TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Integrated Power Management Unit Top Specification Check for Samples: TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103, TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 FEATURES 1 The purpose of the TPS65910 device is to provide the following resources: • • • • • • • • • • • • • Embedded power controller Two efficient step-down dc-dc converters for processor cores One efficient step-down dc-dc converter for I/O power One efficient step-up 5-V dc-dc converter SmartReflex™ compliant dynamic voltage management for processor cores 8 LDO voltage regulators and one RTC LDO (internal purpose) One high-speed I2C interface for generalpurpose control commands (CTL-I2C) One high-speed I2C interface for SmartReflex Class 3 control and command (SR-I2C) Two enable signals multiplexed with SR-I2C, configurable to control any supply state and processor cores supply voltage 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 One configurable GPIO DC-DC switching synchronization through internal or external 3-MHz clock APPLICATIONS • • Portable and handheld systems OMAP3 power management DESCRIPTION The TPS65910 is an integrated power-management IC available in 48-QFN package and dedicated to applications powered by one Li-Ion or Li-Ion polymer battery cell or 3-series Ni-MH cells, or by a 5-V input; it requires multiple power rails. The device provides three step-down converters, one step-up converter, and eight LDOs and is designed to support the specific power requirements of OMAP-based applications. Two of the step-down converters provide power for dual processor cores and are controllable by a dedicated class-3 SmartReflex 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 LDOs providing a wide range of voltage and current capabilities; they are fully controllable by the I2C interface. The use of the LDOs is flexible; they are intended to be used as follows: Two LDOs are designated to power the PLL and video DAC supply rails on the OMAP based processors, four generalpurpose auxiliary LDOs are available to provide power to other devices in the system, and two LDOs are provided to power DDR memory supplies in applications requiring these memories. In addition to the power resources, the device contains an embedded power controller (EPC) to manage the power sequencing requirements of the OMAP systems and an (RTC). Figure 1 shows the top-level diagram of the device. 1 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2010–2012, Texas Instruments Incorporated TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com VBACKUP SWCS046N – MARCH 2010 – REVISED APRIL 2012 CBB VBAT VCC7 VBAT Ci(VCC7) VRTC VRTC (LDO) and POR Co(VRTC) VAUX33 VCC7 Backup management Ci(VDD3) SW3 GNDA GNDA GND3 VDD3 (SMPS) OSC32KIN OSC 32-kHz OSC32KOUT VFB3 Real-time clock Co(VDD3) AGND VCC7 REFGND VDDIO SDA_SDI SCL_SCK VBAT VCC1 CLK32KOUT Ci(VCC1) SW1 GND1 2 I C VDD1 (SMPS) Bus control GPIO_CKSYNC Co(VDD1) VFB1 AGND VCC4 VBAT VCC2 Ci(VCC2) SW2 SDASR_EN2 GND2 2 I C SCLSR_EN1 VDD2 (SMPS) Co(VDD2) VFB2 AGND VCC7 INT1 SLEEP PWRON BOOT1 BOOT0 PWRHOLD NRESPWRON Power control statemachine Co(VREF) TESTV REFGND VIO (SMPS) VCC 7 Analog references and comparators VDAC Co(VDAC) VBAT VDIG1 (LDO) VDDIO VDIG1 Co(VDIG1) DGND AGND2 VCC7 VCC5 Co(VIO) VFBIO VCC7 Test interface VDAC (LDO) Ci(VCCIO) SWIO GNDIO AGND2 VREF VBAT VCCIO VCC6 AGND Ci(VCC5) VDIG2 VPLL VDIG2 (LDO) VPLL (LDO) Co(VPLL) Co(VDIG2) AGND2 AGND VAUX1 VAUX33 (LDO) VAUX1 (LDO) VAUX33 Co(VAUX33) Co(VAUX1) VBAT VBAT AGND2 VCC4 AGND2 VCC3 Ci(VCC4) VAUX2 Co(VAUX2) DGND AGND AGND2 GND3 VAUX2 (LDO) Ci(VCC4) VMMC VMMC (LDO) Co(VMMC) AGND2 GNDP AGND2 GNDP: Power pad ground SWCS046-001 Figure 1. 48-QFN Top-Level Diagram 2 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 1. SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS (1) Compatible Processor (1) Part Number (1) TI processor - AM335x with DDR2 TPS65910AA1RSL TI processor - AM335x with DDR3 TPS65910A3A1RSL TI processors - AM1705/07, AM1806/08, AM3505/17, AM3703/15, DM3730/25, OMAP-L137/38, OMAP3503/15/25/30, TMS320C6742/6/8 TPS65910A1RSL Samsung - S5PV210, S5PC110 TPS659101A1RSL Rockchip - RK29xx TPS659102A1RSL Samsung - S5PC100 TPS659103A1RSL Samsung - S5P6440 TPS659104A1RSL TI processors - DM643x, DM644x TPS659105A1RSL Reserved TPS659106A1RSL Freescale - i.MX27, Freescale - i.MX35 TPS659107A1RSL Freescale - i.MX508 TPS659108A1RSL Freescale - i.MX51 TPS659109A1RSL The RSL package is available in tape and reel. See for details for corresponding part numbers, quantities and ordering information. ABSOLUTE MAXIMUM RATINGS over operating free-air temperature range (unless otherwise noted) Stresses beyond those listed under below may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated below are not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. The absolute maximum ratings for the TPS65910 device are listed below: MIN MAX UNIT Voltage range on pins/balls VCC1, VCC2, VCCIO, VCC3, VCC4, VCC5, VCC6, VCC7 PARAMETER –0.3 7 V Voltage range on pins/balls VDDIO –0.3 3.6 V Voltage range on pins/balls OSC32KIN, OSC32KOUT, BOOT1, BOOT0 –0.3 VRTCMAX + 0.3 V Voltage range on pins/balls SDA_SDI, SCL_SCK, SDASR_EN2, SCLSR_EN1, SLEEP, INT1, CLK32KOUT, NRESPWRON –0.3 VDDIOMAX + 0.3 V Voltage range on pins/balls PWRON –0.3 7 V Voltage range on pins/balls PWRHOLD (1) GPIO_CKSYNC (2) –0.3 7 V Functional junction temperature range –45 150 °C Peak output current on all other terminals than power resources –5 5 mA (1) (2) I/O supplied from VDDIO but which can be driven from to a VBAT voltage level I/O supplied from VRTC but can be driven to a VBAT voltage level THERMAL CHARACTERISTICS over operating free-air temperature range (unless otherwise noted) Package Rθja (°C/W) TA < 25°C Power Rating (W) DERATING FACTOR ABOVE 25 °C (mW/°C) TA = 70°C Power (W) TA = 85°C Power Rating (W) RSL 48-QFN 37 2.6 37 1.48 1 The thermal resistance RθJP junction-to-power PAD of the RSL package is 1.1°C/W The value of thermal resistance RθJA junction-to-ambient was measured on a high K. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 3 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com RECOMMENDED OPERATING CONDITIONS over operating free-air temperature range (unless otherwise noted) Lists of the recommended operating maximum ratings for the TPS65910 device are given below. Note1: VCC7 should be connected to the highest supply that is connected to the device VCCx pin. The exception is that VCC2 and VCC4 can be higher than VCC7. Note2: VCC2 and VCC4 must be connected together (to the same voltage). Note3: If VDD3 boost is used, VAUX33 must be set to 2.8 V or higher and enabled before VDD3. PARAMETER TEST CONDITIONS VCC: Input voltage range on pins/balls VCC1, VCC2, VCCIO, VCC3, VCC4, VCC5, VCC7 MIN NOM MAX UNIT 2.7 3.6 5.5 V VCCP: Input voltage range on pins/balls VCC6 1.7 3.6 5.5 V Input voltage range on pins/balls VDDIO 1.65 1.8/3.3 3.45 V 0 3.6 5.5 V Input voltage range on pins/balls SDA_SDI, SCL_SCK, SDASR_EN2, SCLSR_EN1, SLEEP 1.65 VDDIO 3.45 V Input voltage range on pins/balls PWRHOLD, GPIO_CKSYNC 1.65 VDDIO 5.5 V Input voltage range on balls BOOT1, BOOT0, OSC32KIN 1.65 VRTC 1.95 V Operating free-air temperature, TA –40 27 85 °C Junction temperature TJ –40 27 125 °C Storage temperature range –65 27 150 °C Input voltage range on pins/balls PWRON Lead temperature (soldering, 10 s) 260 °C 100 nF Power References VREF filtering capacitor CO(VREF) Connected from VREF to REFGND Input capacitor CI(VCC1) X5R or X7R dielectric Filter capacitor CO(VDD1) X5R or X7R dielectric CO filter capacitor ESR f = 3 MHz VDD1 SMPS 10 4 Inductor LO(VDD1) µF 10 12 µF 10 300 mΩ 125 mΩ 2.2 LO inductor dc resistor DCRL µH VDD2 SMPS Input capacitor CI(VCC2) X5R or X7R dielectric Filter capacitor CO(VDD2) X5R or X7R dielectric CO filter capacitor ESR f = 3 MHz 10 4 Inductor LO(VDD2) µF 10 12 µF 10 300 mΩ 125 mΩ 2.2 LO inductor dc resistor DCRL µH VIO SMPS Input capacitor CI(VIO) X5R or X7R dielectric Filter capacitor CO(VIO) X5R or X7R dielectric CO filter capacitor ESR f = 3 MHz 10 4 Inductor LO(VIO) µF 10 12 µF 10 300 mΩ 2.2 LO inductor dc resistor DCRL µH 125 mΩ VDIG1 LDO Input capacitor CI(VCC6) X5R or X7R dielectric 4.7 Filtering capacitor CO(VDIG1) 0.8 CO filtering capacitor ESR 2.2 0 µF 2.64 µF 500 mΩ VDIG2 LDO Filtering capacitor CO(VDIG2) 0.8 CO filtering capacitor ESR 2.2 0 2.64 µF 500 mΩ VPLL LDO Input capacitor CI(VCC5) X5R or X7R dielectric Filtering capacitor CO(VPLL) 4 Submit Documentation Feedback 4.7 0.8 2.2 µF 2.64 µF Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 RECOMMENDED OPERATING CONDITIONS (continued) over operating free-air temperature range (unless otherwise noted) Lists of the recommended operating maximum ratings for the TPS65910 device are given below. Note1: VCC7 should be connected to the highest supply that is connected to the device VCCx pin. The exception is that VCC2 and VCC4 can be higher than VCC7. Note2: VCC2 and VCC4 must be connected together (to the same voltage). Note3: If VDD3 boost is used, VAUX33 must be set to 2.8 V or higher and enabled before VDD3. PARAMETER TEST CONDITIONS CO filtering capacitor ESR MIN NOM 0 MAX UNIT 500 mΩ VDAC LDO Filtering capacitor CO(VDAC) 0.8 CO filtering capacitor ESR 0 2.2 2.64 µF 500 mΩ VMMC LDO Input capacitor CI(VCC4) X5R or X7R dielectric 4.7 Filtering capacitor CO(VMMC) 0.8 CO filtering capacitor ESR 2.2 0 µF 2.64 µF 500 mΩ VAUX33 LDO Filtering capacitor CO(VAUX33) 0.8 CO filtering capacitor ESR 2.2 0 2.64 µF 500 mΩ VAUX1 LDO Input capacitor CI(VCC3) X5R or X7R dielectric 4.7 Filtering capacitor CO(VAUX1) 0.8 CO filtering capacitor ESR 2.2 0 µF 2.64 µF 500 mΩ VAUX2 LDO Filtering capacitor CO(VAUX2) 0.8 CO filtering capacitor ESR 2.2 0 2.64 µF 500 mΩ VRTC LDO Input capacitor CI(VCC7) X5R or X7R dielectric 4.7 Filtering capacitor CO(VRTC) 0.8 CO filtering capacitor ESR 2.2 0 µF 2.64 µF 500 mΩ VDD3 SMPS Input capacitor CI(VDD3) X5R or X7R dielectric Filter capacitor CO(VDD3) X5R or X7R dielectric CO filter capacitor ESR f = 1 MHz 4.7 Inductor LO(VDD3) µF 4 10 12 µF 10 300 mΩ 2.8 4.7 6.6 µH 50 500 mΩ 10 LO inductor DC resistor DCRL Backup Battery Backup battery capacitor CBB Series resistors Battery or superCap supplying VBACKUP 5 2000 mF Capacitor supplying VBACKUP 1 40 µF 5 to 15 mF 10 1500 100 to 2000 mF 5 15 Ω I2C Interfaces SDA_SDI, SCL_SCK, SDASR_EN2, SCLSR_EN1 external pull-up resistor Connected to VDDIO 1.2 kΩ 32.768 kHz Crystal Oscillator (connected from OSC32KIN to OSC32KOUT) Crystal frequency @ specified load cap value Crystal tolerance @ 27°C –20 Frequency Temperature coefficient. Oscillator contribution (not including crystal variation) –0.5 Secondary temperature coefficient Voltage coefficient Copyright © 2010–2012, Texas Instruments Incorporated –0.04 –2 0 –0.035 20 ppm 0.5 ppm/°C –0.03 ppm/°C2 2 ppm/V Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 5 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com RECOMMENDED OPERATING CONDITIONS (continued) over operating free-air temperature range (unless otherwise noted) Lists of the recommended operating maximum ratings for the TPS65910 device are given below. Note1: VCC7 should be connected to the highest supply that is connected to the device VCCx pin. The exception is that VCC2 and VCC4 can be higher than VCC7. Note2: VCC2 and VCC4 must be connected together (to the same voltage). Note3: If VDD3 boost is used, VAUX33 must be set to 2.8 V or higher and enabled before VDD3. PARAMETER TEST CONDITIONS MIN Max crystal series resistor @ Fundamental frequency Crystal load capacitor According to crystal data sheet Load crystal oscillator Coscin ,Coscout parallel mode Including parasitic PCB capacitor Quality factor NOM MAX UNIT 90 kΩ 6 12.5 pF 12 25 pF 8000 80000 ESD SPECIFICATIONS over operating free-air temperature range (unless otherwise noted) STANDARD REFERENCE PERFORMANCE TI STANDARD REQUIREMENTS Human body model (HBM) EIA/JESD22-A114D 2000 V 2000 V Charge device model (CDM) EIA/JESD22-C101C 500 V 500 V ESD METHOD 6 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 I/O PULLUP AND PULLDOWN CHARACTERISTICS over operating free-air temperature range (unless otherwise noted) PARAMETER (1) TEST CONDITIONS MIN TYP MAX UNIT –45% 8 +45% kΩ µA SDA_SDI, SCL_SCK, SDASR_EN2, SCLSR_EN1 Programmable pullup (DFT, default inactive) Grounded, VDDIO = 1.8 V SLEEP programmable pulldown (default active) @ 1.8 V, VRTC = 1.8 V 2 4.5 10 @ 1.8 V, VRTC = 1.8 V, VCC7 = 2.7 V 2 4.5 10 @ 5.5 V, VRTC = 1.8 V, VCC7 = 5.5 V 7 14 30 BOOT0, BOOT1 programmable pulldown (default @ 1.8 V, VRTC = 1.8 V active) 2 4.5 10 µA NRESPWRON pulldown @ 1.8 V, VCC7 = 5.5 V, OFF state 2 4.5 10 µA 32KCLKOUT pulldown (disabled in Active-sleep state) @ 1.8 V, VRTC = 1.8 V, OFF state 2 4.5 10 µA PWRON programmable pullup (default active) Grounded, VCC7 = 5.5 V –40 –31 –15 µA GPIO_CKSYNC programmable pullup (default active) Grounded, VRTC = 1.8 V –27 –18 –9 µA PWRHOLD programmable pulldown (default active) (1) µA The internal pullups on the CTL-I2C and SR-I2C balls are used for test purposes or when the SR-I2C interface is not used. Discrete pullups to the VIO supply must be mounted on the board in order to use the I2C interfaces. The internal I2C pullups must not be used for functional applications Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 7 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com DIGITAL I/O VOLTAGE ELECTRICAL CHARACTERISTICS over operating free-air temperature range (unless otherwise noted) PARAMETER MIN TYP MAX UNIT 0.3 x VCC7 V Related I/O: PWRON Low-level input voltage VIL High-level input voltage VIH 0.7 x VCC7 V Related I/Os: PWRHOLD, GPIO_CKSYNC Low-level input voltage VIL High-level input voltage VIH VDDIO/V CC7 1.3 0.45 V VCC7 V 0.35 x VRTC V Related I/Os: BOOT0, BOOT1, OSC32KIN Low-level input voltage VIL High-level input voltage VIH 0.65 x VRTC V Related I/Os: SLEEP Low-level input voltage VIL 0.35 x VDDIO High-level input voltage VIH 0.65 x VDDIO V V Related I/Os: NRESPWRON, INT1, 32KCLKOUT Low-level output voltage VOL High-level output voltage VOH IOL = 100 µA 0.2 V IOL = 2 mA 0.45 V IOH = 100 µA VDDIO – 0.2 V IOH = 2 mA VDDIO – 0.45 V Related Open-Drain I/Os: GPIO0 Low-level output voltage VOL IOL = 100 µA 0.2 V IOL = 2 mA 0.45 V 0.3 x VDDIO V 2 I C-Specific Related I/Os: SCL, SDA, SCLSR_EN1, SDASR_EN2 Low-level input voltage VIL –0.5 High-level input voltage VIH 0.7 x VDDIO Hysteresis 0.1 x VDDIO V V Low-level output voltage VOL @ 3mA (sink current), VDDIO = 1.8 V 0.2 × VDDIO V Low-level output voltage VOL @ 3mA (sink current), VDDIO = 3.3 V 0.4 x VDDIO V 8 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 I2C INTERFACE AND CONTROL SIGNALS over operating free-air temperature range (unless otherwise noted) NO. PARAMETER TEST CONDITIONS MIN TYP MAX 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/SCLSR_EN1 and SDA/SDASR_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 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 0 ns 70 ns SLAVE FAST MODE SCL/SCLSR_EN1 and SDA/SDASR_EN2 rise and fall time, CL = 10 to 400 pF 20 + 0.1 × CL Data rate 250 ns 400 Kbps 0.9 µs I3 tsu(SDA-SCLH) Setup time, SDA valid to SCL high 100 I4 th(SCLL-SDA) Hold time, SDA valid from SCL low 0 ns 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 SLAVE STANDARD MODE SCL/SCLSR_EN1 and SDA/SDASR_EN2 rise and fall time, CL = 10 to 400 pF 250 ns Data rate 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 SWITCHING CHARACTERISTICS 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 SLAVE STANDARD MODE I1 tw(SCLL) Pulse duration, SCL low 4.7 µs I2 tw(SCLH) Pulse duration, SCL high 4 µs Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 9 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com POWER CONSUMPTION over operating free-air temperature range (unless otherwise noted) All current consumption measurements are relative to the FULL chip, all VCC inputs set to VBAT voltage. PARAMETER Device BACKUP state Device OFF state TYP MAX VBAT = 2.4 V, VBACKUP = 0 V, TEST CONDITIONS MIN 11 16 VBAT = 0 V, VBACKUP = 3.2 V 6 9 UNIT µA VBAT = 3.6 V, CK32K clock running BOOT[1:0] = 00: 32-kHz RC oscillator 16.5 23 BOOT[1:0] = 01: 32-kHz quartz or bypass oscillator, BOOT0P =0 15 20 BOOT[1:0] = 01, Backup Battery Charger on, VBACKUP = 3.2 V 32 42 VBAT = 5 V, CK32K clock running: 20 28 µA BOOT[1:0] = 00: RC oscillator Device SLEEP state Device ACTIVE state VBAT = 3.6 V, CK32K clock running, PWRHOLDP = 0 BOOT[1:0] = 00, 3 DC-DCs on, 5 LDOs and VRTC on, no load 295 BOOT[1:0] = 01, 3 DC-DCs on, 3 LDOs and VRTC on, no load, BOOT0P = 0 279 µA VBAT = 3.6 V, CK32K clock running, PWRHOLDP = 0 BOOT[1:0] = 00, 3 DC-DCs on, 5 LDOs and VRTC on, no load 1 BOOT[1:0] = 01, 3 DC-DCs on, 3 LDOs and VRTC on, no load, BOOT0P = 0 0.9 BOOT[1:0] = 00, 3 DC-DCs on PWM mode (VDD1_PSKIP = VDD2_PSKIP = VIO_PSKIP = 0), 5 LDOs and VRTC on, no load 21 mA POWER REFERENCES AND THRESHOLDS over operating free-air temperature range (unless otherwise noted) TEST CONDITIONS MIN TYP MAX UNIT Output reference voltage (VREF terminal) PARAMETER Device in active or low-power mode –1% 0.85 +1% V Main battery charged threshold VMBCH (programmable) Measured on VCC7 terminal Triggering monitored through NRESPRWON VMBCH_VSEL = 11, BOOT[1:0] = 11 or 00 3 VMBCH_VSEL = 10 2.9 VMBCH_VSEL = 01 2.8 VMBCH_VSEL = 00 V bypassed Main battery discharged Measured on VCC7 terminal (MTL prg) threshold VMBDCH (programmable) Triggering monitored through INT1 VMBCH – 100 mV V Main battery low threshold VMBLO (MB comparator) Measured on VCC7 terminal (Triggering monitored on terminal NRESPWRON) 2.5 2.6 2.7 Main battery high threshold VMBHI VBACKUP = 0 V, measured on terminal VCC7 (MB comparator) 2.6 2.75 3 VBACKUP = 3.2 V, measured on terminal VCC7 2.5 2.55 3 Measured on terminal VCC7 (Triggering monitored on terminal VRTC) 1.9 2.1 2.2 Main battery not present threshold VBNPR Ground current (analog references + comparators + backup battery switch) 10 V V V VCC = 3.6 V Device in OFF state 8 Device in ACTIVE or SLEEP state 20 Submit Documentation Feedback µA Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 THERMAL MONITORING AND SHUTDOWN over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS Hot-die temperature rising threshold MIN TYP THERM_HDSEL[1:0] = 00 121 113 125 THERM_HDSEL[1:0] = 11 °C 136 130 Hot-die temperature hysteresis 10 Thermal shutdown temperature rising threshold 136 148 Thermal shutdown temperature hysteresis Device in ACTIVE state, Temp = 27°C, VCC7 = 3.6 V Ground current UNIT 117 THERM_HDSEL[1:0] = 01 THERM_HDSEL[1:0] = 10 MAX °C 160 °C 10 °C 6 µA 32-kHz RTC CLOCK over operating free-air temperature range (unless otherwise noted) PARAMETER CLK32KOUT rise and fall time TEST CONDITIONS MIN TYP CL = 35 pF MAX UNIT 10 ns Bypass Clock (OSC32KIN: input, OSC32KOUT floating) Input bypass clock frequency OSCKIN input Input bypass clock duty cycle OSCKIN input Input bypass clock rise and fall time 10% – 90%, OSC32KIN input, CLK32KOUT duty cycle Logic output signal Bypass clock setup time 32KCLKOUT output Ground current Bypass mode 32 40% kHz 60% 10 40% 20 ns 60% 1 ms 1.5 µA Crystal oscillator (connected from OSC32KIN to OSC32KOUT) Output frequency CK32KOUT output Oscillator startup time On power on 32.768 kHz 2 Ground current 1.5 s µA RC oscillator (OSC32KIN: grounded, OSC32KOUT floating) Output frequency CK32KOUT output Output frequency accuracy @ 25°C Cycle jitter (RMS) Oscillator contribution Output duty cycle 32 –15% 0% +40% +50% kHz +15% +10% Settling time +60% 150 Ground current Active @ fundamental frequency Copyright © 2010–2012, Texas Instruments Incorporated 4 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 µs µA 11 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com BACKUP BATTERY CHARGER over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT Backup battery charging current VBACKUP = 0 to 2.4 V, BBCHEN = 1 350 500 700 µA End-of-charge backup battery voltage (1) VCC7 = 3.6 V, BBSEL = 10 –3% 3.15 +3% VCC7 = 3.6 V, BBSEL = 00 –3% 3 +3% VCC7 = 3.6 V, BBSEL = 01 –3% 2.52 +3% VCC7 = 3.6 V, BBSEL = 11 VBAT – 0.3 V Ground current (1) On mode V VBAT 10 µA Note: (a) BBSEL = 10, 00, or 01 intended to charge battery or superCap (b) BBSEL = 11 intended to charge capacitor VRTC LDO over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage VIN DC output voltage VOUT Rated output current IOUTmax DC load regulation DC line regulation Transient load regulation TEST CONDITIONS MIN TYP MAX On mode 2.5 5.5 Back-up mode 1.9 3 On mode, 3.0 V < VIN < 5.5 V 1.78 1.83 1.88 Back-up mode, 2.3 V ≤ VIN ≤ 2.6 V 1.72 1.78 1.84 On mode 20 Back-up mode 0.1 UNIT V V mA On mode, IOUT = IOUTmax to 0 50 Back-up mode, IOUT = IOUTmax to 0 50 On mode, VIN = 3.0 V to VINmax @ IOUT = IOUTmax 2.5 Back-up mode, VIN = 2.3 V to 5.5 V @ IOUT = IOUTmax 25 On mode, VIN = VINmin + 0.2 V to VINmax mV mV 50 (1) mV 25 (1) mV IOUT = IOUTmax/2 to IOUTmax in 5 µs and IOUT = IOUTmax to IOUTmax/2 in 5 µs 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 Turn-on time IOUT = 0, VIN rising from 0 up to 3.6 V, @ VOUT = 0.1 V up to VOUTmin Ripple rejection VIN = VINDC + 100 mVpp tone, VINDC+ = VINmin + 0.1 V to VINmax @ IOUT = IOUTmax/2 Ground current (1) 12 2.2 f = 217 Hz 55 f = 50 kHz 35 Device in ACTIVE state 23 Device in BACKUP or OFF state 3 ms dB µA These parameters are not tested. They are used for design specification only. Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VIO SMPS over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCCIO and VCC7) VIN DC output voltage (VOUT) TEST CONDITIONS MIN 2.7 5.5 VOUT = 1.5 V or 1.8 V, IOUT > 800 mA 3.2 5.5 VOUT = 2.5 V, IOUT > 800 mA 4.0 5.5 VOUT = 3.3 V, IOUT > 800 mA 4.4 5.5 UNIT V PWM mode (VIO_PSKIP = 0) or pulse skip mode IOUT to IMAX VSEL=00 –3% 1.5 +3% VSEL = 01, default BOOT[1:0] = 00 and 01 –3% 1.8 +3% VSEL = 10 –3% 2.5 +3% VSEL = 11 –3% 3.3 +3% V 0 ILMAX[1:0] = 00, default 500 ILMAX[1:0] = 01 1000 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, SWIO = 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, SWIO = VINmax PMOS current limit (high-side) VIN = VINmin to VINmax, ILMAX[1:0] = 00 650 VIN = VINmin to VINmax, ILMAX[1:0] = 01 1200 VIN = VINmin to VINmax, ILMAX[1:0] = 10 1700 NMOS current limit (low-side) MAX IOUT ≤ 800 mA Power down Rated output current IOUTmax TYP mΩ 400 2 µA mΩ 400 2 µA mA Source current load: VIN = VINmin to VINmax, ILMAX[1:0] = 00 650 VIN = VINmin to VINmax, ILMAX[1:0] = 01 1200 VIN = VINmin to VINmax, ILMAX[1:0] = 10 1700 mA Sink current load: VIN = VINmin to VINmax, ILMAX[1:0] = 00 800 VIN = VINmin to VINmax, ILMAX[1:0] = 01 1200 VIN = VINmin to VINmax, ILMAX[1:0] = 10 1700 DC load regulation On mode, IOUT = 0 to IOUTmax 20 mV DC line regulation On mode, VIN = VINmin to VINmax 20 mV 50 mV VIN = 3.8 V, VOUT = 1.8 V Transient load regulation IOUT = 0 to 500 mA , Max slew = 100 mA/µs IOUT = 700 to 1200 mA , Max slew = 100 mA/µs t on, off to on IOUT = 200 mA 350 Overshoot SMPS turned on 3% Power-save mode Ripple voltage Pulse skipping mode, IOUT = 1 mA µs 0.025 × VOUT Switching frequency VPP 3 Duty cycle MHz 100 Minimum On Time TON(MIN) % 35 ns 1 MΩ P-channel MOSFET VFBIO internal resistance Discharge resistor for power-down sequence RDIS 0.5 During device switch-off sequence 30 50 Ω Note: No discharge resistor is applied if VIO is turned off while the device is on. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 13 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VIO SMPS (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER Ground current (IQ) TEST CONDITIONS MIN TYP Off MAX UNIT 1 PWM mode, IOUT = 0 mA, VIN = 3.8 V, VIO_PSKIP = 0 7500 Pulse skipping mode, no switching, 3-MHz clock on 250 µA Low-power (pulse skipping) mode, no switching ST[1:0]=11 Conversion efficiency 63 PWM mode, DCRL < 50 mΩ, VOUT = 1.8 V, VIN = 3.6 V: IOUT = 10 mA 44% IOUT = 100 mA 87% IOUT = 400 mA 86% IOUT = 800 mA 76% IOUT = 1000 mA 72% Pulse Skipping mode, DCRL < 50 mΩ, VOUT = 1.8 V, VIN = 3.6 V: 14 IOUT = 1 mA 71% IOUT = 10 mA 80% IOUT = 200 mA 87% Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VDD1 SMPS over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCC1 and VCC7) VIN TEST CONDITIONS IOUT ≤ 1200 mA VOUT = 0.6 V to 1.5 V, VGAIN_SEL = 00, IOUT > 1200 mA 2.5 V ≤ VOUT ≤ 3.3 V, VGAIN_SEL = 10 or 11, IOUT > 1200 mA DC output voltage (VOUT) MIN TYP MAX 2.7 5.5 VOUT + 2 V 5.5 4.5 5.5 UNIT V VGAIN_SEL = 00, IOUT = 0 to IOUTmax: max programmable voltage, SEL[6:0] = 1001011 1.5 default voltage, BOOT[1:0] = 00 –3% 1.2 +3% default voltage, BOOT[1:0] = 01 –3% 1.2 +3% V min programmable voltage, SEL[6:0] = 0000011 0.6 SEL[6:0] = 000000: power down 0 VGAIN_SEL = 10, SEL = 0101011 = 43, IOUT = 0 to IOUTmax –3% 2.2 +3% V VGAIN_SEL = 11, SEL = 0101000 = 40, IOUT = 0 to IOUTmax –3% 3.2 +3% V DC output voltage programmable step (VOUTSTEP) VGAIN_SEL = 00, 72 steps Rated output current IOUTmax ILMAX = 0, default 1000 ILMAX = 1 1500 12.5 mV mA P-channel MOSFET VIN = VINmin 300 On-resistance RDS(ON)_PMOS VIN = 3.8 V 250 P-channel leakage current VIN = VINmax, SW1 = 0 V mΩ 400 2 µA ILK_PMOS N-channel MOSFET VIN = VMIN 300 On-resistance RDS(ON)_NMOS VIN = 3.8 V 250 N-channel leakage current ILK_NMOS VIN = VINmax, SW1 = VINmax PMOS current limit (high-side) VIN = VINmin to VINmax, ILMAX = 0 1150 VIN = VINmin to VINmax, ILMAX = 1 2000 NMOS current limit (low-side) mΩ 400 2 µA mA Source current load: VIN = VINmin to VINmax, ILMAX = 0 1150 VIN = VINmin to VINmax, ILMAX = 1 2000 mA Sink current load: VIN = VINmin to VINmax, ILMAX = 0 1200 VIN = VINmin to VINmax, ILMAX = 1 2000 DC load regulation On mode, IOUT = 0 to IOUTmax 20 mV DC line regulation On mode, VIN = VINmin to VINmax 20 mV Transient load regulation VIN = 3.8 V, VOUT = 1.2 V 50 mV IOUT = 0 to 500 mA , Max slew = 100 mA/µs IOUT = 700 mA to 1.2A , Max slew = 100 mA/µs t on, off to on IOUT = 200 mA Output voltage transition rate From VOUT = 0.6 V to 1.5 V and VOUT = 1.5 V to 0.6 V IOUT = 500 mA Overshoot TSTEP[2:0] = 001 12.5 TSTEP[2:0] = 011 (default) 7.5 TSTEP[2:0] = 111 2.5 SMPS turned on Power-save mode ripple voltage 350 Pulse skipping mode, IOUT = 1 mA Switching frequency Copyright © 2010–2012, Texas Instruments Incorporated µs mV/µs 3% 0.025 × VOUT VPP 3 MHz Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 15 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VDD1 SMPS (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP Duty cycle MAX 100 Minimum on time tON(MIN) UNIT % 35 ns 1 MΩ P-channel MOSFET VFB1 internal resistance 0.5 Discharge resistor for power-down sequence RDIS Ground current (IQ) 30 Off PWM mode, IOUT = 0 mA, VIN = 3.8 V, VDD1_PSKIP = 0 Pulse skipping mode, no switching 50 Ω 1 7500 78 µA Low-power (pulse skipping) mode, no switching ST[1:0] = 11 Conversion efficiency 63 PWM mode, DCRL < 0.1 Ω, VOUT = 1.2 V, VIN = 3.6 V: IOUT = 10 mA 35% IOUT = 200 mA 82% IOUT = 400 mA 81% IOUT = 800 mA 74% IOUT = 1500 mA 62% Pulse skipping mode, DCRL < 0.1Ω, VOUT = 1.2 V, VIN = 3.6 V: 16 IOUT = 1 mA 59% IOUT = 10 mA 70% IOUT = 200 mA 82% Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VDD2 SMPS over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS Input voltage (VCC2 and VCC4) VIN IOUT ≤ 1200 mA VOUT = 0.6 V to 1.5 V, VGAIN_SEL = 00, IOUT > 1200 mA 2.5 V ≤ VOUT ≤ 3.3 V, VGAIN_SEL = 10 or 11, IOUT > 1200 mA DC output voltage (VOUT) MIN TYP 2.7 5.5 VOUT + 2 V 5.5 4.5 5.5 UNIT V VGAIN_SEL = 00, IOUT = 0 to IOUTmax: max programmable voltage, SEL[6:0] = 1001011 default, BOOT[1:0] = 01 1.5 –3% min programmable voltage, SEL[6:0] = 0000011 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, default, BOOT[1:0] = 00 –3% 3.3 +3% DC output voltage programmable step (VOUTSTEP) VGAIN_SEL = 00, 72 steps Rated output current IOUTmax ILMAX = 0, default 1000 ILMAX = 1 1500 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, ILMAX = 0 1150 VIN = VINmin to VINmax, ILMAX = 1 2200 Source current load: 1150 VIN = VINmin to VINmax, ILMAX = 0 2000 NMOS current limit (low-side) MAX mΩ 400 2 µA mΩ 400 2 µA mA VIN = VINmin to VINmax, ILMAX = 1 mA Sink current load: VIN = VINmin to VINmax, ILMAX = 0 1200 VIN = VINmin to VINmax, ILMAX = 1 2000 DC load regulation On mode, IOUT = 0 to IOUTmax 20 mV DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax 20 mV Transient load regulation VIN = 3.8 V, VOUT = 1.2 V 50 mV IOUT = 0 to 500 mA , Max slew = 100 mA/µs IOUT = 700 mA to 1.2 A , Max slew = 100 mA/µs t on, Off to on IOUT = 200 mA Output voltage transition rate From VOUT = 0.6 V to 1.5 V and VOUT = 1.5 V to 0.6 V IOUT = 500 mA Power-save mode ripple voltage 350 TSTEP[2:0] = 001 12.5 TSTEP[2:0] = 011 (default) 7.5 TSTEP[2:0] = 111 2.5 Pulse skipping mode, IOUT = 1 mA Overshoot µs µs 0.025 VOUT VPP 3% Switching frequency 3 Duty cycle MHz 100 Minimum On time P-Channel MOSFET Copyright © 2010–2012, Texas Instruments Incorporated 35 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 % ns 17 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VDD2 SMPS (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS VFB2 internal resistance Discharge resistor for power-down sequence RDIS Ground current (IQ) MIN TYP 0.5 1 30 Off PWM mode, IOUT = 0 mA, VIN = 3.8 V, VDD2_PSKIP = 0 Pulse skipping mode, no switching MAX UNIT MΩ 50 Ω 1 7500 78 µA Low-power (pulse skipping) mode, no switching ST[1:0] = 11 Conversion efficiency 63 PWM mode, DCRL < 50 mΩ, VOUT = 1.2 V, VIN = 3.6 V: IOUT = 10 mA 35% IOUT = 200 mA 82% IOUT = 400 mA 81% IOUT = 800 mA 74% IOUT = 1200 mA 66% IOUT = 1500 mA 62% Pulse skipping mode mode, DCRL < 50 mΩ, VOUT = 1.2 V, VIN = 3.6 V: IOUT = 1 mA 59% IOUT = 10 mA 70% IOUT = 200 mA 82% PWM mode, DCRL < 50 mΩ, VOUT = 3.3 V, VIN = 5 V: IOUT = 10 mA 44% IOUT = 200 mA 90% IOUT = 400 mA 91% IOUT = 800 mA 88% IOUT = 1200 mA 84% IOUT = 1500 mA 81% Pulse skipping mode mode, DCRL < 50 mΩ, VOUT = 3.3 V, VIN = 5 V: 18 IOUT = 1 mA 75% IOUT = 10 mA 83% IOUT = 200 mA 90% Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VDD3 SMPS over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS Input voltage VIN MIN MAX UNIT 5.5 V 5 5.25 3 DC output voltage (VOUT) 4.65 Rated output current IOUTmax 100 N-channel MOSFET TYP VIN = 3.6 V V mA 500 mΩ On-resistance RDS(ON)_NMOS N-channel MOSFET leakage current ILK_NMOS VIN = VINmax, SW3 = VINmax N-channel MOSFET DC current limit VIN = VINmin to VINmax, sink current load Turn-on inrush current VIN = VINmin to VINmax Ripple voltage 2 430 µA 550 mA 850 mA 20 mV DC load regulation On mode, IOUT = 0 to IOUTmax 100 mV DC line regulation On mode, VIN = VINmin to 5 V @ IOUT = IOUTmax 100 mV Turn-on time IOUT = 8 mA, VOUT = 0 to 4.4 V Overshoot 200 µs 3% Switching frequency VFB3 internal resistance Ground current (IQ) MHz MΩ Off IOUT = 0 mA to IOUTmax, VIN = 3.6 V Conversion efficiency 1 088 1 360 µA VIN = 3.6 V: IOUT = 10 mA 81% IOUT = 50 mA 85% IOUT = 100 mA 85% Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 19 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VDIG1 AND VDIG2 LDO over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCC6) VIN TEST CONDITIONS MIN TYP MAX UNIT VOUT (VDIG1) = 1.2 V @ 300 mA / 1.5 V @ 100 mA and VOUT (VDIG2) = 1.2 V / 1.1 V / 1.0 V @ 300 mA 1.7 5.5 VOUT (VDIG1) = 1.5 V and VOUT (VDIG2) = 1.8 V @ 200mA 2.1 5.5 VOUT (VDIG1) = 1.8 V and VOUT (VDIG2) = 1.8 V 2.7 5.5 VOUT (VDIG1) = 2.7 V 3.2 5 V VDIG1 DC output voltage VOUT Rated output current IOUTmax ON and Low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to IOUTmax –3% 2.7 +3% SEL = 10 IOUT = 0 to IOUTmax –3% 1.8 +3% SEL = 01 IOUT = 0 to 100 mA/IOUTmax –3% 1.5 +3% SEL = 00, IOUT = 0 to IOUTmax, VIN = VINmin to 4 V, default BOOT[1:0] = 00 or 01 –3% 1.2 +3% On mode 300 Low-power mode Dropout voltage VDO mA 1 Load current limitation (short-circuit On mode, VOUT = VOUTmin – 100 mV protection) 350 V 600 mA ON mode, VDO = VIN – VOUT VOUTtyp = 2.7 V, VIN = 2.8 V, IOUT = IOUTmax, T = 25°C 150 VOUTtyp = 1.5 V, VIN = 1.7 V, IOUT = IOUTmax, T = 25°C 300 mV DC load regulation On mode, IOUT = IOUTmax to 0 25 mV DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax 3 mV Transient load regulation ON mode, VIN = 3.8 V 10 mV 2 mV 100 µs 300 mA IOUT = 20 mA to 180 mA in 5µs and IOUT = 180 mA to 20 mA in 5 µs 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/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on inrush current Ripple rejection VIN = VINDC + 100 mVpp tone, VINDC+= 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VDIG1 internal resistance LDO off 400 Ground current On mode, IOUT = 0, VCC6 = VBAT, VOUT = 2.7 V 54 On mode, IOUT = 0, VCC6 = 1.8 V, VOUT = 1.2 V 67 On mode, IOUT = IOUTmax, VCC6 = VBAT, VOUT = 2.7 V 1870 On mode, IOUT = IOUTmax, VCC6 = 1.8 V, VOUT = 1.2 V 1300 Low-power mode, VCC6 = VBAT, VOUT = 2.7 V 13 Low-power mode, VCC6 = 1.8 V, VOUT = 1.2 V 10 Off mode dB Ω µA 1 VDIG2 DC output voltage VOUT 20 On and low-power mode, VIN = VINmin to VINmax Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VDIG1 AND VDIG2 LDO (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER Rated output current IOUTmax TEST CONDITIONS MIN TYP MAX SEL = 11, IOUT = 0 to IOUTmax –3% 1.8 +3% SEL = 10 IOUT = 0 to IOUTmax, VIN = VINmin to 4 V –3% 1.2 +3% SEL = 01 IOUT = 0 to 100 mA/IOUTmax, VIN= VINmin to 4 V –3% 1.1 +3% SEL = 00, IOUT = 0 to IOUTmax, VIN = VINmin to 4 V, default BOOT[1:0] = 00 or 01 –3% 1 +3% On mode 300 Low-power mode Load current limitation (short-circuit On mode, VOUT = VOUTmin – 100 mV protection) Dropout voltage VDO UNIT V mA 1 350 600 mA 250 mV ON mode, VDO = VIN – VOUT, VOUTtyp = 1.8 V, VIN = 2.1 V, IOUT=IOUTmax, T = 25°C DC load regulation On mode, IOUT = IOUTmax to 0 DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax Transient load regulation ON mode, VIN = 3.8 V 25 mV 3 mV 10 mV 2 mV IOUT = 20 mA to 180 mA in 5µs and IOUT = 180 mA to 20 mA in 5 µs 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/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on inrush current Ripple rejection 100 µs 300 mA VIN = VINDC + 100 mVpp tone, VINDC+= 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VDIG2 internal resistance LDO off 400 Ground current On mode, IOUT = 0, VCC6 = VBAT, VOUT = 1.8 V 52 On mode, IOUT = 0, VCC6 = 1.8 V, VOUT = 1.0 V 67 On mode, IOUT = IOUTmax, VCC6 = VBAT, VOUT = 1.8 V 1750 On mode, IOUT = IOUTmax, VCC6 = 1.8 V, VOUT = 1.0 V 1300 Low-power mode, VCC6 = VBAT, VOUT = 1.8 V 11 Low-power mode, VCC6 = 1.8 V, VOUT = 1.0 V 10 Off mode Copyright © 2010–2012, Texas Instruments Incorporated dB Ω µA 1 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 21 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VAUX33 AND VMMC LDO over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCC3) VIN TEST CONDITIONS MIN TYP MAX VOUT (VAUX33) = 1.8 V / 2 V and VOUT (VMMC) = 1.8 V 2.7 5.5 VOUT (VAUX33) = 2.8 V 3.2 5.5 VOUT (VAUX33) = 3.3 V 3.6 5.5 VOUT (VMMC) = 2.8 V @ 200 mA 3.2 5.5 VOUT (VMMC) = 3.0 V 3.6 5.5 VOUT (VMMC) = 3.3 V @ 200 mA 3.6 5.5 UNIT V VAUX33 DC output voltage VOUT Rated output current IOUTmax On and low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to IOUTmax, Default BOOT[1:0] = 01 –3% 3.3 +3% SEL = 10, IOUT = 0 to IOUTmax –3% 2.8 +3% SEL = 01, IOUT = 0 to IOUTmax –3% 2.0 +3% SEL = 00, IOUT = 0 to IOUTmax, default BOOT[1:0] = 00 –3% 1.8 +3% On mode 150 Low-power mode mA 1 Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV Dropout Voltage VDO On mode, VOUTtyp = 2.8 V, VDO = VIN – VOUT, 350 VIN = 2.9 V, IOUT = IOUTmax, T = 25°C V 500 mA 150 mV DC load regulation On mode, IOUT = IOUTmax to 0 20 mV DC line regulation On mode, IOUT = IOUTmax 3 mV Transient load regulation On mode, VIN = 3.8 V 12 mV 2 mV 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, 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/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on inrush current Ripple Rejection 100 µs 600 mA VIN = VINDC + 100 mVpp tone, VINDC+ = 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VAUX33 internal resistance LDO off 70 Ground current On mode, IOUT = 0 55 On mode, IOUT = IOUTmax dB Ω 1600 Low-power mode µA 15 Off mode 1 VMMC DC output voltage VOUT 22 On and low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to 200 mA, default BOOT[1:0] = 00 –3% 3.3 +3% SEL = 10, IOUT = 0 to IOUTmax –3% 3.0 +3% SEL = 01, IOUT = 0 to 200 mA –3% 2.8 +3% SEL = 00, IOUT = 0 to IOUTmax, default BOOT[1:0] = 01 –3% 1.8 +3% Submit Documentation Feedback V Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VAUX33 AND VMMC LDO (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER Rated output current IOUTmax TEST CONDITIONS On mode Low-power mode Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV Dropout voltage VDO Dropout voltage VDO VIN = 3.0 V, IOUT = 200 mA, T = 25°C DC load regulation On mode, IOUT = IOUTmax to 0 DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax Transient load regulation On mode, VIN = 3.8 V MIN TYP MAX UNIT 300 mA 1 350 500 mA 200 mV 25 mV 3 mV 12 mV 2 mV 100 µs IOUT = 20 mA to 180 mA in 5 µs and IOUT = 180 mA to 20 mA in 5 µs Transient line regulation On mode, IOUT = 200 mA, VIN = VINmin + 0.5 V to VINmin in 30 µs And VIN = VINmin to VINmin + 0.5 V in 30 µs, IOUT = IOUTmax/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Ripple rejection VIN = VINDC + 100 mVpp tone, VINDC+= 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VMMC internal resistance LDO Off 70 Ground current On mode, IOUT = 0 On mode, IOUT = IOUTmax Low-power mode Off mode Copyright © 2010–2012, Texas Instruments Incorporated dB Ω 55 2700 µA 15 1 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 23 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VAUX1 AND VAUX2 LDO over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCC4) VIN TEST CONDITIONS MIN TYP MAX VOUT (VAUX1) = 1.8 V and VOUT (AUX2) = 1.8 V 2.7 5.5 VOUT (VAUX1) = 2.5 V 3.2 5.5 VOUT (VAUX1) = 2.8 V @ Iload = 200 mA and 2.85 V @ Iload = 200mA 3.2 5.5 VOUT (VAUX2) = 2.8 V 3.2 5.5 VOUT (VAUX2) = 2.9 V @ Iload = 100mA 3.2 5.5 VOUT (VAUX2) = 3.3 V 3.6 5.5 UNIT V VAUX1 DC output voltage VOUT Rated output current IOUTmax On and low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to 200 mA –3% 2.85 +3% SEL = 10, IOUT = 0 to 200 mA –3% 2.8 +3% SEL = 01, IOUT = 0 to IOUTmax –3% 2.5 +3% SEL = 00, IOUT = 0 to IOUTmax, default BOOT[1:0] = 00 or 01 –3% 1.8 +3% On mode 300 Low-power mode mA 1 Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV Dropout voltage VDO On mode, VOUTtyp = 2.8 V, VDO = VIN – VOUT, 350 VIN = 3.0 V, IOUT = 200 mA, T = 25°C V 500 mA 200 mV DC load regulation On mode, IOUT = 200 mA to 0 15 mA DC line regulation On mode, IOUT = 200 mA 5 V Transient load regulation On mode, VIN = 3.8 V, IOUT = 20 mA to 180 mA in 5 µs 15 mV 2 mV and IOUT = 180 mA to 20 mA in 5µs Transient line regulation On mode, IOUT = 200 mA, VIN= VINmin + 0.5 V to VINmin in 30 µs and VIN = VINmin to VINmin + 0.5v in 30 µs, IOUT = IOUTmax/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin, no load Turn-on inrush current Ripple Rejection 100 µs 600 mA VIN = VINDC + 100 mVpp tone, VINDC+ = 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VAUX1 internal resistance LDO Off 80 Ground current On mode, IOUT = 0 60 On mode, IOUT = IOUTmax dB Ω 2700 Low-power mode µA 12 Off mode 1 VAUX2 On and low-power mode, VIN = VINmin to VINmax Rated output current IOUTmax SEL = 11, IOUT = 0 to IOUTmax –3% 3.3 +3% SEL = 10, IOUT = 0 to 100 mA –3% 2.9 +3% SEL = 01, IOUT = 0 to IOUTmax –3% 2.8 +3% SEL = 00, IOUT = 0 to IOUTmax, default BOOT[1:0] = 00 or 01 –3% 1.8 +3% On mode 150 Low-power mode 24 Submit Documentation Feedback 1 V mA Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VAUX1 AND VAUX2 LDO (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV 350 500 mA Dropout voltage VDO On mode, VOUTtyp = 2.8 V, VDO = VIN – VOUT 150 mV VIN = 2.9 V, IOUT = IOUTmax, T = 25°C DC load regulation On mode, IOUT = IOUTmax to 0 15 mV DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax 2 mV Transient load regulation On mode, VIN = 3.8 V, IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5µs 12 mV 2 mV 100 µs 600 mA And IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5us Transient line regulation On mode, 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/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on Inrush current Ripple rejection VIN = VINDC + 100 mVpp tone, VINDC+ = 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VAUX2 internal resistance LDO off 80 Ground current On mode, IOUT = 0 60 On mode, IOUT = IOUTmax Low-power mode Off mode Copyright © 2010–2012, Texas Instruments Incorporated dB Ω 1600 µA 12 1 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 25 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VDAC AND VPLL LDO over operating free-air temperature range (unless otherwise noted) PARAMETER Input voltage (VCC5) VIN TEST CONDITIONS MIN TYP MAX VOUT(VDAC) = 1.8 V and VOUT(VPLL) = 1.8 V / 1.1 V / 1.0 V 2.7 5.5 VOUT(VDAC) = 2.6 V and VOUT(VPLL) = 2.5 V 3.0 5.5 VOUT(VDAC) = 2.8 V / 2.85 V 3.2 5.5 UNIT V VDAC DC Output voltage VOUT Rated output current IOUTmax On and low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to IOUTmax –3% 2.85 +3% SEL = 10, IOUT = 0 to IOUTmax –3% 2.8 +3% SEL = 01, IOUT = 0 to IOUTmax –3% 2.6 +3% SEL = 00, IOUT = 0 to IOUTmax, default BOOT[1:0] = 00 or 01 –3% 1.8 +3% On mode 150 Low-power mode mA 1 Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV Dropout Voltage VDO On mode, VOUTtyp = 2.8 V, VDO = VIN – VOUT, 350 V 500 mA 150 mV VIN = 2.9 V, IOUT = IOUTmax, T = 25°C DC load regulation On mode, VOUT = VOUTmin – 100 mV 15 mV DC line regulation On mode, VOUT = 1.8 V, IOUT = IOUTmax 2 mV Transient load regulation On mode, VIN = 3.8 V, IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs 15 mV 0.5 mV And IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs Transient line regulation On mode, 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/2 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on Inrush current Ripple Rejection 100 µs 600 mA VIN = VINDC + 100 mVpp tone, VINDC+ = 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VDAC internal resistance LDO off 360 Ground current On mode, IOUT = 0 60 On mode, IOUT = IOUTmax dB kΩ 1600 Low-power mode µA 12 Off mode 1 VPLL DC output voltage VOUT Rated output current IOUTmax On and low-power mode, VIN = VINmin to VINmax SEL = 11, IOUT = 0 to IOUTmax –3% 2.5 +3% SEL = 10, IOUT = 0 to IOUTmax, default BOOT[1:0 = 00 or 01 –3% 1.8 +3% SEL = 01, IOUT = 0 to IOUTmax –3% 1.1 +3% SEL = 00, IOUT = 0 to IOUTmax –3% 1.0 +3% On mode 50 Low-power mode 1 Load current limitation (shortcircuit protection) On mode, VOUT = VOUTmin – 100 mV Dropout voltage VDO On mode, VOUTtyp = 2.5 V, VDO = VIN – VOUT, 26 Submit Documentation Feedback 200 V mA 400 mA 100 mV Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VDAC AND VPLL LDO (continued) over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT VIN = 2.5 V, IOUT = IOUTmax, T = 25°C DC load regulation On mode, IOUT = IOUTmax to 0 10 mV DC line regulation On mode, VIN = VINmin to VINmax @ IOUT = IOUTmax 1 mV Transient load regulation On mode, VIN = 3.8 V, IOUT = 0.1 × IOUTmax to 0.9 × IOUTmax in 5 µs 9 mV 0.5 mV And IOUT = 0.9 × IOUTmax to 0.1 × IOUTmax in 5 µs 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 Turn-on time IOUT = 0, @ VOUT = 0.1 V up to VOUTmin Turn-on inrush current Ripple rejection 100 µs 300 mA VIN = VINDC + 100 mVpp tone, VINDC+ = 3.8 V, IOUT = IOUTmax/2 f = 217 Hz 70 f = 50 kHz 40 VPLL internal resistance LDO off 535 Ground current On mode, IOUT = 0 60 On mode, IOUT = IOUTmax dB kΩ 1600 Low-power mode µA 12 Off mode 1 SWITCH-ON/-OFF SEQUENCES AND TIMING Time slot length can be selected to be 0.5 ms or 2 ms through the EEPROM for an OFF-to-ACTIVE transition or through the value programmed in the register DEVCTRL2_REG for a SLEEP-to-ACTIVE transition. BOOT1 = 0, BOOT0 = 0 Table 2 provides details about the EEPROM setting for the BOOT modes. The power-up sequence for this boot mode is provided in Figure 2. Table 2. Fixed Boot Mode: 00 Register VDD1_OP_REG VDD1_REG Bit SEL VGAIN_SEL EEPROM Description TPS65910 Boot 00 VDD1 voltage level selection for boot 1.2 V VDD1 Gain selection, x1 or x2 x1 VDD1 time slot selection DCDCCTRL_REG VDD2_OP_REG/VDD2_SR_REG VDD2_REG VDD1_PSKIP SEL VGAIN_SEL EEPROM VDD1 pulse skip mode enable 3 skip enabled VDD2 voltage level selection for boot 1.1 V VDD2 Gain selection, x1 or x3 x3 VDD2 time slot selection DCDCCTRL_REG VIO_REG VDD2_PSKIP SEL EEPROM VDD2 pulse skip mode enable 2 skip enabled VIO voltage selection 1.8 V VIO time slot selection DCDCCTRL_REG VIO_PSKIP EEPROM VDIG1_REG SEL EEPROM VDIG2_REG SEL Copyright © 2010–2012, Texas Instruments Incorporated VIO pulse skip mode enable 1 skip enabled VDD3 time slot OFF LDO voltage selection 1.2 V LDO time slot OFF LDO voltage selection 1.0 V Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 27 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com SWITCH-ON/-OFF SEQUENCES AND TIMING (continued) Table 2. Fixed Boot Mode: 00 (continued) EEPROM VDAC_REG SEL EEPROM LDO time slot OFF LDO voltage selection 1.8 V LDO time slot VPLL_REG SEL EEPROM 5 LDO voltage selection 1.8 V LDO time slot VAUX1_REG SEL EEPROM 4 LDO voltage selection 1.8 V LDO time slot VMMC_REG SEL EEPROM 1 LDO voltage selection 3.3 V LDO time slot VAUX33_REG SEL EEPROM VAUX2_REG SEL LDO voltage selection OFF LDO voltage selection 1.8 V LDO time slot CLK32KOUT pin CLK32KOUT time slot NRESPWRON pin NRESPWRON time slot VRTC_OFFMAS K DEVCTRL_REG RTC_PWDN DEVCTRL_REG CK32K_CTRL DEVCTRL2_REG DEVCTRL2_REG INT_MSK_REG 1.8 V LDO time slot EEPROM VRTC_REG 6 5 7 7+1 0: VRTC LDO will be in low-power mode during OFF state 1: VRC LDO will be in full-power mode during OFF state 0: RTC in normal power mode 28 Submit Documentation Feedback 1 1: Clock gating of RTC register and logic, low-power mode 0: Clock source is crystal/external clock RC 1: Clock source is internal RC oscillator Boot sequence time slot duration: TSLOT_LENGTH 0: 0.5 ms [0] 1: 2 ms IT_POL VMBHI_IT_MSK 0: INT1 signal will be active-low 1: INT1 signal will be active-high 0: Device will automatically switch-on at NOSUPPLY to OFF or BACKUP to OFF transition 1: Startup reason required before switch-on VMBCH_REG Low-power mode VMBCH_SEL[1:0] 2 ms Active-low 0: Automatic switch-on from supply insertion Select threshold for main battery comparator threshold VMBCH. 3V Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Figure 2 shows the 00 Boot mode timing characteristics. tdSOFF2 PWRHOLD tdSON1 1.8 V VIO/VFBIO VAUX1 1.8 V tdSON2 VDD2/VFB2 3.3 V tdSON3 1.2 V VDD1/VFB1 tdSON4 1.8 V VPLL tdSON5 VDAC 1.8 V VAUX2 1.8 V tdSON6 3.3 V VMMC tdSON7 tdSOFF1 CLK32KOUT tdSON8 NRESPWRON tdSONT: Switch-on sequence Switch-off sequence SWCS046-018 Figure 2. Boot Mode: BOOT1 = 0, BOOT0 = 0 Table 3 lists the 00 Boot mode timing characteristics. Table 3. Boot Mode: BOOT1 = 0, BOOT0 = 0 Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP MAX UNIT tdSON1 PWRHOLD rising edge to VIO, VAUX1 enable delay 66 × tCK32k = 2060 µs tdSON2 VIO to VDD2 enable delay 64 × tCK32k = 2000 µs tdSON3 VDD2 to VDD1 enable delay 64 × tCK32k = 2000 µs tdSON4 VDD1 to VPLL enable delay 64 × tCK32k = 2000 µs tdSON5 VPLL to VDAC,VAUX2 enable delay 64 × tCK32k = 2000 µs tdSON6 VDAC to VMMC enable delay 64 × tCK32k = 2000 µs VMMC to CLK32KOUT rising edge delay 64 × tCK32k = 2000 µs 64 × tCK32k = 2000 µs 16 ms tdSON8 CLK32KOUT to NRESPWRON rising edge delay tdSONT Total switch-on delay tdSOFF1 PWRHOLD falling edge to NRESPWRON falling edge delay 2 × tCK32k = 62.5 µs tdSOFF1B NRESPWRON falling edge to CLK32KOUT low delay 3 × tCK32k = 92 µs tdSOFF2 PWRHOLD falling edge to supplies and reference disable delay 5 × tCK32k = 154 µs Registers default setting: CK32K_CTRL = 1 (32-kHz RC oscillator is used), RTC_PWDN = 1 (RTC domain off), IT_POL = 0 (INt2 interrupt flag active low), VMBHI_IT_MSK = 0 (automatic switch-on on Battery plug), VMBCH_SEL = 11. BOOT1 = 0, BOOT0 = 1 Table 4 provides details about the EEPROM setting for the BOOT modes. The power-up sequence for this boot mode is provided in Figure 3. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 29 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 4. Fixed Boot Mode: 01 Register VDD1_OP_REG VDD1_REG Bit SEL VGAIN_SEL EEPROM Description VDD1 voltage level selection for boot 1.2 V VDD1 Gain selection, x1 or x2 x1 VDD1 time slot selection DCDCCTRL_REG VDD2_OP_REG/VDD2_SR_REG VDD2_REG VDD1_PSKIP SEL VGAIN_SEL EEPROM DCDCCTRL_REG VIO_REG VDD2_PSKIP SEL EEPROM 3 VDD1 pulse skip mode enable Skip enabled VDD2 voltage level selection for boot 1.2 V VDD2 Gain selection, x1 or x3 x1 VDD2 time slot selection 4 VDD2 pulse skip mode enable Skip enabled VIO voltage selection 1.8 V VIO time slot selection DCDCCTRL_REG VIO_PSKIP EEPROM VDIG1_REG SEL EEPROM VDIG2_REG SEL EEPROM VDAC_REG SEL EEPROM VPLL_REG SEL EEPROM 1 VIO pulse skip mode enable Skip enabled VDD3 time slot OFF LDO voltage selection 1.2 V LDO time slot OFF LDO voltage selection 1.0 V LDO time slot OFF LDO voltage selection 1.8 V LDO time slot OFF LDO voltage selection 1.8 V LDO time slot VAUX1_REG SEL EEPROM VMMC_REG SEL EEPROM VAUX33_REG SEL EEPROM 2 LDO voltage selection 1.8 V LDO time slot OFF LDO voltage selection 1.8 V LDO time slot OFF LDO voltage selection 3.3 V LDO time slot VAUX2_REG SEL LDO time slot CLK32KOUT pin CLK32KOUT time slot NRESPWRON pin NRESPWRON time slot VRTC_OFFMAS K VRTC_REG DEVCTRL_REG RTC_PWDN DEVCTRL_REG CK32K_CTRL DEVCTRL2_REG DEVCTRL2_REG INT_MSK_REG 6 LDO voltage selection EEPROM 1.8 V 5 7 7+1 0: VRTC LDO will be in low-power mode during OFF state 1: VRC LDO will be in full-power mode during OFF state VMBCH_REG Submit Documentation Feedback low-power mode 0: RTC in normal power mode 1 1: Clock gating of RTC register and logic, low-power mode 0: Clock source is crystal/external clock Crystal 1: Clock source is internal RC oscillator Boot sequence time slot duration: TSLOT_LENGTH 0: 0.5 ms [0] 1: 2 ms IT_POL VMBHI_IT_MSK 0: INT1 signal will be active-low 1: INT1 signal will be active-high 0: Device will automatically switch-on at NOSUPPLY to OFF or BACKUP to OFF transition 1: Startup reason required before switch-on 30 TPS65910 Boot 01 VMBCH_SEL[1:0] 2 ms Active-low 0: Automatic switch-on from supply insertion Select threshold for main battery comparator threshold VMBCH. 3V Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Figure 3 shows the 01 Boot mode timing characteristics. tdSOFF2 PWRHOLD tdSON1 VIO/VFBIO 1.8 V tdSON2 VPLL 1.8 V tdSON3 1.2 V VDD1/VFB1 tdSON4 1.2 V VDD2/VFB2 tdSON5 VAUX2 1.8 V tdSON6 VAUX33 3.3 V tdSON7 tdSOFF1 CLK32KOUT tdSON8 NRESPWRON tdSONT: Switch-on sequence Switch-off sequence SWCS046-019 Figure 3. Boot Mode: BOOT1 = 0, BOOT0 = 1 Table 5 lists the 01 Boot mode timing characteristics. Table 5. Boot Mode: BOOT1 = 0, BOOT0 = 1 Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP MAX UNIT tdSON1 PWRHOLD rising edge to VIO enable delay 66 × tCK32k = 2060 µs tdSON2 VIO to VPLL enable delay 64 × tCK32k = 2000 µs tdSON3 VPLL to VDD1 enable delay 64 × tCK32k = 2000 µs tdSON4 VDD1 to VDD2 enable delay 64 × tCK32k = 2000 µs tdSON5 VDD2 to VAUX2 enable delay 64 × tCK32k = 2000 µs VAUX2 to VAUX33 enable delay 64 × tCK32k = 2000 µs tdSON7 VAUX33 to CLK32KOUT enable delay 64 × tCK32k = 2000 µs tdSON8 CLK32KOUT to NRESPWRON enable delay 64 × tCK32k = 2000 µs tdSONT Total switch-on delay 16 ms tdSOFF1 PWRHOLD falling edge to NRESPWRON falling edge 2 × tCK32k = 62.5 µs tdSOFF1B NRESPWRON falling edge to CLK32KOUT low delay 3 × tCK32k = 92 µs tdSOFF2 PWRHOLD falling edge to supplies disable delay 5 × tCK32k = 154 µs Registers default setting: CK32K_CTRL = 0 (32-kHz quartz or external bypass clock is used), RTC_PWDN = 1 (RTC domain off), IT_POL = 0 (INt2 interrupt flag active low), VMBHI_IT_MSK = 0 (automatic switch-on on battery plug), VMBCH_SEL = 11. POWER CONTROL TIMING Device Turn-On/Off With Rising/Falling Input Voltage Figure 4 shows the device turn-on/-off with rising/falling input voltage. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 31 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com POWER CONTROL TIMING (continued) VMBCH threshold VMBDCH threshold VMBLO threshold VMBHI threshold VBNPR threshold VCC7 VRTC 1.8V VBACKUP > VBNPR VIO 1.8V CLK33KOUT t dOINT1 NRESPWRON t dbVMBLO (1) Interrupt aknowledge INT1 t dbVMBDCH VMBHI_IT=1 PWRHOLD t d32KON t dbVMBHI t dSONT Switch-on sequence Switch-off sequence t dONVMBHI SWCS046-022 NOTE: (1) The DEV_ON control bit (set to 1) or the PWRHOLD signal (set high) can be used to maintain supplies on after the switch-on sequence. If none of these devce Power On enable conditions is set, the supplies will be turned off after tdOINT1 delay. Figure 4. Device Turn-On/Off with Rising/Falling Input Voltage Device State Control Through PWRON Signal Figure 5 shows the device state control through PWRON signal. PWRON VIO 1.8 V CLK33KOUT t dOINT1 NRESPWRON (1) Interrupt acknowledge INT1 PWRON_IT=1 Interrupt acknowledge PWRON_IT=1 PWRHOLD t dbPWRHOLDF t dbPWRONF t dSONT Switch-on sequence t dONPWHOLD t dbPWRONF Switch-off sequence SWCS046-009 NOTE: (1) The DEV_ON control bit (set to 1) or the PWRHOLD signal (set high) can be used to maintain supplies on after switch-on sequence, If none of these device POWER ON enable condition is set the supplies will be turned off after TdOINT1 delay. Figure 5. PWRON Turn-On/Turn-Off Figure 6 shows the long-press turn-off timing characteristics. 32 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 POWER CONTROL TIMING (continued) PWRON VIO NRESPWRON INT1 PWRON_IT=1 PWRON_LP_IT=1 PWRON_IT=1 PWRHOLD t dPWRONLP Switch-off sequence t dPWRONLPTO t dbPWRONF SWCS046-010 NOTE: If the DEV_ON control bit is set to 1 or PWRHOLD is kept high, the device will be turned on again after PWRON long press turn-off and PWRON released. Figure 6. PWRON Long-Press Turn-Off Table 6 lists the power control timing characteristics. Table 6. Power Control Timing Characteristics PARAMETER td32KON: 32-kHz Oscillator turn-on time TEST CONDITIONS MIN TYP BOOT[1:0] = 00, RC oscillator 0.1 BOOT[1:0] = 01, Quartz oscillator 400 BOOT[1:0] = 01, Bypass clock MAX UNIT 2000 ms 4 × tCK32k = 125 µs 0.1 3× tdbVMBHI: VMBHI rising-edge debouncing delay tCK32k = 94 tdbVMBDCH: Main Battery voltage = VMBDCH threshold to INT1 falling-edge 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 500 550 µs 4 × tCK32k = 125 µs 3× tCK32k= 94 µs tdbPWRONF: PWRON falling-edge debouncing delay 3× tdbPWRONR: PWRON rising-edge debouncing delay tCK32k= 94 tdbPWRHOLD: PWRON rising-edge debouncing delay 2× tCK32k = 63 tdOINT: INT1 (internal) Power-on pulse duration after PWRON low-level (debounced) event tdONPWHOLD: delay to set high PWRHOLD signal or DEV_ON control bit after NRESPWRON released to keep on the supplies 1 s 984 ms tdPWRONLP: PWRON long-press delay to interrupt PWRON falling edge to PWON_LP_IT = 1 6 s tdPWRONLPTO: PWRON long-press delay to turn-off PWRON falling edge to NRESPWRON falling edge 8 s Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 33 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Device SLEEP State Control Figure 7 shows the device SLEEP state control timing characteristics. tACT2SLP tSLP2ACT SLEEP 1.8 V PWM mode 1.8 V Low-power mode 1.8 V PWM mode 1.8 V Active mode 1.8 V Low-power mode 1.8 V Active mode 3.3 V Pulse skip mode 3.3 V Low-power mode 3.3 V Pulse skip mode VIO/VFBIO SWIO VAUX1 VDD2/VFB2 SW2 1.2 V PWM mode Off VPLL 1.8 V Active mode Off VDAC 1.8 V Active mode Off VAUX2 1.8 V Active mode 1.8 V Active mode VMMC 3.3 V Active mode 3.3 V Low-power mode VDD1/VFB1 tdONDCDCSLP 1.2 V PWM mode SW1 1.8 V Active mode 1.8 V Active mode 1.8 V Active mode 3.3 V Active mode tSLP2ACTCK32K CLK32KOUT tACT2SLPCK32K tdSLPON1 tdSLPONST tdSLPONST SWCS046-024 NOTE: Registers programming: VIO_PSKIP = 0, VDD1_PSKIP = 0, VDD1_SETOFF = 1, VDAC_SETOFF = 1, VPLL_SETOFF = 1, VAUX2_KEEPON = 1 Figure 7. Device SLEEP State Control Table 7. Device SLEEP State Control Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 3 × tCK32k = 94 µs 188 µs 9 × tCK32k = 281 µs tACT2SLP SLEEP falling edge to supply in low power mode (SLEEP resynchronization delay) tACT2SLP SLEEP falling edge to CLK32KOUT low tSLP2ACT SLEEP rising edge to supply in high power mode 8 × tCK32k = 250 tSLP2ACTCK32K SLEEP rising edge to CLK32KOUT running 344 tSLP2ACT + 3 × tCK32k 375 µs tdSLPON1 SLEEP rising edge to time step 1 of the tun-on sequence from SLEEP state 281 tSLP2ACT + 1 × tCK32k 312 µs 2 × tCK32k = 62 tACT2SLP + 3 × tCK32k 156 turn-on sequence step duration, from SLEEP state tdSLPONST tdSLPONDCDC 34 TSLOT_LENGTH[1:0] = 00 0 TSLOT_LENGTH[1:0] = 01 200 TSLOT_LENGTH[1:0] = 10 500 TSLOT_LENGTH[1:0] = 11 2000 VDD1, VDD2 or VIO tun-on delay from tun-on sequence time step Submit Documentation Feedback 2 × tCK32k = 62 µs us Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Power Supplies State Control Through the SCLSR_EN1 and SDASR_EN2 Signals Figure 8 andFigure 9 show the power supplies state control through the SCLSR_EN1 and SDASR_EN2 signals timing characteristics. Switch-on sequence Switch-off sequence Device on NRESPWRON tdEN SCLSR_EN1 tdVEN VDIG1 tdEN 1.2 V tdSOFF2 tdEN SCLSR_EN2 VPLL tdEN Low-power mode 1.8 V SWCS046-016 NOTE: Register setting: VDIG1_EN1 = 1, VPLL_EN2 = 1, and VPLL_KEEPON = 1 Figure 8. LDO Type Supplies State Control Through SCLSR_EN1 and SCLSR_EN2 Switch-on sequence Switch-off sequence Device on NRESPWRON tdEN SCLSR_EN2 VDD2/VFB2 tdOEN tdVDDEN tdVDDEN 0V 3.3 V tdSOFF2 SCLSR_EN1 VDD1/VFB1 1.2 V PWM mode tdEN tdEN Low-power mode PFM (pulse skipping) mode SW1 SWCS046-017 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 9. VDD1 and VDD2 Supplies State Control Through SCLSR_EN1 and SCLSR_EN2 Table 8. Supplies State Control Though SCLSR_EN1 and SCLSR_EN2 Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP MAX UNIT tdEN: NREPSWON to supply state change delay, SCLSR_EN1 or SCLSR_EN2 driven 0 ms tdEN: SCLSR_EN1 or SCLSR_EN2 edge to supply state change delay 1 × tCK32k = 31 µs tdVDDEN: SCLSR_EN1 or SCLSR_EN2 edge to VDD1 or VDD2 dc-dc turn on delay 3 × tCK32k = 63 µs Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 35 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com VDD1 and VDD2 Voltage Control Through SCLSR_EN1 and SDASR_EN2 Signals Figure 10 shows the VDD1 and VDD2 voltage control through the SCLSR_EN1 and SDASR_EN2 signals timing characteristics. SCLSR_EN2 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 SWCS046-021 NOTE: Register setting: VDD1_EN1 = 1, SEL[6:0] = hex13 in VDD1_SR_REG Figure 10. VDD1 Supply Voltage Control Though SCLSR_EN1 Table 9. VDD1 Supply Voltage Control Through SCLSR_EN1 Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP tdDVSEN: SCLSR_EN1 or SCLSR_EN2 edge to VDD1 or VDD2 voltage change delay tdDVSENL: VDD1 or VDD2 voltage settling delay MAX UNIT 2 × tCK32k = 62 µs 32 µs TSTEP[2:0] = 001 TSTEP[2:0] = 011 (default) 0.4/7.5 = 53 TSTEP[2:0] = 111 160 SMPS Switching Synchronization Figure 11 shows the SMPS switching synchronization timing characteristics. SWIO SW1 tdswio2sw1 tdviosync tdswio2sw2 SW2 tdswio2sw3 SW3 SWCS046-025 NOTE: VDD1 or VDD2 switching synchronization is available in PWM mode (VDD1_PSKIP = 0 or VDD2_PSKIP = 0). SMPS external clock (GPIO_CKSYNC) synchronization is available when VIO PWM mode is set (VIO_PSKIP = 0). Figure 11. SMPS Switching Synchronization Table 10. SMPS Switching Synchronization Timing Characteristics PARAMETER TEST CONDITIONS MIN TYP MAX UNIT VDD1_PSKIP = 0, tdSWIO2SW1: delay from SWIO rising edge to SW1 rising edge DCDCCKSYNC[1:0] = 11 160 DCDCCKSYNC[1:0] = 01 220 ns VDD2_PSKIP = 0, tdSWIO2SW2: delay from SWIO rising edge to SW1 rising edge 36 Submit Documentation Feedback DCDCCKSYNC[1:0] = 11 160 DCDCCKSYNC[1:0] = 01 290 ns Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 10. SMPS Switching Synchronization Timing Characteristics (continued) PARAMETER tdSWIO2SW3: delay from SWIO rising edge to SW3 rising edge Copyright © 2010–2012, Texas Instruments Incorporated TEST CONDITIONS MIN TYP MAX 206 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 UNIT ns 37 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com DEVICE INFORMATION Table 11. Terminal Functions NAME QFN PIN VDDIO SUPPLIES TYPE I/O VDDIO/DGND Power I DESCRIPTION PU/PD Digital I/Os supply No SDA_SDI VDDIO/DGND Digital I/O I2C bidirectional data signal/serial peripheral interface data input (multiplexed) SCL_SCK VDDIO/DGND Digital I/O I2C bidirectional clock signal/serial peripheral interface Clock Input (multiplexed) External PU SDASR_EN2 VDDIO/DGND Digital I/O I2C SmartReflex bidirectional data signal/enable of supplies (multiplexed) External PU SCLSR_EN1 VDDIO/DGND Digital I/O I2C SmartReflex bidirectional clock signal/enable of supplies (multiplexed) External PU SLEEP VDDIO/DGND Digital I Active-sleep state transition control signal Programmable PD (default active) GPIO_CKSYNC VDDIO/DGND Digital I/O Configurable general-purpose I/O or DC-DCs synchronization clock input signal Programmable PD (default active) PWRHOLD VRTC/DGND Digital I Switch-on/-off control signal Programmable PD (default active) PWRON VBAT/DGND Digital I External switch-on control (ON button) Programmable PU (default active) NRESPWRON VDDIO/DGND Digital O Power off reset PD active during device OFF state INT1 VDDIO/DGND Digital O Interrupt flag External PU No BOOT0 VRTC/DGND Digital I Power-up sequence selection Programmable PD (default active) BOOT1 VRTC/DGND Digital I Power-up sequence selection Programmable PD (default active) CLK32KOUT VDDIO/DGND Digital O 32-kHz clock output PD disable in ACTIVE or SLEEP state OSC32KIN VRTC/REFGND Analog I 32-kHz crystal oscillator No OSC32KOUT VRTC/REFGND Analog I 32-kHz crystal oscillator No VREF VCC7/REFGND Analog O Bandgap voltage No REFGND Analog I/O Reference ground No VCC7/AGND Analog O Analog test output (DFT) No VBACKUP/AGND Power I Backup battery input (short to VCC5 if not used) No VCC1 VCC1/GND1 Power I VDD1 dc-dc power input No GND1 VCC1/GND1 Power I/O VDD1 dc-dc power ground No SW1 VCC1/GND1 Power O VDD1 dc-dc switched output No VFB1 VCC7/AGND Analog I VDD1 feedback voltage PD VCC2 VCC2/GND2 Power I VDD2 dc-dc power input No GND2 VCC2/GND2 Power I/O VDD2 dc-dc power ground No SW2 VCC2/GND2 Power O VDD2 dc-dc switched output No VFB2 VCC4/AGND2 Analog I VDD2 dc-dc feedback voltage PD VCCIO VCCIO/GNDIO Power I VIO dc-dc power input No GNDIO VCCIO/GNDIO Power I/O VIO dc-dc power ground No SWIO VCCIO/GNDIO Power O VIO dc-dc switched output No VFBIO VCC7/AGND Analog I VIO feedback voltage PD VCC3 VCC3/AGND2 Power I VMMC VAUX33 power input No VMMC VCC3/REFGND Power O LDO regulator output PD REFGND TESTV VBACKUP 38 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 11. Terminal Functions (continued) NAME QFN PIN VAUX33 VCC4 SUPPLIES TYPE VCC3/REFGND Power I/O DESCRIPTION O LDO regulator output, VDD3 internal regulated supply PU/PD PD VCC4/AGND2 Power I VAUX1, VAUX2 power input No VAUX1 VCC4/REFGND Power O LDO regulator output PD VAUX2 PD VCC4/REFGND Power O LDO regulator output VCC5 VCC5/AGND Power I VDAC, VPLL power input No VDAC VCC5/REFGND Power O LDO regulator output PD VPLL VCC5/REFGND Power O LDO regulator output PD VRTC VCC7/REFGND Power O LDO regulator output PD VCC6 VCC6/AGND2 Power I VDIG1, VDIG2 power input No VDIG1 VCC6/REFGND Power O LDO regulator output No VDIG2 VCC6/REFGND Power O LDO regulator output No I VRTC power input, VDD3 internal and analog references supply No VCC7 VCC7/REFGND Power VFB3 VCC7/AGND Analog I VDD3 feedback voltage No SW3 VCC7/GND3 Power O VDD3 dc-dc switched output No GND3 Power PAD AGND Power I/O VDD3 dc-dc power ground No AGND Power PAD AGND Power I/O Analog ground No AGND2 Power PAD AGND Power I/O Analog ground No DGND Power PAD DGND Power I/O Digital ground No Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 39 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com 25 TESTV 26 BOOT0 27 VBACKUP 28 VCC7 29 VRRTC 30 VFB3 31 SW3 32 VFB1 33 PWRON 34 GND1 35 SW1 36 VCC1 PIN ASSIGNMENT (TOP VIEW) SLEEP 37 24 VPLL CLK32KOUT 38 23 VCC5 GPIO/CKSYN 39 22 VDAC 21 OSC32KOUT NRESPWRON 40 20 OSC32KIN VCC2 41 19 BOOT1 SW2 42 PowerPad GND2 43 18 VREF VFB2 44 17 REFGND INT1 45 16 VFBIO VAUX1 46 15 GNDIO VDDIO 12 SCLSR/EN1 11 SDASR/EN2 10 SCL 9 SDA 8 VDIG1 7 VCC6 6 VDIG2 5 VAUX33 4 13 VCCIO VCC3 3 VAUX2 48 VMMC 2 14 SWIO PWRHOLD 1 VCC4 47 SWCS046-004 Figure 12. 48-QFN Top View Pin Assignment 40 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 DETAILED DESCRIPTION POWER REFERENCE The bandgap voltage reference is filtered by using an external capacitor connected across the VREF output and the analog ground REFGND (see RECOMMENDED OPERATING CONDITIONS, Recommended Operating Conditions). The VREF voltage is distributed and buffered inside the device. POWER SOURCES The power resources provided by the TPS65910 device include inductor-based switched mode power supplies (SMPS) and linear low drop-out voltage regulators (LDOs). These supply resources provide the required power to the external processor cores and external components, and to modules embedded in the TPS65910 device. Two of these SMPS have DVS capability SmartReflex Class 3 compatible. These SMPS provide independent core voltage domains to the host processor. The remaining SMPS provides supply voltage for the host processor I/Os. Table 12 lists the power sources provided by the TPS65910 device. Table 12. Power Sources RESOURCE TYPE VOLTAGES POWER VIO SMPS 1.5 V / 1.8 V / 2.5 V / 3.3 V 1000 mA VDD1 SMPS 0.6 ... 1.5 in 12.5-mV steps 1500 mA Programmable multiplication factor: x2, x3 VDD2 SMPS 0.6 ... 1.5 in 12.5-mV steps 1500 mA Programmable multiplication factor: x2, x3 VDD3 SMPS 5V 100 mA VDIG1 VDIG2 LDO 1.2 V, 1.5 V, 1.8 V, 2.7 V 300 mA LDO 1 V, 1.1 V, 1.2 V, 1.8 V 300 mA VPLL LDO 1.0 V, 1.1 V, 1.8 V, 2.5 V 50 mA VDAC LDO 1.8 V, 2.6 V, 2.8 V, 2.85 V 150 mA VAUX1 LDO 1.8 V, 2.5 V, 2.8 V, 2.85 V 300 mA VAUX2 LDO 1.8 V, 2.8 V, 2.9 V, 3.3 V 150 mA VAUX33 LDO 1.8 V, 2.0 V, 2.8 V, 3.3 V 150 mA VMMC LDO 1.8 V, 2.8 V, 3.0 V, 3.3 V 300 mA EMBEDED POWER CONTROLLER The embedded power controller manages the state of the device and controls the power-up sequence. STATE-MACHINE The EPC supports the following states: No supply: The main 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 main 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 32-K oscillator and RTC module are operating (if enabled). All other resources are off or under reset. Off: The main battery supply voltage is high enough to start the power-up sequence but device power on is not enabled. All power supplies are in 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. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 41 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Figure 13 shows the transitions of the state-machine. PWRHOLD NRESPWRON Pulse generator INT1 DEV_ON POWER ON enable tDOINT PWRON PWRON_LP_IT tD THERM_TS DEV_OFF NO SUPPLY DEV_OFF_RST SLEEPSIG_POL MB and BB<VBNPR SLEEP SLEEP enable DEV_SLP INT1 MB>VMBHI MB<VMBLO MB and BB<VBNPR OFF MB>VMBHI MB and BB<VBNPR POWER ON enabled and MB>VMBCH POWER ON disabled Backup MB or BB>VBNPR and MB<VMBLO ACTIVE POWER ON disabled MB<VMBLO SLEEP enabled SLEEP disabled MB: Main battery voltage BB: Backup battery voltage MB<VMBLO SLEEP SWCS046-011 Figure 13. Embebded Power Control State-Machine Device power-on enable conditions: If none of the device power-on disable conditions is met, the following conditions are available to turn on and/or maintain the ON state of the device: • PWRON signal low level. • Or PWRHOLD signal high level. • Or DEV_ON control bit set to 1 (default inactive). 42 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com • SWCS046N – MARCH 2010 – REVISED APRIL 2012 Or interrupt flag active (default INT1 low) while the device is off (NRESPWRON = 0) generates a poweron enable condition during a fixed delay (TDOINT1 pulse duration defined in POWER CONTROL TIMING, Power Control Timing). The power-on enable condition pulse occurs only if the interrupt status bit is initially low (no previous identical interrupt pending in the status register). The Interrupt sources expected when the device is off are: • PWRON low-level interrupt (PWRON_IT = 1 in INT_STS_REG register) • PWRHOLD rising-edge interrupt (PWRHOLD_IT = 1 in INT_STS_REG register) The Interrupt sources expected if enabled when the device is off are: • RTC Alarm interrupt (RTC_ALARM_IT = 1 or RTC_PERIOD_IT = 1 in INT_STS_REG register) • First-time input voltage rising above VMBHI threshold (Boot mode or EEPROM dependent) and input voltage > VMBCH threshold (VMBCH_IT = 1 in INT_STS_REG register). GPIO_CKSYNC cannot be used to turn on the device (OFF-to-ACTIVE state transition), even if its associated interrupt is not masked, but can be used as an interrupt source to wake up the device from SLEEP-to-ACTIVE state. Device power-on disable conditions: • PWRON signal low level during more than the long-press delay: tdPWRONLP (can be disabled though register programming). The interrupt corresponding to this condtion is PWRON_LP_IT in the INT_STS_REG register. • Or Die temperature has reached the thermal shutdown threshold. • Or DEV_OFF or DEV_OFF_RST control bit set to 1 (value of DEV_OFF is cleared when the device is in OFF state). Device SLEEP enable conditions: • SLEEP signal low level (default, or high level depending on the programmed polarity) • And DEV_SLP control bit set to 1 • And interrupt flag inactive (default INT1 high): no nonmasked interrupt pending The SLEEP state can be controlled by programming DEV_SLP 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 once, after device turn-on. SWITCH-ON/-OFF SEQUENCES The power sequence is the automated switching on of the device resources when an off-to-active transition takes place. The device supports three embedded power sequences selectable by the device BOOT pins. BOOT0 BOOT1 Processor Supported 0 0 AM3517, AM3505 1 0 OMAP3 Family, AM3715/03, DM3730/25 0 1 EEPROM sequence Details of the boot sequence timing are given in SWITCH-ON/-OFF SEQUENCES AND TIMING. EEPROM sequences can be used for specific power up sequence for corresponding application processor. For details of EEPROM sequence refer to the user guides on the product folder: http://focus.ti.com/docs/prod/folders/print/tps65910.html. CONTROL SIGNALS 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 ACTIVE state. This input signal is level sensitive and no debouncing is applied. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 43 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com While the device is in 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), 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 SLEEP state. 32KCLKOUT is also included in the SLEEP_KEEP_RES_ON register and the 32-kHz clock output is maintained in SLEEP state if the corresponding mask bit is set. PWRHOLD When none of the device power-on disable conditions are met, a rising edge of this signal causes an OFF-toACTIVE state transition of the device and a falling edge causes a transition back to OFF state. Typically, this signal is used to control the device in a slave configuration. It can be connected to the SYSEN output signal from other TPS659xx devices, or the NRESPWRON signal of another TPS65910 device. This input signal is level sensitive and no debouncing is applied. A rising edge of PWRHOLD is highlighted though an associated interrupt. BOOT0/BOOT1 These signals determine which processor the device is working with and hence which power-up sequence is needed. See SWITCH-ON/-OFF SEQUENCES AND TIMING for more details. There is no debouncing on this input signal. NRESPWRON This signal is used as the reset to the processor. It is held low until the ACTIVE state is reached. See POWER CONTROL TIMING to get detailed timing. 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 ACTIVE state of the device. CLK32KOUT output can also be enabled or not during SLEEP state of the device depending on the SLEEPMASK register programming. PWRON A falling edge on this signal causes after tdbPWRONF debouncing delay (defined in Figure 5 and Table 6) an OFFto-ACTIVE state or SLEEP-to-ACTIVE state transition of the device and makes the corresponding interrupt (PWRON_IT) active. The PWRON input is connected to an external push-button. The built-in debouncing time defines a minimum button press duration that is required for button press detection. Any button press duration which is lower than this value is ignored, considered an accidental touch. After an OFF-to-ACTIVE state transition, the PMIC maintains ACTIVE during tdOINT delay, if the button is released. After this delay if none of the device enabling conditions is set by the processor supplied, the PMIC automatically turns off. If the button is not released, the PMIC maintains ACTIVE up to tdPWRONLPTO, because PWRON low is a device enabling condition. After a SLEEP-to-ACTIVE state transition, the PMIC maintains ACTIVE as long as an interrupt is pending. If the device is already in ACTIVE state, a PWRON low level makes the corresponding interrupt (PWRON_IT) active. When the PMIC is in ACTIVE mode, if the button is pressed for longer time than tdPWRONLP, the PMIC generates the PWON_LP_IT interrupt. If the processor does not acknowledge the long press interrupt within a period of tdPWRONLPTO – tdPWRONLP, the PMIC goes to OFF mode and shuts down the DCDCs and LDOs. INT1 INT1 signal (default active low) warns the host processor of any event that occurred on the TPS65910 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 by programming the IT_POL control bit. 44 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Any (not masked or masked) interrupt detection causes a POWER ON enable condition during a fixed delay tDOINT1 (only) when the device is in OFF state (when NRESPWON signal is low). Any (not masked) interrupt detection is causing a device wakeup from SLEEP state up to acknowledge of the pending interrupt. Any of the interrupt sources can be masked by 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 turn off of the device after the tDOINT1 POWER ON enable pulse duration.. See section: Interrupts, for interrupt sources definition. SDASR_EN2 and SCLSR_EN1 SDASR_EN2 and SCLSR_EN1 are the data and clock signals of the serial control interface (SR-I2C) dedicated to SmartReflex 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 SDASR_EN2 or SCLSR_EN1 control automatically disables the serial control interface. Programming EN1_LDO_ASS_REG, EN2_LDO_REG, and SLEEP_KEEP_LDO_ON_REG registers: SCLSR_EN1 and SDASR_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: SCLSR_EN1 and SDASR_EN2 signals can be used to control the turn on/off or low-power state (PFM mode) of SMPS type supplies. SDASR_EN2 and SCLSR_EN1 can be used to set output voltage of VDD1 and VDD2 SMPS from a roof to a floor value, preprogrammed in the VDD1_OP_REG, VDD2_OP_REG, and teh VDD1_SR_REG, VDD2_SR_REG registers. Tun-off of VDD1 and VDD2 can also be programmed either in VDD1_OP_REG, VDD2_OP_REG or in VDD1_SR_REG, VDD2_SR_REG registers. When a supply is controlled through SCLSR_EN1 or SCLSR_EN2 signals, its state is no longer driven by the device SLEEP state. GPIO_CKSYNC GPIO_CKSYNC is a configurable open-drain digital I/O: directivity, debouncing delay and internal pullup can be programmed in the GPIO0_REG register. GPIO_CKSYNC cannot be used to turn on the device (OFF-to-ACTIVE state transition), even if its associated interrupt is not masked, but can be used as an interrupt source to wake up the device from SLEEP-to-ACTIVE state. Programming DCDCCKEXT = 1, VDD1, VDD2, VIO, and VDD3 dc-dc switching can be synchronized using a 3MHz clock set though the GPIO_CKSYNC pin. 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 selfevaluation. 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 (SR-I2C) is dedicated to SmartReflex applications such as DVFS and class 3 AVS, and thus gives access to the VDD1_OP_REG, VDD1_SR_REG, and VDD2_OP_REG, VDD2_SR_REG register. A general-purpose serial control interface (CTL-I2C) also gives access to these registers, if 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). Figure 14 shows an example of a SmartReflex operation. To optimize power efficiency, the voltage domains of the host processor uses the DVFS and AVS features provided by SmartReflex. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 45 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com OPP5 Coarse steps (DVFS) Fine steps (AVS) OPP4 OPP Change end OPP3 OPP2 OPP Change start OPP1 TSR TI2C TSMPS TSR TI2C TSMPS TSR TI2C TSMPS TSR TI2C TSMPS SWCS046-012 (1) TSR: Time used by the SmartReflex controller (2) TI2C: Time used for data transfer through the I2C interface (3) TSMPS: Time required by the SMPS to converge to new voltage value Figure 14. SmartReflex Operation Example 32-kHz RTC CLOCK The TPS65910 device can provide a 32-kHz clock to the platform through the CLK32KOUT output, the source of this 32-kHz clock can be: • 32-kHz crystal connected from OSC32IN to OSC32KOUT pins • A square-wave 32-kHz clock signal applied to OSC32IN input (OSC32KOUT kept floating). • Internal 32-kHz RC oscillator, to reduce 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 mode or device version (EEPROM programming): • BOOT1 = 0, BOOT0 = 1: quartz oscillator or external square wave 32-kHz clock default • BOOT1 = 0, BOOT0 = 0: 32-kHz RC oscillator default 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 DEVCTRL_REG register, taking benefit of the shorter turn-on time of the internal RC oscillator. Switching from the 32-kHz crystal oscillator or external square-wave clock to the RC oscillator is not supported. 46 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 VRTC 32 kHz to digital block Biasing and amplitude control OSC32KIN REFGND OSC32KOUT Q Coscin Coscout SWCS046-013 Figure 15. Crystal Oscillator 32-kHz 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 or the BACKUP state. The main functionalities 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 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 47 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com 32-kHz clock input Seconds Week Days Frequency compensation 32-kHz counter Minutes Hours Days Interrupt Control Months Alarm Years INT_ALARM INT_TIMER SWCS046-014 Figure 16. RTC Digital Section Block Diagram NOTE INT_ALARM can generate a wakeup of the platform. INT_TIMER cannot generate a wakeup of the platform. TIME CALENDAR REGISTERS All the time and calendar information are available in these dedicated registers, called TC registers. Values of the TC registers are written in BCD format. 1. Year data ranges from 00 to 99 – Leap year = Year divisible by four (2000, 2004, 2008, 2012...) – Common year = other years 2. Month data ranges from 01 to 12 3. Day 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. Week value ranges from 0 to 6 5. Hour 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 DBB can write into 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 TC values, and then restart the RTC by setting the STOP_RTC bit. Example: Time is 10H54M36S PM (PM_AM mode set), 2008 September 5, previous register values are: 48 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Register Value SECONDS_REG 0x36 MINUTES_REG 0x54 HOURS_REG 0x90 DAYS_REG 0x05 MONTHS_REG 0x09 YEARS_REG 0x08 The user can round to the closest minute, by setting the ROUND_30S register bit. TC values are set to the closest 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. 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). 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 4 3 58 59 0 1 6 58 2 59 0 1 2 Compensation event Hours 3 Seconds 59 4 0 1 Compensation event swcs046-015 Figure 17. RTC Compensation Scheduling Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 49 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com 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 one time hour 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 one 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. BACKUP BATTERY MANAGEMENT The device includes a back-up battery switch connecting the VRTC regulator input to a main battery (VCC7) or to a back-up battery (VBACKUP), depending on the batteries voltage value. The VRTC supply can then be maintained during a BACKUP state as far 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 POR (PowerOnReset). The back-up domain functions which are always supplied from VRTC comprehend: • The internal 32-kHz oscillator • Backup registers The back-up battery can be charged from the main battery through an embedded charger. The back-up battery charge voltage and enable is controlled through BBCH_REG register programming. This register content is maintained during the device Backup state. Hence enabled the back-up battery charge is maintained as far as the main battery voltage is higher than the VMBLO threshold and the back-up battery voltage. BACKUP REGISTERS As part of the RTC the device contains five 8-bit registers which 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. 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 (SR-I2C) is dedicated to SmartReflex applications such as DVFS or AVS. Both control interfaces are compliant with 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 addresse (ID1 = 2Dh). The SmartReflex I2C module uses one slave hard-coded address (ID0 = 12h). The master mode is not supported. Addressing: Seven-bit mode addressing device They do not support the following features: • 10-bit addressing • General call THERMAL MONITORING AND SHUTDOWN A thermal protection module monitors the junction temperature of the device versus two thesholds: • Hot-die temperature threshold • Thermal shutdown temperature theshold 50 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 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 theshold is reached, the TPS65910 device is set under reset and a transition to OFF state is initiated. Then the power-on enable conditions of the device is not considered until the die temperature has decreased below the hot-die threshold. An hysteresis is applied to the hot-die and shutdown threshold, when detecting a falling edge of temperature, and both detection are debounced to avoid any parasitic detection. The TPS65910 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 register THERM_REG. The thermal protection can be enabled in SLEEP state programming register SLEEP_KEEP_RES_ON. The thermal protection is automatically enabled during an OFF-to-ACTIVE 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 detections state can be monitored or masked by reading or programming the THERM_REG register. Hot-die interrupt can be masked by programming the INT_MSK_REG register. INTERRUPTS Table 13. 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 (every second or minute) (running in ACTIVE, OFF, and SLEEP state, default inactive) 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_IT PWRHOLD signal rising edge PWRON_LP_IT PWRON is low during more than the long-press delay: tdPWRONLP (can be disable though register programming). PWRON_IT PWRON is low while the device is on (running in ACTIVE and SLEEP state) or PWON was low while the device was off (causing a device turn-on). Level-sensitive interrupt VMBHI_IT The battery voltage rise above the VMBHI threshold: NOSUPPLY to Off or Backup-to-Off device states transition (first battery plug or battery voltage bounce detection). This interrupt source can be disabled through EEPROM programming (VMBHI_IT_DIS). Edge-sensitive interrupt VMBDCH_IT The battery voltage falls down below the VMBDCH threshold(running in ACTIVE and SLEEP state, if enabled programming VMBCH_VSEL). Edge-sensitive interrupt GPIO0_R_IT GPIO_CKSYNC rising-edge detection (available in ACTIVE and SLEEP state) GPIO0_F_IT GPIO_CKSYNC falling-edge detection (available in ACTIVE and SLEEP state) INT1 signal (active low) warns the host processor of any event that occurred on the TPS65910 device. The host processor can then poll the interrupt from the interrupt status register via I2C to identify the interrupt source. Each interrupt source can be individually masked via the interrupt mask register. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 51 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com PACKAGE DESCRIPTION The following are the package descriptions of the TPS65910 PMU devices: • Package type: Package TPS65910 Type RSL QFN-N48 Size (mm) 6x6 Substrate layers 1 layer Pitch ball array (mm) 0.4 mm ViP (via-in-pad) No Number of balls 48 Thickness (mm) (max. height including balls) 1 Others • Green, ROHS-compliant Moisture sensitivity level target: JEDEC MSL3 @ 260°C APPENDIX A: FUNCTIONAL REGISTERS TPS65910_FUNC_REG REGISTERS MAPPING SUMMARY Table 14. TPS65910_FUNC_REG Register Summary Register Name Type Register Width (Bits) Register Reset Address Offset SECONDS_REG 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 0x9F 0x1C REF_REG RW 8 0x01 0x1D VRTC_REG RW 8 0x01 0x1E VIO_REG RW 8 0x00 0x20 52 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 14. TPS65910_FUNC_REG Register Summary (continued) Register Name Type Register Width (Bits) Register Reset Address Offset VDD1_REG RW 8 0x0C 0x21 VDD1_OP_REG RW 8 0x00 0x22 VDD1_SR_REG RW 8 0x00 0x23 VDD2_REG RW 8 0x04 0x24 VDD2_OP_REG RW 8 0x00 0x25 VDD2_SR_REG RW 8 0x00 0x26 VDD3_REG RW 8 0x04 0x27 VDIG1_REG RW 8 0x00 0x30 VDIG2_REG RW 8 0x00 0x31 VAUX1_REG RW 8 0x00 0x32 VAUX2_REG RW 8 0x00 0x33 VAUX33_REG RW 8 0x00 0x34 VMMC_REG RW 8 0x00 0x35 VPLL_REG RW 8 0x00 0x36 VDAC_REG RW 8 0x00 0x37 THERM_REG RW 8 0x0D 0x38 BBCH_REG RW 8 0x00 0x39 DCDCCTRL_REG RW 8 0x3B 0x3E DEVCTRL_REG RW 8 0x40 0x3F DEVCTRL2_REG RW 8 0x34 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 RESERVED RW 8 0x00 0x49 RESERVED RW 8 0x00 0x4A INT_STS_REG RW 8 0x00 0x50 INT_MSK_REG RW 8 0x02 0x51 INT_STS2_REG RW 8 0x00 0x52 INT_MSK2_REG RW 8 0x00 0x53 GPIO0_REG RW 8 0x0A 0x60 JTAGVERNUM_REG RO 8 0x00 0x80 TPS65910_FUNC_REG REGISTER DESCRIPTIONS Table 15. SECONDS_REG Address Offset 0x00 Physical Address Instance Description RTC register for seconds Type RW Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 53 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 7 6 5 Reserved Bits www.ti.com 4 3 2 SEC1 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 16. MINUTES_REG Address Offset 0x01 Physical Address Instance Description RTC register for minutes Type RW 7 6 5 Reserved Bits 4 3 2 MIN1 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 Table 17. HOURS_REG Address Offset 0x02 Physical Address Instance Description RTC register for hours Type RW 7 6 PM_NAM Reserved Bits 5 4 3 HOUR1 2 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 Second digit of hours(range is 0 up to 2) RW 0x0 3:0 HOUR0 First digit of hours (range is 0 up to 9) RW 0x0 Table 18. DAYS_REG Address Offset 0x03 Physical Address Instance Description RTC register for days Type RW 54 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 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 19. MONTHS_REG Address Offset 0x04 Physical Address Instance Description RTC register for months Type RW 7 6 5 Reserved 4 3 2 MONTH1 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 Table 20. YEARS_REG Address Offset 0x05 Physical Address Instance Description RTC register for day of the week Type RW 7 6 5 4 3 2 YEAR1 1 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 21. WEEKS_REG Address Offset 0x06 Physical Address Instance Description RTC register for day of the week Type RW 7 6 5 Reserved Copyright © 2010–2012, Texas Instruments Incorporated 4 3 2 1 0 WEEK Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 55 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com 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 22. ALARM_SECONDS_REG Address Offset 0x08 Physical Address Instance Description RTC register for alarm programmation for seconds Type RW 7 6 5 4 3 2 Reserved ALARM_SEC1 Bits 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 ALARM_SEC0 Table 23. ALARM_MINUTES_REG Address Offset 0x09 Physical Address Instance Description RTC register for alarm programmation for minutes Type RW 7 6 Reserved Bits 5 4 3 2 ALARM_MIN1 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 24. ALARM_HOURS_REG Address Offset 0x0A Physical Address Instance RTC register for alarm programmation for hours Type RW 56 7 6 ALARM_PM_NAM Description Reserved Submit Documentation Feedback 5 4 ALARM_HOUR1 3 2 1 0 ALARM_HOUR0 Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com Bits SWCS046N – MARCH 2010 – REVISED APRIL 2012 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 digitof alarm programmation for hours (range is 0 up to 9) RW 0x0 Table 25. ALARM_DAYS_REG Address Offset 0x0B Physical Address Instance Description RTC register for alarm programmation for days Type RW 7 6 5 Reserved 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 Table 26. ALARM_MONTHS_REG Address Offset 0x0C Physical Address Instance Description RTC register for alarm programmation for months Type RW 6 5 4 3 ALARM_MONTH1 7 Reserved 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 27. ALARM_YEARS_REG Address Offset 0x0D Physical Address Instance Description RTC register for alarm programmation for years Type RW Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 57 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 7 6 www.ti.com 5 4 3 2 ALARM_YEAR1 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 Table 28. RTC_CTRL_REG Address Offset 0x10 Physical Address Instance 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 5 4 3 2 1 0 RTC_V_OPT GET_TIME SET_32_COUNTER Description TEST_MODE MODE_12_24 AUTO_COMP ROUND_30S STOP_RTC 58 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 (i.e.: reset it to 0 and then re-write 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 32kHz 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 closest minute. This bit is a toggle bit, the micro-controller can only write one and RTC clears it. If the micro-controller sets the ROUND_30S bit and then read it, the micro-controller will read one until the rounded to the closet. RW 0 0 STOP_RTC 0: RTC is frozen 1: RTC is running RW 0 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 29. RTC_STATUS_REG Address Offset 0x11 Physical Address Instance 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 6 5 4 3 2 1 0 POWER_UP ALARM EVENT_1D EVENT_1H EVENT_1M EVENT_1S RUN Reserved Bits Field Name Description Type Reset 7 POWER_UP 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 6 ALARM Indicates that an alarm interrupt has been generated (bit clear by writing 1). The alarm interrupt keeps its low level, until the micro-controller 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 Table 30. RTC_INTERRUPTS_REG Address Offset 0x12 Physical Address Instance RTC interrupt control register Type RW 7 6 5 Reserved 4 3 2 IT_SLEEP_MASK_EN Description 1 IT_ALARM IT_TIMER 0 EVERY Bits Field Name Description Type Reset 7:5 Reserved Reserved bit RO R returns 0s 0x0 IT_SLEEP_MASK_E N 1: Mask periodic interrupt while the TPS65910 device is in SLEEP mode. Interrupt event is back up in a register and occurred as soon as the TPS65910 device is no more in SLEEP mode. 0: Normal mode, no interrupt masked RW 0 4 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 59 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Bits Field Name Description Type Reset 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: every second 01: every minute 10: every hour 11: every day RW 0x0 1:0 Table 31. RTC_COMP_LSB_REG Address Offset 0x13 Physical Address Instance Description RTC compensation register (LSB) Notes: This register must be written in 2-complement. This means that to add one 32kHz oscillator period every hour, micro-controller needs to write FFFF into RTC_COMP_MSB_REG & RTC_COMP_LSB_REG. To remove one 32-kHz oscillator period every hour, micro-controller needs to write 0001 into RTC_COMP_MSB_REG & RTC_COMP_LSB_REG. The 7FFF value is forbidden. Type RW 7 6 5 4 3 2 1 0 RTC_COMP_LSB 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 every hour [LSB] Type Reset RW 0x00 Table 32. RTC_COMP_MSB_REG Address Offset 0x14 Physical Address Instance Description RTC compensation register (MSB) Notes: See RTC_COMP_LSB_REG Notes. Type RW 7 6 5 4 3 2 1 0 RTC_COMP_MSB 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 every hour [MSB] Type Reset RW 0x00 Table 33. RTC_RES_PROG_REG Address Offset 0x15 Physical Address Instance Description RTC register containing oscillator resistance value Type RW 7 6 Reserved 60 Submit Documentation Feedback 5 4 3 2 1 0 SW_RES_PROG Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 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 34. RTC_RESET_STATUS_REG Address Offset 0x16 Physical Address Instance Description RTC register for reset status Type RW 6 5 4 3 2 1 0 RESET_STATUS 7 Reserved Bits Field Name Description Type Reset 7:6 Reserved Reserved bit RO R returns 0s 0x0 5:0 RESET_STATUS RW 0x27 Table 35. BCK1_REG Address Offset 0x17 Physical Address Instance 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 36. BCK2_REG Address Offset 0x18 Physical Address Instance 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 Copyright © 2010–2012, Texas Instruments Incorporated Type Reset RW 0x00 Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 61 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 37. BCK3_REG Address Offset 0x19 Physical Address Instance 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 38. BCK4_REG Address Offset 0x1A Physical Address Instance 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 39. BCK5_REG Address Offset 0x1B Physical Address Instance 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 40. PUADEN_REG Address Offset 0x1C Physical Address Instance Description Pull-up/pull-down control register. Type RW 62 7 6 5 4 3 2 1 0 RESERVED I2CCTLP I2CSRP PWRONP SLEEPP PWRHOLDP BOOT1P BOOT0P Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits Field Name Description Type Reset 7 RESERVED Reserved bit RW 1 6 I2CCTLP SDACTL and SCLCTL pull-up control: 1: Pull-up is enabled 0: Pull-up is disabled RW 0 5 I2CSRP SDASR and SCLSR pull-up control: 1: Pull-up is enabled 0: Pull-up is disabled RW 0 4 PWRONP PWRON pad pull-up control: 1: Pull-up is enabled 0: Pull-up is disabled RW 1 3 SLEEPP SLEEP pad pull-down control: 1: Pull-down is enabled 0: Pull-down is disabled RW 1 2 PWRHOLDP PWRHOLD pad pull-down control: 1: Pull-down is enabled 0: Pull-down is disabled RW 1 1 BOOT1P BOOT1 pad control: 1: Pull-down is enabled 0: Pull-down is disabled RW 1 0 BOOT0P BOOT0 pad control: 1: Pull-down is enabled 0: Pull-down is disabled RW 1 1 0 Table 41. REF_REG Address Offset 0x1D Physical Address Instance Description Reference control register Type RW 7 6 5 4 3 Reserved 2 VMBCH_SEL ST Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 VMBCH_SEL Main Battery comparator VMBCH programmable threshold (EEPROM bits): VMBCH_SEL[1:0] = 00 : bypass VMBCH_SEL[1:0] = 01 : VMBCH = 2.8 V VMBCH_SEL[1:0] = 10 : VMBCH = 2.9 V VMBCH_SEL[1:0] = 11 : VMBCH = 3.0 V RW 0x0 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 Table 42. VRTC_REG Address Offset 0x1E Physical Address Instance Description VRTC internal regulator control register Type RW Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 63 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 7 6 www.ti.com 5 4 Reserved 3 2 VRTC_OFFMASK SWCS046N – MARCH 2010 – REVISED APRIL 2012 Reserved 1 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 enter in low-power mode during device OFF state.(EEPROM bit) 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 Table 43. VIO_REG Address Offset 0x20 Physical Address Instance Description VIO control register Type RW 7 6 5 ILMAX (1) 64 4 Reserved 3 2 1 SEL 0 ST Bits Field Name Description 7:6 ILMAX Select maximum load current: when 00: 0.5 A when 01: 1.0 A when 10: 1.0 A when 11: 1.0 A Type Reset RW 0x0 5:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL 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 RW 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) (Write access available in test mode only) RW See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 44. VDD1_REG Address Offset 0x21 Physical Address Instance Description VDD1 control register Type RW 7 6 5 VGAIN_SEL 4 3 ILMAX 2 1 TSTEP 0 ST Bits Field Name Description Type Reset 7:6 VGAIN_SEL Select output voltage multiplication factor: G (EEPROM bits): when 00: x1 when 01: x1 when 10: x2 when 11: x3 RW 0x0 5:4 ILMAX Select maximum load current: when 0: 1.0 A when 1: 1.5 A RW 0 3:2 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 Table 45. VDD1_OP_REG Address Offset 0x22 Physical Address Instance Description VDD1 voltage selection register. This register can be accessed by both control and smartreflex I2C interfaces depending on SR_CTL_I2C_SEL register bit value. Type RW 7 6 5 CMD 4 3 2 1 0 SEL Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 65 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits (1) www.ti.com Field Name Description Type Reset 7 CMD Smart-Reflex command: when 0: VDD1_OP_REG voltage is applied when 1: VDD1_SR_REG voltage is applied RW 0 6:0 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 mV) × G RW See (1) The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 46. VDD1_SR_REG Address Offset 0x23 Physical Address Instance Description VDD1 voltage selection register for smartreflex. This register can be accessed by both control and smartreflex I2C interfaces depending on SR_CTL_I2C_SEL register bit value. Type RW 7 6 5 4 Reserved Bits 7 6:0 (1) 3 2 1 0 SEL 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 : 1.5V ... SEL[6:0] = 0111111 : 1.35V ... SEL[6:0] = 0110011 : 1.2V ... SEL[6:0] = 0000001 to 0000011 : 0.6V SEL[6:0] = 0000000 : Off (0.0V) Note: from SEL[6:0] = 3 to 75 (dec) Vout = (SEL[6:0] × 12.5 mV + 0.5625 mV) × G RW See (1) The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 47. VDD2_REG Address Offset 0x24 Physical Address Instance Description VDD2 control register Type RW 7 6 VGAIN_SEL 66 5 ILMAX Submit Documentation Feedback 4 3 TSTEP 2 1 0 ST Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits Field Name Description Type Reset 7:6 VGAIN_SEL Select output voltage multiplication factor: G (EEPROM bits): when 00: x1 when 01: x1 when 10: x2 when 11: x3 RW 0x0 5:4 ILMAX Select maximum load current: when 0: 1.0 A when 1: 1.5 A RW 0 3:2 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 Table 48. VDD2_OP_REG Address Offset 0x25 Physical Address Instance Description VDD2 voltage selection register. This register can be accessed by both control and smartreflex I2C interfaces depending on SR_CTL_I2C_SEL register bit value. Type RW 7 6 5 CMD Bits (1) 4 3 2 1 0 SEL Field Name Description Type Reset 7 CMD Smart-Reflex command: when 0: VDD2_OP_REG voltage is applied when 1: VDD2_SR_REG voltage is applied RW 0 6:0 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 mV) × G RW See (1) The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 49. VDD2_SR_REG Address Offset 0x26 Physical Address Description Instance VDD2 voltage selection register for smartreflex. This register can be accessed by both control and smartreflex I2C interfaces depending on SR_CTL_I2C_SEL register bit value. Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 67 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 49. VDD2_SR_REG (continued) Type RW 7 6 5 4 3 Reserved Bits 7 6:0 (1) 2 1 0 SEL 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: 1.35V ... SEL[6:0] = 0110011: 1.2V ... SEL[6:0] = 0000001 to 0000011: 0.6V SEL[6:0] = 0000000: Off (0.0V) Note: from SEL[6:0] = 3 to 75 (dec) Vout= (SEL[6:0] × 12.5 mV + 0.5625 mV) ×G RW See (1) The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 50. VDD3_REG Address Offset 0x27 Physical Address Instance Description VDD2 voltage selection register for smartreflex. This register can be accessed by both control and smartreflex I2C interfaces depending on SR_CTL_I2C_SEL register bit value. Type RW 7 6 5 4 3 2 Reserved 1 CKINEN 0 ST Bits Field Name Description Type Reset 7:3 Reserved Reserved bit RO R returns 0s 0x00 2 CKINEN Enable 1Mhz clock synchronization RW 1 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 1:0 Table 51. VDIG1_REG Address Offset 0x30 Physical Address Instance Description VDIG1 regulator control register Type RW 7 6 5 Reserved 68 Submit Documentation Feedback 4 3 2 SEL 1 0 ST Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com (1) SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.2 V SEL[1:0] = 01 : 1.5 V SEL[1:0] = 10 : 1.8 V SEL[1:0] = 11 : 2.7 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 52. VDIG2_REG Address Offset 0x31 Physical Address Instance Description VDIG2 regulator control register Type RW 7 6 5 4 3 Reserved (1) 2 1 SEL 0 ST Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.0 V SEL[1:0] = 01 : 1.1 V SEL[1:0] = 10 : 1.2 V SEL[1:0] = 11 : 1.8 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 53. VAUX1_REG Address Offset 0x32 Physical Address Instance Description VAUX1 regulator control register Type RW 7 6 5 Reserved Copyright © 2010–2012, Texas Instruments Incorporated 4 3 2 SEL 1 0 ST Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 69 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 (1) www.ti.com Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.8 V SEL[1:0] = 01 : 2.5 V SEL[1:0] = 10 : 2.8 V SEL[1:0] = 11 : 2.85 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 54. VAUX2_REG Address Offset 0x33 Physical Address Instance Description VAUX2 regulator control register Type RW 7 6 5 4 3 Reserved (1) 2 1 SEL 0 ST Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.8 V SEL[1:0] = 01 : 2.8 V SEL[1:0] = 10 : 2.9 V SEL[1:0] = 11 : 3.3 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 55. VAUX33_REG Address Offset 0x34 Physical Address Instance Description VAUX33 regulator control register Type RW 7 6 5 Reserved 70 Submit Documentation Feedback 4 3 2 SEL 1 0 ST Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com (1) SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.8 V SEL[1:0] = 01 : 2.0 V SEL[1:0] = 10 : 2.8 V SEL[1:0] = 11 : 3.3 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 56. VMMC_REG Address Offset 0x35 Physical Address Instance Description VMMC regulator control register Type RW 7 6 5 4 3 Reserved (1) 2 1 SEL 0 ST Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.8 V SEL[1:0] = 01 : 2.8 V SEL[1:0] = 10 : 3.0 V SEL[1:0] = 11 : 3.3 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 57. VPLL_REG Address Offset 0x36 Physical Address Instance Description VPLL regulator control register Type RW 7 6 5 Reserved Copyright © 2010–2012, Texas Instruments Incorporated 4 3 2 SEL 1 0 ST Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 71 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 (1) www.ti.com Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.0V SEL[1:0] = 01 : 1.1 V SEL[1:0] = 10 : 1.8 V SEL[1:0] = 11 : 2.5 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 58. VDAC_REG Address Offset 0x37 Physical Address Instance Description VDAC regulator control register Type RW 7 6 5 4 3 Reserved (1) 2 1 SEL 0 ST Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:2 SEL Supply voltage (EEPROM bits): SEL[1:0] = 00 : 1.8 V SEL[1:0] = 01 : 2.6 V SEL[1:0] = 10 : 2.8 V SEL[1:0] = 11 : 2.85 V RW 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 See (1) 0x0 The reset value for this field varies with boot mode selection and the processor support. Please refer to the corresponding processor user guide to find the correct default value. Table 59. Therm_REG Address Offset 0x38 Instance Description Thermal control register Type RW 7 6 Reserved 72 5 4 THERM_HD THERM_TS Submit Documentation Feedback 3 2 THERM_HDSEL 1 0 RSVD1 THERM_STATE Physical Address Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 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 1 RSVD1 Reserved bit RW 0 0 THERM_STATE Thermal shutdown module enable signal: when 0: thermal shutdown module is disable when 1: thermal shutdown module is enable RW 1 3:2 Table 60. BBCH_REG Address Offset 0x39 Physical Address Instance Description Back-up battery charger control register Type RW 7 6 5 4 3 2 Reserved 1 0 BBSEL BBCHEN Bits Field Name Description Type Reset 7:4 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 1 0 0 Table 61. DCDCCTRL_REG Address Offset 0x3E Physical Address Instance Description DCDC control register Type RW 7 6 Reserved 5 4 3 2 VDD2_PSKIP VDD1_PSKIP VIO_PSKIP DCDCCKEXT DCDCCKSYNC Bits Field Name Description Type Reset 7:6 Reserved Reserved bit RO R returns 0s 0x0 5 VDD2_PSKIP VDD2 pulse skip mode enable (EEPROM bit) RW 1 4 VDD1_PSKIP VDD1 pulse skip mode enable (EEPROM bit) RW 1 3 VIO_PSKIP VIO pulse skip mode enable (EEPROM bit) RW 1 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 73 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits 2 1:0 www.ti.com Field Name Description Type Reset DCDCCKEXT This signal control the muxing of the GPIO0 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 0x3 Table 62. DEVCTRL_REG Address Offset 0x3F Physical Address Instance Type RW 7 6 5 4 3 2 1 0 Reserved RTC_PWDN CK32K_CTRL DEV_OFF_RST Device control register SR_CTL_I2C_SEL Description DEV_ON DEV_SLP DEV_OFF Bits Field Name Description Type Reset 7 Reserved Reserved bit RO R returns 0s 0 6 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. (EEPROM bit) RW 1 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 Smartreflex registers access control bit: when 0: access to smartreflex registers by smartreflex I2C when 1: access to smartreflex registers by control I2C The smartreflex registers are: VDD1_OP_REG, VDD1_SR_REG, VDD2_OP_REG and VDD2_SR_REG. RW 0 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. RW 0 2 DEV_ON Write 1 will maintain the device on (ACTIVE or SLEEP device state) (if DEV_OFF = 0 and DEV_OFF_RST = 0). 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 Table 63. DEVCTRL2_REG Address Offset 0x40 Physical Address Description 74 Instance Device control register Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 63. DEVCTRL2_REG (continued) 6 5 4 3 2 1 0 TSLOT_LENGTH PWRON_LP_RST 7 PWRON_LP_OFF RW SLEEPSIG_POL Type IT_POL Bits Field Name Description Type Reset 7:6 Reserved Reserved bit RO R returns 0s 0x0 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 RW 0x3 3 SLEEPSIG_POL When 1, SLEEP signal active high When 0, SLEEP signal active low RW 0 2 PWRON_LP_OFF When 1, allows device turn-off after a PWRON long press (signal low). RW 1 1 PWRON_LP_RST When 1, allows digital core reset when the device is OFF after a PWRON long press (signal low). RW 0 0 IT_POL INT1 interrupt pad polarity control signal (EEPROM bit): When 0, active low When 1, active high RW 0 Reserved Table 64. SLEEP_KEEP_LDO_ON_REG Address Offset 0x41 Physical Address Instance 5 4 3 2 VAUX1_KEEPON VDIG2_KEEPON Copyright © 2010–2012, Texas Instruments Incorporated 1 0 VMMC_KEEPON 6 VDIG1_KEEPON 7 VAUX2_KEEPON RW VAUX33_KEEPON Type VPLL_KEEPON When corresponding control bit=0 in EN1/2_ 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 EN1/2_ LDO_ASS register: Configuration Register setting the LDO regulator state driven by SCLSR_EN1/2 signal low level (when SCLSR_EN1/2 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 VDAC_KEEPON Description Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 75 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits www.ti.com Field Name Description Type Reset 7 VDAC_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 6 VPLL_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 5 VAUX33_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 4 VAUX2_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 3 VAUX1_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 2 VDIG2_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 1 VDIG1_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 0 VMMC_KEEPON Setting supply state during device SLEEP state or when SCLSR_EN1/2 is low RW 0 Table 65. SLEEP_KEEP_RES_ON_REG Address Offset 0x42 Physical Address Instance Bits 76 7 6 5 4 3 2 1 0 I2CHS_KEEPON VDD3_KEEPON VDD2_KEEPON VDD1_KEEPON RW VRTC_KEEPON Type CLKOUT32K_KEEPON 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 - 32KHz 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. THERM_KEEPON Description VIO_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. Type Reset RW 0 6 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 VDD3_KEEPON When 1, VDD3 SMPS high power mode is maintained during device SLEEP state. No effect if VDD3 working mode is low power. When 0, VDD3 SMPS low power mode is set during device SLEEP state. RW 0 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com Bits SWCS046N – MARCH 2010 – REVISED APRIL 2012 Field Name Description Type Reset 2 VDD2_KEEPON If VDD2_EN1&2 control bit = 0 (default setting): 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 If VDD1_EN1&2 control bit=0 (default setting): 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 If VIO_EN1&2 control bit=0 (default setting): 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 Table 66. SLEEP_SET_LDO_OFF_REG Address Offset 0x43 Physical Address Instance Bits 4 3 2 1 0 VMMC_SETOFF VPLL_SETOFF 5 VDIG1_SETOFF 6 VDIG2_SETOFF 7 VAUX1_SETOFF RW VAUX2_SETOFF Type VAUX33_SETOFF 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 VDAC_SETOFF Description Field Name Description Type Reset 7 VDAC_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 6 VPLL_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 5 VAUX33_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 4 IVAUX2_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 3 VAUX1_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 2 VDIG2_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 1 VDIG1_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 0 VMMC_SETOFF When 1, LDO regulator is turned off during device SLEEP state. When 0, No effect RW 0 Table 67. SLEEP_SET_RES_OFF_REG Address Offset 0x44 Physical Address Instance 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 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 77 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 Bits 3 2 1 0 VDD1_SETOFF RSVD 4 VDD2_SETOFF 5 VDD3_SETOFF 6 DEFAULT_VOLT 7 www.ti.com SPARE_SETOFF SWCS046N – MARCH 2010 – REVISED APRIL 2012 VIO_SETOFF Field Name Description DEFAULT_VOLT When 1, default voltages (registers value after switch-on) will be used to turned-on supplies during SLEEP to ACTIVE state 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. Type Reset RW 0 RSVD Reserved bit RO R returns 0s 0x0 4 SPARE_SETOFF 3 VDD3_SETOFF Spare bit RW 0 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 7 6:5 Table 68. EN1_LDO_ASS_REG Address Offset 0x45 Physical Address Instance 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 78 7 6 5 4 3 2 1 0 VDAC_EN1 VPLL_EN1 VAUX33_EN1 VAUX2_EN1 VAUX1_EN1 VDIG2_EN1 VDIG1_EN1 VMMC_EN1 Bits Field Name Description Type Reset 7 VDAC_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 6 VPLL_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 5 VAUX33_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 4 VAUX2_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 3 VAUX1_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 2 VDIG2_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 1 VDIG1_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 0 VMMC_EN1 Setting supply state control though SCLSR_EN1 signal RW 0 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Table 69. EN1_SMPS_ASS_REG Address Offset 0x46 Physical Address Instance 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 RSVD 4 3 2 1 0 SPARE_EN1 VDD3_EN1 VDD2_EN1 VDD1_EN1 VIO_EN1 Bits Field Name Description Type Reset 7:5 RSVD Reserved bit RW 0 4 SPARE_EN1 Spare bit Rw 0 3 VDD3_EN1 When 1: When SCLSR_EN1 is high the supply is on. When SCLSR_EN1 is low and SLEEP_KEEP_RES_ON = '0' the supply voltage is off. When SCLSR_EN1 is low and SLEEP_KEEP_RES_ON = '1' the SMPS is working in low power mode. 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 VDD2_KEEPON = 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 VDD1_KEEPON = 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 VIO_KEEPON = 1 When control bit = 0 no effect: SMPS state is driven though registers programming and the device state RW 0 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 79 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 70. EN2_LDO_ASS_REG Address Offset 0x47 Physical Address Instance 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 6 5 4 3 2 1 0 VDAC_EN2 VPLL_EN2 VAUX33_EN2 VAUX2_EN2 VAUX1_EN2 VDIG2_EN2 VDIG1_EN2 VMMC_EN2 Bits Field Name Description Type Reset 7 VDAC_EN2 6 VPLL_EN2 Setting supply state control though SDASR_EN2 signal RW 0 Setting supply state control though SDASR_EN2 signal RW 5 0 VAUX33_EN2 Setting supply state control though SDASR_EN2 signal RW 0 4 VAUX2_EN2 Setting supply state control though SDASR_EN2 signal RW 0 3 VAUX1_EN2 Setting supply state control though SDASR_EN2 signal RW 0 2 VDIG2_EN2 Setting supply state control though SDASR_EN2 signal RW 0 1 VDIG1_EN2 Setting supply state control though SDASR_EN2 signal RW 0 0 VMMC_EN2 Setting supply state control though SDASR_EN2 signal RW 0 Table 71. EN2_SMPS_ASS_REG Address Offset 0x48 Physical Address Instance 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 RSVD 80 4 3 2 1 0 SPARE_EN2 VDD3_EN2 VDD2_EN2 VDD1_EN2 VIO_EN2 Bits Field Name Description Type Reset 7:5 RSVD Reserved bit RO R returns 0s 0x0 4 SPARE_EN2 Spare bit RW 0 3 VDD3_EN2 When 1: When SDASR_EN2 is high the supply is on. When SDASR_EN2 is low and SLEEP_KEEP_RES_ON = 0 the supply voltage is off. When SDASR_EN2 is low and SLEEP_KEEP_RES_ON = 1 the SMPS is working in low power mode. When control bit = 0 no effect: supply state is driven though registers programming and the device state RW 0 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 Bits Field Name Description Type Reset 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 and VDD2_KEEPON = 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 and VDD1_KEEPON = 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 VIO_KEEPON = 1 When control bit = 0 no effect: SMPS state is driven though registers programming and the device state RW 0 1 0 Table 72. RESERVED Address Offset 0x49 Physical Address Instance Description Reserved register Type RW 7 6 5 4 3 2 RESERVED Bits Field Name Description Type Reset 7:0 RESERVED Reserved bit RW 0 1 0 Table 73. RESERVED Address Offset 0x4A Physical Address Instance Description Reserved register Type RW 7 6 5 4 3 2 RESERVED Bits Field Name Description Type Reset 7:0 RESERVED Reserved bit RW 0x00 Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 81 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 74. INT_STS_REG Address Offset 0x50 Physical Address Instance Type RW 7 6 5 4 3 2 1 0 RTC_ALARM_IT 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. RTC_PERIOD_IT Description HOTDIE_IT PWRHOLD_IT PWRON_LP_IT PWRON_IT VMBHI_IT VMBDCH_IT Bits 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_IT 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 > VMBHI event interrupt status RW W1 to Clr 0 0 VMBDCH_IT VBAT > VMBDCH event interrupt status. Active only if Main Battery comparator VMBCH programmable threshold is not bypassed (VMBCH_SEL[1:0] ≠ 00) RW W1 to Clr 0 Table 75. INT_MSK_REG Address Offset 0x51 Physical Address Instance 82 4 3 PWRON_LP_IT_MSK Submit Documentation Feedback 2 1 0 VMBDCH_IT_MSK 5 VMBHI_IT_MSK 6 PWRON_IT_MSK 7 PWRHOLD_IT_MSK RW HOTDIE_IT_MSK Type RTC_ALARM_IT_MSK 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. RTC_PERIOD_IT_MSK Description Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com Bits SWCS046N – MARCH 2010 – REVISED APRIL 2012 Type Reset 7 Field Name RTC_PERIOD_IT_MS RTC period event interrupt mask. K Description RW 0 6 RTC_ALARM_IT_MS K RTC alarm event interrupt mask. RW 0 5 HOTDIE_IT_MSK Hot die event interrupt mask. RW 0 4 PWRHOLD_IT_MSK PWRHOLD rising edge event interrupt mask. RW 0 3 PWRON_LP_IT_MSK PWRON Long Press event interrupt mask. RW 0 2 PWRON_IT_MSK PWRON event interrupt mask. RW 0 1 VMBHI_IT_MSK VBAT > VMBHI event interrupt mask. When 0, enable the device automatic switch on at BACKUP to OFF or NOSUPPLY to OFF device state transition (EEPROM bit) RW 1 0 VMBDCH_IT_MSK VBAT < VMBDCH event interrupt status. Active only if the main battery comparator VMBCH programmable threshold is not bypassed (VMBCH_SEL[1:0] ≠ 00). RW 0 Table 76. INT_STS2_REG Address Offset 0x52 Physical Address Instance 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 6 5 4 3 2 Reserved 1 0 GPIO0_F_IT GPIO0_R_IT Bits Field Name Description Type Reset 7:2 Reserved Reserved bit RW W1 to Clr 0 1 GPIO0_F_IT GPIO_CKSYNC falling edge detection interrupt status RW W1 to Clr 0 0 GPIO0_R_IT GPIO_CKSYNC rising edge detection interrupt status RW W1 to Clr 0 Table 77. INT_MSK2_REG Address Offset 0x53 Physical Address Instance Type RW 7 6 5 4 Reserved Copyright © 2010–2012, Texas Instruments Incorporated 3 2 1 0 GPIO0_R_IT_MSK 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. GPIO0_F_IT_MSK Description Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 83 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Bits Field Name Description Type Reset 7:2 Reserved Reserved bit RW 0 1 GPIO0_F_IT_MSK GPIO_CKSYNC falling edge detection interrupt mask. RW 0 0 GPIO0_R_IT_MSK GPIO_CKSYNC rising edge detection interrupt mask. RW 0 Table 78. GPIO0_REG Address Offset 0x60 Physical Address Instance Description GPIO0 configuration register Type RW 7 6 5 Reserved 4 3 2 1 0 GPIO_DEB GPIO_PUEN GPIO_CFG GPIO_STS GPIO_SET Bits Field Name Description Type Reset 7:5 Reserved Reserved bit RO R returns 0s 0x0 4 GPIO_DEB GPIO_CKSYNC 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_PUEN GPIO_CKSYNC pad pull-up control: 1: Pull-up is enabled 0: Pull-up is disabled RW 1 2 GPIO_CFG Configuration of the GPIO_CKSYNC 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_CKSYNC pad RO 1 0 GPIO_SET Value set on the GPIO output when configured in output mode RW 0 1 0 Table 79. JTAGVERNUM_REG Address Offset 0x80 Physical Address Instance Description Silicon version number Type RO 7 6 5 4 3 2 Reserved 84 VERNUM Bits Field Name Description Type Reset 7:4 Reserved Reserved bit RO R returns 0s 0x0 3:0 VERNUM Value depending on silicon version number 0000 - Revision 1.0 RO 0x0 Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 www.ti.com SWCS046N – MARCH 2010 – REVISED APRIL 2012 GLOSSARY ACRONYMS, ABBREVIATIONS, AND DEFINITIONS ACRONYM 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 2 I C 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 OMAP™ Open Multimedia Application Platform™ RTC Real-Time Clock SMPS Switched Mode Power Supply SPI Serial Peripheral Interface POR Power-On Reset Copyright © 2010–2012, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 85 TPS65910, TPS65910A, TPS65910A3, TPS659101, TPS659102, TPS659103 TPS659104, TPS659105, TPS659106, TPS659107, TPS659108, TPS659109 SWCS046N – MARCH 2010 – REVISED APRIL 2012 www.ti.com Table 80. REVISION HISTORY (1) (2) (3) (4) (5) (6) (7) (8) (9) (10) (11) (12) (13) (14) (15) 86 VERSION DATE * 03/2010 NOTES See (1) . A 05/2010 See (2) B 06/2010 See (3) C 06/2010 See (4) D 11/2010 See (5) . . . . E 01/2011 See (6) F 01/2011 See (7) G 05/2011 See (8) . . . H 06/2011 See (9) I 07/2011 See (10) J 10/2011 See (11) K 10/2011 See (12) L 01/2012 See (13) M 03/2012 See (14) N 04/2012 See (15) . Initial release SWCS046A: Updated register tables VMMC_REG and VDAC_REG. Added register table VPLL_REG SWCS046B: Update Absolute Maximum Ratings, Recommended Operating Conditions, I/O Pullup and Pulldown Characteristics, DigitaL I/Os Voltage Electrical Characteristics, Power Consumption, Power References and Thresholds, Thermal Monitoring and Shutdown, 32kHz RTC Clock, VRTC LDO, VIO SMPS, VDD1 SMPS, VDD2 SMPS, VDD3 SMPS, Switch-On/-Off Sequences and Timing SWCS046C: Associate parts; no change. SWCS046D: Update Recommended Operating Conditions - Backup Battery, I/O Pullup and Pulldown Characteristics, Backup Battery Charger. Update Rated output current, PMOS current limit (High-Side), NMOS current limit (Low-Side), and Conversion Efficiency for VIO SMPS, VDD1/VDD2/VDD3 SMPS and VDIG1/VDIG2 LDO. Update Input Voltage for VIO/VDD1/VDD2 SMPS. Update DC and Transient Load and Line Regulatio and Internal Resistance for VDIG1/VDIG2 LDO, VAUX33/VMMC LDO, VAUX1,VAUX2, LDO, and VDAC/VPLL LDO. Update DC Load Regulation for VAUX3/VMMC/VDAC. Update Power Control Timing. Add Device SLEEP State Control. Add SMPS Switching Synchronization. Update VIO_REG, VDD1_REG, and VDD2_REG. SWCS046E: Manually added Thermal Pad Mechanical Data. SWCS046F: UpdateTable 1, SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS. SWCS046G: Update PACKAGE DESCRIPTION, RECOMMENDED OPERATING CONDITIONS, DIGITAL I/O VOLTAGE ELECTRICAL CHARACTERISTICS, and PWRON. SWCS046H: Update Table 40, PUADEN_REG, Table 72, RESERVED, and Table 73, RESERVED. SWCS046I: Update DC Output voltage VOUT in VAUX1 AND VAUX2 LDO. SWCS046J: UpdateTable 1, SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS. SWCS046K: UpdateTable 1, SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS - Add AM335x. SWCS046L: Update Table 1, SUPPORTED PROCESSORS AND CORRESPONDING PART NUMBERS - Add AM335x with DDR2 and AM335x with DDR3. SWCS046M: Update STATE-MACHINE, - Update Device Sleep enable conditions control information. SWCS046N: (a) VIO SMPS - Update PMOS current limit (high side) conditions (b) Table 74 - Update INT_STS_REG register - VMBHI_IT description (c) Update Input voltage: VDIG1 AND VDIG2 LDO Submit Documentation Feedback Copyright © 2010–2012, Texas Instruments Incorporated Product Folder Link(s): TPS65910 TPS65910A TPS65910A3 TPS659101 TPS659102 TPS659103 TPS659104 TPS659105 TPS659106 TPS659107 TPS659108 TPS659109 WARNING: EXPORT NOTICE Recipient agrees to not knowingly export or re-export, directly or indirectly, any product or technical data (as defined by the U.S., EU, and other Export Administration Regulations) including software, or any controlled product restricted by other applicable national regulations, received from Disclosing party under this Agreement, or any direct product of such technology, to any destination to which such export or re-export is restricted or prohibited by U.S. or other applicable laws, without obtaining prior authorisation from U.S. Department of Commerce and other competent Government authorities to the extent required by those laws. This provision shall survive termination or expiration of this Agreement. According to our best knowledge of the state and end-use of this product or technology, and in compliance with the export control regulations of dual-use goods in force in the origin and exporting countries, this technology is classified as follows: US ECCN: EAR99 EU ECCN: EAR99 And may require export or re-export license for shipping it in compliance with the applicable regulations of certain countries. PACKAGE OPTION ADDENDUM www.ti.com 19-May-2012 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Qty Eco Plan (2) Lead/ Ball Finish MSL Peak Temp (3) (Requires Login) TPS659101A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659101A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659102A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659102A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659103A1RSL PREVIEW VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659103A1RSLR PREVIEW VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659104A1RSL PREVIEW VQFN RSL 48 60 TBD TPS659104A1RSLR PREVIEW VQFN RSL 48 2500 TBD TPS659105A1RSL PREVIEW VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659105A1RSLR PREVIEW VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659106A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659106A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659107A1RSL PREVIEW VQFN RSL 48 60 TBD TPS659107A1RSLR PREVIEW VQFN RSL 48 2500 TBD TPS659108A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659108A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659109A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS659109A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR Addendum-Page 1 Samples Call TI Call TI Call TI Call TI Call TI Call TI Call TI Call TI PACKAGE OPTION ADDENDUM www.ti.com Orderable Device 19-May-2012 Status (1) Package Type Package Drawing Pins Package Qty Eco Plan (2) Lead/ Ball Finish MSL Peak Temp (3) TPS65910A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS65910A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS65910A3A1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS65910A3A1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS65910AA1RSL ACTIVE VQFN RSL 48 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR TPS65910AA1RSLR ACTIVE VQFN RSL 48 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-3-260C-168 HR Samples (Requires Login) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. 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Addendum-Page 2 PACKAGE OPTION ADDENDUM www.ti.com 19-May-2012 Addendum-Page 3 PACKAGE MATERIALS INFORMATION www.ti.com 19-May-2012 TAPE AND REEL INFORMATION *All dimensions are nominal Device Package Package Pins Type Drawing SPQ Reel Reel A0 Diameter Width (mm) (mm) W1 (mm) B0 (mm) K0 (mm) P1 (mm) W Pin1 (mm) Quadrant TPS659101A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 TPS659102A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.5 12.0 16.0 Q2 TPS659102A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 TPS659106A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 TPS659108A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 TPS65910A3A1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 TPS65910AA1RSLR VQFN RSL 48 2500 330.0 16.4 6.3 6.3 1.1 12.0 16.0 Q2 Pack Materials-Page 1 PACKAGE MATERIALS INFORMATION www.ti.com 19-May-2012 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) TPS659101A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS659102A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS659102A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS659106A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS659108A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS65910A3A1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 TPS65910AA1RSLR VQFN RSL 48 2500 346.0 346.0 33.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. 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