
RW
W1 to Clr
0
4
WTCHDG_IT
Watchdog interrupt status
RW
W1 to Clr
0
3
GPIO5_F_IT
GPIO5 falling-edge detection interrupt status
RW
W1 to Clr
0
2
GPIO5_R_IT
GPIO5 rising-edge detection interrupt status
RW
W1 to Clr
0
1
GPIO4_F_IT
GPIO4 falling-edge detection interrupt status
RW
W1 to Clr
0
0
GPIO4_R_IT
GPIO4 rising-edge detection interrupt status
RW
W1 to Clr
0
Table 6-71. INT_MSK3_REG
Address Offset
0x55
Instance
Reset Domain: GENERAL RESET
Description
Interrupt mask register:
When *_IT_MSK is set to 1, the associated interrupt is masked: INT1 signal is not activated, but *_IT interrupt
status bit is updated.
When *_IT_MSK is set to 0, the associated interrupt is enabled: INT1 signal is activated, *_IT is updated.
Type
RW
7
PWRDN_
IT_MSK
Bits
6
VMBCH2_L_
IT_MSK
5
VMBCH2_H_
IT_MSK
4
WTCHDG_
IT_MSK
3
GPIO5_F_
IT_MSK
2
GPIO5_R_
IT_MSK
1
GPIO4_F_
IT_MSK
0
GPIO4_R_
IT_MSK
Field Name
Description
Type
Reset
7
PWRDN_IT_MSK
PWRDN interrupt mask
RW
1
6
VMBCH2_L_IT_MSK
Comparator2 input below threshold detection interrupt mask
RW
1
5
VMBCH2_H_IT_MSK
Comparator2 input above threshold detection interrupt mask
RW
1
4
WTCHDG_IT_MSK
Watchdog interrupt mask.
RW
1
3
GPIO5_F_IT_MSK
GPIO5 falling-edge detection interrupt mask.
RW
1
2
GPIO5_R_IT_MSK
GPIO5 rising-edge detection interrupt mask.
RW
1
1
GPIO4_F_IT_MSK
GPIO4 falling-edge detection interrupt mask.
RW
1
0
GPIO4_R_IT_MSK
GPIO4 rising-edge detection interrupt mask.
RW
1
Detailed Description
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Table 6-72. GPIO0_REG
Address Offset
0x60
Instance
Reset Domain: GENERAL RESET
Description
GPIO0 configuration register
Type
RW
7
GPIO_SLEEP
Bits
(1)
108
6
Reserved
5
GPIO_ODEN
4
GPIO_DEB
3
GPIO_PDEN
Field Name
Description
7
GPIO_SLEEP (1)
1: as GPO, force low
0: No impact, keep as in active mode
6
Reserved
Reserved bit
5
GPIO_ODEN
4
2
GPIO_CFG
1
GPIO_STS
0
GPIO_SET
Type
Reset
RW
0
RO
R returns
0s
0
Selection of output mode, EEPROM bit
0: Push-pull output
1: Open-drain output
(Default value: See boot configuration)
GPIO assigned to power-up sequence, this bit will be set to 1 by a
TURNOFF reset
RW
0
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
0
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
(Default value: See boot configuration)
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
GPIO assigned to power-up sequence, this bit will be in TURNOFF reset
RW
0
The GPIO_SLEEP bit is a bit available only for GPIO_0/2/6/7.This bit will be take into account and be effective only if the GPIO_0/2/6/7
is associated to a TIME_SLOT. It means that this bit is useful only if the GPIO is part of the POWER UP SEQUENCE. Note that in this
case the associated GPIO will be set as GPO. GPIO_SLEEP bit is a bit related to the PMU sleep mode only, No action in ACTIVE
mode. It is used to define SLEEP mode state for GPIO 0/2/6/7.
Detailed Description
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Table 6-73. GPIO1_REG
Address Offset
0x61
Instance
Reset Domain: GENERAL RESET
Description
GPIO1 configuration register
Type
RW
7
6
Reserved
Bits
Field Name
7:6
Reserved
5
GPIO_SEL
4
GPIO_DEB
3
GPIO_PDEN
2
GPIO_CFG
Description
1
GPIO_STS
0
GPIO_SET
Type
Reset
RO
R returns
0s
0x0
5
GPIO_SEL
Select signal to be available at GPIO when configured as output:
0: GPIO_SET
1: LED1 out
RW
0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
RW
0
Detailed Description
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Table 6-74. GPIO2_REG
Address Offset
0x62
Instance
Reset Domain: GENERAL RESET
Description
GPIO2 configuration register
Type
RW
7
GPIO_SLEEP
Bits
7
6:5
110
6
5
Reserved
4
GPIO_DEB
Field Name
Description
GPIO_SLEEP
1: as GPO, force low
0: no impact, keep as in active mode
3
GPIO_PDEN
2
GPIO_CFG
Reserved
1
GPIO_STS
0
GPIO_SET
Type
Reset
RW
0
RO
R returns
0s
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
GPIO assigned to power-up sequence, this bit will be set to 0 by a
TURNOFF reset
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
(Default value: See boot configuration)
GPIO assigned to power-up sequence, this bit will be set to 1 by a
TURNOFF reset
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
GPIO assigned to power-up sequence, this bit will be in TURNOFF reset
RW
0
Detailed Description
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Table 6-75. GPIO3_REG
Address Offset
0x63
Instance
Reset Domain: GENERAL RESET
Description
GPIO3 configuration register
Type
RW
7
Reserved
Bits
6
5
GPIO_SEL
Field Name
7
4
GPIO_DEB
3
GPIO_PDEN
2
GPIO_CFG
Description
Reserved
1
GPIO_STS
0
GPIO_SET
Type
Reset
RO
R returns
0s
0
6:5
GPIO_SEL
Select signal to be available at GPIO when configured as output:
00: GPIO_SET
01: LED2 out
10: PWM out
RW
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
RW
0
Table 6-76. GPIO4_REG
Address Offset
0x64
Instance
Reset Domain: GENERAL RESET
Description
GPIO4 configuration register
Type
RW
7
6
Reserved
Bits
Field Name
7:5
Reserved
5
4
GPIO_DEB
3
GPIO_PDEN
2
GPIO_CFG
Description
1
GPIO_STS
0
GPIO_SET
Type
Reset
RO
R returns
0s
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
RW
0
Detailed Description
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Table 6-77. GPIO5_REG
Address Offset
0x65
Instance
Reset Domain: GENERAL RESET
Description
GPIO5 configuration register
Type
RW
7
6
Reserved
Bits
Field Name
7:5
Reserved
112
5
4
GPIO_DEB
3
GPIO_PDEN
2
GPIO_CFG
Description
1
GPIO_STS
0
GPIO_SET
Type
Reset
RO
R returns
0s
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
RW
0
Detailed Description
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Table 6-78. GPIO6_REG
Address Offset
0x66
Instance
Reset Domain: GENERAL RESET
Description
GPIO6 configuration register
Type
RW
7
GPIO_SLEEP
Bits
7
6:5
6
5
Reserved
4
GPIO_DEB
Field Name
Description
GPIO_SLEEP
1: as GPO, force low
0: no impact, keep as in active mode
3
GPIO_PDEN
2
GPIO_CFG
Reserved
1
GPIO_STS
0
GPIO_SET
Type
Reset
RW
0
RO
R returns
0s
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
GPIO assigned to power-up sequence, this bit will be set to 0 by a
TURNOFF reset
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
(Default value: See boot configuration)
GPIO assigned to power-up sequence, this bit will be set to 1 by a
TURNOFF reset
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
GPIO assigned to power-up sequence, this bit will be in TURNOFF reset
RW
0
Detailed Description
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Table 6-79. GPIO7_REG
Address Offset
0x67
Instance
Reset Domain: GENERAL RESET
Description
GPIO7 configuration register
Type
RW
7
GPIO_SLEEP
Bits
7
6:5
114
6
5
Reserved
4
GPIO_DEB
Field Name
Description
GPIO_SLEEP
1: as GPO, force low
0: no impact, keep as in active mode
3
GPIO_PDEN
2
GPIO_CFG
Reserved
1
GPIO_STS
0
GPIO_SET
Type
Reset
RW
0
RO
R returns
0s
0x0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
GPIO assigned to power-up sequence, this bit will be set to 0 by a
TURNOFF reset
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
(Default value: See boot configuration)
GPIO assigned to power-up sequence, this bit will be set to 1 by a
TURNOFF reset
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
GPIO assigned to power-up sequence, this bit will be in TURNOFF reset
RW
0
Detailed Description
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Table 6-80. GPIO8_REG
Address Offset
0x68
Instance
Reset Domain: GENERAL RESET
Description
GPIO8 configuration register
Type
RW
7
6
Reserved
Bits
Field Name
7:6
Reserved
5
GPIO_SEL
4
GPIO_DEB
3
GPIO_PDEN
2
GPIO_CFG
Description
1
GPIO_STS
0
GPIO_SET
Type
Reset
RO
R returns
0s
0x0
5
GPIO_SEL
Select signal to be available at GPIO when configured as output:
0: GPIO_SET
1: PWM out
RW
0
4
GPIO_DEB
GPIO input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
3
GPIO_PDEN
GPIO pad pulldown control:
1: Pulldown is enabled
0: Pulldown is disabled
RW
1
2
GPIO_CFG
Configuration of the GPIO pad direction:
When 0, the pad is configured as an input
When 1, the pad is configured as an output
RW
0
1
GPIO_STS
Status of the GPIO pad
RO
1
0
GPIO_SET
Value set on the GPIO output when configured in output mode
RW
0
Detailed Description
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Table 6-81. WATCHDOG_REG
Address Offset
0x69
Instance
Reset Domain: GENERAL RESET
Description
Watchdog
Type
RW
7
6
5
4
Reserved
Bits
Field Name
7:4
Reserved
3
2:0
3
WTCHDG_
MODE
2
1
0
WTCHDG_TIME
Description
Type
Reset
RO
R returns
0s
0x0
WTCHDG_MODE
0: Periodic operation:
A periodical interrupt is generated based on WTCHDG_TIME setting. IC
will generate WTCHDOG shutdown if interrupt is not cleared during the
period.
1: Interrupt mode:
IC will generate WTCHDOG shutdown if an interrupt is pending (no
cleared) more than WTCHDG_TIME s.
RW
0
WTCHDG_TIME
000: Watchdog disabled
001: 5 seconds
010: 10 seconds
011: 20 Seconds
100: 40 seconds
101: 60 seconds
110: 80 seconds
111: 100 seconds (EEPROM bit)
(Default value: See boot configuration)
RW
0x0
Table 6-82. VMBCH_REG
Address Offset
0x6A
Instance
Reset Domain: GENERAL RESET
Description
Comparator control register
Type
RW
7
6
5
Reserved
Bits
Field Name
7:6
Reserved
5:1
VMBCH_SEL
0
116
4
3
VMBCH_SEL
Description
Battery voltage comparator threshold (EEPROM)
11000 to 11111: 3.5 V
10111: 3.45 V
...
01110: 3 V (default)
...
00101: 2.55 V
00001 to 00100: 2.5 V
00000: Bypass
(Default value: See boot configuration)
Reserved
Detailed Description
2
1
0
Reserved
Type
Reset
RO
R returns
0s
0x0
RW
0x00
RO
R returns
0s
0
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Table 6-83. VMBCH2_REG
Address Offset
0x6B
Instance
Reset Domain: GENERAL RESET
Description
Comparator for detecting battery discharge below threshold level
Type
RW
7
6
5
4
Reserved
3
2
1
VMBDCH2_SEL
Bits
Field Name
7:6
Reserved
Description
5:1
VMBDCH2_SEL
0
VMBDCH2_DEB
0
VMBDCH2_
DEB
Type
Reset
RO
R returns
0s
0x0
Battery voltage comparator threshold
11000 to 11111: 3.5 V
10111: 3.45 V
...
00101: 2.55 V
00001 to 00100: 2.5 V
00000: Bypass
RW
0x00
Comp2 input debouncing time configuration:
When 0, the debouncing is 91.5 µs using a 30.5 µs clock rate
When 1, the debouncing is 150 ms using a 50 ms clock rate
RW
0
Table 6-84. LED_CTRL1_REG
Address Offset
0x6C
Instance
Reset Domain: GENERAL RESET
Description
LED ON/OFF control register.
Type
RW
7
6
5
Reserved
Bits
Field Name
7:6
Reserved
5:3
LED2_PERIOD
2:0
LED1_PERIOD
4
LED2_PERIOD
3
Description
2
1
LED1_PERIOD
0
Type
Reset
RO
R returns
0s
0x0
Period of LED2 signal:
000: LED2 OFF
001: 0.125 s
010: 0.25 s
...
110: 4 s
111: 8 s
RW
0x0
Period of LED1 signal:
000: LED1 OFF
001: 0.125 s
010: 0.25 s
...
10: 2 s
110: 4 s
111: 8 s
RW
0x0
Detailed Description
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Table 6-85. LED_CTRL2_REG1
Address Offset
0x6D
Instance
Reset Domain: GENERAL RESET
Description
LED ON/OFF control register.
Type
RW
7
6
Reserved
Bits
Field Name
7:6
Reserved
5
LED2_SEQ
4
LED1_SEQ
3
2
LED2_ON_TIME
Description
1
0
LED1_ON_TIME
Type
Reset
RO
R returns
0s
0x0
5
LED2_SEQ
When 1, LED2 will repeat 2 pulse sequence: ON (ON_TIME) - OFF (ON
TIME) - ON (ON TIME) - OFF remainder of the period
When 0, LED2 will generate 1 pulse: ON (ON_TIME) - OFF (ON TIME))
RW
0
4
LED1_SEQ
When 1, LED1 will repeat 2 pulse sequence: ON (ON_TIME) - OFF (ON
TIME) - ON (ON TIME) - OFF remainder of the period.
When 0, LED1 will generate 1 pulse: ON (ON_TIME) - OFF (ON TIME))
RW
0
3:2
LED2_ON_TIME
LED2 ON time:
00: 62.5 ms
01: 125 ms
10: 250 ms
11: 500 ms
RW
0x0
1:0
LED1_ON_TIME
LED1 ON time:
00: 62.5 ms
01: 125 ms
10: 250 ms
11: 500 ms
RW
0x0
Table 6-86. PWM_CTRL1_REG
Address Offset
0x6E
Instance
Reset Domain: GENERAL RESET
Description
PWM frequency
Type
RW
7
6
5
4
3
Reserved
2
1
0
PWM_FREQ
Bits
Field Name
Description
Type
Reset
7:2
Reserved
Reserved bit
RO
R returns
0s
0x00
1:0
PWM_FREQ
Frequency of PWM:
00: 500 Hz
01: 250 Hz
10: 125 Hz
11: 62.5 Hz
RW
0x0
118
Detailed Description
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Table 6-87. PWM_CTRL2_REG
Address Offset
0x6F
Instance
Reset Domain: GENERAL RESET
Description
PWM duty cycle.
Type
RW
7
6
5
4
3
FREQ_DUTY_CYCLE
Bits
Field Name
7:0
FREQ_DUTY_CYCLE Duty cycle of PWM:
00000000: 0/256
...
11111111: 255/256
2
1
Description
0
Type
Reset
RW
0x00
Table 6-88. SPARE_REG
Address Offset
0x70
Instance
Reset Domain: FULL RESET
Description
Spare functional register
Type
RW
7
6
5
4
3
2
1
0
SPARE
Bits
Field Name
Description
7:0
SPARE
Spare bits
Type
Reset
RW
0x00
Table 6-89. VERNUM_REG
Address Offset
0x80
Instance
Reset Domain: FULL RESET
Description
Silicon version number
Type
RW
7
READ_BOOT
Bits
6
5
Reserved
4
3
2
1
Field Name
Description
READ_BOOT
To enable the read of the BOOT mode if you want to go to JTAG mode,
this be must set to 1.
6:4
Reserved
Reserved bit
3:0
VERNUM
Value depending on silicon version number 0000 - Revision 1.0
7
0
VERNUM
Type
Reset
RW
0
RO
R returns
0s
0x0
RO
0x0
Detailed Description
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7 Applications, Implementation, and Layout
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
7.1
Application Information
The TPS65911 device is an integrated power management IC (PMIC) available in a 98-pin 0.65-mm pitch
BGA MicroStar Junior package. The device is designed for applications powered by one Li-Ion or Li-Ion
polymer battery cell, 3-series Ni-MH cells, or a 5-V input supply. The device has three step-down
converters, one step-down controller with external FETs to support high current rails, eight LDO
regulators, nine GPIOs, and EERPOM-programmable power sequencing to support a variety of
processors and system sequencing requirements.
The following sections include a typical application diagram, description of the recommended external
components, and PCB layout guidelines. The TPS65911x Schematic Checklist is available and provides
recommended connections for each pin.
7.2
Typical Application
The default voltages in Figure 7-1 reflect the TPS65911A configuration. Other TPS65911 device options
may have different default voltages.
120
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TPS65911A
< 12V
GNDC
GND
66AK2G12
VBST
V5IN
DRVH
1 …F
GND
Default 1.0 V, DVS
SW
CVDD
GND
VREF
DRVL
100 nF
GND
GND
VOUT
REFGND
GND
VFB
To V5IN
+5 V
VDDCtrl
TRIP
VCC1
10 …F
GND
GND
VCC2
VDD1
1500 mA
DVS
10 …F
GND
VCCIO
SW1
2.2 …H
VFB1
GND1
10 …F
VDD2
1500 mA
DVS
GND
VCC3
4.7 …F
2.2 …H
VIO
1100 mA
4.7 …F
Default 1.35 V
VFB2
DVDD_DDR
10 …F
GND
SWIO
VCC4
CVDD1
GND
SW2
GND2
GND
Default 1.0 V
10 …F
Default 3.3 V
2.2 …H
VFBIO
DVDD33
10 …F
GND
GNDIO
VCC5
4.7 …F
VCC6
GND
2.7V < Vin < 3.6V
If LDO1 or LDO2 used
LDO1
320 mA
VCC6
4.7 …F
GND
Default 1.8 V
Default 1.8 V
2.2 …F
GND
OSC32KIN
Default 1.8 V
2.2 …F
GND
LDO4
50 mA
VBACKUP
5-2000 mF
GND
GND
LDO3
200 mA
VCCS
VCC4
Default 1.8 V
2.2 …F
GND
LDO5
300 mA
Default 3.3 V
2.2 …F
VCC3
(crystal is optional)
12 pF
OSC32KOUT
GND
(leave GPIO floating if not used)
5V
GND
LDO6
300 mA
Default 3.3 V
2.2 …F
GND
LDO7
300 mA
BOOT1
VRTC
GPIO1/3/4/5/8
Default 3.3 V
2.2 …F
GND
LDO8
300 mA
Default 3.3 V
2.2 …F
10 k
PWRON
VCC7
GND
VRTC
20 mA
VRTC
VDDIO
GND
1.8 V (Always-ON)
2.2 …F
GND
(If not used, connect to VRTC)
(leave floating if not used)
DVDD18
AVDDA_XPLL
GND
VCC5
GND
GND
Connects to system 1.8V/3.3V IO supply
2.2 …F
LDO2
320 mA
VCC7
4.7 …F
12 pF
VDDIO
1.2 k
1.2 k
PWRDN
SDA_SDI
I2CSDA
HDRST
SCL_SCK
I2CSCL
(leave floating)
EN
INT1
(leave floating)
TRAN
EN2
(leave floating)
(leave floating)
PGOOD
EN1
(leave floating)
(leave floating)
TESTV
GPIO
SLEEP
PWRHOLD
GPIO
(leave floating)
PORZ
NRESPWRON2
CLK32KOUT
Figure 7-1. TPS65911A Typical Application
Applications, Implementation, and Layout
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7.2.1
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Design Requirements
For a typical application shown in Figure 7-1, Table 7-1 lists the primary design parameters of the power
resources.
Table 7-1. Design Parameters
DESIGN PARAMETER
VALUE
Supply voltage
2.7 V to 5.5 V
VDD1 voltage
1V
VDD1 current
Up to 1.5 A
VDD2 voltage
1.35 V
VDD2 current
Up to 1.5 A
VDDCtrl voltage
VDDCtrl current
(1)
7.2.2
1V
See
(1)
VIO voltage
3.3 V
VIO current
Up to 1.1 A
LDO1 voltage
1.8 V
LDO1 current
Up to 320 mA
LDO2 voltage
1.8 V
LDO2 current
Up to 320 mA
LDO3 voltage
1.8 V
LDO3 current
Up to 200 mA
LDO4 voltage
1.8 V
LDO4 current
Up to 50 mA
LDO5 voltage
3.3 V
LDO5 current
Up to 300 mA
LDO6 voltage
3.3 V
LDO6 current
Up to 300 mA
LDO7 voltage
3.3 V
LDO7 current
Up to 300 mA
LDO8 voltage
3.3 V
LDO8 current
Up to 300 mA
Value is dependent on external FETs.
Detailed Design Procedure
7.2.2.1
External Component Recommendation
For crystal oscillator components, see Section 5.10. If RTC domain is expected to be maintained after
shutdown, VCC7 must have enough capacitance to make sure that when supply is switched off, voltage
does not fall at a rate faster than 10 mV/ms. This makes sure that RTC domain data is maintained.
Table 7-2. External Component Recommendation
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
POWER REFERENCES
VREF filtering capacitor (CO(VREF))
Connected from VREF to REFGND
100
nF
10
µF
VDD1 SMPS
Input capacitor (CI(VCC1))
X5R or X7R dielectric
Output filter capacitor (CO(VDD1))
X5R or X7R dielectric
CO filter capacitor ESR
ƒ = 3 MHz
122
Applications, Implementation, and Layout
4
10
12
µF
10
300
mΩ
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Table 7-2. External Component Recommendation (continued)
PARAMETER
TEST CONDITIONS
MIN
Inductor (LO(VDD1))
NOM
MAX
2.2
LO inductor DC resistor (DCRL)
UNIT
µH
125
mΩ
VDD2 SMPS
Input capacitor (CI(VCC2))
X5R or X7R dielectric
Output filter capacitor (CO(VDD2))
X5R or X7R dielectric
CO filter capacitor ESR
ƒ = 3 MHz
10
4
Inductor (LO(VDD2))
µF
10
12
µF
10
300
mΩ
2.2
LO inductor DC resistor (DCRL)
µH
125
mΩ
VIO SMPS
Input capacitor (CI(VCCIO))
X5R or X7R dielectric
Output filter capacitor (CO(VIO))
X5R or X7R dielectric
CO filter capacitor ESR
ƒ = 3 MHz
10
4
Inductor (LO(VIO))
µF
10
12
µF
10
300
mΩ
125
mΩ
2.2
LO inductor DC resistor (DCRL)
µH
VDDCtrl SMPS
Input capacitor (CVIN)
4 × 10
µF
High-side drive boost capacitor
(Cboost)
0.1
µF
Input capacitor for V5IN supply
(CV5IN)
1
µF
330
µF
Output filter capacitor (CO(VDDCtrl))
CO filter capacitor ESR
9
15
mΩ
Inductor (LO(VDDCtrl))
2.7
µH
LO Inductor DC resistor (DCRL)
20
mΩ
40
kΩ
330
pF
Trip resistance (Rtrip)
Feed forward capacitor (C1)
FET FDMC7660
LDO1
Input capacitor (CI(VCC6))
X5R or X7R dielectric
Output filtering capacitor (CO(LDO1))
4.7
0.8
CO filtering capacitor ESR
2.2
0
µF
2.64
µF
500
mΩ
LDO2
Output filtering capacitor (CO(LDO2))
0.8
CO filtering capacitor ESR
2.2
0
2.64
µF
500
mΩ
LDO3
Input capacitor (CI(VCC5))
X5R or X7R dielectric
Output filtering capacitor (CO(LDO3))
4.7
0.8
CO filtering capacitor ESR
2.2
0
µF
2.64
µF
500
mΩ
LDO4
Output filtering capacitor (CO(LDO4))
0.8
CO filtering capacitor ESR
2.2
0
2.64
µF
500
mΩ
LDO5
Input capacitor (CI(VCC4))
X5R or X7R dielectric
Output filtering capacitor (CO(LDO5))
4.7
0.8
CO filtering capacitor ESR
2.2
0
µF
2.64
µF
500
mΩ
LDO6
Input capacitor (CI(VCC3))
X5R or X7R dielectric
Output filtering capacitor (CO(LDO6))
4.7
0.8
2.2
µF
2.64
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Table 7-2. External Component Recommendation (continued)
PARAMETER
TEST CONDITIONS
CO filtering capacitor ESR
MIN
NOM
0
MAX
UNIT
500
mΩ
LDO7
Output filtering capacitor (CO(LDO7))
0.8
CO filtering capacitor ESR
2.2
0
2.64
µF
500
mΩ
LDO8
Output filtering capacitor (CO(LDO8))
0.8
CO filtering capacitor ESR
2.2
0
2.64
µF
500
mΩ
VRTC LDO
Input capacitor (CI(VCC7))
X5R or X7R dielectric
Output filtering capacitor (CO(VRTC))
4.7
0.8
CO filtering capacitor ESR
2.2
0
µF
2.64
µF
500
mΩ
2000
mF
1500
Ω
BACKUP BATTERY
Backup battery capacitor (CBB)
Series resistors
7.2.2.2
5
CBB = 5 mF to 15 mF
10
10
Controller Design Procedure
Follow these steps to design the controller:
1. Design the output filter
2. Select the FETs
3. Select the bootstrap capacitor
4. Select the input capacitors
5. Set the current limits
VDDCtrl requires a 5-V supply at the V5IN pin with an input capacitor. For most applications, a 1-μF, X5R,
20%, 10-V, or similar capacitor must be used for decoupling.
7.2.2.2.1 Inductor Selection
An inductor must be placed between the external FETs and the output capacitors. Together, the inductor
and output capacitors make the double-pole that contributes to stability. In addition, the inductor is directly
responsible for the output ripple, efficiency, and transient performance. As the inductance increases, the
ripple current decreases, which typically results in an increased efficiency. However, with an increase in
inductance, the transient performance decreases. Finally, the selected inductor must be rated for the
appropriate saturation current, core losses, and DC resistance (DCR). Use Equation 1 to calculate the
recommended inductance for the controller (L).
L
VOUT u VIN
VOUT
VIN u fSW u IOUT max u KIND
where
•
•
•
•
•
VOUT is the typical output voltage.
VIN is the typical input voltage.
fSW is the typical switching frequency.
IOUTmax is the maximum load current.
KIND is the ratio of ILripple to the IOUTmax. For this application, TI recommends that KIND is set to a value
from 0.2 to 0.4.
(1)
After selecting the value of the inductor, use Equation 2 to calculate the peak current for the inductor in
steady state operation, ILmax. The rated saturation current of the inductor must be greater than the ILmax
current.
124
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VOUT u VIN
VOUT
VIN u fSW u IOUT max u KIND
(2)
Following Equation 1 and Equation 2, the preferred inductor for VDDCtrl is 2.7 µH, with a DCR of
approximately 20 mΩ.
7.2.2.2.2 Selecting the RTRIP Resistor
The TRIP pin is used to set the VDDCtrl current limit. The load current is sensed by measuring the voltage
over the low-side FET and comparing it to the voltage at the TRIP pin, VTRIP, with an 8:1 ratio. If the lowside FET is greater than an eighth of VTRIP, the VDDCtrl rail shuts down.
The TRIP resistor then adjusts the range of the VDDCtrl load current monitoring. Use Equation 3 to
calculate the value of the TRIP resistor (RTRIP) for the application and selected external FETs.
RTRIP
8 u IOUT max u RDS(on)
ITRIP
where
•
•
•
IOUTmax is the maximum load current.
ITRIP is the current through the TRIP pin, estimated at 10 µA.
RDS(on) is the on resistance from the external FETs.
(3)
7.2.2.2.3 Selecting the Output Capacitors
Texas Instruments recommends using ceramic capacitors with low ESR values to provide the lowest
output voltage ripple. The output capacitor requires an X7R or an X5R dielectric. Y5V and Z5U dielectric
capacitors, aside from their wide variation in capacitance over temperature, become resistive at high
frequencies. At light load currents, the controller operates in PFM mode, and the output voltage ripple is
dependent on the output-capacitor value and the PFM peak inductor current. Higher output-capacitor
values minimize the voltage ripple in PFM mode. To achieve specified regulation performance and low
output voltage ripple, the DC-bias characteristic of ceramic capacitors must be considered. The effective
capacitance of ceramic capacitors drops with increasing DC bias voltage. TI recommends the use of small
ceramic capacitors placed between the inductor and load with many vias to the power-ground (PGND)
plane for the output capacitors of the controller. This solution typically provides the smallest and lowest
cost solution available for DCAP controllers. The selection of the output capacitor is typically driven by the
output transient response. Equation 4 provides a rough estimate of the minimum required capacitance to
make sure the transient response is correct.
COUT !
ITRAN(max)2 u L
VIN
VOUT u VOVER
where
•
•
•
•
•
ITRAN(max) is the maximum load current step.
L is the selected inductance.
VOUT is the minimum programmed output voltage.
VIN is the maximum input voltage.
VOVER is the maximum allowable overshoot from programmed voltage.
(4)
Because the transient response is affected significantly by the board layout, some experimentation is
expected to confirm that values derived in this section are applicable to any particular use case.
Equation 4 is not provided as an absolute requirement, but as a starting point. Alternatively, lists
recommended capacitor values.
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7.2.2.2.4 Selecting FETs
This controller is designed to drive two n-channel MOSFETs. Typically, lower RDS(on) values are better for
improving the overall efficiency of the controller, however higher gate-charge thresholds result in lower
efficiency so these two values must be balanced for optimal performance. As the RDS(on) for the low-side
FET decreases, the minimum current limit increases. Therefore, make sure the appropriate values are
selected for the FETs, inductor, output capacitors, and current limit resistor. The Texas Instruments'
CSD87330Q3D device is a recommended for the controller, depending on the required maximum current.
7.2.2.2.5 Bootstrap Capacitor
To make sure the internal high-side gate drivers are supplied with a stable low-noise supply voltage, a
capacitor must be connected between the SW pin and the VBST pin. TI recommends placing ceramic
capacitors with a value of 0.1 μF for the controller. TI recommends reserving a small resistor in series with
the bootstrap capacitor in case the turnon and turnoff of the FETs must be slowed to decrease voltage
ringing on the switch node, which is a common practice for controller design.
7.2.2.2.6 Selecting Input Capacitors
Because of the nature of the switching controller with a pulsating input current, a low ESR input capacitor
is required for the best input-voltage filtering and also to minimize the interference with other circuits
caused by high input-voltage spikes. For the controller, a typical 1-μF capacitor can be used for the V5IN
pin to support the transients on the driver. For the FET input, 40 μF of input capacitance is recommended
for most applications. To achieve the low ESR requirement, a ceramic capacitor is recommended.
However, the voltage rating and DC-bias characteristic of ceramic capacitors must be considered. For
better input-voltage filtering, the input capacitor can be increased without any limit. TI recommends placing
a ceramic capacitor as near as possible to the FET across the respective VSYS and PGND pins of the
FETs.
NOTE
Use the correct value for the ceramic capacitor capacitance after derating to achieve the
recommended input capacitance.
7.2.2.3
Converter Design Procedure
7.2.2.3.1 Selecting the Inductor
An inductor must be placed between the external FETs and the output capacitors. Together, the inductor
and output capacitors form a double pole in the control loop that contributes to stability. In addition, the
inductor is directly responsible for the output ripple, efficiency, and transient performance. As the
inductance increases, the ripple current decreases, which typically results in an increase in efficiency.
However, with an increase in inductance, the transient performance decreases. Finally, the selected
inductor must be rated for the appropriate saturation current, core losses, and DC resistance (DCR).
NOTE
The internal parameters for the converters are optimized for a 2.2-µH inductor, however
using other inductor values is possible as long as they are carefully selected and thoroughly
tested.
Use Equation 5 to calculate the recommended inductance for the converter.
L
VOUT u VIN
VOUT
VIN u fSW u IOUT max u KIND
where
•
126
VOUT is the typical output voltage.
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•
•
•
•
VIN is the typical input voltage.
fSW is the typical switching frequency.
IOUTmax is the maximum load current.
KIND is the ratio of ILripple to the IOUTmax. For this application, TI recommends that KIND is set to a value
from 0.2 to 0.4.
(5)
After selecting the value of the inductor, use Equation 6 to calculate the peak current for the inductor in
steady state operation, ILmax. The rated current of the inductor must be greater than the ILmax current.
IL max
VOUT u VIN
VOUT
2 u VIN u fSW u L
(6)
7.2.2.3.2 Selecting Output Capacitors
TI recommends ceramic capacitors with low ESR values because they provide the lowest output voltage
ripple. The output capacitor requires either an X7R or X5R rating. Y5V and Z5U capacitors, aside from the
wide variation in capacitance over temperature, become resistive at high frequencies. At light load
currents, the converter operates in PFM mode and the output voltage ripple is dependent on the outputcapacitor value and the PFM peak inductor current. Higher output-capacitor values minimize the voltage
ripple in PFM mode. To achieve specified regulation performance and low output voltage ripple, the DCbias characteristic of ceramic capacitors must be considered. The effective capacitance of ceramic
capacitors drops with increasing DC-bias voltage. For the output capacitors of the BUCK converters, TI
recommends placing small ceramic capacitors between the inductor and load with many vias to the PGND
plane. This solution typically provides the smallest and lowest-cost solution available for the converters.
The output capacitance must equal to or greater than the minimum capacitance listed for VDD1, VDD2,
and VIO (assuming quality layout techniques are followed). The recommended value is 10 µF.
7.2.2.3.3 Selecting Input Capacitors
Because of the nature of the switching converter with a pulsating input current, a low ESR input capacitor
is required for the best input-voltage filtering and to minimize the interference with other circuits caused by
high input-voltage spikes. For the VCC1, VCC2, and VCCIO pins, 10 μF of input capacitance (after
derating) is required for most applications. A ceramic capacitor is recommended to achieve the low ESR
requirement. However, the voltage rating and DC-bias characteristic of ceramic capacitors must be
considered. The input capacitor can be increased without any limit for better input-voltage filtering.
NOTE
Use the correct value for the ceramic capacitor capacitance after derating to achieve the
recommended input capacitance.
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7.2.3
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Application Curves
VCC1 = 3.8 V
Vout = 1.2 V
PWM Mode
Vout = 1.2 V
PWM Mode
Figure 7-2. VDD1 Falling Load Transient Response
Figure 7-3. VDD1 Rising Load Transient Response
VCC2 = 3.8 V
VCC2 = 3.8 V
Vout = 1.2 V
PWM Mode
Figure 7-4. VDD2 Falling Load Transient Response
VCCIO = 3.8 V
Vout = 1.8 V
PWM Mode
Figure 7-6. VDDIO Falling Load Transient Response
128
VCC1 = 3.8 V
Vout = 1.2 V
PWM Mode
Figure 7-5. VDD2 Rising Load Transient Response
VCCIO = 3.8 V
Vout = 1.8 V
PWM Mode
Figure 7-7. VDDIO Rising Load Transient Response
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7.2.4
SWCS049S – JUNE 2010 – REVISED AUGUST 2018
Layout Guidelines
7.2.4.1
PCB Layout
As with all switching power supplies, the layout is an important step in the design. Proper layout is
important for stability, EMI, as well as achieve higher efficiency and load transient response.
• Place the input capacitors as close as possible to the input pins on the IC, and on the same side of the
board as the IC.
• Place the inductor and output capacitor close to the switch node of the IC.
• Use a solid ground plane for the GND of the buck converters and controller, and use plenty of vias.
• Keep the loop area formed by switch node, inductor, output capacitor, and ground as small as
possible.
• Route the analog grounds separately from the power grounds, and connect them at the ground plane.
• Use short, wide traces for any trace which carries high current like regulator input, output, and ground
traces.
For more detailed guidelines, refer to the TPS65911 Layout Guidelines.
7.2.5
Layout Example
Figure 7-8. VDD1 Layout
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Figure 7-9. VDD2 Layout
Figure 7-10. VDDIO Layout
130
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Figure 7-11. VDDCtrl Layout
7.3
Power Supply Recommendations
The TPS65911 device uses a supply voltage from 2.7 V to 5.5 V. The input supply should be well
regulated and connected to the VCC input pins. Add external capacitors at each of the device supply pins
as described in Table 7-2.
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8 Device and Documentation Support
8.1
8.1.1
Device Support
Development Support
For development support, see the following:
• 66AK2G02 DSP + ARM Processor Audio Processing Reference Design
• 66AK2G02 DSP + ARM Processor Power Solution Reference Design
• DDR ECC Reference Design to Improve Memory Reliability in 66AK2G02-based Systems
• Freescale i.MX6 Dual&Quad Power Reference Design with TPS65911
• Freescale i.MX6 Power Reference Design for Electronic Point of Sale Applications
8.1.2
Device Nomenclature
Table 8-1 lists the acronyms and abbreviations used in this document.
Table 8-1. Acronyms, Abbreviations, and Definitions
132
ACRONYM OR
ABBREVIATION
DEFINITION
DDR
Dual-Data Rate (memory)
ES
Engineering Sample
ESD
Electrostatic Discharge
FET
Field Effect Transistor
EPC
Embedded Power Controller
FSM
Finite State Machine
GND
Ground
GPIO
General-Purpose I/O
HBM
Human Body Model
HD
Hot-Die
HS-I2C
High-Speed I2C
I2C
Inter-Integrated Circuit
IC
Integrated Circuit
ID
Identification
IDDQ
Quiescent supply current
IEEE
Institute of Electrical and Electronics Engineers
IR
Instruction Register
I/O
Input/Output
JEDEC
Joint Electron Device Engineering Council
JTAG
Joint Test Action Group
LBC7
Lin Bi-CMOS 7 (360 nm)
LDO
Low Drop Output voltage linear regulator
LP
Low-Power application mode
LSB
Least Significant Bit
MMC
Multimedia Card
MOSFET
Metal Oxide Semiconductor Field Effect Transistor
NVM
Nonvolatile Memory
OD
Open Drain
OMAP™
Open Multimedia Application Platform™
RTC
Real-Time Clock
Device and Documentation Support
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Table 8-1. Acronyms, Abbreviations, and Definitions (continued)
8.2
8.2.1
ACRONYM OR
ABBREVIATION
DEFINITION
SMPS
Switched Mode Power Supply
SPI
Serial Peripheral Interface
POR
Power-On Reset
Documentation Support
Related Documentation
For related documentation see the following:
• Texas Instruments, CSD87330Q3D Synchronous Buck NexFET™ Power Block data sheet
• Texas Instruments, Empowering Designs With Power Management IC (PMIC) for Processor
Applications application report
• Texas Instruments, Basic Calculation of a Buck Converter's Power Stage application report
• Texas Instruments, TPS65911x Schematic Checklist
• Texas Instruments, TPS65911 Layout Guidelines
• Texas Instruments, TPS65911A User's Guide for 66AK2G12 Processor
• Texas Instruments, TPS659114 for Freescale i.MX6 Dual/Quad User's Guide
• Texas Instruments, TPS659118 User’s Guide for 66AK2G02 Processor
• Texas Instruments, TPS6591133 Centaurus User Guide
• Texas Instruments, TPS659113 Centaurus User Guide
• Texas Instruments, TPS659112 Netra User Guide
8.3
Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. In the
upper right corner, click on Alert me to register and receive a weekly digest of any product information that
has changed. For change details, review the revision history included in any revised document.
8.4
8.4.1
Community Resources
Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the
respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views;
see TI's Terms of Use.
TI E2E™ Online Community The TI engineer-to-engineer (E2E) community was created to foster
collaboration among engineers. At e2e.ti.com, you can ask questions, share knowledge,
explore ideas and help solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools
and contact information for technical support.
8.5
Trademarks
MicroStar Junior, OMAP, NexFET, E2E are trademarks of Texas Instruments.
All other trademarks are the property of their respective owners.
8.6
Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
Device and Documentation Support
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8.7
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Glossary
TI Glossary This glossary lists and explains terms, acronyms, and definitions.
9 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 this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
9.1
Package Description
The following table lists the package descriptions for the TPS65911 PMU devices:
PACKAGE
Type
Size (mm)
Substrate layers
Pitch ball array (mm)
Number of balls
Thickness (mm) (maximum height including balls)
134
TPS65911
ZRC98 BGA MicroStar Junior™
Mechanical, Packaging, and Orderable Information
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6×9
1 layer
0.65 mm
98
1 mm
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PACKAGE OPTION ADDENDUM
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14-Nov-2022
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)
Samples
(4/5)
(6)
TPS6591104DA2NMA
ACTIVE
NFBGA
NMA
98
240
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
6591104DA2NMA
Samples
TPS659110A2NMAR
ACTIVE
NFBGA
NMA
98
2500
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
659110A2NMA
Samples
TPS659112A2NMAR
ACTIVE
NFBGA
NMA
98
2500
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
659112A2NMA
Samples
TPS659112A2ZRC
OBSOLETE
BGA
MICROSTAR
JUNIOR
ZRC
98
TBD
Call TI
Call TI
TPS6591133A2NMA
ACTIVE
NFBGA
NMA
98
240
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
6591133A2NMA
Samples
TPS659114A2NMAR
ACTIVE
NFBGA
NMA
98
2500
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
659114A2NMA
Samples
TPS659114A2ZRCT
OBSOLETE
BGA
MICROSTAR
JUNIOR
ZRC
98
TBD
Call TI
Call TI
659114A2
TPS659116A2ZRC
OBSOLETE
BGA
MICROSTAR
JUNIOR
ZRC
98
TBD
Call TI
Call TI
TPS659116A2
TPS659116A2ZRCR
OBSOLETE
BGA
MICROSTAR
JUNIOR
ZRC
98
TBD
Call TI
Call TI
TPS659116A2
TPS659118A2ZRCT
OBSOLETE
BGA
MICROSTAR
JUNIOR
ZRC
98
TBD
Call TI
Call TI
659118A2
TPS65911AA2NMAR
ACTIVE
NFBGA
NMA
98
2500
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
65911AA2NMA
Samples
TPS65911AA2NMAT
ACTIVE
NFBGA
NMA
98
250
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 85
65911AA2NMA
Samples
(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.
Addendum-Page 1
TPS659112A2
PACKAGE OPTION ADDENDUM
www.ti.com
14-Nov-2022
(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