TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Single Chip Power Solution for Battery Powered Systems Check for Samples: TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 FEATURES 1 • • 2 • • • • Qualified for Automotive Applications Charger/Power Path Management: – 2A Output Current on the Power Path – Linear Charger; 1.5A Maximum Charge Current – 100mA/500mA/ 800mA/1300mA Current Limit From USB Input – Thermal Regulation, Safety Timers – Temperature Sense Input 3 Step-Down Converters: – 2.35MHz Fixed Frequency Operation – Up to 1.5A of Output Current – Adjustable or Fixed Output Voltage – VIN Range From 2.8V to 6.3V – Power Save Mode at Light Load Current – Output Voltage Accuracy in PWM Mode ±1.5% – Typical 19 mA Quiescent Current per Converter – 100% Duty Cycle for Lowest Dropout LDOs: – Fixed Output Voltage – Dynamic Voltage Scaling on LDO2 – 20mA Quiescent Current – 200mA Maximum Output Current – VIN Range From 1.8V to 6.3V wLED Boost Converter: – Internal Dimming Using I2C – Up to 2 × 10 LEDs – Up to 25mA per String With Internal Current Sink 2 I C Interface • • • 10 Bit A/D Converter Touch Screen Interface Undervoltage Lockout and Battery Fault Comparator APPLICATIONS • • Portable Navigation Systems Low-Power DSP Supply DESCRIPTION The TPS6507x are single chip Power Management ICs for portable applications consisting of a battery charger with power path management for a single Li-Ion or Li-Polymer cell. The charger can either be supplied by a USB port on pin USB or by a dc voltage from a wall adapter connected to pin AC. Three highly efficient 2.25MHz step-down converters are targeted at providing the core voltage, memory and I/O voltage in a processor based system. The step-down converters enter a low power mode at light load for maximum efficiency across the widest possible range of load currents. For low noise applications the devices can be forced into fixed frequency PWM using the I2C interface. The step-down converters allow the use of small inductors and capacitors to achieve a small solution size. The TPS6507x also integrate two general purpose LDOs for an output current of 200mA. These LDOs can be used to power an SD-card interface and an always-on rail, but can be used for other purposes as well. Each LDO operates with an input voltage range between 1.8V and 6.3V allowing them to be supplied from one of the step-down converters or directly from the main battery. An inductive boost converter with two programmable current sinks power two strings of white LEDs. The TPS6507x come in a 48-pin leadless package (6mm × 6mm QFN) with a 0.4mm pitch. 1 2 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. PowerPAD is a trademark of Texas Instruments. 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 © 2011, Texas Instruments Incorporated TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. ORDERING INFORMATION TA -40°C to 105°C (1) OUTPUT VOLTAGE AT DCDC3 OUTPUT VOLTAGE AT DCDC1/DCDC2 OUTPUT VOLTAGE AT LDO1/LDO2 OUTPUT CURRENT AT DCDC1/DCDC2/DCD C3 1.0V / 1.2V (OMAP-L1x8) 3.3V 1.8V / 3.3V 1.8V / 1.2V 0.6A / 1.5A / 1.5A VQFN-48 RSL 1.2V / 1.4V (Atlas IV) 3.3V 1.8V / 2.5V 1.2V / 1.2V 3 x 600 mA 1.2V / 1.35V (OMAP35xx) 1.8V 1.2V / 1.8V 1.8V / 1.8V 1.2V / 1.35V (OMAP35xx) 1.8V 1.2V / 1.8V 1.2V / 1.35V (AM3505) 1.8V 1.8V / 3.3V PART NUMBER (1) TOP-SIDE MARKING Reel of 2500 TPS65070TRSLRQ1 Preview VQFN-48 RSL Reel of 2500 TPS65072TRSLRQ1 Preview 0.6A / 0.6A / 1.5A External sequencing VQFN-48 RSL Reel of 2500 TPS65073TRSLRQ1 Preview 1.8V / 1.8V 0.6A / 0.6A / 1.5A Internal sequencing VQFN-48 RSL Reel of 2500 TPS650731TRSLRQ1 Preview 1.8V / 1.8V 0.6A / 0.6A / 1.5A Internal sequencing VQFN-48 RSL Reel of 2500 TPS650732TRSLRQ1 TPS650732T PACKAGE Package drawings, thermal data, and symbolization are available at www.ti.com/packaging. ABSOLUTE MAXIMUM RATINGS (1) over operating free-air temperature range (unless otherwise noted) VALUE / UNIT Voltage range on all pins except the pins listed below with respect to AGND –0.3 to 7V Voltage range on pins INT, RESET, PGOOD, PB_OUT with respect to AGND –0.3 to V(AVDD6) Voltage range on pins VINDCDC1/2, VINDCDC3, VINLDO respect to AGND –0.3 to V(SYS) Voltage range on pins AD_IN1, AD_IN2, AD_IN3, AD_IN4 with respect to AGND –0.3 to 3.3 V Voltage range on pins ISINK1, ISINK2, AC, USB –0.3 to 20 V Voltage range on pin L4 (output voltage of boost converter), FB_wLED –0.3 to 40 V Current at SYS, AC, USB, BAT, L3 3000 mA Current at all other pins 1000 mA Continuous total power dissipation See Dissipation Rating Table Operating free-air temperature, TA 40°C to 105°C Maximum junction temperature, TJ 125°C Storage temperature, Tst (1) –65°C to 150°C Stresses beyond those listed under absolute maximum ratings 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 under recommended operating conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. DISSIPATION RATINGS (1) PACKAGE RqJA TA ≤ 25°C POWER RATING DERATING FACTOR ABOVE TA = 25°C TA = 70°C POWER RATING TA = 85°C POWER RATING TA = 105°C POWER RATING RSL 37 K/W 2.6 W 26 mW/K 1.48 W 1.0 W 520 mW (1) 2 The thermal resistance RqJ-P junction to PowerPAD of the RSL package is 1.1 K/W. The value for RqJ-A was measured on a high K board. Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 RECOMMENDED OPERATING CONDITIONS MIN NOM MAX UNIT BATTERY CHARGER AND POWER PATH VIN Input voltage for power path manager at pins AC or USB 4.30 17 Input voltage for power path manager at pins AC or USB, charger and power path active (no overvoltage lockout) 4.30 5.8 3.6 17 Input voltage for power path manager at pins AC or USB in case there is no battery connected at pin BAT IIN IBAT Input current at AC pin 2.5 Input current at USB pin 1.3 Current at BAT pin V A 2 A DCDC CONVERTERS AND LDOs VINDCDC Input voltage range for step-down converter DCDC1, DCDC2, DCDC3 2.8 6.3 (1) V VDCDC1 Output voltage range for VDCDC1 step-down converter 0.6 VINDCDC1 V VDCDC2 Output voltage range for VDCDC2, DCDC3 step-down converter 0.6 VINDCDC2 V (1) V VINLDOx Input voltage range for LDO1 and LDO2 1.8 VLDO1 Output voltage range for LDO1 0.9 3.3 V VLDO2 Output voltage range for LDO2 0.8 3.3 V IOUTDCDC1 Output current at L1 L1 Inductor at L1 CINDCDC12 Input Capacitor at VINDCDC1 and VINDCDC2 (2) 22 COUTDCDC1 Output Capacitor at VDCDC1 (2) 10 IOUTDCDC2 Output current at L2 L2 Inductor at L2 (2) COUTDCDC2 Output Capacitor at VDCDC2 IOUTDCDC3 Output current at L3 L3 Inductor at L3 (2) 1.5 CINDCDC3 Input Capacitor at VINDCDC3 (2) 10 (2) 10 (2) 1.5 (2) 6.3 600 mA 2.2 mH mF 22 mF 1500 mA 1.5 2.2 mH 10 22 mF 1500 mA 2.2 mH mF COUTDCDC3 Output Capacitor at VDCDC3 L4 Inductor at L4 COUTWLED Output Capacitor at wLED boost converter 4.7 mF CINLDO1/2 Input Capacitor at VINLDO1/2 2.2 mF COUTLDO1 Output Capacitor at VLDO1 2.2 IOUTLDO1 Output Current at VLDO1 COUTLDO2 Output Capacitor at VLDO2 IOUTLDO2 Output Current at VLDO2 CAC Input Capacitor at AC 1 mF CUSB Input Capacitor at USB 1 mF CBAT Capacitor at BAT pin 10 CSYS Capacitor at SYS pin 22 CBYPASS Capacitor at BYPASS pin 10 mF CINT_LDO Capacitor at INT_LDO pin 2.2 mF CAVDD6 Capacitor at AVDD6 pin 4.7 TA Operating ambient temperature –40 105 °C TJ Operating junction temperature –40 125 °C (1) (2) (3) (2) 22 mF 22 mH mF 100 mA 2.2 mF 100 mA mF 100 (3) mF mF 6.3 V or VSYS whichever is less See application section for more details For proper soft-start Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 3 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com ELECTRICAL CHARACTERISTICS VSYS = 3.6V, EN_DCDCx = VSYS, L = 2.2mH, COUT = 10mF, TA = –40°C to 105°C typical values are at TA = 25°C (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT SUPPLY CURRENT VINDCDC Input voltage range for DCDC converters 2.8 Only DCDC2, DCDC3 and LDO1 enabled, device in ON-mode; DCDC converters in PFM IQ ISD VUVLO TSD Operating quiescent current Total current into VSYS, VINDCDCx, VINLDO1/2 6.3 140 Per DC/DC converter, PFM mode 19 Per DC/DC converter, PWM mode 2.5 For LDO1 or LDO2 (either one enabled) 20 For LDO1 and LDO2 (both enabled) 34 For wLED converter 1.5 Shutdown current All converters, LDOs, wLED driver and ADC disabled, no input voltage at AC and USB; SYS voltage turned off Undervoltage lockout threshold Voltage at the output of the power manager detected at pin SYS; falling voltage, voltage defined with <UVLO0>, <UVLO1> DEFAULT: 3.0V Undervoltage lockout hysteresis Rising voltage defined with <UVLO hysteresis>; DEFAULT: 500mV Undervoltage lockout deglitch time Due to internal delay Thermal shutdown for DCDC converters, wLED driver and LDOs Thermal shutdown hysteresis V –2% 30 mA 35 mA 8 12 2.8 3.0 3.1 3.25 2% mA V 360 450 mV 4 ms Increasing junction temperature 150 °C Decreasing junction temperature 20 °C EN_DCDC1, EN_DCDC2, EN_DCDC3, DEFDCDC2, DEFDCDC3, SDAT, SCLK, EN_wLED (optional) VIH High Level Input Voltage, EN_DCDC1, EN_DCDC2, EN_DCDC3, DEFDCDC2, DEFDCDC3, SDAT, SCLK, EN_wLED 1.2 VSYS V VIL Low Level Input Voltage, EN_DCDC1, EN_DCDC2, EN_DCDC3, DEFDCDC2, DEFDCDC3, SDAT, SCLK, EN_wLED 0 0.4 V IIN Input bias current, EN_DCDC1, EN_DCDC2, EN_DCDC3, DEFDCDC2, DEFDCDC3, SDAT, SCLK 1.0 mA 4 Submit Documentation Feedback 0.01 Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 DCDC1 CONVERTER PARAMETER VVINDCDC1 Input voltage range IO Maximum output RDS(ON) High side MOSFET on-resistance ILH High side MOSFET leakage current TEST CONDITIONS MIN Connected to SYS pin TYP MAX 2.8 mA VINDCDC1 = 2.8 V 150 300 VINDCDC1 = 3.5 V 120 200 VINDCDC1 = 2.8 V 200 300 VINDCDC1 = 3.5 V 160 180 VINDCDC1 = 6.3 V ILL Low side MOSFET leakage current VDS = 6.3 V ILIMF Forward current limit for TPS65072, TPS65073, TPS650731, TPS650732 ILIMF Forward current limit for TPS65070 fS Oscillator frequency Vout Fixed output voltage range 0.8 Internal resistor divider, I2C selectable 1.1 mA mΩ 1 mA 1.5 A 1.1 1.6 2.2 A 1.95 2.35 2.55 MHz 3.3 V 0.725 For TPS65070, TPS65072 3.3 For TPS65073, TPS650731, TPS650732 1.8 Vout Default output voltage Vout DC output voltage accuracy; PFM mode (1) VINDCDC1 = VDCDC1 +0.3 V to 6.3 V; 0 mA ≤ IO ≤ 0.6 A –2% 3% Vout DC output voltage accuracy; PWM mode (1) VINDCDC1 = VDCDC1 +0.3 V to 6.3 V; 0 mA ≤ IO ≤ 0.6 A –1.5% 1.5% ΔVOUT Power save mode ripple voltage (2) IOUT = 1 mA, PFM mode tStart Start-up time Time from active EN to Start switching tRamp VOUT ramp up time (2) mΩ 2 Low side MOSFET on-resistance (1) V 600 RDS(ON) RDIS UNIT 6.3 V 40 mVpp 170 ms Time to ramp from 5% to 95% of VOUT 250 ms power good threshold rising voltage Vo 5% power good threshold falling voltage Vo 10% Internal discharge resistor at L1 –35% 250 Ω 35% Output voltage specification does not include tolerance of external voltage programming resistors. Output voltage in PFM mode is scaled to +1% of nominal value. Configuration L= 2.2 mH, COUT = 10 mF DCDC2 CONVERTER PARAMETER VVINDCDC TEST CONDITIONS Input voltage range Connected to SYS pin MIN TYP 2.8 MAX 6.3 UNIT V 2 IO Maximum output current RDS(ON) High side MOSFET on-resistance ILH High side MOSFET leakage current RDS(ON) Low side MOSFET on-resistance ILL Low side MOSFET leakage current ILIMF Forward current limit fS Oscillator frequency Vout Adjustable output voltage range Vref Reference voltage Vout Fixed output voltage range TPS65072/73/731/732 TPS65070 600 Vin > 2.8 V mA 1500 VINDCDC2 = 2.8 V 150 300 VINDCDC2 = 3.5 V 120 200 VINDCDC2 = 2.8 V 200 300 VINDCDC2 = 3.5 V 160 180 0.8 1.1 1.5 2.1 2.4 3.5 1.95 2.35 2.55 VINDCDC2 = 6.3 V 2 VDS = 6.3 V TPS65072/73/731/732 TPS65070 1 2.8 V < VINDCDC2 < 6.3 V External resistor divider 0.6 Vin 600 Copyright © 2011, Texas Instruments Incorporated Internal resistor divider, I2C selectable (Default setting) 0.725 mA mΩ mA A MHz V mV 3.3 Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 mΩ V 5 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com DCDC2 CONVERTER (continued) PARAMETER TEST CONDITIONS Default output voltage for TPS65070, TPS650732 Vout Default output voltage for TPS65072 Default output voltage for TPS65073, TPS650731 DC output voltage accuracy; PFM mode DC output voltage accuracy; PWM mode Vout 1.8 For DEFDCDC2 = HIGH 3.3 For DEFDCDC2 = LOW 1.8 For DEFDCDC2 = HIGH 2.5 For DEFDCDC2 = LOW 1.2 For DEFDCDC2 = HIGH (1) VINDCDC2 = 2.8 V to 6.3 V; 0 mA ≤ IO ≤ 1.5 A DC output voltage accuracy with resistor divider at DEFDCDC2; PWM VINDCDC2 = VDCDC2 +0.3 V (min 2.8 V) to 6.3 V; 0 mA ≤ IO ≤ 1.5A Power save mode ripple voltage IOUT = 1 mA, PFM mode (2) tStart tRamp RDIS (1) (2) MAX UNIT V 1.8 (1) DC output voltage accuracy with resistor divider at DEFDCDC2; PFM ΔVOUT MIN TYP For DEFDCDC2 = LOW –2% 3% –1.5 % 1.5% –2% 3% –1% 1% 40 mVpp Start-up time Time from active EN to Start switching 170 ms VOUT ramp up time Time to ramp from 5% to 95% of VOUT 250 ms power good threshold rising voltage Vo 5% power good threshold falling voltage Vo 10% Internal discharge resistor at L2 –35% 250 35% Ω Output voltage specification does not include tolerance of external voltage programming resistors. Output voltage in PFM mode is scaled to +1% of nominal value. Configuration L= 2.2 mH, COUT = 10 mF DCDC3 CONVERTER PARAMETER VVINDCDC TEST CONDITIONS Input voltage range MIN Connected to SYS pin TYP 2.8 MAX 6.3 UNIT V 3 TPS65072 IO Maximum output current RDS(ON) High side MOSFET on-resistance ILH High side MOSFET leakage current RDS(ON) Low side MOSFET on-resistance ILL Low side MOSFET leakage current ILIMF Forward current limit fS Oscillator frequency Vout Adjustable output voltage range Vref Reference voltage Vout Fixed output voltage range TPS65070, TPS65073, TPS650731, TPS650732 (1) 6 VINDCDC3 = 2.8 V 150 300 VINDCDC3 = 3.5 V 120 200 VINDCDC3 = 2.8 V 200 300 VINDCDC3 = 3.5 V 160 180 0.8 1.1 1.5 2.1 2.4 3.5 1.95 2.35 2.55 2 VDS = 6.3 V TPS65072 TPS65070/73/731/732 1 2.8 V < VINDCDC3 < 6.3 V External resistor divider 0.6 Vin 600 Internal resistor divider, I2C selectable (Default setting) Default output voltage for TPS65072 Default output voltage for TPS65073, TPS650731, TPS650732 Vout mA 1500 VINDCDC3 = 6.3 V Default output voltage for TPS65070 Vout 600 Vin > 2.8 V DC output voltage accuracy; PFM mode DC output voltage accuracy; PWM mode (1) (1) 0.725 1.0 For DEFDCDC3 = HIGH 1.2 For DEFDCDC3 = LOW 1.2 For DEFDCDC3 = HIGH 1.4 For DEFDCDC3 = LOW 1.2 For DEFDCDC3 = HIGH 1.35 VINDCDC3 = 2.8 V to 6.3 V; 0 mA ≤ IO ≤ 1.5 A mA mΩ mA A MHz V mV 3.3 For DEFDCDC3 = LOW mΩ V V –2% 3% –1.5% 1.5% Output voltage specification does not include tolerance of external voltage programming resistors. Output voltage in PFM mode is scaled to +1% of nominal value. Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 DCDC3 CONVERTER (continued) PARAMETER TEST CONDITIONS MIN DC output voltage accuracy with resistor divider at DEFDCDC3; PWM VINDCDC3 = VDCDC3 +0.3 V (min 2.8 V) to 6.3 V; 0 mA ≤ IO ≤ 1.5A –2% ΔVOUT Power save mode ripple voltage IOUT = 1 mA, PFM mode (2) tStart Start-up time tRamp Vout DC output voltage accuracy with resistor divider at DEFDCDC3; PFM Vout RDIS (2) TYP MAX UNIT 3% –1% 1% 40 mVpp Time from active EN to Start switching 170 ms VOUT ramp up time Time to ramp from 5% to 95% of VOUT 250 ms power good threshold rising voltage Vo 5% power good threshold falling voltage Vo 10% Internal discharge resistor at L3 –35% 250 35% Ω Configuration L= 2.2 mH, COUT = 10 mF Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 7 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com VLDO1 and VLDO2 LOW DROPOUT REGULATORS MAX UNIT VINLDO Input voltage range for LDO1, LDO2 PARAMETER 1.8 6.3 (1) V VLDO1 LDO1 output voltage range 1.0 3.3 V VLDO2 LDO2 output voltage range 0.725 3.3 V IO Output current for LDO1 200 mA VLDO1 LDO1 default output voltage VLDO2 LDO2 default output voltage TEST CONDITIONS MIN Voltage options available see register description TYP For TPS65072 1.2 For TPS65070, TPS65073, TPS650731, TPS650732 1.8 For TPS65070 1.2 For TPS65072 1.2 For TPS65073, TPS650731, TPS650732 1.8 V V IO Output current for LDO2 200 mA ISC LDO1 short circuit current limit VLDO1 = GND 400 mA ISC LDO2 short circuit current limit VLDO2 = GND 400 mA Minimum voltage drop at LDO1 IO = 100 mA, VINLDO = 3.3 V 150 mV Minimum voltage drop at LDO2 IO = 100 mA, VINLDO = 3.3 V 150 mV Output voltage accuracy for LDO1, LDO2 ILDO1 = 100 mA; ILDO2 = 100 mA; Vin ≥ Vout + 200 mV –1% 1.5% Line regulation for LDO1, LDO2 VINLDO1,2 = VLDO1,2 + 0.5 V (min. 2.8 V) to 6.5 V, ILDO1 = 100 mA; ILDO2 = 100 mA –1% 1% Load regulation for LDO1, LDO2 IO = 1 mA to 200 mA Load regulation for LDO1, LDO2 IO < 1 mA ; Vo < 1V RDIS Internal discharge resistor at VLDO1, VLDO2 tRamp VOUT ramp up time (1) 8 –1% 1% –2.5% 2.5% Time to ramp from 5% to 95% of VOUT 400 Ω 250 ms 6.3 V or VSYS whichever is less Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 wLED BOOST CONVERTER PARAMETER VL4 voltage at L4 pin Vsink1,2 Input voltage at ISINK1, ISINK2 pins VOUT Internal overvoltage protection TEST CONDITIONS MIN Maximum boost factor (Vout/Vin) Tmin_off Minimum off pulse width RDS(ON) N-channel MOSFET on-resistance Isink1 = Isink2 = 20 mA, Vin = 2.8 V N-channel leakage current 35 37 9 10 0.8 Minimum voltage drop at Isink pin to GND for proper regulation VISET ISET pin voltage KISET Isink1, Isink2 fPWM Current multiple Iout/Iset 1.6 VDS = 25 V, TA = 25°C V 16 V 39 V ns Ω 2.0 A 1 mA 1.125 MHz 400 mV 1.24 V Iset current = 15 mA 1000 Iset current = 25 mA 1000 Minimum current into ISINK1, ISINK2 pins For proper dimming (string can be disabled also) Maximum current into ISINK1, ISINK2 pins Vin = 3.3 V DC current set accuracy Isinkx = 5 mA to 25 mA; no PWM dimming ±5% Current difference between Isink1 and isink2 Rset1 = 50k; Isink1 = 25 mA, Vin = 3.6 V; no PWM dimming ±5% Current difference between Isink1 and Isink2 Rset2 = 250k; Isink1 = 5 mA, Vin = 3.6 V; no PWM dimming ±5% PWM dimming frequency Rise / fall time of PWM signal 4 25 –15% 100 15% PWM dimming Bit = 01 (default) –15% 200 15% PWM dimming Bit = 10 –15% 500 15% PWM dimming Bit = 11 –15% 1000 15% 2 Dimming PWM DAC resolution mA mA PWM dimming Bit = 00 For all PWM frequencies UNIT 39 0.6 Switching frequency Vsink1, Vsink2 MAX 70 VL4 = 3.6 V N-channel MOSFET current limit ILN_NFET TYP 2.8 Hz ms 1% Reset, PB_IN, PB_OUT, PGood, Power_on, INT, EN_EXTLDO, EN_wLED PARAMETER Reset delay time and PGOOD delay time TEST CONDITIONS Input voltage at threshold pin rising; time defined with <PGOOD DELAY0>, <PGOOD DELAY1> PB-IN debounce time PB_IN “Reset-detect- time” Internal timer PGOOD low time when PB_IN = Low for >15s MIN TYP MAX –15% 20 100 (1) 200 400 15% UNIT –15% 50 15% –15% 15 15% s –15% 0.5 15% ms ms ms VIH High level input voltage on pin POWER_ON 1.2 VIN V VIH High level input voltage on pin PB_IN 1.8 AVDD6 V VIL Low Level Input Voltage, PB_IN, Power_on 0 0.4 Internal pull-up resistor from PB_IN to AVDD6 50 Output current at AVDD6 IIN Input bias current at Power_on 0.01 VOL Reset, PB_OUT, PGood, INT output low voltage, EN_EXTLDO IOL = 1 mA, Vthreshold < 1 V VOH EN_EXTLDO HIGH level output voltage IOH = 0.1 mA; optional push pull output IOL Reset, PB_OUT, PGood, INT sink current mA mA 0.3 V VSYS Reset, PB_OUT, PGood, INT open drain output in high impedance state Vth Threshold voltage at THRESHOLD pin Input voltage falling Vth_hyst Hysteresis on THRESHOLD pin Input voltage rising Iin Input bias current at EN_wLED, THRESHOLD (1) 1 1.0 1 Reset, PB_OUT, PGood,INT output leakage current 1 V mA 0.25 –4% V kΩ 4% 7 mA V mV 1 mA Default Reset delay time is set to 100 ms typical Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 9 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com ADC CONVERTER PARAMETER VIN TEST CONDITIONS MIN TYP MAX Input voltage range at AD_IN1 to AD_IN4 pin (channel 0 to channel 3) For full scale measurement 0 2.25 Input voltage range internal channel 6 to channel 9 For full scale measurement 0 6 Input voltage range on channel4 (TS pin) and channel5 (ISET pin) Unipolar measurement of charge current at pin ISET (voltage at ISET) 0 2.25 4 UNIT V Iin AD_IN1 to AD_IN4 input current 0.1 Cin Input capacitance at AD_IN1 to AD_IN4 15 pF ADC resolution 10 Bits Differential linearity error ±1 mA LSB Offset error 1 Gain error ±8 LSB 220 ms Sampling time Conversion time 5 19 Wait time after enable Time needed to stabilize the internal voltages Quiescent current, ADC enabled by I2C includes current needed for I2C block ms 1.5 ms 500 mA Quiescent current, conversion ongoing 1 Reference voltage output on pin BYPASS –1% LSB 2.260 Output current on reference output pin BYPASS mA 1% V 0.1 mA TOUCH SCREEN INTERFACE PARAMETER VTSREF TEST CONDITIONS MIN Voltage at internal voltage regulator for TSC TYP MAX 2.30 UNIT V TOUCHSCREEN PANEL SPECIFICATIONS Plate resistance X Specified by design 200 400 1200 Ω Plate resistance Y Specified by design 200 400 1200 Ω Resistance between plates contact 180 400 1000 Ω Resistance between plates pressure 180 400 1000 Position measurement; 400 Ω, 100 pF Settling time 5.5 Capacitance between plates 2 10 100 pF 20.9 22 23.1 kΩ 111 160 Total capacitance at pins TSX1,TSX2,TSY1,TSY2 to GND internal TSC reference resistance Ω ms nF SWITCH MATRIX SPECIFICATIONS Tgate resistance Specified by design 230 Ω PMOS resistance Specified by design 20 Ω NMOS resistance Specified by design 20 Ω Quiescent supply current in TSC standby mode with TSC_M[2..0] = 101 10 mA POWER PATH PARAMETER TEST CONDITIONS MIN TYP MAX UNIT QUIESCENT CURRENT IQSPP1 Quiescent current, AC or USB mode Current into AC or USB, AC or USB selected, no load at SYS 20 mA INPUT SUPPLY VBATMIN Minimum battery voltage for BAT SWITCH operation No input power, BAT_SWITCH on 2.75 V VIN(DT) Input voltage detection threshold AC detected when V(AC)–V(BAT) > VIN(DT) ; USB detected when V(USB)–V(BAT) > VIN(DT) 150 mV VIN(NDT) Input Voltage removal threshold AC not detected when V(AC)–V(BAT) < VIN(NDT) ; USB not detected when V(USB)–V(BAT) < VIN(NDT) IDISCH Internal discharge current at AC and USB input Activated based on settings in CHGCONFIG3 Bit 0 and Bit 7 10 Submit Documentation Feedback 75 95 mV mA Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 POWER PATH (continued) PARAMETER TDGL(DT) Power detected deglitch VIN(OVP) Input over voltage detection threshold TEST CONDITIONS MIN TYP AC or USB voltage increasing MAX 22.5 5.8 6 UNIT ms 6.3 V POWER PATH TIMING TSW(ACBAT) Switching from AC to BAT No USB, AC power removed 200 ms SW(USBBAT) T Switching from USB to BAT No AC, USB power removed 200 ms TSW(PSEL) Switching from USB to AC I2C 150 ms TSW(ACUSB) Switching from AC/ USB, USB / AC AC power removed or USB power removed 200 ms SYS power up delay Measured from power applied to start of power-up sequence TSYSOK 11 ms POWER PATH INTEGRATED MOSFETS CHARACTERISTICS AC Input switch dropout voltage (ILIMITAC set = 2.5 A I(SYS) = 1 A) 150 mV USB input switch dropout voltage ILIMITUSB = 1300 mA I(SYS) = 500 mA ILIMITUSB = 1300 mA I(SYS) = 800 mA 100 160 mV Battery switch dropout voltage V(BAT) = 3.0 V, I(BAT) = 1 A 85 100 mV Input Current Limit IUSB100 Input current limit; USB pin USB input current [0,0] 90 100 mA IUSB500 Input current limit; USB pin USB input current [0,1] (default) 450 500 mA IUSB800 Input current limit; USB pin USB input current [1,0] 700 800 mA IUSB1300 Input current limit; USB pin USB input current [1,1] 1000 1300 mA IAC100 Input current limit; AC pin AC input current [0,0] 90 100 mA IAC500 Input current limit; AC pin AC input current [0,1] 450 500 mA IA1300 Input current limit; AC pin AC input current [1,0] 1000 1300 mA IAC2500 Input current limit; AC pin AC input current [1,1] (default) 2000 2500 mA POWER PATH SUPPLEMENT DETECTION PROTECTION AND RECOVERY FUNCTIONS VBSUP1 Enter battery supplement mode VBSUP2 Exit battery supplement mode VSYS(SC1) Sys short-circuit detection threshold, power-on VOUT ≤ VBAT – 45 mV AC input current set to 10: 1.3A VOUT ≥ VBAT – 35 mV All power path switches set to OFF if V VSYS < VSYS(SC1) 1.4 Short circuit detection threshold hysteresis RFLT(AC) Sys Short circuit recovery pull-up resistors Internal resistor connected from AC to SYS; Specified by design RFLT(USB) Sys Short circuit recovery pull-up resistors Internal resistor connected from USB to SYS; Specified by design VSYS(SC2) Output short-circuit detection threshold, supplement mode VBAT – VSYS > VO(SC2) indicates short-circuit tDGL(SC2) Deglitch time, supplement mode short circuit tREC(SC2) Recovery time, supplement mode short circuit VBAT(SC) BAT pin short-circuit detection threshold IBAT(SC) Source current for BAT pin short-circuit detection 200 1.8 2.0 V 50 mV 500 Ω 500 Ω 250 300 mV 120 ms 60 ms 1.4 1.8 2.0 V 4 7.5 11 mA DPPM LOOP (1) VDPM (1) Threshold at which DPPM loop is enabled. This is the approximate voltage at SYS pin, when the USB or AC switch reaches current limit and the charging current is reduced; Selectable by I2C 3.5 3.75 4.25 4.50 Set with Bits <PowerPath DPPM threshold1>; <PowerPath DPPM threshold0> V If the DPPM threshold is lower than the battery voltage, supplement mode will be engaged first and the SYS voltage will chatter around the battery voltage; during that condition no DPPM mode is available. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 11 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com BATTERY CHARGER (1) PARAMETER TEST CONDITIONS MIN TYP MAX –1% 4.10 1% –1% 4.15 1% –1% 4.20 1% –1% 4.25 1% UNIT CHARGER SECTION Battery discharge current 2 Battery charger voltage Depending on setting in CHGCONFIG2 And internal EEPROM Default = 4.20V VLOWV Pre-charge to fast-charge transition threshold default = 2.9 V set with Bit <Precharge Voltage> tDGL1(LOWV) Vo(BATREG) A V 2.9 2.5 V Deglitch time on pre-charge to fast-charge transition 25 ms tDGL2(LOWV) Deglitch time on fast-charge to pre-charge transition 25 ms ICHG Battery fast charge current range VBAT(REG) > VBAT > VLOWV, VIN = VAC or VUSB = 5V ICHG Battery fast charge current VBAT > VLOWV, VIN = 5 V, IIN-MAX > ICHG, no load on SYS pin, thermal loop not active, DPPM loop not active KISET Fast charge current factor for a charge current of 1500 mA 840 900 1000 AΩ KISET Fast charge current factor for a charge current of 100 mA 930 1100 1200 AΩ 0.1× ICHG 0.12× ICHG A 0.13× ICHG A 100 1500 KISET/RISET IPRECHG Pre-charge current 0.08× ICHG ITERM Charge current value for termination detection threshold (internally set) 0.08× ICHG 0.1× ICHG tDGL(TERM) Deglitch time, termination detected VRCH Recharge detection threshold 150 100 tDGL(RCH) Deglitch time, recharge threshold detected tDGL(NO-IN) Delay time, input power loss to charger turn-off IBAT(DET) Sink current for battery detection tDET Battery detection timer A 25 Voltage below nominal charger voltage VBAT = 3.6V. Time measured from VIN: 5V → 3.3V 1ms fall-time ms 65 ms 20 ms 10 250 TCHG Charge safety timer TPRECHG Precharge timer Pre charge timer range, thermal and DPM/DPPM loops not active scalable with <Precharge Time> TPCHGADD Pre-charge safety timer “add-on” time range Maximum value for pre-charge safety timer, thermal, DPM or DPPM loops always active mV 125 3 Safety timer range, thermal and DPM not active selectable by I2C with Bits <ChargeSafetyTimerValue1> <ChargeSafetyTimerValue0> mA ms –15% 4 5 6 8 15% 25 50 30 60 35 70 0 mA 2×TCHG h min h BATTERY-PACK NTC MONITOR RT1 Pull-up resistor from thermistor to Internal LDO . I2C selectable 10 k curve 2 NTC –2% 7.35 2% 100 k curve 1 NTC –2% 62.5 2% VHOT High temperature trip point (set to 45°C) Battery charging VHYS(HOT) Hysteresis on high trip point (set to 3°C) VCOLD Low temperature trip point (set to 0°C) VHYS(COLD) kΩ kΩ 860 mV Battery charging 50 mV Battery charging 1660 mV Hysteresis on low trip point (set to 3°C) Battery charging 50 mV VnoNTC No NTC detected NTC error 2000 mV THRMDLY Deglitch time for thermistor detection after thermistor power on tDGL(TS) Deglitch time, pack temperature fault detection (1) 12 3 Battery charging ms 50 ms The Battery Charger is DISABLED by default Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 BATTERY CHARGER (1) (continued) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 115 125 135 °C THERMAL REGULATION If temperature is exceeded, charge current is reduced TJ(REG) Temperature regulation limit TJ(OFF) Charger thermal shutdown TJ(OFF-HYS) Charger thermal shutdown hysteresis 155 °C 20 °C DEVICE INFORMATION PIN ASSIGNMENT (TOP VIEW) 30 PGND3 SYS 8 29 VDCDC3 ISET 9 28 SCLK AC 10 27 SDAT TS 11 26 PGOOD USB 12 25 PB_IN 21 22 23 24 VINDCDC1/2 L2 VDCDC2 PB_OUT 19 20 L1 DEFDCDC2 VDCDC1 17 18 DEFDCDC3 15 16 EN_DCDC2 EN_DCDC1 EN_DCDC3 13 14 POWER_ON POWER PAD AGND BYPASS INT RESET FB_WLED L4 42 41 40 39 38 37 AD_IN2 (TSX2) AD_IN1 (TSX1) 44 43 AD_IN4 (TSY2) AD_IN3 (TSY1) 46 45 INT_LDO THRESHOLD 48 47 31 L3 SYS 7 30 PGND3 SYS 8 29 VDCDC3 ISET 9 28 SCLK AC 10 27 SDAT TS 11 26 PGOOD USB 12 25 PB_IN POWER PAD 24 7 6 PB_OUT SYS VIN_DCDC3 BAT 23 L3 VDCDC2 31 32 22 6 5 21 BAT ISINK2 BAT L2 VIN_DCDC3 VINDCDC1/2 32 33 19 5 4 20 BAT ISINK1 VLDO1 L1 ISINK2 VDCDC1 33 34 17 4 3 18 VLDO1 ISET1 VINLDO1/2 DEFDCDC2 ISINK1 ISET2 35 DEFDCDC3 34 36 2 15 3 1 16 VINLDO1/2 AVDD6 VLDO2 EN_DCDC2 ISET1 EN_DCDC3 ISET2 35 13 36 2 14 1 EN_DCDC1 L4 37 AVDD6 VLDO2 POWER_ON EN_EXTLDO FB_WLED 38 INT 40 39 AGND BYPASS 41 TPS65070, TPS65073, TPS650731, TPS650732 42 AD_IN2 AD_IN1 44 43 AD_IN4 AD_IN3 46 45 INT_LDO EN_wLED 48 47 TPS65072 PIN FUNCTIONS PIN NAME NO. I/O DESCRIPTION CHARGER BLOCK: AC 10 I Input power for power path manager, connect to external DC supply. Connect external 1mF (minimum) to GND USB 12 I Input power for power path manager, connect to external voltage from a USB port. Connect external 1mF (minimum) to GND. Default input current limit is 500 mA max BAT 5,6 O Charger power stage output, connect to battery. Place a ceramic capacitor of 10mF from these pins to GND 1 O Internal “always-on”-voltage. Connect a 4.7mF cap from AVDD6 to GND SYS 7, 8 O System voltage; output of the power path manager. All voltage regulators are typically powered from this output. TS 11 I Temperature sense input. Connect to NTC thermistor to sense battery pack temperature. TPS6507x can be internally programmed to operate with a 10k curve 2 or 100k curve 1 thermistor. To linearize the thermistor response, use a 75k (for the 10k NTC) or a 360k (for the 100k NTC) in parallel with the thermistor. Default setting is 10k NTC ISET 9 I Connect a resistor from ISET to GND to set the charge current. SCLK 28 I Clock input for the I2C interface. SDAT 27 AD_IN1 (TSX1) 43 AVDD6 I/O Data line for the I2C interface. I Analog input1 for A/D converter TPS65070, TPS65073, TPS650731, TPS650732 only: Input 1 to the x-plate for the touch screen. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 13 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PIN FUNCTIONS (continued) PIN I/O DESCRIPTION NAME NO. AD_IN2 (TSX2) 44 I Analog input2 for A/D converter TPS65070, TPS65073, TPS650731, TPS650732 only: Input 2 to the x-plate for the touch screen AD_IN3 (TSY1) 45 I Analog input3 for A/D converter TPS65070, TPS65073, TPS650731, TPS650732 only: Input 1 to the y-plate for the touch screen AD_IN4 (TSY2) 46 I Analog input4 for A/D converter TPS65070, TPS65073, TPS650731, TPS650732 only: Input 2 to the y-plate for the touch screen BYPASS 41 O Connect a 10mF bypass cap from this pin to GND. This pin can optionally be used as a reference output (2.26 V). The maximum load on this pin is 0.1mA. INT_LDO 48 O Connect a 2.2mF bypass cap from this pin to GND. The pin is connected to an internal LDO providing the power for the touch screen controller (TSREF). O Open drain interrupt output. An interrupt can be generated upon: • A touch of the touch screen • Voltage applied or removed at pins AC or USB • PB_IN actively pulled low (optionally actively pulled high) INT 40 The output is actively pulled low if the interrupt is active. The output goes high after the Bit causing the interrupt in register INT has been read. The interrupt sources can be masked in register INT, so no interrupt is generated and pin INT is pulled high with its external pull-up resistor. CONVERTERS: VINDCDC1/2 21 I Input voltage for DCDC1 and DCDC2 step-down converter. This pin must be connected to the SYS pin. VDCDC1 19 I Feedback voltage sense input. For the fixed voltage option, this pin must directly be connected to Vout1, for the adjustable version, this pin is connected to an external resistor divider. L1 20 O Switch Pin for DCDC1. Connect to Inductor EN_DCDC1 14 I Enable Input for DCDC1, active high VDCDC2 23 I Feedback voltage sense input, connect directly to Vout2 DEFDCDC2 18 I Select Pin of DCDC2 output voltage. L2 22 O Switch Pin of DCDC2. Connect to Inductor. EN_DCDC2 15 I Enable Input for DCDC2, active high VINDCDC3 32 I Input voltage for DCDC3 step-down converter. This pin must be connected to the SYS pin. VDCDC3 29 I Feedback voltage sense input, connect directly to Vout3 DEFDCDC3 17 I Select Pin of DCDC3 output voltage. L3 31 O Switch Pin of DCDC3. Connect to Inductor. EN_DCDC3 16 I Enable Input for DCDC3, active high PGND3 30 AGND 42 VINLDO1/2 3 I Input voltage for LDO1 and LDO2 VLDO1 4 O Output voltage of LDO1 VLDO2 2 O Output voltage of LDO2 L4 37 I Switch Pin of the white LED (wLED) boost converter. Connect to Inductor and rectifier diode. FB_wLED 38 I Feedback input for the boost converter's output voltage. Iset1 (AD_IN6) 35 I Connect a resistor from this pin to GND to set the full scale current for Isink1 and Isink2 with Bit Current Level in register WLED_CTRL0 set to 1. Analog input6 for the A/D converter. Iset2 (AD_IN7) 36 I Connect a resistor from this pin to GND to set the full scale current for Isink1 and Isink2 with Bit Current Level in register WLED_CTRL0 set to 0. Analog input7 for the A/D converter. Isink1 34 I Input to the current sink 1. Connect the cathode of the LEDs to this pin. Isink2 33 I Input to the current sink 2. Connect the cathode of the LEDs to this pin. PB_IN 25 I Enable input for TPS6507x. When pulled LOW, the DCDC converters and LDOs start with the sequencing as programmed internally. Internal 50kΩ pull-up resistor to AVDD6 14 Power GND for DCDC3. Connect to PGND (PowerPAD) Analog GND, connect to PGND (PowerPAD) Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 PIN FUNCTIONS (continued) PIN NAME NO. I/O DESCRIPTION POWER_ON 13 I Power_ON input for the internal state machine. After PB_IN was pulled LOW to turn on the TPS6507x, the POWER_ON pin needs to be pulled HIGH by the application processor to keep the system in ON-state when PB_IN is released HIGH. If POWER_ON is released LOW, the DCDC converters and LDOs will turn off when PB_IN is HIGH. PB_OUT 24 O Open drain output. This pin is driven by the status of the /PB_IN input (after debounce). PB_OUT=LOW if PB_IN=LOW PGOOD 26 O Open drain power good output. The delay time equals the setting for Reset. The pin will go low depending on the setting in register PGOODMASK. Optionally it is also driven LOW for 0.5ms when PB_IN is pulled LOW for >15s. THRESHOLD 47 I TPS65070, TPS65073, TPS650731, TPS650732:Input for the reset comparator. RESET will be LOW if this voltage drops below 1V. RESET 39 O Open drain active low reset output, reset delay time. The status depends on the voltage applied at THRESHOLD. PowerPAD™ Power ground connection for the PMU. Connect to GND Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 15 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com Functional Block Diagram AC SYS AC switch 22 mF SYS USB USB switch AVDD6 Iset 4.7 mF Batt BAT switch Charger/power path mgmt Batt TS TSX1 TSX2 INT_LDO AD_IN1 INTERNAL BIASING Thermistor biasing Touch screen biasing AD_IN2 BYPASS AD_IN3 TSY1 TSY2 AD_IN4 AD_IN1 AD_IN2 AD_IN3 AD_IN4 V_TS ANALOG MUX I_Ch V_AC V_USB AD_IN5 V_SYS V_BAT_SNS 10 BIT SAR ADC SCLK State machine I²C SDAT INT Power_ON PB_IN PB_OUT ON/OFF circuitry / power good logic undervoltage lockout PGOOD 2.2 mH L1 VIN_DCDC1/2 DCDC1 STEP-DOWN CONVERTER 600mA EN_DCDC1 VI/O VDCDC1 10 mF PGND1 2.2 mH L2 DCDC2 STEP-DOWN CONVERTER 600mA / 1500mA DEFDCDC2 EN_DCDC2 Vmem VDCDC2 10 mF PGND2/PAD 2.2 mH L3 VIN_DCDC3 DCDC3 STEP-DOWN CONVERTER DEFDCDC3 EN_DCDC3 Sequencing 600mA / 1500mA 10 mF PGND3/PAD VINLDO1/2 EN_LDO1(I2C) Vcore VDCDC3 VLDO1 LDO1 200mA LDO VLDO1 2.2 mF VLDO2 EN_LDO2(I2C) VLDO2 LDO2 200mA LDO 2.2 mF L4 SYS FB_wLED iset1 1 mF wLED boost I2C controlled up to 25mA per string iset2 Isink1 Isink2 THRESHOLD PGND4/PAD (EN_wLED) Reset - (EN_EXTLDO ) delay + Vref =1V AGND 16 Submit Documentation Feedback PGND(PAD) Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 PARAMETER MEASUREMENT INFORMATION The data sheet graphs were taken on the evaluation module (EVM). Please refer to the EVM user´s guide (SLVU291) for the setup information. TYPICAL CHARACTERISTICS TABLE OF GRAPHS FIGURE Efficiency DCDC1 vs Load current / PWM mode VO = 3.3V; VI = 3.0V, 3.6V, 4.2V, 5V 1 Efficiency DCDC1 vs Load current / PFM mode VO = 3.3V; VI = 3.0V, 3.6V, 4.2V, 5V 2 Efficiency DCDC2 vs Load current / PWM mode up to 1.5A VO = 2.5V; VI = 3.0V, 3.6V, 4.2V, 5V 3 Efficiency DCDC2 vs Load current / PFM mode up to 1.5A VO = 2.5V; VI = 3.0V, 3.6V, 4.2V, 5V 4 Efficiency DCDC2 vs Load current / PWM mode up to 1.5A VO = 1.8V; VI = 3.0V, 3.6V, 4.2V, 5V 5 Efficiency DCDC2 vs Load current / PFM mode up to 1.5A VO = 1.8V; VI = 3.0V, 3.6V, 4.2V, 5V 6 Efficiency DCDC3 vs Load current / PWM mode up to 1.5A VO = 1.2V; VI = 3.0V, 3.6V, 4.2V, 5V 7 Efficiency DCDC3 vs Load current / PFM mode up to 1.5A VO = 1.2V; VI = 3.0V, 3.6V, 4.2V, 5V 8 Efficiency DCDC3 vs Load current / PWM mode up to 1.5A VO = 1.0V; VI = 3.0V, 3.6V, 4.2V, 5V 9 Efficiency DCDC3 vs Load current / PFM mode up to 1.5A VO = 1.0V; VI = 3.0V, 3.6V, 4.2V, 5V 10 Load transient response converter 1 Scope plot; IO= 60mA to 540mA; VO = 3.3V; VI = 3.6V 11 Load transient response converter 2 Scope plot; IO= 150mA to 1350mA; VO = 1.8V; VI = 3.6V 12 Load transient response converter 3 Scope plot; IO= 150mA to 1350mA; VO = 1.2V; VI = 3.6V 13 Line transient response converter 1 Scope plot; VO= 3.3; VI = 3.6V to 5V to 3.6V; IO= 600mA 14 Line transient response converter 2 Scope plot; VO= 1.8; VI = 3.6V to 5V to 3.6V; IO = 600mA 15 Line transient response converter 3 Scope plot; VO = 1.2V; VI=3.6V to 5V to 3.6V; IO = 600mA 16 Output voltage ripple and inductor current converter 2; PWM Mode Scope plot; VI = 3.6V; VO=1.8V; IO = 10mA 17 Output voltage ripple and inductor current converter 2; PFM Mode Scope plot; VI = 3.6V; VO=1.8V; IO = 10mA 18 Startup DCDC1, DCDC2 and DCDC3, LDO1, LDO2 Scope plot 19 Load transient response LDO1 Scope plot; VO= 1.2V; VI=3.6V 20 Line transient response LDO1 Scope plot 21 KSET vs RISET 22 wLED efficiency vs duty cycle 2 x 6LEDs (VLED=19.2V); IO= 2x20mA 23 wLED efficiency vs input voltage 2 x 6LEDs (VLED=19.2V); IO= 2x20mA 24 Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 17 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com EFFICIENCY DCDC1 vs LOAD CURRENT/PWM MODE EFFICIENCY DCDC1 vs LOAD CURRENT/PFM MODE 100 3.4V 80 60 5V 50 40 60 50 40 30 30 20 20 10 10 100 90 0.001 0.01 0.1 IO - Output Current - A 1 VO = 3.3 V, PWM Mode 25°C 0 0.0001 10 0.001 1 Figure 2. EFFICIENCY DCDC2 vs LOAD CURRENT/PWM MODE EFFICIENCY DCDC2 vs LOAD CURRENT/PFM MODE 10 100 VO = 2.5 V, PWM Mode 25°C 3V 90 3V 80 3.6V 3.6V 4.2V 70 70 5V 60 Efficiency - % 4.2V Efficiency - % 0.01 0.1 IO - Output Current - A Figure 1. 80 5V 50 40 60 50 40 30 30 20 20 10 10 0 0.0001 0.001 0.01 0.1 IO - Output Current - A Figure 3. 18 4.2V 70 4.2V 0 0.0001 5V 3.6V 80 3.6V 70 Efficiency - % 3.4V 90 Efficiency - % 90 100 VO = 3.3 V, PWM Mode 25°C Submit Documentation Feedback 1 10 0 0.0001 VO = 2.5 V, PWM Mode 25°C 0.001 0.01 0.1 IO - Output Current - A 1 10 Figure 4. Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 EFFICIENCY DCDC2 vs LOAD CURRENT/PWM MODE EFFICIENCY DCDC2 vs LOAD CURRENT/PFM MODE 100 100 VO = 1.8 V, 90 PWM Mode 25°C 80 80 3V 60 4.2V 50 5V 40 20 10 10 0.01 0.1 IO - Output Current - A 1 0 0.0001 10 0.001 0.01 0.1 IO - Output Current - A 1 Figure 6. EFFICIENCY DCDC3 vs LOAD CURRENT/PWM MODE EFFICIENCY DCDC3 vs LOAD CURRENT/PFM MODE 70 VO = 1.2 V, 90 PWM Mode 25°C 80 3V 3V 70 3.6V Efficiency - % 3.6V 60 4.2V 5V 40 40 20 20 10 10 Figure 7. Copyright © 2011, Texas Instruments Incorporated 1 10 5V 50 30 0.01 0.1 IO - Output Current - A 4.2V 60 30 0.001 10 100 VO = 1.2 V, 90 PWM Mode 25°C 80 Efficiency - % VO = 1.8 V, PWM Mode 25°C Figure 5. 100 0 0.0001 5V 40 20 50 4.2V 50 30 0.001 3.6V 60 30 0 0.0001 3V 70 3.6V Efficiency - % Efficiency - % 70 90 0 0.0001 0.001 0.01 0.1 IO - Output Current - A 1 10 Figure 8. Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 19 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com EFFICIENCY DCDC3 vs LOAD CURRENT/PWM MODE EFFICIENCY DCDC3 vs LOAD CURRENT/PFM MODE 100 90 100 VO = 1 V, PWM Mode 25°C 90 80 3.6V 70 70 3.6V 60 50 4.2V Efficiency - % Efficiency - % 3V 80 3V 5V 40 40 20 20 10 10 0.01 0.1 IO - Output Current - A 1 10 5V 50 30 0.001 4.2V 60 30 0 0.0001 0 0.0001 0.001 0.01 0.1 IO - Output Current - A 1 Figure 9. Figure 10. LOAD TRANSIENT RESPONSE CONVERTER 1 LOAD TRANSIENT RESPONSE CONVERTER 2 VOUT DCDC1 (Offset: 3.3 V) 10 VOUT DCDC2 (Offset: 1.8 V) ILoad DCDC2 ILoad DCDC1 VIN DCDC3 = 3.6V, Load = 60 mA - 560 mA - 60 mA Figure 11. 20 VO = 1 V, PWM Mode 25°C Submit Documentation Feedback VIN DCDC3 = 3.6 V, Load mA - 1350 mA - 150 mA Figure 12. Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 LOAD TRANSIENT RESPONSE CONVERTER 3 VOUT DCDC3 (Offset: 1.2 V) LINE TRANSIENT RESPONSE CONVERTER 1 VOUT DCDC1 (Offset: 3.25 V) ILoad DCDC3 VIN DCDC1 (Offset: 3 V) VIN = 3.6 V - 5 V - 3.6V, Load = 0.6 A VIN DCDC3 = 3.6 V, Load = 150 mA - 1350 mA - 150 mA Figure 13. Figure 14. LINE TRANSIENT RESPONSE CONVERTER 2 LINE TRANSIENT RESPONSE CONVERTER 3 VOUT DCDC2 (Offset: 1.75 V) VOUT DCDC3 (Offset: 1.16 V) VIN DCDC2 (Offset: 3 V) VIN DCDC3 (Offset: 3 V) VIN = 3.6 V - 5 V - 3.6V, Load = 1.5 A Figure 15. Copyright © 2011, Texas Instruments Incorporated VIN = 3.6 V - 5 V - 3.6V, Load = 1.5 A Figure 16. Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 21 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com OUTPUT VOLTAGE RIPPLE AND INDUCTOR CURRENT CONVERTER 2 – PWM MODE OUTPUT VOLTAGE RIPPLE AND INDUCTOR CURRENT CONVERTER 2 – PFM MODE VOUT DCDC2 (Offset: 1.8 V) VOUT DCDC2 (Offset: 1.78 V) IL DCDC2 IL DCDC2 VIN = 3.6 V, Load = 200 mA PWM VIN = 3.6 V, Load = 15 mA PFM Figure 17. Figure 18. STARTUP DCDC1, DCDC2, AND DCDC3, LDO1, LDO2 LOAD TRANSIENT RESPONSE LDO1 VOUT DCDC1, (LOAD: 100 mA) VOUT LDO1 (Offset: 1.8 V) VOUT DCDC2, (LOAD: 100 mA) Vbat = VIN LDO1 = 3.6 V, LOAD = 20 mA - 180 mA VOUT DCDC3 (LOAD: 100 mA) LDO1 (LOAD: 50 mA) VOUT LDO2 (LOAD: 50 mA) VIN = 3.6 V Figure 19. 22 Submit Documentation Feedback ILOAD LDO1 Figure 20. Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 KSET vs RISET LINE TRANSIENT RESPONSE LDO1 1200 1150 VOUT LDO1 (Offset: 1.8 V) 1100 Kset Vbat = 5 V, VIN LDO1: 3.6 V - 5 V - 3.6 V, LOAD = 40 mA VIN LDO1 (Offset: 3 V) 1050 1000 950 900 0.1 1 10 100 RIset - kW Figure 21. Figure 22. wLED EFFICIENCY vs Duty Cycle wLED EFFICIENCY vs Vin 100 100 2x6 LEDs 20 mA each 90 90 2x6 LEDs 20 mA each 100% duty cycle 5V 3V 70 60 50 40 50 40 20 20 10 10 10 20 30 40 50 60 70 Duty Cycle - % Figure 23. Copyright © 2011, Texas Instruments Incorporated 80 90 100 25% duty cycle 60 30 0 50% duty cycle 70 30 0 75% duty cycle 80 3.6V wLED - Efficiency - % wLED - Efficiency - % 80 0 2.8 3.2 3.6 4 4.4 4.8 5.2 VI - Input Voltage - V 5.6 6 Figure 24. Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 23 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com DETAILED DESCRIPTION BATTERY CHARGER AND POWER PATH The integrate a Li-ion linear charger and system power path management targeted at space-limited portable applications. The power the system while simultaneously and independently charging the battery. This feature reduces the number of charge and discharge cycles on the battery, allows for proper charge termination and enables the system to run with a defective or absent battery pack. It also allows instant system turn-on even with a totally discharged battery. The input power source for charging the battery and running the system can be an AC adapter or an USB port. The power-path management feature automatically reduces the charging current if the system load increases. The power-path architecture also permits the battery to supplement the system current requirements when the adapter cannot deliver the peak system currents. 250 mV AVDD6V Vsys (sc1) V BAT SYS-SC1 SYS - SC2 t DGL(SC2) 500 W AC VSYS I(AC) VAC ADC2 SYS ADC0 AC SWITCH V ISET V IPRECHG I(AC) / KILIMIT ADC5 ISET 500 VI CHG I(USB) VUSB ADC1 USB I(USB) IAC T J(REG) V DPPM V OUT I²C IAC100 IAC500 DAC Sys V BAT(REG) DUSBSWON IAC1300 IAC2500 ISAMPLE Short Detect USB SWITCH DACSWON IINLIM I²C IPRECHG ITERM TJ AC Input Current Limit Error Opamp 40 mV VSYS Supplement IUSB100 IUSB500 IUSB800 IUSB1300 I²C USB Input Current Limit Error Opamp IBAT(SC) I²C BAT V LOWV V VRCH V BAT(SC) ADC3 BAT_sense IUSB I BAT (DET) tDGL(TERM) V BAT + V IN- DT t DGL2( LOWV) t DGL1( LOWV) /VUSB t DGL(RCH) BAT - SC VAC DAC I²C t DGL(NO-IN) t DGL(PGOOD) V UVLO I²C V OVP t BLK(OVP) VTHRON DTHCHG Charge control Half timers I²C I²C V HOT(45) Dynamically controlled Oscillator Fast-charge timer Pre-charge timer V ISET I²C TS t DGL(TS) V IPRECHG VI CHG ADC4 Reset timers Timers disabled V COLD (0) Timer fault I²C CC1 3 RST CC1 0 V DIS(TS) EN I²C EN Figure 25. Charger Block Diagram 24 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 POWER DOWN The charger remains in a power down mode when the input voltage at the AC or USB pin is below the under-voltage lockout threshold VUVLO. During the power down mode the host commands at the control pins are not interpreted. POWER-ON RESET The charger resets when the input voltage at the AC or USB pin enters the valid range between VUVLO and VOVLO. All internal timers and other circuit blocks are reset. The device then waits for a time period TDGL(PGOOD), after which CHARGER ACTIVE Bit indicates the input power status, and the Iset pin is interpreted. POWER-PATH MANAGEMENT There are two inputs to the power path called AC and USB. Both inputs support the same voltage rating but are typically set to a different current limit with AC beeing at the higher limit and USB at the lower. If voltage is applied at both inputs and both are enabled in register PPATH1 (default setting), AC will be preferred over USB. In this case, the deivce is only powered from AC and there is no current from USB. If voltage at AC is removed, the USB input will become and is powered from USB. The current at the input pin AC or USB of the power path manager is shared between charging the battery and powering the system load on the SYS pin. Priority is given to the system load. The input current is monitored continuously. If the sum of the charging and system load currents exceeds the preset maximum input current (programmed internally by I2C), the charging current is reduced automatically. See the electrical characteristics or the register desciption for the default current limit on AC and USB for the different family members. Figure 26 illustrates what happens in an example case where the battery fast-charge current is set to 500mA, the input current limit is set at 900mA and the system load varies from 0 to 750mA. IOUT 400 mA IBAT 750 mA 500 mA 150 mA IIN IIN -MAX 900 mA 500 mA Figure 26. Power Path Functionality SYS Output The SYS pin is the output of the power path. When is turned off and there is no voltage at AC or USB, the SYS output is disconnected internally from the battery. When is turned on by pulling PB_IN =LOW, the voltage at SYS will ramp with a soft-start. During soft start, the voltage at SYS is ramped with a 30mA current source until the voltage reached 1.8V. During the soft start, the SYS pin must not be loaded by an external load. BATTERY CHARGING When Bit CHARGER ENABLE in register CHGCONFIG1 is set to 1, battery charging can begin. First, the device checks for a short-circuit on the BAT pin: IBAT(SC) is turned on till the voltage on the BAT pin rises above VBAT(SC). If conditions are safe, it proceeds to charge the battery. The battery is charged in three phases: conditioning pre-charge, constant current fast charge (current regulation) and a constant voltage tapering-off (voltage regulation). In all charge phases, an internal control loop monitors the IC junction temperature and reduces the charge current if the internal temperature threshold is exceeded. Figure 27 shows what happens in each of the three phases: Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 25 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PRECHARGE CC FAST CHARGE CV TAPER DONE VBAT(REG) IO(CHG) Battery Current Battery Voltage VLOWV TERM CURRENT = 1 I(PRECHG) I(TERM) Figure 27. Battery Charge In the pre-charge phase, the battery is charged at a current of IPRECHG. The battery voltage starts rising. Once the battery voltage crosses the VLOWV threshold, the battery is charged at a current of ICHG. The battery voltage continues to rise. When the battery voltage reaches VBAT(REG), the battery is held at a constant value of VBAT(REG). The battery current now decreases as the battery approaches full charge. When the battery current reaches ITERM, the TERM CURRENT flag in register CHGCONFIG0 indicates charging done by going high. Note that termination detection is disabled whenever the charge rate is reduced from the set point because of the actions of the thermal loop, the DPM loop or the VIN-LOW loop. The value of the fast-charge current is set by the resistor connected from the ISET pin to GND, and is given by the equation ICHG = KISET / RISET (1) (1) RISET = KISET / ICHG (2) (2) Note that if ICHG is programmed as greater than the input current limit, the battery will not charge at the rate of ICHG, but at the slower rate of IIN-MAX (minus the load current on the OUT pin, if any). In this case, the charger timers will be slowed down by 2x whenever the thermal loop or DPPM is active. I-PRECHARGE: The value for the pre-charge current is fixed to a factor of 0.1 of the fast charge current (full scale current) programmed by the external resistor Rset ITERM: The value for the termination current threshold can be set in register CHGCONFIG3 using Bits TERMINATION CURRENT FACTOR 0 and TERMINATION CURRENT FACTOR 1. The termination current is pre-set to a factor of 0.1 of the fast charge current programmed by the external resistor Rset. Battery Detection and Recharge: Whenever the battery voltage falls below VRCH (Vset-100mV), a check is performed to see whether the battery has been removed: current IBAT(DET) is pulled from the battery for a duration tDET. If the voltage on the BAT pin remains above VLOWV, it indicates that the battery is still connected. If the charger is enabled by Bit CHARGER ENABLE in register CHGCONFIG1 set to 1, the charger is turned on again to top up the battery. 26 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 If the BAT pin voltage falls below VLOWV in the battery detection test, it indicates that the battery has been removed. The device then checks for battery insertion: it turns on FET Q2 and sources IPRECHG out of the BAT pin for duration tDET. If the voltage does not rise above VRCH, it indicates that a battery has been inserted, and a new charge cycle can begin. If, however, the voltage does rise above VRCH, it is possible that a fully charged battery has been inserted. To check for this, IBAT(DET) is pulled from the battery for tDET: if the voltage falls below VLOWV, a battery is not present. The device keeps looking for the presence of a battery. Charge Termination On/Off: Charge termination can be disabled by setting the Bit CHARGE TERMINATION ON/OFF in register CHGCONFIG1 to logic high. When termination is disabled, the device goes through the pre-charge, fast-charge and CV phases, then remains in the CV phase – the charger behaves like an LDO with an output voltage equal to VBAT(REG), able to source current up to ICHG or IIN-MAX, whichever is lesser. Battery detection is not performed. Timers: The charger in has internal safety timers for the pre-charge and fast-charge phases to prevent potential damage to either the battery or the system. The default values for the timers can be changed in registers CHGCONFIG1 and CHGCONFIG3. The timers can be disabled by clearing Bit SAFETY TIMERS ENABLE in register CHGCONFIG1. (Note that the timers are disabled when termination is disabled: Bit CHARGE TERMINATION ON/OFF in register CHGCONFIG1 =1). Dynamic Timer Function: The following events can reduce the charging current and increase the timer durations in the fast charge phase: 1. The system load current increases, and the DPPM loop reduces the available charging current 2. The input current is reduced because the input voltage has fallen to VIN-LOW 3. The device has entered thermal regulation because the IC junction temperature has exceeded TJ(REG) In each of these events, the internal timers are slowed down proportionately to the reduction in charging current. Note also that whenever any of these events occurs, termination detection is disabled. A modified charge cycle with the thermal loop active is shown in Figure 28. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 27 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PRECHARGE THERMAL REGULATION CC FAST CHARGE CV TAPER DONE VO(REG) IO(CHG) Battery Voltage Battery Current V(LOWV) TERM CURRENT = 1 I(PRECHG) I(TERM) IC junction temperature, TJ TJ(REG) Figure 28. Thermal Loop Timer Fault: The following events generate a fault status: 1. If the battery voltage does not exceed VLOWV in time tPRECHG during pre-charging 2. If the battery current does not reach ITERM in time tMAXCH in fast charge (measured from beginning of fast charge). The fault status is indicated by Bits CHG TIMEOUT or PRECHG TIMEOUT in register CHGCONFIG0 set to 1. BATTERY PACK TEMPERATURE MONITORING The device has a TS pin that connects to the NTC resistor in the battery pack. During charging, if the resistance of the NTC indicates that the battery is operating outside the limits of safe operation, charging is turned off. All timers maintain their values. When the battery pack temperature returns to a safe value, charging is resumed, and the timers are also turned back on. Battery pack temperature sensing is disabled when termination is disabled and the voltage on the TS pin is higher than VDIS(TS) (caused by absence of pack and thus absence of NTC). The default for the NTC is defined in register CHGCONFIG1 with Bit SENSOR TYPE as a 10k curve 2 NTC. The sensor can be changed to a 100k curve 1 NTC by setting the Bit to 0. There needs to be a resistor in parallel to the NTC for linearization of the temperature curve. The value for the resistor is given in the table below: 28 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Sensor type resistor value in parallel to the NTC 10K curve 2 75k 100k curve 1 360k BATTERY CHARGER STATE DIAGRAM Wait 1 ms after EN_REF_CHG=1 At any state, exit and force EN_CHG=0 && EN_SHRT=0 && DBATSINK=0. TEMP_ERROR=0. Also register should be enabled. Check Bat lowV EN_CHG=0 EN_ISHRT = 1 BAT_SHRT_D = 1 When TEMP_ERROR=1 || BAT_OVERI_D=1 || (BAT_SHRT_D = 1 && EN_CHG=1) Or when AC and USB are not detected. Out of normal mode. YES Reset timers when Supplement mode is detected. SUPLM_D=1. Per customer request. NO Check Iset shrt EN_CHG=0 Slower timers 2x when DPPM_ON=1 or TREG_ON = 1 EN_ISHRT=0 EN_ISETDET_D = 1 And wait 1ms YES ISET_SHRT_D = 1 TEMP_HOT = 0 && TEMP_COLD = 0 && TSHUT = 0 NO suspend = 0 cont precharge timer EN_ISETDET_D=0 PRCHF = 1 Reset precharge timer HALT_PRECHARGE EN_CHG=0 suspend = 1 Halt precharge timer PRECHARGE EN_CHG=1 DPRCHF=1 TEMP_HOT = 1 || TEMP_COLD = 1 || TSHUT=1 FAULT NO Timeout = 1 TEMP_HOT = 0 && TEMP_COLD = 0 && TSHUT = 0 NO PRCH_D = 1 YES EN_CHG=0 suspend = 1 Halt safety timer TEMP_HOT = 1 || TEMP_COLD = 1 || TSHUT=1 CC_CV_CHARGE EN_CHG=1 DPRCHF=0 FAULT Timeout = 1 PRCH_D = 1 YES HALT_CC_CV_CHARGE suspend = 0 cont safety timer Clear precharge timer Reset safetytimer PRCHF = 0 NO TAPER_D = 1 YES Clear safety timer EN_CHG=0 RECHARGE EN_CHG=0 NO RCH_D = 1 YES EN_DCH=1 && DBATSINK = 1 for Tdet Then release. EN_DCH returns to previous state. BAT_SRHT_D = 1 YES EN_ISHRT=1 for Tdet Figure 29. Charger State Machine DCDC CONVERTERS AND LDOs OPERATION The step down converters operate with typically 2.25MHz fixed frequency pulse width modulation (PWM) at moderate to heavy load currents. At light load currents the converter automatically enters Power Save Mode and operates in Pulse Frequency Modulation (PFM) . During PWM operation the converter use a unique fast response voltage mode controller scheme with input Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 29 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com voltage feed-forward to achieve good line and load regulation allowing the use of small ceramic input and output capacitors. At the beginning of each clock cycle initiated by the clock signal, the High Side MOSFET switch is turned on. The current flows now from the input capacitor via the High Side MOSFET switch through the inductor to the output capacitor and load. During this phase, the current ramps up until the PWM comparator trips and the control logic will turn off the switch. The current limit comparator will also turn off the switch in case the current limit of the High Side MOSFET switch is exceeded. After a dead time preventing shoot through current, the Low Side MOSFET rectifier is turned on and the inductor current will ramp down. The current flows now from the inductor to the output capacitor and to the load. It returns back to the inductor through the Low Side MOSFET rectifier. The next cycle will be initiated by the clock signal again turning off the Low Side MOSFET rectifier and turning on the on the High Side MOSFET switch. The DC-DC converters operate synchronized to each other, with converter 1 as the master. A phase shift of 180° between converter 1 and converter 2 decreases the input RMS current. Therefore smaller input capacitors can be used. Converter 3 operates in phase with converter 1. DCDC1 Converter The output voltage for converter 1 is set to a fixed voltage internally in register DEFDCDC1. The voltage can be changed using the I2C interface. The default settings are given in Table 1. Optionally the voltage can be set by an external resistor divider if configured in register DEFDCDC1. DCDC2 Converter The VDCDC2 pin must be directly connected to the DCDC2 converter's output voltage. The DCDC2 converter's output voltage can be selected via the DEFDCDC2 pin or optionally by changing the values in registers DEFDCDC2_LOW and DEFDCDC2_HIGH. If pin DEFDCDC2 is pulled to GND, register DEFDCDC2_LOW defines the output voltage. If the pin DEFDCDC2 is driven HIGH, register DEFDCDC2_HIGH defines the output voltage. Therefore, the voltage can either be changed between two values by toggling pin DEFDCDC2 or by changing the register values. Default voltages for DCDC1, DCDC2 and DCDC3 are: Table 1. Default Voltages DCDC1 DCDC2 DEFDCDC2=LOW DCDC3 DEFDCDC2=HIGH DEFDCDC3=LOW DEFDCDC3=HIGH DCDC3 Converter The VDCDC3 pin must be directly connected to the DCDC3 converter's output voltage. The DCDC3 converter's output voltage can be selected via the DEFDCDC3 pin or optionally by changing the values in registers DEFDCDC3_LOW and DEFDCDC3_HIGH. If pin DEFDCDC3 is pulled to GND, register DEFDCDC3_LOW defines the output voltage. If the pin DEFDCDC3 is driven HIGH, register DEFDCDC3_HIGH defines the output voltage. Therefore, the voltage can either be changed between two values by toggling pin DEFDCDC3 or by changing the register values. LDO2 can optionally be forced to follow the voltage defined for DCDC3 by setting Bit LDO2 TRACKING in register DEFLDO2. POWER SAVE MODE The Power Save Mode is enabled by default. If the load current decreases, the converter will enter Power Save Mode operation automatically. During Power Save Mode the converter skips switching and operates with reduced frequency in PFM mode and with a minimum quiescent current to maintain high efficiency. The converter will position the output voltage typically +1% above the nominal output voltage. This voltage positioning feature minimizes voltage drops caused by a sudden load step. The transition from PWM Mode to PFM Mode occurs once the inductor current in the Low Side MOSFET switch becomes 0. 30 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 During the Power Save Mode the output voltage is monitored with a PFM comparator. As the output voltage falls below the PFM comparator threshold of VOUTnominal +1%, the device starts a PFM pulse. For this the High Side MOSFET switch will turn on and the inductor current ramps up. Then it will be turned off and the Low Side MOSFET switch will be turned on until the inductor current becomes 0. The converter effectively delivers a current to the output capacitor and the load. If the load is below the delivered current the output voltage will rise. If the output voltage is equal or higher than the PFM comparator threshold, the device stops switching and enters a sleep mode with typical 15mA current consumption. In case the output voltage is still below the PFM comparator threshold, further PFM current pulses will be generated until the PFM comparator threshold is reached. The converter starts switching again once the output voltage drops below the PFM comparator threshold. With a single threshold comparator, the output voltage ripple during PFM Mode operation can be kept very small. The ripple voltage depends on the PFM comparator delay, the size of the output capacitor and the inductor value. Increasing output capacitor values and/or inductor values will minimize the output ripple. The PFM Mode is left and PWM Mode entered in case the output current can not longer be supported in PFM Mode or if the output voltage falls below a second threshold, called PFM comparator low threshold. This PFM comparator low threshold is set to –1% below nominal Vout, and enables a fast transition from Power Save Mode to PWM Mode during a load step. In Power Save Mode the quiescent current is reduced typically to 15mA. The Power Save Mode can be disabled through the I2C interface for each of the step-down converters independent from each other. If Power Save Mode is disabled, the converter will then operate in fixed PWM mode. Dynamic Voltage Positioning This feature reduces the voltage under/overshoots at load steps from light to heavy load and vice versa. It is active in Power Save Mode. It provides more headroom for both the voltage drop at a load step, and the voltage increase at a load throw-off. This improves load transient behavior. At light loads, in which the converter operates in PFM Mode, the output voltage is regulated typically 1% higher than the nominal value. In case of a load transient from light load to heavy load, the output voltage drops until it reaches the PFM comparator low threshold set to –1% below the nominal value and enters PWM mode. During a load throw off from heavy load to light load, the voltage overshoot is also minimized due to active regulation turning on the Low Side MOSFET switch. Figure 30. Power Save Mode 100% Duty Cycle Low Dropout Operation The device starts to enter 100% duty cycle Mode once the input voltage comes close the nominal output voltage. In order to maintain the output voltage, the High Side MOSFET switch is turned on 100% for one or more cycles. With further decreasing VIN the High Side MOSFET switch is turned on completely. In this case the converter offers a low input-to-output voltage difference. This is particularly useful in battery-powered applications to achieve longest operation time by taking full advantage of the whole battery voltage range. The minimum input voltage to maintain regulation depends on the load current and output voltage, and can be calculated as: Vinmin = Voutmax + Ioutmax × (RDSonmax + RL) (3) (3) With: Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 31 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com Ioutmax = maximum output current plus inductor ripple current RDSonmax = maximum P-channel switch RDSon. RL = DC resistance of the inductor Voutmax = nominal output voltage plus maximum output voltage tolerance Under-Voltage Lockout The under voltage lockout circuit prevents the device from malfunctioning at low input voltages and from excessive discharge of the battery and disables the DCDC converters and LDOs. The under-voltage lockout threshold is configurable in the range of typically 2.8V to 3.25V with falling voltage at the SYS pin. The default undervoltage lockout voltage as well as the hysteresis are defined in register CON_CTRL2. The default undervoltage lockout voltage is 3.0V with 500mV hysteresis. SHORT-CIRCUIT PROTECTION The High Side and Low Side MOSFET switches are short-circuit protected with maximum output current = ILIMF. Once the High Side MOSFET switch reaches its current limit, it is turned off and the Low Side MOSFET switch is turned. The High Side MOSFET switch can only turn on again, once the current in the Low Side MOSFET switch decreases below its current limit. Soft Start The 3 step-down converters in have an internal soft start circuit that controls the ramp up of the output voltage. The output voltage ramps up from 5% to 95% of its nominal value within typ. 250ms. This limits the inrush current in the converter during start up and prevents possible input voltage drops when a battery or high impedance power source is used. The Soft start circuit is enabled after the start up time tStart has expired. During soft start, the output voltage ramp up is controlled as shown in Figure 31. EN 95% 5% VOUT tStart tRAMP Figure 31. Soft Start ENABLE To start up each converter independently, the device has a separate enable pin for each of the DCDC converters. In order to enable any converter with its enable pins, the devices need to be in ON-state by pulling PB_IN=LOW or POWER_ON=HIGH. The sequencing option programmed needs to be DCDC_SQ[2..0] = 101. If EN_DCDC1, EN_DCDC2, EN_DCDC3 are set to high, the corresponding converter starts up with soft start as previously described. Pulling the enable pin low forces the device into shutdown, with a shutdown quiescent current as defined in the electrical characteristics. In this mode, the high side and low side MOSFETs are turned-off, and the entire internal control circuitry is switched-off. If disabled, the outputs of the DCDC converters are pulled low by internal 250Ω resistors, actively discharging the output capacitor. For proper operation the enable pins must be terminated and must not be left floating. 32 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Optionally, there is internal sequencing for the DCDC converters and both LDOs available. Bits DCDC_SQ[0..2] in register CON_CTRL1 define the start-up and shut-down sequence for the DCDC converters. Depending on the sequencing option, the signal at EN_DCDC1, EN_DCDC2 and EN_DCDC3 are ignored. For automatic internal sequencing, the enable signals which are not used should be connected to GND. LDO1 and LDO2 will start up automatically as defined in register LDO_CTRL1. See details about the sequencing options in the register description for CON_CTRL1 and LDO_CTRL1. RESET The contain circuitry that can generate a reset pulse for a processor with a certain delay time. The input voltage at a comparator is sensed at an input called THRESHOLD. When the voltage exceeds the threshold, the output goes high with the delay time defined in register PGOOD. The reset circuitry is not active in OFF-state. The pull-up resistor for this open drain output must not be connected directly to the battery as this may cause a leakage path when the power path (SYS voltage) is turned off. The reset delay time equals the setting for the PGOOD signal. Vbat THRESHOLD /RESET + delay - Vref = 1 V Vbat THRESHOLD comparator output (internal) RESET T RESET Figure 32. Reset Timing PGOOD (reset signal for applications processor) This open drain output generates a power-good signal depending on the status of the power good Bits for the DCDC converters and the LDOs. Register PGOODMASK defines which of the power good Bits of the converters and LDOs are used to drive the external PGOOD signal low when the voltage is below the target value. If e.g., Bit MASK DCDC2 is set to 1, the PGOOD pin will be driven low as long as the output of DCDC2 is below the target voltage. If the output voltage of DCDC2 rises to its nominal value, the PGOOD pin will be released after the delay time defined. See the default settings in the register description. PB_IN (Push-button IN) This pin is the ON/OFF button for the PMU to leave OFF-state and enter ON-state by pulling this pin to GND. Entering ON-state will first ramp the output voltage of the power path (SYS), load the default register settings and start up the DCDC converters and LDOs with the sequencing defined. In ON-state, the I2C interface is active and the wLED converter can be enabled. The system turns on if PB_IN is pulled LOW for >50ms (debounce time) AND the output voltage of the power path manager is above the undervoltage lockout voltage (AVDD6 > 3V). This is for Vbat>3V OR VAC>3V OR VUSB>3V. The default voltage for the undervoltage lockout voltage can be changed with Bits <UVLO1>, <UVLO0> in register CON_CTRL2. The value will be valid until the device was turned off completely by entering Off state. The system turns off if PB_IN is released OR the system voltage falls below the undervoltage lockout voltage of 3V. This is the case when either the battery voltage drops below 3.0V or the input voltage at the pins AC or USB is below 3V. In order to keep the enabled after PB_IN is released HIGH, there is an input pin called POWER_ON which needs to be pulled HIGH before the PB_IN button is released. POWER_ON=HIGH will typically be asserted by the application processor to keep the PMU in ON-state after the power button at PB_IN is released. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 33 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com In addition to this, there is a 15s timer which will drive PGOOD=LOW for 0.5ms when 15s are expired. The 15s timer is enabled again when PB_IN is released HIGH. If PB_IN is pulled LOW for 30s continuously, PGOOD will be driven LOW only once after the first 15s. When PGOOD is driven LOW due to PB_IN=low for 15s, all registers in are set to their default value. See Figure 33. Power OFF SYS = OFF voltage at AC applied OR voltage at USB applied OR PB_IN=0 Power OFF 2 SYS = ON all voltages powered down voltage at AC applied OR voltage at USB applied all voltages powered down YES NO AC=1 OR USB=1 WAIT FOR POWER ON SYS = ON PB_IN=0 PB_IN=1 && POWER_ON=1 POWER OFF 3 SYS = ON PB_IN=0 (falling edge detect) POWER_ON=0 POWER ON_1 SYS = ON POWER_ON=1 DCDC converters power down LDOs power down depending on sequencing option POWER ON_2 SYS = ON DCDC converters start LDOs start depending on sequencing option Figure 33. State Machine PB_OUT This pin is a status output. PB_OUT is used as the wake-up interrupt to an application processor based on the status of PB_IN. If PB_IN=LOW, PB_OUT = LOW (after 50ms debounce). If PB_IN=HIGH, PB_OUT= high impedance (HIGH). The pull-up resistor for this open drain output must not be connected directly to the battery as this may cause a leakage path when the power path (SYS) is turned off. POWER_ON This pin is an input to the PMU which needs to be pulled HIGH for the PMU to stay in POWER ON_2-state once PB_IN is released. Once this pin is pulled LOW while PB_IN=LOW, the PMU is shutting down without delay, turning off the DCDC converters and the LDOs. If POWER_ON is pulled HIGH while there is power at USB or AC, the will enter POWER ON_2-state and start the DCDC converters and LDOs according to the sequence programmed. See Figure 33. 34 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 SHORT-CIRCUIT PROTECTION All outputs are short circuit protected with a maximum output current as defined in the electrical specifications. THERMAL SHUTDOWN As soon as the junction temperature, TJ, exceeds typically 150°C for the DCDC converters or LDOs, the device goes into thermal shutdown. In this mode, the high side MOSFETs are turned-off. The device continues its operation when the junction temperature falls below the thermal shutdown hysteresis again. A thermal shutdown for one of the DCDC converters or LDOs will disable all step-down converters simultaneously. Low Dropout Voltage Regulators The low dropout voltage regulators are designed to operate well with low value ceramic input and output capacitors. They operate with input voltages down to 1.8V. The LDOs offer a maximum dropout voltage of 200mV at rated output current. Each LDO supports a current limit feature. LDO2 is enabled internally using Bit ENABLE_LDO2 in register CON_CTRL1. The output voltage for LDO2 is defined by the settings in register DEFLDO2. LDO2 can also be configured in such a way that it follows the output voltage of converter DCDC3 by setting Bit LDO2 TRACKING = 1 in register DEFLDO2. LDO1 is enabled internally using Bit ENABLE_LDO1 in register CON_CTRL1. The output voltage for LDO1 is defined by the settings in register DEFLDO1. LDO1 can also be enabled automatically depending on the settings in register LDO_CTRL1. White LED Boost Converter The converter is in shutdown mode by default and is being turned on by setting the enable Bit with the I2C interface or for TPS65072 with pin EN_wLED. The enable Bit is located in register WLED_CTRL1 and is called ENABLE ISINK as it enables the current sink for the white LEDs. Once enabled, an output voltage is automatically generated at FB_wLED, high enough to force the programmed current through the string of white LEDs. Two strings of white LEDs can be powered. The current in each of the two strings is regulated by an internal current sink at pins Isink1 and Isink2. The maximum current through the current sinks is set with two external resistors connected from pins ISET1 and ISET2 to GND. ISET1 sets the maximum current when Bit CURRENT LEVEL in register WLED_CTRL2 is set to 1. If this Bit is set to 0, which is the default setting, the maximum current is defined by the resistor connected at ISET2. This allows change between two different maximum current settings during operation. The LED current can further be dimmed with an internal PWM signal. The duty cycle for this PWM signal can be changed with the Bits LED DUTY CYCLE 0 to LED DUTY CYCLE 6 in register WLED_CTRL2 in a range from 1% to 100%. In case a dimming ratio higher than 1:100 is needed, the maximum LED current need to be changed to a lower value as defined with Iset2. In order to do this without any flicker, the PWM dimming and the current level is defined in the same register, so both settings can be changed at the same time with a single write access to register WLED_CTRL2. An internal overvoltage protection limits the maximum voltage at FB_wLED to 37V typically. The output voltage at FB_WLED also has a lower limit which is set to 12V. In case less than 4LEDs are used, the output voltage at the boost converter will not drop below 12V but the voltage from ISINK1 and ISINK2 to GND is increased accordingly. A/D Converter The 10Bit successive approximation (SAR) A/D converter with an input multiplexer can be used to monitor different voltages in the system. These signals are monitored: • Battery voltage • Voltage at AC input • Voltage at SYS output • Input voltage of battery charger • Battery temperature • Battery charge current (voltage at pin Iset; Icharge = UISET/Rset × KISET) • External voltage 1 to external voltage 4 (AD_IN1 to AD_IN4); 0V to 2.25V • Optionally: External voltage 5 to external voltage 7 (AD_IN5 to AD_IN7); 0V to 6.0V • Internal channel AD_IN14 and AD_IN15 for touch screen measurements The A/D converter uses an internal 2.26V reference. The reference needs a bypass capacitor for stability which Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 35 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com is connected to pin BYPASS. The pin can be used as a reference output with a maximum output current of 0.1mA. The internal reference voltage is forced to be on when the ADC or the touch screen interface is enabled. The reference voltage can additionally forced to be on using Bit Vref_enable in register ADCONFIG while ADC and touch screen are off to allow external circuits to be supplied with a precise reference voltage while ADC and touch screen are not used. Touch Screen Interface The touch screen itself consists of two parallel plates, called the X and Y plates, separated by short distance; contact is initiated by using a stylus or your finger. This action creates a series of resistances noted by RX1, RX2, RY1, RY2 , and Rcontact, shown in Figure 35. The points shown in the diagram as TSX1, TSX2, TSY1 and TSY2 are connected to the touch screen interface. The resistances RX1 and RX2 scale linearly with the x-position of the point of contact, where the RY1 and RY2 resistances scale with the y-position. The Rcontact resistance decreases as the pressure applied at the point of contact increases and increases as the pressure decreases. Using these relationships, the touch screen interface can make measurements of either position or pressure. X-Plate TSX1 TSX2 RX1 RX2 Rcontact TSY2 RY2 Y-Plate RY1 TSY1 Figure 34. Touch Screen The touch screen interface consists of a digital state machine, a voltage reference, and an analog switch matrix which is connected to the four wire resistive touch screen inputs (TSX1, TSX2, TSY1, TSY2) and an internal 10-Bit ADC. The state machine controls the sequencing of the switch matrix to cycle through the three types of measurement modes (position, pressure, plate resistance) and the low power standby mode. The separate internal voltage reference (TSREF) is disabled in standby and off modes. The voltage is generated by an internal LDO. Its voltage is bypassed by a capacitor connected to pin INT_LDO. The state of the touch screen is controlled by the TSC_M[2,0] Bits of the TSCMODE register (08h) as shown in Table 2. The touch screen controller uses transfer gates to the internal ADC on input channels AD_IN14 and AD_IN15. Table 2. TSC Modes CONTROL MULTIPLEXER CONNECTIONS MODE MEASUREMENT ADC_IN4 TGATE X-Position Voltage TSY1 TSREF PMOS GND NMOS Y-Position Voltage TSX1 TSREF GND NMOS GND NMOS Pressure Current TSX1 and TSX2 TSREF PMOS GND NMOS HiZ HiZ Plate X Reading on ADC_IN14 Current TSX1 0 HiZ HiZ TSREF PMOS GND NMOS Plate Y Reading on ADC_IN14 Current TSY1 1 TSREF TGATE TSREF TGATE GND NMOS GND NMOS TSC standby Voltage TSX1 and TSX2 TSC_M2 TSC_M1 TSC_M0 TSX1 TSX2 TSY1 TSY2 0 0 0 TSREF PMOS GND NMOS ADC_IN3 TGATE 0 0 1 ADC_IN1 TGATE ADC_IN2 TGATE 0 1 0 TSREF 0 1 1 1 0 1 0 36 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Table 2. TSC Modes (continued) CONTROL MULTIPLEXER CONNECTIONS MODE MEASUREMENT A/D TGATE A/D ADC used as stand alone ADC using its analog inputs OPEN Disabled (no interrupt) None TSC_M2 TSC_M1 TSC_M0 TSX1 TSX2 TSY1 TSY2 1 1 0 A/D TGATE A/D TGATE A/D TGATE 1 1 1 OPEN OPEN OPEN If the Touch screen multiplexer is set to disabled mode [111], touch to the screen will not be detected. Standby mode is entered by setting TSC_M[2:0] to 101. When there is a touch, the controller will detect a change in voltage at the TSX1 point and after a 8ms deglitch the INT pin will be asserted if the interrupt is unmasked in register INT. Once the host detects the interrupt signal, will enable the ADC converter and set the TSC_M<2:0> via the I2C bus to select any of five measurements (position, pressure, plate) as shown in Table 3. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 37 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com Table 3. TSC Equations MEASUREMENT CHANNEL EQUATION X Plate resistance AD_IN14 Rx = VTSREF/ [(VADC / 22k) × 150] Y plate resistance AD_IN14 Ry = VTSREF / [(VADC / 22k) × 150] X position AD_IN14 Xpos = Rx2 / (Rx1 + Rx2) = Rx2 / Rx Rx2 = VADC x Rx/ VTSREF; Rx1 = Rx – Rx2 Xpos = ADRESULT / 1024 Y position AD_IN14 Ypos = Ry2 / (Ry1 + Ry2) = Ry2 / Ry Ry2 = VADC x Ry/ VTSREF; Ry1 = Ry – Ry2 Ypos = ADRESULT / 1024 Pressure AD_IN14 Rc = R – Rx1//Rx2 – Ry1//Ry2 R = VTSREF/ [(VADC / 22k) × 150] Rx1//Rx2 = Rx × Xpos × (1 – Xpos) Ry1//Ry2 = Ry × Ypos × (1 – Ypos) Performing Measurements Using the Touch Screen Controller In order to take measurements with the touch screen controller, the ADC has to be enabled and configured for use with the touch screen controller (TSC) first. In case the TSC is planned to be operated interrupt driven, the TSC needs to be in TSC standby mode per default. Only in TSC standby mode an interrupt is generated based on a touch of the screen. The TSC should therefore be in this mode until a touch is detected. Afterwards, the TSC has to be configured for x-position measurement followed by y-position measurement. Now, the TSC can be set to TSC standby again to wait for the next touch of the screen. For a non-interrupt driven sequence, see TSCMODE. Register Address: 08h (page 50) in the Registers section. A typical interrupt driven sequence is given below: • Set TSCMODE to 101 to set TSC to TSC standby, so an interrupt is generated when the screen is touched • Set Bit AD enable = 1 to provide power to the ADC • Set input select for the ADC in register ADCONFIG to 1110 (AD_IN14 selected) • In register INT, set MASK TSC = 1 to unmask the interrupt on a touch of the touch screen • Read Bit TSC INT as it will be set after the TSC has been configured. Reading clears the interrupt. • After a touch was detected, an interrupt is generated by INT pin going LOW • Read Bit TSC INT to clear the interrupt • Set TSCMODE to 000 to select x-position measurement • Start an ADC conversion by setting CONVERSION START =1; wait until END OF CONVERSION = 1 • Read register ADRESULT_1 and AD_RESULT_2 • Set TSCMODE to 001 to select y-position measurement • Start an ADC conversion by setting CONVERSION START =1; wait until END OF CONVERSION = 1 • Read register ADRESULT_1 and AD_RESULT_2 • Set TSCMODE to 101 to set TSC to TSC standby again 38 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 TO ADC TSX1 TSY1 TO ADC TSX1 TGATE TGATE TSY1 PMOS PMOS RX1 RY1 RY1 RX1 RC TSREF RC RX2 TSREF RY2 RY2 R X2 NMOS TSX2 TSY2 NMOS TSY2 TSX2 Y POSITION MEASUREMENT X POSITION MEASUREMENT Figure 35. Two Position Measurement TSX1 I L/150 TSY1 IL NMOS R X1 RY1 TGATE RC TSREF TO ADC R X2 TGATE RY2 22 kW NMOS TSY2 TSX2 PRESSURE MEASUREMET Figure 36. Pressure Measurement IL/150 IL TSX1 TSY1 TSY1 PMOS R X1 TGATE TO ADC TSX1 PMOS R Y1 IL TGATE RC RC IL/150 R Y1 R X1 TSREF TSREF TGATE RX2 R Y2 RX2 TO ADC TGATE R Y2 22 kW 22 kW NMOS NMOS TSX2 TSY2 X PLATE RESISTANCE MEASUREMENT TSX2 TSY2 Y PLATE RESISTANCE MEASUREMENT Figure 37. Two Plate Resistance Measurement Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 39 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com TGATE TSX1 TSY1 NMOS TO INT BLOCK TRESHOLD DETECTOR RX1 22 kW R Y1 RC TSREF RX2 R Y2 NMOS TGATE TSX2 TSY2 STANDBY MODE Figure 38. Touch Screen Standby Mode I2C Interface Specification: Serial interface The serial interface is compatible with the standard and fast mode I2C specifications, allowing transfers at up to 400kHz. The interface adds flexibility to the power supply solution, enabling most functions to be programmed to new values depending on the instantaneous application requirements and charger status to be monitored. The has a 7-Bit address: ‘1001000’, other addresses are available upon contact with the factory. Attempting to read data from register addresses not listed in this section will result in 00h being read out. For normal data transfer, SDAT is allowed to change only when SCLK is low. Changes when SCLK is high are reserved for indicating the start and stop conditions. During data transfer, the data line must remain stable whenever the clock line is high. There is one clock pulse per Bit of data. Each data transfer is initiated with a start condition and terminated with a stop condition. When addressed, the device generates an acknowledge Bit after the reception of each byte. The master device (microprocessor) must generate an extra clock pulse that is associated with the acknowledge Bit. The device must pull down the SDAT line during the acknowledge clock pulse so that the SDAT line is a stable low during the high period of the acknowledge clock pulse. The SDAT line is a stable low during the high period of the acknowledge–related clock pulse. Setup and hold times must be taken into account. During read operations, a master must signal the end of data to the slave by not generating an acknowledge Bit on the last byte that was clocked out of the slave. In this case, the slave device must leave the data line high to enable the master to generate the stop condition. All registers are set to their default value by one of these conditions: • Voltage is below the UVLO threshold defined with registers <UVLO1>, <UVLO0> • PB_IN is asserted LOW for >15s (option) DATA CLK Data line stable; data valid Change of data allowed Figure 39. Bit Transfer on the Serial Interface 40 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 DATA CLK S P START Condition STOP Condition Figure 40. START and STOP Conditions SCLK ... SDAT A6 ... A5 A4 ... A0 R/W ACK 0 R7 R6 ... R5 R0 ACK 0 D7 D5 ... D6 D0 ACK 0 Slave Address Start ... 0 Register Address Data Stop NOTE: SLAVE=TPS6507x Figure 41. Serial I/f WRITE to TPS6507x SCLK ... SDAT A6 .. ... A0 R/W ACK 0 R7 .. ... R0 A6 .. ACK 0 ... A0 0 R/W ACK D7 Register Address D0 Slave Drives the Data Slave Address Repeated Start NOTE: SLAVE=TPS6507x ACK 0 1 Start Slave Address .. Stop Master Drives ACK and Stop Figure 42. Serial I/f READ from TPS6507x: Protocol A SCLK ... SDAT A6 .. Start ... A0 R/W ACK 0 R7 .. .. 0 Register Address Slave Address A6 .. R0 ACK 0 ... Stop Start A0 R/W ACK D7 .. D0 ACK 0 1 Slave Address Slave Drives the Data Stop Master Drives ACK and Stop Figure 43. Serial I/f READ from TPS6507x: Protocol B Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 41 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com DATA t( BUF) th(STA) t(LOW) tr tf CLK t h(STA) t(HIGH) th(DATA) STO STA tsu(STA) tsu(STO) tsu(DATA) STA STO Figure 44. Serial I/f Timing Diagram MIN MAX fMAX Clock frequency twH(HIGH) Clock high time 600 twL(LOW) Clock low time 1300 tR SDAT and CLK rise time tF SDAT and CLK fall time th(STA) Hold time (repeated) START condition (after this period the first clock pulse is generated) 600 ns th(SDAT) Setup time for repeated START condition 600 ns th(SDAT) Data input hold time 0 ns tsu(SDAT) Data input setup time 100 ns tsu(STO) STOP condition setup time 600 ns t(BUF) Bus free time 1300 ns 42 Submit Documentation Feedback 400 UNIT kHz ns ns 300 ns 300 ns Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 REGISTERS PPATH1. Register Address: 01h PPATH1 Bit name and function Default Set by signal B7 B6 USB power AC power x x B5 USB power enable 0 B4 AC power enable 0 UVLO UVLO R/W R/W Default value loaded by: Read/write R R B3 AC input current MSB 1 B2 AC input current LSB 1 Voltage Voltage removed at removed at AC OR UVLO AC OR UVLO R/W R/W B1 USB input current MSB 0 BO USB input current LSB 1 Voltage removed at USB OR UVLO R/W Voltage removed at USB OR UVLO R/W Bit 7 USB power: 0 = USB power is not present and/or not in the range valid for charging 1 = USB source is present and in the range valid for charging. B7 remains active as long as the charge source is present Bit 6 AC power: 0 = wall plug is not present and/or not in the range valid for charging 1 = wall plug source is present and in the range valid for charging. B6 remains active as long as the charge source is present Bit 5 USB POWER ENABLE 0 = USB power input is enabled 1 = USB power input is disabled (USB suspend mode) Bit 4 AC POWER ENABLE 0 = AC power input is enabled 1 = AC power input is disabled Bit 3..2 AC INPUT CURRENT 00 = input current from AC 01 = input current from AC 10 = input current from AC 11 = input current from AC Bit 1..0 input input input input USB INPUT CURRENT 00 = input current from USB 01 = input current from USB 10 = input current from USB 11 = input current from USB is is is is input input input input 100 mA max 500 mA max 1300 mA max 2500 mA is 100 mA max is 500 mA max is 800 mA max is 1300 mA max Note: safety timers are cleared if the input voltage at both AC and USB are removed. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 43 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com INT. Register Address: 02h INT B7 B6 B5 Bit name and function MASK AC/USB MASK TSC MASK PB_IN Default 0 0 0 UVLO UVLO UVLO R/W R/W R/W B4 0 Set by signal Default value loaded by: Read/write R B3 B2 B1 BO USB or AC USB or AC PB_IN TSC INT input voltage input voltage INT applied removed 0 0 0 0 Cleared when Cleared when Cleared when Cleared when read read read read UVLO UVLO UVLO UVLO R R R R Bit 7 MASK AC/USB 0 = no interrupt generated if voltage at AC or USB is applied or removed 1 = the pin INT is actively pulled low if one of the Bits 1 to Bit 0 are 1 Bit 6 MASK TSC 0 = no interrupt generated if the touch screen is detecting a “touch” 1 = the pin INT is actively pulled low if a “touch” on the touch screen is detected Bit 5 MASK PB_IN 0 = no interrupt generated if the PB_IN is pulled low. 1 = the pin INT is actively pulled low if PB_IN was pulled low. Bit 3 TSC INT 0 = no “touch” on the touch screen detected 1 = “touch” detected and the Bit has not been read ever since Bit 2 PB_IN INT 0 = PB_IN not active 1 = PB_IN is actively pulled low (or high optionally) and the Bit has not been read ever since Bit 1 USB or AC INPUT VOLTAGE APPLIED 0 = no change (voltage still applied or never applied) 1 = voltage at USB or AC has been applied and the Bit has not been read ever since Bit 0 USB or AC INPUT VOLTAGE REMOVED 0 = no change (voltage still applied or never applied) 1 = the voltage at USB or AC has been removed and the Bit has not been read ever since 44 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 CHGCONFIG0. Register Address: 03h CHGCONFIG0 Bit name and function Default Set by signal Default value loaded by: Read/write B7 Thermal regulation x B6 DPPM active x B5 Thermal Suspend x B4 Term Current x UVLO R UVLO R UVLO R UVLO R B3 0 B2 Chg Timeout x B1 Prechg Timeout x BO BatTemp error x R UVLO R UVLO R UVLO R Bit 7 THERMAL REGULATION: 0 = charger is in normal operation 1 = charge current is reduced due to high chip temperature Bit 6 DPPM ACTIVE: 0 = DPPM loop is not active 1 = DPPM loop is active; charge current is reduced to support the load with the current required Bit 5 THERMAL SUSPEND: 0 = charging is allowed 1 = charging is momentarily suspended because battery temperature is out of range Bit 4 TERM CURRENT: 0 = charge termination current threshold has not been crossed; charging or no voltage at AC and USB 1 = charge termination current threshold has been crossed and charging has been stopped. This can be due to a battery reaching full capacity or to a battery removal condition Bit 2..Bit1 CHG TIMEOUT, PRECHG TIMEOUT 0 = charging, timers did not time out 1 = one of the timers has timed out and charging has been terminated Bit 0 BAT TEMP ERROR: 0 = battery temperature is in the allowed range for charging 1 = no temperature sensor detected Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 45 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com CHGCONFIG1. Register Address: 04h CHGCONFIG1 B7 B6 B5 B4 B3 Bit name and function Charge safety timer value1 Charge safety timer value0 Safety timer enable SENSOR TYPE Charger reset 0 0 1 1 UVLO UVLO UVLO R/W R/W R/W Default Set by signal Default value loaded by: Read/write B1 BO Suspend Charge Charger enable 0 B2 Charge Termination ON/OFF 0 0 1 UVLO UVLO UVLO UVLO UVLO R/W R/W R/W R/W R/W Bit 7..6 CHARGE SAFETY TIMER VALUE0/1: 00 = safety timer times out after 4 hours 01 = safety timer times out after 5 hours 10 = safety timer times out after 6 hours 11 = safety timer times out after 8 hours Bit 5 SAFETY TIMER ENABLE 0 = pre-charge timer, fast charge timer and taper timers are disabled 1 = pre-charge timer, fast charge timer and taper timers are enabled Bit 4 SENSOR TYPE (NTC for battery temperature measurement) 0 = 100k curve 1 NTC 1 = 10k curve 2 NTC Bit 3 CHARGER RESET: 0 = inactive 1 = Reset active. This Bit must be set and then reset via the serial interface to restart the charge algorithm Bit 2 CHARGE TERMINATION ON/OFF: 0 = charge termination enabled, based on timers and termination current 1 = charge termination will not occur and the charger will always be on Bit 1 SUSPEND CHARGE: 0 = Safety Timer and Pre-Charge timers are not suspended 1 = Safety Timer and Pre-Charge timers are suspended Bit 0 CHARGER ENABLE 0 = charger is disabled 1 = charger is enabled; toggling the enable Bit will not reset the charger. Use CHARGER RESET Bit to reset charger. 46 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 CHGCONFIG2. Register Address: 05h CHGCONFIG2 Bit name and function Default Set by signal Default value loaded by: Read/write B7 Dynamic Timer function 1 B6 1 B5 Charge voltage selection1 1 B4 Charge voltage selection0 0 Precharge voltage UVLO R/W UVLO R/W UVLO R/W UVLO R/W B3 B2 B1 BO 0 0 0 0 R R R R Bit 7 DYNAMIC TIMER FUNCTION 0 = safety timers run with their nominal clock speed 1 = clock speed is divided by 2 if thermal loop or DPPM loop is active Bit 6 PRECHARGE VOLTAGE 0 = pre-charge to fast charge transition voltage is 2.5V 1 = pre-charge to fast charge transition voltage is 2.9V Bit 5..4 CHARGE VOLTAGE SELECTION0/1: 00 = 4.10V 01 = 4.15V 10 = 4.20V 11 = 4.25V Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 47 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com CHGCONFIG3. Register Address: 06h CHGCONFIG3 B7 Bit name and function Disable Isink at AC Default Set by signal Default value loaded by: Read/write B5 Power path DPPM threshold0 1 Precharge time 0 B6 Power path DPPM threshold1 1 B4 B2 Termination current factor0 1 B1 BO Charger active Disable Isink at USB 0 B3 Termination current factor1 0 x 0 UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R UVLO R/W Bit 7 DISABLE ISINK AT AC (disables an internal current sink from pin AC to GND) 0 = 60 mA current sink enabled when no input voltage at pin AC detected 1 = 60 mA current sink disabled Bit 6..5 POWER PATH DPPM THRESHOLD1/0: 00 = 3.5 V 01 = 3.75 V 10 = 4.25 V 11 = 4.50 V Bit 4 PRECHARGE TIME 0 = pre-charge time is 30 min 1 = pre-charge time is 60 min Bit 3..2 TERMINATION CURRENT FACTOR1/0: 00 = 0.04 01 = 0.1 10 = 0.15 11 = 0.2 Bit 1 CHARGER ACTIVE: 0 = charger is not charging 1 = charger is charging (DPPM or thermal regulation may be active) Bit 0 DISABLE ISINK AT USB (disables an internal current sink from pin USB to GND) 0 = 60 mA current sink enabled when no input voltage at pin USB detected 1 = 60 mA current sink disabled Note: There is a current sink on pins AC and USB which is activated when there is no voltage detected at the pin and Bit7 or Bit0 in CHCONFIG3 are set to 0. This is implemented in order to avoid the pins to be floating when not connected to a power source. The current sink is disabled automatically as soon as an input voltage is detected at the pin. 48 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 ADCONFIG. Register Address: 07h ADCONFIG B7 B5 End of conversion 1 Vref enable 0 B6 Conversion start 0 Bit name and function AD enable Default Set by signal Default value loaded by: Read/write B4 0 B3 INPUT SELECT_3 0 B2 INPUT SELECT_2 0 B1 INPUT SELECT_1 0 BO INPUT SELECT_0 0 UVLO R/W UVLO R/W UVLO R UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W Bit 7 AD ENABLE: 0 = A/D converter disabled 1 = A/D converter enabled Bit 6 CONVERSION START 0 = no conversion in progress 1 = start A/D conversion, Bit is automatically cleared if conversion is done Bit 5 END OF CONVERSION 0 = conversion did not finish 1 = conversion done Bit 4 VREF ENABLE 0 = reference voltage LDO (pin BYPASS) for ADC is disabled 1 = reference voltage LDO (pin BYPASS) for ADC is enabled Bit 3..0 INPUT SELECT – see table INPUT SELECT_3 INPUT SELECT_2 INPUT SELECT_1 INPUT SELECT_0 FULL SCALE INPUT VOLTAGE INPUT SELECTED 0 0 0 0 2.25V Voltage at AD_IN1 0 0 0 1 2.25V Voltage at AD_IN2 0 0 1 0 2.25V Voltage at AD_IN3 0 0 1 1 2.25V Voltage at AD_IN4 0 1 0 0 2.25V Voltage at TS pin 0 1 0 1 2.25V Voltage at ISET pin == battery charge current 0 1 1 0 6.0V Voltage at AC pin 0 1 1 1 6.0V Voltage at SYS pin 1 0 0 0 6.0V Input voltage of the charger 1 0 0 1 6.0V Voltage at BAT pins 1 0 1 0 6.0V Voltage at AD_IN5 (at pin THRESHOLD) 1 0 1 1 6.0V Voltage at AD_IN6 (at pin ISET1) 1 1 0 0 6.0V Voltage at AD_IN7 (at pin ISET2) 1 1 1 0 2.25 Touch screen controller (TSC); all functions 1 1 1 1 2.25 Touch screen controller (TSC); x-position and y-position only Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 49 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com TSCMODE. Register Address: 08h TSCMODE Bit name and function Default Set by signal Default value loaded by: Read/write B7 B6 B5 B4 B3 0 B2 TSC_M2 1 B1 TSC_M1 1 BO TSC_M0 1 0 0 0 0 R R R R R UVLO R/W UVLO R/W UVLO R/W Bit 3..0 MODE SELECT BITS FOR THE TOUCH SCREEN INTERFACE Note: Data conversions using the touch screen interface require setting the touch screen mode with register TSCMODE and selecting the analog input channel for the ADC according to the following table. Measurement of x-position: • Set TSCMODE to 000 to select x-position measurement • Set Bit AD ENABLE=1 to provide power to the ADC. • Set input select for the ADC in register ADCONFIG to 1110 (AD_IN14 selected). • Start a conversion by setting CONVERSION START=1; wait until END OF CONVERSION=1 • Read register ADRESULT_1 and ADRESULT_2 TSC_M2 TSC_M1 TSC_M0 TSX1 (AD_IN1) TSX2 (AD_IN2) TSY1(AD_ TSY2(AD_ IN3) IN4) MODE MEASUREMENT 0 0 0 TSREF GND A/D 0 0 1 A/D HiZ TSREF HiZ X-Position Voltage TSY1 GND Y-Position 0 1 0 TSREF TSREF GND Voltage TSX1 GND Pressure Current TSX1 and TSX2 0 1 1 TSREF GND 1 0 0 HiZ HiZ HiZ HiZ Plate X Current TSX1 TSREF GND Plate Y Current TSY1 1 0 1 V2 V2 GND GND TSC standby Voltage TSX1 and TSX2 1 1 0 A/D A/D A/D A/D A/D Voltage measurement with ADC 1 1 1 open open open open TSC and ADC disabled (no interrupt generation) ADRESULT_1. Register Address: 09h ADRESULT_1 Bit name and function Default Set by signal Default value loaded by: Read/write 50 B7 AD_BIT7 x B6 AD_BIT6 x B5 AD_BIT5 x B4 AD_BIT4 x B3 AD_BIT3 x B2 AD_BIT2 x B1 AD_BIT1 x BO AD_BIT0 LSB x R R R R R R R R Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 ADRESULT_2. Register Address: 0Ah ADRESULT_2 B7 B6 B5 B4 B3 B2 0 0 0 0 0 0 B1 AD_BIT9 MSB x R R R R R R R R B6 PGOOD DELAY 1 B5 PGOOD DELAY 0 B4 PGOOD VDCDC1 B3 PGOOD VDCDC2 B2 PGOOD VDCDC3 B1 PGOOD LDO1 BO PGOOD LDO2 x 1 1 x 0 0 PGOOD VDCDC1 PGOOD VDCDC1 R PGOOD VDCDC2 PGOOD VDCDC2 R PGOOD VDCDC3 PGOOD VDCDC3 R PGOOD LDO1 PGOOD LDO1 R PGOOD LDO2 PGOOD LDO2 R Bit name and function Default Set by signal Default value loaded by: Read/write BO AD_BIT8 x PGOOD. Register Address: 0Bh PGOOD B7 Bit name and function Reset Default for –70, -73, -731, -732 Default for TPS65072 Set by signal Default value loaded by: Read/write Bit 7 R R/W R/W Reset: 0 = indicates that the comparator input voltage is above the 1V threshold. 1 = indicates that the comparator input voltage is below the 1V threshold. Bit 6..5 PGOOD DELAY 0,1 (sets the delay time of Reset and PGOOD output): 00 = delay is 20ms 01 = delay is 100ms 10 = delay is 200ms 11 = delay is 400ms Bit 4 PGOOD VDCDC1: 0 = indicates that the VDCDC1 converter output voltage is below its target regulation voltage or disabled. 1 = indicates that the VDCDC1 converter output voltage is within its nominal range. Bit 3 PGOOD VDCDC2: 0 = indicates that the VDCDC2 converter output voltage is below its target regulation voltage or disabled. 1 = indicates that the VDCDC2 converter output voltage is within its nominal range. Bit 2 PGOOD VDCDC3: 0 = indicates that the VDCDC3 converter output voltage is below its target regulation voltage or disabled 1 = indicates that the VDCDC3 converter output voltage is within its nominal range. Bit 1 PGOOD LDO1: 0 = indicates that LDO1 output voltage is below its target regulation voltage or disabled 1 = indicates that the LDO1 output voltage is within its nominal range. Bit 0 PGOOD LDO2: 0 = indicates that the LDO2 output voltage is below its target regulation voltage or disabled. 1 = indicates that the LDO2 output voltage is within its nominal range. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 51 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PGOODMASK. Register Address: 0Ch B7 B6 0 0 0 0 B5 MASK VDCDC3 and LDO1 0 0 0 0 0 1 1 1 0 0 UVLO UVLO UVLO UVLO UVLO UVLO R/W R/W R/W R/W R/W R/W Bit name and function Default for –70 Default for -72 Default for -73, -731, -732 Set by signal Default value loaded by: Read/write R R B4 B3 B2 B1 BO MASK VDCDC1 MASK VDCDC2 MASK VDCDC3 MASKLDO1 MASK LDO2 0 1 1 0 0 0 0 0 0 0 Bit 5 MASK VDCDC3 and LDO1: 0 = indicates that the output voltage of either DCDC3 or LDO1 is within its nominal range. The PGOOD output is not affected (not driven LOW) 1 = indicates that both LDO1 AND DCDC3 output voltage is below its target regulation voltage or disabled. This will drive the PGOOD output low. Bit 4..0 MASK VDCDC1/2/3, LDO1,2: 0 = the status of the power good Bit in Register PGOOD does not affect the status of the PGOOD output pin 1 = the PGOOD pin is driven low in case the output voltage of the converter or LDO is below its target regulation voltage or disabled. 52 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 CON_CTRL1. Register Address: 0Dh CON_CTRL1 B7 B6 B5 Bit name and function DCDC_SQ2 DCDC_SQ1 DCDC_SQ0 Default for –70, –72, -73, -732 for TPS65731 only See Table 9 See Table 9 See Table 9 Set by signal Default value loaded by: Read/write UVLO R/W UVLO R/W UVLO R/W B4 DCDC1 ENABLE B3 DCDC2 ENABLE B2 DCDC3 ENABLE B1 LDO1 ENABLE BO LDO2 ENABLE 1 1 1 1 1 1 1 1 1 0 DCDC1_E DCDC2_EN DCDC3_EN LDO_ENZ NZ Z Z UVLO UVLO UVLO UVLO R/W R/W R/W R/W LDO_ENZ UVLO R/W The CON_CTRL1 register can be used to disable and enable all power supplies via the serial interface. Default is to allow all supplies to be on, providing the relevant enable pin is high. The following tables indicate how the enable pins and the CON_CTRL1 register are combined. The CON_CTRL1 Bits are automatically reset to default when the corresponding enable pin is low. Bit 7..5 DCDC_SQ2 to DCDC_SQ0: power-up sequencing (power down sequencing is the reverse) 000 = power-up sequencing is: DCDC2 only; DCDC1 and DCDC3 are not part of the automatic sequencing and are enabled by their enable pins EN_DCDC1 and EN_DCDC3 001 = power-up sequencing is DCDC2 and DCDC3 at the same time, DCDC1 is not part of the automatic sequencing and is enabled by its enable pin EN_DCDC1 010 = power-up sequencing is: DCDC1 when power good then DCDC2 and DCDC3 at the same time 011 = power-up sequencing is: DCDC3 when power good then DCDC2; DCDC1 is not part of the automatic sequencing and is controlled by its EN_DCDC1 pin. 100 = power-up sequencing is: DCDC3 is started at the same time with LDO2 if Bit MASK_EN_DCDC3 in register 0Eh is set (default is set). DCDC1 and DCDC2 are started at the same time when LDO2 is PGOOD (defined in LDO sequencing 111); DCDC3 is enabled or disabled with its EN_DCDC3 pin if MASK_EN_DCDC3 in register 0Eh is cleared (set =0). (Sirf PRIMA, start-up from OFF or start-up after SLEEP) 101 = DCDC converters are enabled individually with the external enable pins 110 = DCDC1first, when power good then DCDC2, when power good then DCDC3 111 = power-up sequencing is: DCDC1 and DCDC2 at the same time >1ms after LDO2 has been started (defined in LDO sequencing 010); DCDC3 is not part of the automatic sequencing but is enabled with its EN_DCDC3 pin (Atlas4) In case of automatic sequencing other than 101, the start is initiated by going into ON-state. DCDC converters that are not part of the automatic sequencing can be enabled by pulling their enable pin to a logic HIGH level at any time in ON-state. The enable pins for the converters that are automatically enabled, should be tied to GND. For sequencing option DCDC_SEQ=111, the start is initiated by going into ON-state, however, the external LDO connected to pin EN_EXTLDO is powered first, followed by LDO2. (The sequencing of LDO1 and LDO2 is defined in register LDO_CTRL1) Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 53 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 Bit 4..0 EN_DCDC1 PIN www.ti.com DCDC1,2,3: See tables below CON_CTRL1<4> DCDC1 CONVERTER EN_DCDC2 PIN 0 x disabled 1 0 disabled 1 1 enabled EN_DCDC3 PIN 54 Submit Documentation Feedback CON_CTRL1<3> DCDC2 CONVERTER 0 x disabled 1 0 disabled 1 1 enabled CON_CTRL1<2> DCDC3 CONVERTER 0 x disabled 1 0 disabled 1 1 enabled Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 CON_CTRL2. Register Address: 0Eh CON_CTRL2 Bit name and function Default value loaded by: Read/write B7 ENABLE 1s timer B6 ENABLE 5s timer B5 B4 B3 DS_RDY PWR_D S MASK_EN_DCDC3 UVLO UVLO UVLO UVLO UVLO R/W R/W R/W R/W R/W B2 UVLO hysteresis B1 BO UVLO1 UVLO0 BG_GOOD BG_GOOD BG_GOOD R/W R/W R/W Bit 7…6 ENABLE TIMERS: 0 = the state machine timers of 1s and 5s, respectively are disabled 1 = the state machine timers of 1s and 5s, respectively are enabled Bit 5 DS_RDY (data ready, memory content valid) for use with Sirf Prima processor DEEP SLEEP mode: 0 = status Bit which is indicating the memory content is not valid after wake up from DEEP SLEEP. This Bit is set / cleared by the Prima application processor. Cleared when device is in UVLO to tell processor there was a power loss. The Bits needs to be cleared by user software after a wake up from DEEP SLEEP to enable the DCDC2 converter to be powered down in shutdown sequencing depending on the status of LDO2. 1 = memory content is valid after wake up from DEEP SLEEP (set by I2C command by application processor only). The Prima processor is ready to power down to DEEP SLEEP mode or was just waking up from DEEP SLEEP mode. Bit 4 PWR_DS (enter DEEP SLEEP for sequencing option DCDC_SEQ=100, LDO_SQ=111): 0 = PMU is in normal operation 1 = PMU powers down all rails except DCDC2 and the external LDO on pin “EXT_LDO”. PGOOD is pulled LOW. Bit 3 MASK_EN_DCDC3; used for Prima application processor start-up sequencing: 0 = DCDC3 is enabled or disabled by the status of EN_DCDC3 for sequencing option DCDC_SEQ=100. 1 = DCDC3 will start at the same time with LDO2 for sequencing option DCDC_SEQ=100. The status of EN_DCDC3 is ignored Bit 2 UNDERVOLTAGE LOCKOUT HYSTERESIS: 0 = 400mV hysteresis 1 = 500mV hysteresis Bit 1..0 UVLO1, UVLO2 (undervoltage lockout voltage): 00 = the device turns off at 2.8V with the reverse of the sequencing defined in CON_CTRL1 01 = the device turns off at 3.0V with the reverse of the sequencing defined in CON_CTRL1 10 = the device turns off at 3.1V with the reverse of the sequencing defined in CON_CTRL1 11 = the device turns off at 3.25V with the reverse of the sequencing defined in CON_CTRL1 Note: The undervoltage lockout voltage is sensed at the SYS pin and the device goes to OFF state when the voltage is below the value defined in the register. BG_GOOD is the internal bandgap good signal which occurs at lower voltages than UVLO. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 55 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com CON_CTRL3. Register Address: 0Fh CON_CTRL3 Bit name and function Default value loaded by: Read/write B7 FPWM DCDC3 UVLO R/W B6 FPWM DCDC2 UVLO R/W B5 FPWM DCDC1 UVLO R/W B4 DCDC1 discharge UVLO R/W B3 DCDC2 discharge UVLO R/W B2 DCDC3 discharge UVLO R/W B1 LDO1 discharge UVLO R/W BO LDO2 discharge UVLO R/W Bit 7 FPWM DCDC3: 0 = DCDC3 converter operates in PWM / PFM mode 1 = DCDC3 converter is forced into fixed frequency PWM mode Bit 6 FPWM DCDC2: 0 = DCDC2 converter operates in PWM / PFM mode 1 = DCDC2 converter is forced into fixed frequency PWM mode Bit 5 FPWM DCDC1: 0 = DCDC1 converter operates in PWM / PFM mode 1 = DCDC1 converter is forced into fixed frequency PWM mode Bit 4–0 0 = the output capacitor of the associated converter or LDO is not actively discharged when the converter or LDO is disabled 1 = the output capacitor of the associated converter or LDO is actively discharged when the converter or LDO is disabled. This decreases the fall time of the output voltage at light load DEFDCDC1. Register Address: 10h DEFDCDC1 Bit name and function Default value loaded by: Read/write B7 DCDC1 extadj UVLO R/W B6 UVLO R B5 B4 B3 B2 B1 BO DCDC1[5] DCDC1[4] DCDC1[3] DCDC1[2] DCDC1[1] DCDC1[0] UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W DEFDCDC1 sets the output voltage for the DCDC1 converter. Per default the converter is internally fixed but can be programmed to an externally adjustable version by setting Bit 7 (Ext adj). The default setting is defined in an EEPROM Bit. In case the externally adjustable version is programmed, the external resistor divider need to be connected to the VDCDC1 pin, otherwise this pin needs to be connected to the output voltage directly. For the fixed voltage version, the output voltage is set with Bits B0 to B5 (DCDC1[5] to DCDC1[0]): All step-down converters provide the same output voltage range, see details under DEFDCDC3 56 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 DEFDCDC2_LOW. Register Address: 11h DEFDCDC2_LOW Bit name and function Default value loaded by: Read/write B7 B6 R R B5 DCDC2[5] UVLO R/W B4 DCDC2[4] UVLO R/W B3 DCDC2[3] UVLO R/W B2 DCDC2[2] UVLO R/W B1 DCDC2[1] UVLO R/W BO DCDC2[0] UVLO R/W B5 DCDC2[5] B4 DCDC2[4] B3 DCDC2[3] B2 DCDC2[2] B1 DCDC2[1] BO DCDC2[0] UVLO UVLO UVLO UVLO UVLO UVLO R/W R/W R/W R/W R/W R/W DEFDCDC2_HIGH. Register Address: 12h DEFDCDC2_HIGH Bit name and function Default value loaded by: Read/write B7 DCDC2 extadj B6 UVLO R/W R The output voltage for DCDC2 is switched between the value defined in DEFDCDC2_LOW and DEFDCDC2_HIGH depending on the status of the DEFDCDC2 pin. IF DEFDCDC2 is LOW the value in DEFDCDC2_LOW is selected, if DEFDCDC2 = HIGH, the value in DEFDCDC2_HIGH is selected. Per default the converter is internally fixed but can be programmed to an externally adjustable version by EEPROM similar to DCDC1. DEFDCDC3_LOW. Register Address: 13h DEFDCDC3_LOW Bit name and function Default value loaded by: Read/write B7 B6 R/W R B5 DCDC3[5] UVLO R/W B4 DCDC3[4] UVLO R/W B3 DCDC3[3] UVLO R/W B2 DCDC3[2] UVLO R/W B1 DCDC3[1] UVLO R/W BO DCDC3[0] UVLO R/W B5 B4 B3 B2 B1 BO DCDC3[5] DCDC3[4] DCDC3[3] DCDC3[2] DCDC3[1] DCDC3[0] UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W UVLO R/W DEFDCDC3_HIGH. Register Address: 14h DEFDCDC3_HIGH Bit name and function Default value loaded by: Read/write B7 DCDC3 extadj UVLO R/W B6 R The output voltage for DCDC3 is switched between the value defined in DEFDCDC3_LOW and DEFDCDC3_HIGH depending on the status of the DEFDCDC3 pin. IF DEFDCDC3 is LOW the value in DEFDCDC3_LOW is selected, if DEFDCDC3 = HIGH, the value in DEFDCDC3_HIGH is selected. Per default the converter is internally fixed but can be programmed to an externally adjustable version by EEPROM similar to DCDC2. OUTPUT VOLTAGE [V] B5 B4 B3 B2 B1 B0 0.725 0 0 0 0 0 0 0.750 0 0 0 0 0 1 0.775 0 0 0 0 1 0 0.800 0 0 0 0 1 1 0.825 0 0 0 1 0 0 0.850 0 0 0 1 0 1 0.875 0 0 0 1 1 0 0.900 0 0 0 1 1 1 Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 57 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 58 www.ti.com OUTPUT VOLTAGE [V] B5 B4 B3 B2 B1 B0 0.925 0 0 1 0 0 0 0.950 0 0 1 0 0 1 0.975 0 0 1 0 1 0 1.000 0 0 1 0 1 1 1.025 0 0 1 1 0 0 1.050 0 0 1 1 0 1 1.075 0 0 1 1 1 0 1.100 0 0 1 1 1 1 1.125 0 1 0 0 0 0 1.150 0 1 0 0 0 1 1.175 0 1 0 0 1 0 1.200 0 1 0 0 1 1 1.225 0 1 0 1 0 0 1.250 0 1 0 1 0 1 1.275 0 1 0 1 1 0 1.300 0 1 0 1 1 1 1.325 0 1 1 0 0 0 1.350 0 1 1 0 0 1 1.375 0 1 1 0 1 0 1.400 0 1 1 0 1 1 1.425 0 1 1 1 0 0 1.450 0 1 1 1 0 1 1.475 0 1 1 1 1 0 1.500 0 1 1 1 1 1 1.550 1 0 0 0 0 0 1.600 1 0 0 0 0 1 1.650 1 0 0 0 1 0 1.700 1 0 0 0 1 1 1.750 1 0 0 1 0 0 1.800 1 0 0 1 0 1 1.850 1 0 0 1 1 0 1.900 1 0 0 1 1 1 1.950 1 0 1 0 0 0 2.000 1 0 1 0 0 1 2.050 1 0 1 0 1 0 2.100 1 0 1 0 1 1 2.150 1 0 1 1 0 0 2.200 1 0 1 1 0 1 2.250 1 0 1 1 1 0 2.300 1 0 1 1 1 1 2.350 1 1 0 0 0 0 2.400 1 1 0 0 0 1 2.450 1 1 0 0 1 0 2.500 1 1 0 0 1 1 2.550 1 1 0 1 0 0 2.600 1 1 0 1 0 1 2.650 1 1 0 1 1 0 2.700 1 1 0 1 1 1 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 OUTPUT VOLTAGE [V] B5 B4 B3 B2 B1 B0 2.750 1 1 1 0 0 0 2.800 1 1 1 0 0 1 2.850 1 1 1 0 1 0 2.900 1 1 1 0 1 1 3.000 1 1 1 1 0 0 3.100 1 1 1 1 0 1 3.200 1 1 1 1 1 0 3.300 1 1 1 1 1 1 B7 B6 B5 B4 B3 0 0 0 0 0 R R R R R DEFSLEW. Register Address: 15h DEFSLEW Bit name and function Default Default value loaded by: Read/write B2 SLEW2 1 UVLO R/W B1 SLEW1 1 UVLO R/W BO SLEW0 0 UVLO R/W The DEFSLEW register defines the slew rate of the output voltage for DCDC2 and DCDC3 in case the voltage is changed during operation. In case Bit “LDO2 tracking“ in register DEFLDO2 is set, this is also valid for LDO2. When the voltage change is initiated by toggling pin DEFDCDC2 or DEFDCDC3, the start of the voltage change is triggered by the rising or falling edge of the DEFDCDC2 or DEFDCDC3 pin. If a voltage change is done internally be re-programming register DEFDCDC2_LOW, DEFDCDC2_HIGH, DEFDCDC3_LOW or DEFDCDC3_HIGH, the voltage change is initiated immediately after the new value has been written to the register with the slew rate defined. SLEW2 SLEW SLEW 1 0 VDCDC3 SLEW RATE 0 0 0 0.11 mV/ms 0 0 1 0.22 mV/ms 0 1 0 0.45 mV/ms 0 1 1 0.9 mV/ms 1 0 0 1.8 mV/ms 1 0 1 3.6 mV/ms 1 1 0 7.2 mV/ms 1 1 1 Immediate Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 59 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com LDO_CTRL1. Register Address: 16h LDO_CTRL1 Bit name and function Default value loaded by: Read/write Bit 7..5 B7 LDO_SQ2 UVLO R/W B6 LDO_SQ1 UVLO R/W B5 LDO_SQ0 UVLO R/W B4 R B3 LDO1[3] UVLO R/W B2 LDO1[2] UVLO R/W B1 LDO1[1] UVLO R/W BO LDO1[0] UVLO R/W LDO_SQ2 to LDO_SQ0: power-up sequencing: (power down sequencing is the reverse) 000 = LDO1 and LDO2 are enabled as soon as device is in ON-state by pulling PB_IN=LOW or POWER_ON=HIGH 001 = LDO1 and LDO2 are enabled after DCDC3 was enabled and its power good Bit is high. 010 = external pin at “EN_EXTLDO” is driven HIGH first, after >1ms LDO2 is enabled, LDO1 is enabled at the same time with DCDC3. EN_EXTLDO is driven LOW by going into OFF-state, LDO2 is disabled at the same time with EN_EXTLDO going LOW. Disabling LDO2 in register CON_CTRL1 will not drive EN_EXTLDO=LOW. (Atlas4) 011 = LDO1 is enabled 300us after PGOOD of DCDC1, LDO2 is off. LDO2 can be enabled/disabled by an I2C command in register CON_CTRL1. 100 = LDO1 is enabled after DCDC1 shows power good; LDO2 is enabled with DCDC3 101 = LDO1 is enabled with DCDC2; LDO2 is enabled after DCDC1 is enabled and its power good Bit is high 110 = LDO1 is enabled 10ms after DCDC2 is enabled and its power good Bit is high, LDO2 is off. LDO2 can be enabled / disabled by an I2C command in register CON_CTRL1. 111 = external pin at EN_EXTLDO is driven HIGH first, after >1ms LDO2 is enabled, LDO1 is enabled when EN_DCDC3 pin is pulled high AND DCDC3 is power good (first power–up from OFF state). LDO1 is disabled when EN_DCDC3 pin goes LOW for SLEEP mode. LDO2 is disabled at the same time with DCDC2 and DCDC1 during shutdown (Sirf PRIMA). Automatic sequencing sets the enable Bits of the LDOs accordingly, so the LDOs can be enabled or disabled by the I2C interface in ON-state. All sequencing options that define a ramp in sequence for the DCDC converters and the LDOs, (not at the same time) are timed such that the power good signal triggers the start for the next converter. If there is a time defined such as 1ms delay, the timer is started after the power good signal of the previous converter is high. LDO enable is delayed by 170us internally to match the delay for the DCDC converters. By this, for sequencing options that define a ramp at the same time for an LDO and a DCDC converter, it is made sure they will ramp at the same time, given the fact the DCDC converters have an internal 170us delay as well. 60 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com Bit 3..0 SLVSAP7 – JANUARY 2011 LDO1(3) to LDO1(0): The Bits define the default output voltage of LDO1 according to the table below: LDO1[3] LDO1[2] LDO1[1] LDO1[0] LDO1 OUTPUT VOLTAGE 0 0 0 0 1.0 V 0 0 0 1 1.1 V 0 0 1 0 1.2 V 0 0 1 1 1.25 V 0 1 0 0 1.3 V 0 1 0 1 1.35 V 0 1 1 0 1.4 V 0 1 1 1 1.5 V 1 0 0 0 1.6 V 1 0 0 1 1.8 V 1 0 1 0 2.5 V 1 0 1 1 2.75 V 1 1 0 0 2.8 V 1 1 0 1 3.0 V 1 1 1 0 3.1 V 1 1 1 1 3.3 V DEFLDO2. Register Address: 17h DEFLDO2 Bit name and function Default value loaded by: Read/write B7 R B6 LDO2 tracking B5 LDO2[5] B4 LDO2[4] B3 LDO2[3] B2 LDO2[2] B1 LDO2[1] BO LDO2[0] UVLO UVLO UVLO UVLO UVLO UVLO UVLO R/W R/W R/W R/W R/W R/W R/W The DEFLDO2 register is used to set the output voltage of LDO2 according to the voltage table defined under DEFDCDC3 when Bit LDO2 tracking is set to 0. In case Bit LDO2 tracking is set to 1, the output voltage of LDO2 is defined by the contents defined for DCDC3. Bit 6 LDO2 TRACKING: 0 = the output voltage is defined by register DEFLDO2 1 = the output voltage follows the setting defined for DCDC3 (DEFDCDC3_LOW or DEFDCDC3_HIGH, depending on the state of pin DEFDCDC3) Bit 5..0 LDO2[5] to LDO2[0]: output voltage setting for LDO2 similar to DCDC3 Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 61 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com WLED_CTRL1. Register Address: 18h WLED_CTRL1 Bit name and function Default Default value loaded by: Read/write B7 Enable ISINK 0 UVLO R/W B6 0 R B5 Dimming frequency1 0 UVLO R/W B4 Dimming frequency0 1 UVLO R/W B3 B2 B1 BO 0 0 0 0 R R R R B1 LED DUTY CYCLE_1 1 UVLO R/W BO LED DUTY CYCLE_0 0 UVLO R/W Bit 7 ENABLE ISINK: 0 = both current sinks are turned OFF, the wLED boost converter is disabled 1 = both current sinks are turned on, the wLED boost converter is enabled Bit 5..4 DIMMING FREQUENCY 0/1: 00 = 100 Hz 01 = 200 Hz 10 = 500 Hz 11 = 1000 Hz WLED_CTRL2. Register Address: 19h WLED_CTRL2 Bit name and function Default Default value loaded by: Read/write B7 Current level 0 UVLO R/W B6 LED DUTY CYCLE_6 0 UVLO R/W B5 LED DUTY CYCLE_5 0 UVLO R/W B4 LED DUTY CYCLE_4 1 UVLO R/W B3 LED DUTY CYCLE_3 1 UVLO R/W B2 LED DUTY CYCLE_2 1 UVLO R/W Bit 7 CURRENT LEVEL: 0 = current defined with resistor connected from ISET2 to GND 1 = current defined with resistor connected from ISET1 to GND Bit 6..0 sets the duty cycle for PWM dimming from 1% (0000000) to 100% (1100011). Values above 1100011 set the duty cycle to 0 %; default is 30% duty cycle 62 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 APPLICATION INFORMATION STEP-DOWN CONVERTERS OUTPUT FILTER DESIGN (INDUCTOR AND OUTPUT CAPACITOR) Inductor Selection The step-down converters operate typically with 2.2mH output inductor. Larger or smaller inductor values can be used to optimize the performance of the device for specific operation conditions. The selected inductor has to be rated for its DC resistance and saturation current. The DC resistance of the inductance will influence directly the efficiency of the converter. Therefore an inductor with lowest DC resistance should be selected for highest efficiency. Equation 4 can be used to calculate the maximum inductor current under static load conditions. The saturation current of the inductor should be rated higher than the maximum inductor current as calculated with Equation 4. This is recommended because during heavy load transient the inductor current will rise above the calculated value. Vout 1Vin D IL = Vout ´ L ´ ¦ (4) ILmax = Ioutmax + DIL 2 (5) With f = Switching Frequency (2.25MHz typical) L = Inductor Value ΔIL= Peak to Peak inductor ripple current ILmax = Maximum Inductor current The highest inductor current will occur at maximum Vin. Open core inductors have a soft saturation characteristic and they can usually handle higher inductor currents versus a comparable shielded inductor. A more conservative approach is to select the inductor current rating just for the maximum switch current of the corresponding converter. It must be considered, that the core material from inductor to inductor differs and will have an impact on the efficiency especially at high switching frequencies. Refer to Table 4 and the typical applications for possible inductors. Table 4. Tested Inductors INDUCTOR TYPE RECOMMENDED MAXIMUM DC CURRENT INDUCTOR VALUE SUPPLIER LPS3010 0.6 A 2.2 mH Coilcraft LPS3015 1.2 A 2.2 mH Coilcraft LPS4018 1.5 A 2.2 mH Coilcraft VLCF4020 1.5 A 2.2 mH TDK Output Capacitor Selection The advanced Fast Response voltage mode control scheme of the two converters allow the use of small ceramic capacitors with a typical value of 10mF, without having large output voltage under and overshoots during heavy load transients. Ceramic capacitors having low ESR values result in lowest output voltage ripple and are therefore recommended. Please refer to for recommended components. If ceramic output capacitors are used, the capacitor RMS ripple current rating will always meet the application requirements. Just for completeness the RMS ripple current is calculated as: Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 63 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com Vout 1 Vin ´ L ´ ¦ 2 ´ 3 1IRMSCout = Vout ´ (6) At nominal load current the inductive converters operate in PWM mode and the overall output voltage ripple is the sum of the voltage spike caused by the output capacitor ESR plus the voltage ripple caused by charging and discharging the output capacitor: Vout 1ö 1 Vin ´ æ DVout = Vout ´ + ESR ÷ ç L ´ ¦ è 8 ´ Cout ´ ¦ ø (7) Where the highest output voltage ripple occurs at the highest input voltage Vin. At light load currents the converters operate in Power Save Mode and the output voltage ripple is dependent on the output capacitor value. The output voltage ripple is set by the internal comparator delay and the external capacitor. The typical output voltage ripple is less than 1% of the nominal output voltage. Input Capacitor Selection/Input Voltage Because of the nature of the buck converter having a pulsating input current, a low ESR input capacitor is required for best input voltage filtering and minimizing the interference with other circuits caused by high input voltage spikes. The converters need a ceramic input capacitor of 10mF. The input capacitor can be increased without any limit for better input voltage filtering. The input voltage for the step-down converters needs to be connected to pin VINDCDC1/2 for DCDC1 and DCDC2 and to pin VINDCDC3 for DCDC3. These pins need to be tied together to the power source on pin SYS (output of the power path). The 3 step-down converters must not be supplied from different input voltages. Table 5. Possible Capacitors 22 mF 0805 TDK C2012X5R0J226MT Ceramic 22 mF 0805 Taiyo Yuden JMK212BJ226MG Ceramic 10 mF 0805 Taiyo Yuden JMK212BJ106M Ceramic 10 mF 0805 TDK C2012X5R0J106M Ceramic Output Voltage Selection The DEFDCDC2 and DEFDCDC3 pins are used to set the output voltage for step-down converter DCDC2 and DCDC3. See table 1 for the default voltages if the pins are pulled to GND or to Vcc. Voltage Change on DCDC2 and DCDC3 The output voltage of DCDC2 and DCDC3 can be changed during operation from e.g. 1.0V to 1.2V (TPS65070) and back by toggling the DEFDCDC2 or DEFDCDC3 pin. The status of the DEFDCDC3 pin is sensed during operation and the voltage is changed as soon as the logic level on this pin changes from low to high or vice versa. The output voltage for DCDC2 and DCDC3 can also be changed by changing the register content in registers DEFDCDC2_LOW, DEFDCDC2_HIGH, DEFDCDC3_LOW and DEFDCDC3_HIGH. White-LED BOOST CONVERTER LED-Current Setting/Dimming The white LED boost converter generates an output voltage, high enough to drive current through up to 10 white LEDs connected in series. support one or two strings of white LEDs. If two strings of white LEDs are used, the number of LEDs in each string is limited to 6LEDs due to the switch current limit as defined in the electrical characteristics. The boost converter block contains two current sinks to control the current through the white LEDs. The anodes of the “upper” white-LEDs are directly connected to the output voltage at the output capacitor. The cathode of the “lowest” LED is connected to the input of the current sink at pin ISINK1 or ISINK2. The internal current sink controls the output voltage of the boost converter such that there is a minimum voltage at the current sink to regulate the defined current. The maximum current is set with a resistor connected from pin 64 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 ISET1 to GND. Dimming is done with an internal PWM modulator by changing the duty cycle in the current sinks from 1% to 100%. In order to set a LED current of less than 1% of the current defined at ISET1, a second current range is set with a resistor at pin ISET2 to GND. By changing between the two current ranges and varying the duty cycle, it is possible to achieve a dimming ratio of > 1:100. The main functions of the converter like enable / disable of the converter, PWM duty cycle and dimming frequency are programmed in registers WLED_CTRL1 and WLED_CTRL2 – see the register description for details. If only one string of white LEDs are used, ISINK1 and ISINK2 need to be connected in parallel. Setup In applications not requiring the wLED boost converter, the pins should be tied to a GND as stated below: Pins L4, FB_wLED, ISINK1 and ISINK2 should be directly connected to GND. Each ISET1 and ISET2 should be connected to GND with a 100k resistor. Optionally ISET1 and ISET2 can be used as analog inputs to the ADC. In this case, these pins can be tied to a voltage source in the range from 0V to 2.25V. Setting the LED Current There are two resistors which set the default current for the current sinks at ISINK1 and ISINK2. The resistor connected to ISET1 is used if Bit CURRENT LEVEL is set 1 in register 19h. The resistor connected to ISET2 is used if Bit CURRENT LEVEL is set 0 in register 19h (default). This allows switching between two different maximum values for the LED current with one Bit to extend the resolution for dimming. Dimming is done by an internal PWM signal that turns on and off the current sinks ISINK1 and ISINK2 at 200Hz (default). The duty cycle range is 1% to 100% with a 1% resolution and a default duty cycle of 30%. In order to get the full scale LED current, the PWM dimming needs to be set to 100% in register 19h. This is done by writing 63h to register 19h. KISET is defined to be 1000 in the electrical spec, the reference voltage at ISET1 and ISET2 is 1.24V. The current for each string is set by the resistor to: ISINK1=ISINK2= KISET × 1.24V/RISETx RISET1, RISET2 = KISET × 1.24V/10mA=124 kΩ (8) (8) (9) (9) A resistor value of 124 kΩ sets the current on each string to 10mA. For one string of wLEDs, both strings need to be connected in parallel, so the current in the wLEDs is twice the current programmed by the resistor at ISET1 or ISET2. Connecting both strings in parallel is required because the wLED converter generates its output voltage dependant on the current in ISINK1 and ISINK2. If the current falls below the target, the output voltage is increased. If one string is open, the wLED driver will boost the output voltage to its maximum because it assumes the voltage is not high enough to drive current into this string (there could be different numbers of wLEDs in the two strings). Inductor Design The inductor in a boost converter serves as an energy storage element. The energy stored equals ½ L × I2. Therefore, the inductor must not be saturated as the inductance will drop and the energy stored will be reduced causing bad efficiency. The converter operates with typically 15mH to 22mH inductors. A design example for an application powering 6LEDs in one string given below: Vin = 2.8 V — minimum input voltage for the boost converter Vo = 6 × 3.2 V = 19.2 V — assuming a forward voltage of 3.2V per LED Vf = 0.5 V — forward voltage of the Schottky diode Io = 25 mA maximum LED current Fsw = 1.125 MHz — switching frequency — T=890ns Rds(on) = 0.6R — drain-source resistance of the internal NMOS switch Vsw — voltage drop at the internal NMOS switch IAVG — average current in NMOS when turned on Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 65 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com The duty cycle for a boost converter is: Vo + V ¦ - Vin D= Vo + V ¦ - Vsw (10) With: Vsw = Rds(on) ´ IAVG Iavg = Io 1 - D (11) A different approach to calculate the duty cycle is based on the efficiency of the converter. The typical number can be found in the graphs, or as a first approach, we can assume to get an efficiency of about 80% as a typical value. æ ö Vi D » ç1 - h ´ ÷ Vo + V ¦ ø è (12) With the values given above 2.8 V æ ö D » ç 1 - 0.8 ÷ » 89% 19.2 V + 0.5 V è ø (13) ton = T × D = 890 ns × 0.89 = 792 ns toff = 890 ns – 792 ns = 98ns Vsw = Rds(on) ´ IAVG = Rds(on) Io 25 mA = 0.6W ´ » 140 mV 1 - D 1 - 0.89 ´ (14) When the NMOS switch is turned on, the input voltage is forcing a current into the inductor. The current slope can be calculated with: V L ´ dt (Vin - Vsw) ´ dt (2.8V - 0.14V) ´ 792 ns di = = = = 117 mA L L 18 mH (15) Iavg = Io 25 mA = = 227 mA 1 - D 1 - 0.89 (16) The minimum and maximum inductor current can be found by adding half of the inductor current ripple (di) to the average value, which gives: 117 mA Imax = 227 mA + = 285 m A 2 117 mA Imin = 227 m A = 169 mA 2 (17) Given the values above, an inductor with a current rating greater than 290mA is needed. Plenty of margin should be kept to the rating in the inductor vendors data sheets as the maximum current is typically specified at a inductance drop of 20% or even 30%. A list of tested inductors is given in Table 6 with the test conditions as mentioned below. Test conditions: • Vin = 2.8V • Vf = 3.2V (per LED) • Vf = 0.5V (Schottky diode) • Iout = 25mA per string; no dimming Table 6. Tested Inductors 66 LED CONFIGURATION INDUCTOR TYPE INDUCTOR VALUE SUPPLIER 1 × 6LEDs LPS3015 18 mH Coilcraft 2 × 6LEDs LPS4018 47 mH Coilcraft 1 × 10LEDs LPS4018 47 mH Coilcraft Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Other inductors, with lower or higher inductance values can be used. A higher inductance will cause a lower inductor current ripple and therefore will provide higher efficiency. The boost converter will also stay in continuous conduction mode over a wider load current range. The energy stored in an inductor is given by E=1/2L × I2 where I is the peak inductor current. The maximum current in the inductor is limited by the internal current limit of the device, so the maximum power is given by the minimum peak current limit (see electrical specifications) times the inductance value. For highest output power, a large inductance value is needed. The minimum inductor value possible is limited by the energy needed to supply the load. The limit for the minimum inductor value is given during the on-time of the switch such that the current limit is not reached. Example for the minimum inductor value: Vin = 4.2 V, Vout = 19.7 V, Iout = 5 mA, Vsw =0.1 V → D = 79% → ton = 703 ns During the on-time, the inductor current should not reach the current limit of 1.4 A. With V… voltage across the inductor (V = Vin–Vsw) → L = V × dt/di = (4.2 V–0.1 V) × 703ns/1.4A = 2mH Diode Selection Due to the non-synchronous design of the boost converter, an external diode is needed. For best performance, a Schottky diode with a voltage rating of 40V or above should be used. A diode such as the MBR0540 with an average current rating of 0.5A is sufficient. Output Capacitor Selection A ceramic capacitor such as X5R or X7R type is required at the output. See Table 7 for reference. Table 7. Tested Capacitor LED CONFIGURATION TYPICAL VOLTAGE ACROSS OUTPUT CAPACITOR CAPACITOR VALUE CAPACITOR SIZE 2x6LEDs or 1x6LEDs 21 V 4.7 mF / 50 V 1x10LEDs 35 V 4.7 mF / 50 V CAPACITOR TYPE MANUFACTURER 1206 UMK316BJ475KL Taiyo Yuden 1210 GRM32ER71H475KA Murata Input Capacitor Selection A small ceramic input capacitor of 10 mF is needed at the input of the boost converter. If the inductor is directly connected to the SYS output of , the capacitor can be shared. In this case the capacitance needs to be 22mF or above. Only X5R or X7R ceramic capacitors should be used. BATTERY CHARGER Temperature Sensing The battery charger integrated in has an over temperature protection for the Li-ion cell. The temperature is sensed with a NTC located at the battery. Comparators in suspend charge at a temperature below 0°C and above 45°C. The charger supports two different resistor values for the NTC. The default is internally programmed to 10k. It is possible to change to a 100k NTC with the I2C interface. Table 8. NTCs Supported RESISTANCE AT 25°C CURVE / B VALUE RT2 NEEDED FOR LINEARIZATION MANUFACTURER 10k Curve 2 / B=3477 75k Several 100k Curve 1 / B=3964 370k Several Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 67 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com For best performance, the NTC needs to be linearized by connecting a resistor (RT2) in parallel to the NTC as shown in Figure 46. The resistor value of RT2 needed for linearization can be found in Table 8. If the battery charger needs to be operated without a NTC connected, e.g. for test purposes, a resistor of 10k or 100k needs to be connected from TS to GND, depending for which NTC is configured to in register CHCONFIG1. RT1 TS 2.25 V RT2 NTC VHOT(45) VCOLD(0) + + Figure 45. Linearizing the NTC Changing the Charging Temperature Range (Default 0°C to 45°C) The battery charger is designed to operate with the two NTCs listed above. These will give a cold and hot temperature threshold of 0°C and 45°C. If the charger needs to operate (charge) in a wider temperature range e.g. –5°C to 50°C, the circuit can be modified accordingly. The NTC changes its resistance based on the equation listed below: RNTC (T ) = æ æ 1 1 öö ç B´ç ÷ T T 0 ÷ø ø R 25 ´ eè è (18) With: R25 = NTC resistance at 25°C T = temperature in Kelvin T0 = reference temperature (298K) Resistor RT2 in parallel to the NTC is used to linearize the resistance change with temperature of the NTC. As the NTC has a high resistance at low temperature, the resulting resistance of NTC in parallel with RT2 is lower especially for low temperatures where the NTC has a high resistance, so RT2 in parallel has a significant impact. For higher temperatures, the resistance of the NTC dropped significantly, so RT2 in parallel does not change the resulting resistance a lot. See Figure 46. RT1 2.25 V TS RT3 RT2 NTC VHOT(45) VCOLD(0) + + Figure 46. Changing the Temperature Range 68 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 40000 36000 32000 RNTC (T) 28000 24000 20000 16000 Rp (T) 12000 8000 4000 0 -5 0 5 10 15 20 25 30 35 Temperature - (T) 40 45 50 Figure 47. NTC [R(T)] and NTC in Parallel to RT2 [Rges(T)] 1.8 1.7 1.6 1.5 VTS (T) 1.4 1.3 1.2 1.1 1 0.9 0.8 -5 0 5 10 15 20 25 30 35 Temperature - (T) 40 45 50 Figure 48. Resulting TS Voltage As Figure 47 shows, the result is an extended charging temperature range at lower temperatures. The upper temperature limit is shifted to lower values as well resulting in a V(HOT) temperature of slightly less than 45°C. Therefore RT3 is needed to shift the temperature range to higher temperatures again. Figure 48 shows the result for: • RT2 = 47k • RT3 = 820R Using these values will extend the temperature range for charging to –5°C to 50°C. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 69 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com POWER SOLUTIONS FOR DIFFERENT APPLICATION PROCESSORS Default Settings For proper power supply design with , not only the default output voltage is relevant but also in what sequence the different power rails are enabled. The voltages are typically enabled internally based on the sequencing options programmed. For different application processors, there are different sequencing options available. In addition, the delay time and pulse for the reset signal to the application processor is different. See Table 9 with the default settings for sequencing, output voltages and reset options for the family: Table 9. Sequencing Settings DEDICATED FOR DCDC_SQ[2..0] LDO_SQ[2..0] COMMENT Starting was developed for battery powered applications with focus on lowest shutdown and quiescent current. In order to achieve this, in shutdown all mayor blocks and the system voltage at the output of the power path (SYS) are turned off and only the input that turns on , pin PB_IN, is supervised. is designed such that only an ON-key on PB_IN is needed pulling this pin LOW to enable . No external pull-up is needed as this is integrated into . Once PB_IN is pulled LOW, the system voltage is ramped and the dcdc converters and LDOs are started with the sequencing defined for the version used. If PB_IN is released again, TPS6507x would turn off, so a pin was introduced to keep TPS6507x enabled after PB_IN was released. Pin POWER_ON serves this function and needs to be pulled HIGH before the user releases the ON-key (PB_IN = HIGH). This HIGH signal at POWER_ON can be provided by the GPIO of a processor or by a pull-up resistor to any voltage in the system which is higher than 1.2V. Pulling POWER-ON to a supply voltage would significantly reduce the time PB_IN has to be asserted LOW. If POWER_ON is tied to a GPIO, the processor has to boot up first which may take some time. In this case however, the processor could do some additional debouncing, hence does not keep the power enabled if the ON-key is only pressed for a short time. When there is a supply voltage for the battery charger at pins AC or USB, the situation is slightly different. In this case, the power path is enabled and the system voltage (SYS) has ramped already to whatever the voltage at AC or USB is. The dcdc converters are not enabled yet but the start-up could not only be done by pulling PB_IN=LOW but also by pulling POWER_ON=HIGH. In applications that do not require an ON-key but shall power-up automatically once supply voltage is applied, there are two cases to consider. If TPS6507x is powered from its AC or USB pin (not powered from its BAT pin), POWER-ON just needs to be pulled HIGH to enable the converters. PB_IN must not be tied LOW in this case. If TPS6507x is powered from its BAT pin, PB_IN needs to be tied LOW to start-up the converters. Layout Considerations As for all switching power supplies, the layout is an important step in the design. Proper function of the device demands careful attention to PCB layout. Care must be taken in board layout to get the specified performance. If the layout is not carefully done, the regulators may show poor line and/or load regulation, and stability issues as well as EMI problems. It is critical to provide a low impedance ground path. Therefore, use wide and short traces for the main current paths. The input capacitors should be placed as close as possible to the IC pins as well as the inductor and output capacitor. For TPS6507x, connect the PGND pin of the device to the PowerPAD™ land of the PCB and connect the analog ground connection (GND) to the PGND at the PowerPAD™. The PowerPAD™ serves as the power ground connection for the DCDC1 and DCDC2 converters. Therefore it is essential to provide a good thermal and electrical connection to GND using multiple vias to the GND-plane. Keep the common path to the GND pin, which returns the small signal components, and the high current of the output capacitors as short as possible to avoid ground noise. The VDCDCx line should be connected right to the output capacitor and routed away from noisy components and traces (for example, the L1, L2, L3 and L4 traces). See the EVM users guide for details about the layout for TPS6507x. 70 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 APPLICATION CIRCUITS TPS65070 AC BAT BAT 1 mF charger / power path USB 1 mF LiIon TS SYS NTC Vin BYPASS DEFDCDC2 L1 SYS sets default voltage of DCDC3 to 1.0 V or 1.2 V DCDC1 600 mA DEFDCDC3 AVDD6 EN 10 mF 2.2 mH USB0_VDDA33 (3.3 V) USB1_VDDA33 (3.3 V) VDCDC1 TPS3805H33 10 mF VDD SYS EN_DCDC1 Sense Reset VINLDO1/2 SYS RTC_CVDD (1.2V) VINDCDC3 set charge current SYS sets default voltage of DCDC2 to 1.8 V or 3.3 V LDO VINDCDC1/2 ISET OMAP-L138 TPS78101 22 mF L2 1 mF DCDC2 1500 mA INT_LDO 2.2 mF VDCDC2 L3 AVDD6 DCDC3 1500 mA PB_IN LDO2 200 mA 2.2 mH DVDD3318_A (3.3V or 1.8 V) DVDD3318_B (3.3V or 1.8 V) 10 mF DVDD3318_C (3.3V or 1.8 V) 2.2 mH CVDD (1.2 V) 10 mF VDCDC3 4.7 mF SATA_VDD (1.2 V) VLDO2 ON PLL0_VDDA (1.2 V) PLL1_VDDA (1.2 V) 2.2 mF USBs CVDD (1.2 V) EN_DCDC2 L4 SYS 2.2 mF VDDARNWA/1 (1.2 V) SATA_VDDR (1.8 V) 10 kW EN_DCDC3 Si2333 VLDO1 100 kW LDO1 200 mA USB0_VDDA18 (1.8 V) 1 mF USB1_VDDA18 (1.8 V) DDR_DVDD18 (1.8 V) FB_wLED PGND 1 mF BC847 ISINK1 VDDIO wLED boost PowerPad(TM) ISINK2 ISET1 AD_IN1(TSX1) 100 kW 100 kW 3.3 kW 3.3 kW RESET SDAT SDAT INT POWER_ON AD_IN3(TSY1) AD_IN4(TSY2) + PB_INTERRUPT PGOOD SCLK AD_IN2(TSX2) THRESHOLD 100 kW PB_OUT 100 kW AGND ISET2 SCLK INT GPIO (power hold) Reset delay Figure 49. Powering OMAP-L138 Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 71 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PB_IN can be released HIGH any time after POWR_ON = HIGH PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50 ms debounce SYS POWER_ON asserted HIGH by the application processor any time while PB_IN = LOW to keep the system alive external LDO (RTC_CVDD) 1.2 V VDCDC3 (CVDD) 1.2 V 170 ms 250 ms VLDO2 (SATA_VDD) 1.2 V VDCDC2 (VDDSHV) 1.8 V 170 ms 250 ms VLDO1 (SATA_VDDR) 1.8 V VDCDC1 (USB0_VDDA33) 3.3 V 250 ms 170 ms PGOOD (Reset) 400 ms Figure 50. Timing for OMAP-L138 72 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 AC BAT TPS65072 BAT 1 mF USB charger / power path LiIon TS NTC SYS 1 mF VINDCDC1/2 ISET 2 x 10 mF VINDCDC3 set charge current BYPASS (2.25 V reference output) DEFDCDC2 ALTAS IV L1 DEFDCDC3 DCDC1 600 mA VINLDO1/2 SYS 1 mF 2.2 mH VCC_3V3 (VDDIO) VDCDC1 10 mF L2 2.2 mH DCDC2 600 mA INT_LDO VCC_1V8 (VDDIO_MEM) VDCDC2 2.2 mF L3 DCDC3 600 mA AVDD6 4.7 mF 10 mF 2.2 mH VDD_PDN (1.2 V) VDCDC3 10 mF VLDO2 /PB_IN VDD_PRE (1.2 V) LDO2 200 mA 2.2 mF LDO1 200 mA 2.2 mF ON / OFF VDDPLL (1.2 V) EN_DCDC1 VIN SYS EN_DCDC2 EN_EXTLDO L4 SYS LDO EN EN_wLED FB_wLED 1 mF ISINK1 GPIO (enable wLED) GPIO (power hold) POWER_ON wLED boost VDD_RTCIO EN_DCDC3 X_PWR_EN VIO ISET1 ISET2 PB_OUT 4.7k 4.7k ISINK2 PGOOD SDAT SCLK INT PB_INTERRUPT RESET SDAT SCLK INT Note: /Reset to Atlas 4 may need to be a RC delay from VDDIO Figure 51. Powering Atlas IV Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 73 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PB_IN can be released HIGH any time after POWR_ON=HIGH 15s PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50ms debounce SYS POWER_ON asserted HIGH by the application processor any time while /PB_IN=LOW to keep the system alive EN_EXTLDO (VDD_RTCIO) VLDO2 (VDD_PRE) VDCDC1 (VCC_3V3) 1ms 0.95 x Vout,nominal 1ms 0.95 x Vout,nominal 1ms 250 ms 1ms 250 ms VDCDC2 (VCC_1V8) EN_DCDC3 (X_PWR_EN) VDCDC3 (VDD_PDN) 170 ms VLDO1 (VDDPLL) 250 ms 170 ms 250 ms PGOOD (X_RESET_B) 20ms 0.5ms Figure 52. Timing for Atlas IV 74 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 Prima SLEEP Mode and DEEP SLEEP Mode Support TPS6507x contains a sequencing option for the Sirf Prima processor. The sequencing option defines how the voltages are ramped at initial power-up and shutdown as well as the timing for entering power save mode for the processor (SLEEP mode). The Prima processor supports SLEEP mode and also DEEP SLEEP mode. The main difference from a power supply point of view is: • How the supply voltages are turned off • Which voltages are turned off • How power save mode is exited into normal mode • Reset asserted or not (PGOOD pin of TPS6507x going actively low) The sequencing option for Prima is defined in one register each for the sequencing of the DCDC converters and for the LDOs. DCDC_SQ[2..0]=100 in register CON_CTRL1 defines the startup sequence for the DCDC converters while LDO_SQ[2..0]=111 defines the sequence for the LDOs. The default is factory programmed therefore it is ensured the first power-up is done in the right sequence. When TPS6507x is off, a small state machine supervises the status of pin PB_IN while major blocks are not powered for minimum current consumption from the battery as long as there is no input voltage to the charger. Power-up for the TPS6507x is started by PB_IN going LOW. This will turn on the power-FET from the battery so the system voltage (SYS) is rising and the main blocks of the PMU are powered. After a debounce time of 50ms, the main state machine will pull PB_OUT = LOW to indicate that there is a “keypress” by the user and will ramp the DCDC converters and LDOs according to the sequence programmed. It is important to connect the power rails for the processor to exactly the dcdc converters and LDOs as shown in the schematic and sequencing diagrams for proper sequencing. For Prima, the voltage rails for VDD_RTCIO needs to ramp first. This power rail is not provided by the PMU but from an external LDO which is enabled by a signal called EN_EXTLDO from the PMU. The PMU will therefore first rise the logic level an pin EN_EXTLDO high to enable the external LDO. After a 1ms delay the PMU will ramp LDO2 for VDD_PRE and DCDC3 for VDD_PDN. When the output voltage of LDO2 is within it s nominal range the internal power good comparator will trigger the state machine which will ramp DCDC1 and DCDC2 to provide the supply voltage for VCC_3V3 and VCC_1V8. Now Prima needs to pull its X_PWR_EN signal high which drives EN_DCDC3 on the PMU. This will now enable LDO1 to power VDDPLL. X_RESET_B will be released by the PMU on pin PGOOD based on the voltage of DCDC1 after a delay of 20ms. SLEEP Mode At first power-up (start-up from OFF state), the voltage for VDD_PDN is ramped at the same time than VDD_PRE. This is defined by Bit MASK_EN_DCDC3 in register CON_CTRL2 which is “1” per default. For enabling SLEEP mode, Prima needs to clear this Bit, so the EN_DCDC3 pin takes control over the DCDC3 converter. Prima SLEEP mode is initialized by Prima pulling its X_PWR_EN pin LOW which is driving the EN_DCDC3 pin of TPS6507x. This will turn off the power for VDDPLL (LDO1) and also for VDD_PDN (DCDC3). All other voltage rails will stay on. Based on a “keypress” with PB_OUT going LOW, Prima will wake up and assert EN_DCDC3=HIGH. This will turn DCDC3 and LDO1 back on and Sirf PRIMA will enter normal operating mode. DEEP SLEEP Mode Entry into DEEP SLEEP mode is controlled by Prima by writing to register CON_CTRL2 of TPS6507x. Before entering DEEP SLEEP mode, Prima will back up all memory and set Bit DS_RDY=1 to indicate the memory was saved and the content is valid. Setting PWR_DS=1 will turn off all voltage rails except DCDC2 for the memory voltage and the PMU will apply a reset signal by pulling PGOOD=LOW. Prima can not detect logic level change by PB_OUT going low in DEEP SLEEP mode. A wakeup from DEEP sleep is therefore managed by the PMU. The PMU will clear Bit PWR_DS and turn on the converters again based on a user “keypress” when PB_IN is being pulled LOW. Prima will now check if DS_RDY=1 to determine if the memory content is still valid and clear the Bit afterwards. In case there is a power loss and the voltage of the PMU is dropping below the undervoltage lockout threshold, the registers in the PMU are re-set to the default and DS_RDY is cleared. The PMU would perform a start-up from OFF state instead of exit from DEEP SLEEP and Sirf PRIMA would read DS_RDY=0, which indicates memory data is not valid. See timing diagrams for Sirf Prima SLEEP and DEEP SLEEP in Figure 53 and Figure 54. Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 75 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com PB_IN can be released HIGH any time after POWR_ON=HIGH 15s PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50ms debounce SYS POWER_ON asserted HIGH by the application processor any time while /PB_IN=LOW to keep the system alive EN_EXTLDO (VDD_RTCIO) VLDO2 (VDD_PRE) 1ms 0.95 x Vout,nominal 1ms VDCDC1 (VCC_3V3) 0.95 x Vout,nominal 250 ms 170 ms VDCDC2 (VCC_1V8) 250 ms 170 ms Bit MASK_EN_DCDC3 Bit MASK_EN_DCDC3 is cleared by the application processor. DCDC3 and LDO1 are enabled / disabled by EN_DCDC3 to enter / exit SLEEP mode EN_DCDC3 (X_PWR_EN) VDCDC3 (VDD_PDN) Bit MASK_EN_DCDC3 is set per default. DCDC3 is startted with LDO2 170 ms VLDO1 (VDDPLL) 170 ms 250 ms 250 ms 170 ms PGOOD (X_RESET_B) 20ms 0.5ms Figure 53. Timing for Sirf Prima SLEEP Mode 76 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 PB_IN can be released HIGH any time after POWR_ON=HIGH startup from OFF state PB_OUT wakeup from DEEP SLEEP level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50ms debounce SYS POWER_ON asserted HIGH by the application processor any time while /PB_IN=LOW to keep the system alive EN_EXTLDO (VDD_RTCIO) VLDO2 (VDD_PRE) VDCDC1 (VCC_3V3) 1ms 0.95 x Vout,nominal 0.95 x Vout,nominal 1ms 0.95 x Vout,nominal 250 ms 170 ms VDCDC2 (VCC_1V8) 250 ms 170 ms Bit MASK_EN_DCDC3 set Bits DS_RDY to indicate memory was backed-up Bit DS_RDY Bit PWR_DS DS_RDY=0, start with initial power-up sequence DS_RDY=1, start wake-up sequence; otherwise start initial power-up from OFF state set Bits PWR_DS to set Titan 2 to DEEP SLEEP mode DS_RDY is cleared by user software PWR_DS is cleared by PB_IN going LOW EN_DCDC3 (driven from VDCDC1) VDCDC3 Bit MASK_EN_DCDC3 is (VDD_PDN) set per default. DCDC3 is startted at the same time with LDO2 VLDO1 (VDDPLL) PGOOD (X_RESET_B) 20ms 20ms Figure 54. Timing for Sirf Prima DEEP SLEEP Mode Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 77 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com TPS65073 AC 1uF BAT USB charger / power path 1uF VDDS_MMC1(1.8V / 3.0V) LiIon TS NTC SYS ISET VINDCDC1/2 set charge current VINDCDC3 2 x 10uF 1.5uH L1 DEFDCDC2 DCDC1 600mA DEFDCDC3 SYS OMAP35xx TPS79901 Vin SYS LDO EN BAT VINLDO1/2 VDCDC1 L2 1uF DCDC2 600mA L3 ON / OFF DCDC3 1500mA AVDD6 1.5uH VDDCORE (1.2V) VDCDC2 /PB_IN VDDS_WKUP_BG (1.8V) VDDS_MEM; VDDS VDDS_SRAM 10uF 10uF 1.5uH VDD_MPU_IVA (1.2V) VDCDC3 10uF LDO2 LDO2 200mA AD_IN1 (TSX1) VDDA_DAC (1.8V) 2.2uF LDO1 AD_IN2 (TSX2) LDO1 200mA AD_IN3 (TSY1) AD_IN4 (TSY2) VDDS_DPLL_DLL (1.8V) VDDS_DPLL_PER (1.8V) 2.2uF VDDS EN_DCDC1 BYPASS SYS SN74LVC1G06DCK VDDS VCC INT_LDO EN_DCDC2 TPS3825-33DBVT VDD /RST /MR L4 SYS SYS EN_DCDC3 Y A SYS_OFF_MODE GND VDDS GND FB_wLED 1uF PB_OUT 100k 4.7k 4.7k 100k wLED boost 100k 100kk ISINK1 POWER_ON ISINK2 PGOOD ISET1 SDAT ISET2 SCLK /INT THRESHOLD GPIO (push-button int) GPIO (/disable power) SYS.nRESPWRON SDAT SCLK /INT /Reset + delay Figure 55. OMAP35xx (Supporting SYS-OFF Mode) 78 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 PB_IN can be released HIGH any time after POWR_ON=HIGH PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce SYS POWER_ON asserted HIGH by the application processor (OMAP) any time while /PB_IN=LOW to keep the system alive VDCDC1 (VDDS_WKUP_BG, VDDS, VDDS_MEM ) 250 ms 170 ms + RC delay VDCDC2 (VDD_CORE) 170 ms + RC delay 250 ms VDCDC3 (VDD_MPU_IVA) VLDO1 250 ms 170 ms + RCdelay (VDDS_DPLL_DLL, VDDS_DPLL_PER) VLDO2 (VDDA_DAC) PGOOD (SYS.nRESPWRON) 400ms Figure 56. OMAP35xx Timing (Supporting SYS-OFF Mode) Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 79 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com TPS650731 BAT AC BAT 1 mF USB charger / power path NTC SYS 1 mF VINDCDC1/2 ISET VINDCDC3 set charge current L1 DCDC1 600mA DEFDCDC2 OMAP35xx 2 x 10 mF 2.2 mH VDCDC1 VDDS_WKUP_BG (1.8 V) VDDS_MEM; VDDS 10 mF VDDS_SRAM DEFDCDC3 L2 SYS LiIon TS DCDC2 600mA VINLDO1/2 2.2 mH VDDCORE (1.2 V) VDCDC2 10 mF 2.2 mH 1uF L3 DCDC3 1500mA VDD_MPU_IVA (1.2 V) VDCDC3 10 mF LDO2 PB_IN LDO2 200mA ON / OFF VDDA_DAC (1.8 V) 2.2 mF VDDDLL VDDS_DPLL_DLL (1.8 V) VDDS_DPLL_PER (1.8 V) LDO1 LDO1 200mA AD_IN1 (TSX1) AD_IN2 (TSX2) 2.2 mF VIO AD_IN3 (TSY1) EN_DCDC1 AD_IN4 (TSY2) EN_DCDC2 SYS POWER_ON FB_wLED PGOOD 1 mF SDAT ISINK1 SCLK wLED boost /INT 4.7k 1M PB_OUT 1M 4.7 k L4 SYS 100 K EN_DCDC3 GPIO (/disable power) SYS.nRESPWRON SDAT SCLK /INT AVDD6 ISINK2 ISET1 ISET2 BYPASS INT_LDO THRESHOLD /Reset + delay Figure 57. TPS650731 for OMAP35xx 80 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 PB_IN can be released HIGH any time after POWR_ON=HIGH PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50ms debounce SYS POWER_ON asserted HIGH by the application processor any time while /PB_IN=LOW to keep the system alive VDCDC1 (VDDS_WKUP_BG, VDDS, VDDS_MEM ) 250 ms 170 ms VDCDC2 (VDD_CORE) 170 ms 250 ms VDCDC3 (VDD_MPU_IVA) 250 ms 170 ms VLDO1 (VDDS_DPLL_DLL, VDDS_DPLL_PER) VLDO2 300 ms (VDDA_DAC) enabled by OMAP35xx by I2C command PGOOD (SYS.nRESPWRON) 400ms Figure 58. TPS650731: OMAP35xx timing Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 81 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 SLVSAP7 – JANUARY 2011 www.ti.com TPS650732 BAT AC BAT 1uF USB charger / power path 1uF SYS ISET VINDCDC3 VDDS1-5 (1.8V) VDCDC1 DEFDCDC3 VINLDO1/2 10uF 2.2uH L2 DCDC2 600mA AM3505 2 x 10uF 2.2uH L1 DCDC1 600mA DEFDCDC2 SYS NTC VINDCDC1/2 set charge current SYS LiIon TS VDDSHV (3.3V) VDCDC2 10uF 2.2uH 1uF L3 DCDC3 1500mA /PB_IN VDD_CORE (1.2V) VDCDC3 10uF LDO2 LDO2 200mA ON / OFF VDDS_DPLL (1.8V) 2.2uF LDO1 LDO1 200mA AD_IN1 (TSX1) AD_IN2 (TSX2) VDDA1P8V(1.8V) 2.2uF AD_IN3 (TSY1) EN_DCDC1 AD_IN4 (TSY2) EN_DCDC2 SYS 1uF GPIO (/disable power) SYS.nRESPWRON SDAT SCLK /INT PGOOD SDAT ISINK1 SCLK wLED boost 1M 4.7 k POWER_ON FB_wLED 1M PB_OUT 4.7 k SYS 100K EN_DCDC3 L4 /INT AVDD6 ISINK2 ISET1 ISET2 BYPASS SYS TPS79918 Vin EN VDDS_SRAM (1.8V) LDO INT_LDO THRESHOLD /Reset + delay SYS TPS79933 Vin VDDA3P3V (3.3V) LDO EN Figure 59. Powering AM3505 Using TPS650732 82 Submit Documentation Feedback Copyright © 2011, Texas Instruments Incorporated Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 TPS65070-Q1, TPS65072-Q1, TPS65073-Q1, TPS650732-Q1 www.ti.com SLVSAP7 – JANUARY 2011 /PB_IN can be released HIGH any time after POWR_ON=HIGH PB_OUT level not defined as voltage at pull-up has not ramped at that time 50ms debounce 50ms debounce SYS POWER_ON asserted HIGH by the application processor any time while /PB_IN=LOW to keep the system alive VDCDC1 (VDDS1-5 1.8V ) 170us 250us VDCDC2 (VDDSHV) 3.3V 170us 250us VLDO_ext1 (VDDS_SRAM) 1.8V VDCDC3 (VDD_CORE) 1.2V 250us 170us VLDO2 (VDDS_DPLL) 1.8V VLDO1 (VDDA1P8V) 1.8V VLDO_ext2 (VDDA3P3V) 3.3V PGOOD (SYS.nRESPWRON) 400ms Figure 60. Timing Using TPS650732 for AM3505 Copyright © 2011, Texas Instruments Incorporated Submit Documentation Feedback Product Folder Link(s) :TPS65070-Q1 TPS65072-Q1 TPS65073-Q1 TPS650732-Q1 83 PACKAGE OPTION ADDENDUM www.ti.com 19-Sep-2011 PACKAGING INFORMATION Orderable Device TPS650732TRSLRQ1 Status (1) Package Type Package Drawing ACTIVE VQFN RSL Pins Package Qty 48 2500 Eco Plan (2) Green (RoHS & no Sb/Br) Lead/ Ball Finish MSL Peak Temp (3) Samples (Requires Login) CU NIPDAU Level-3-260C-168 HR (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. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. 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OTHER QUALIFIED VERSIONS OF TPS650732-Q1 : • Catalog: TPS650732 NOTE: Qualified Version Definitions: • Catalog - TI's standard catalog product Addendum-Page 1 PACKAGE MATERIALS INFORMATION www.ti.com 14-Jul-2012 TAPE AND REEL INFORMATION *All dimensions are nominal Device TPS650732TRSLRQ1 Package Package Pins Type Drawing VQFN RSL 48 SPQ Reel Reel A0 Diameter Width (mm) (mm) W1 (mm) 2500 330.0 16.4 Pack Materials-Page 1 6.3 B0 (mm) K0 (mm) P1 (mm) W Pin1 (mm) Quadrant 6.3 1.1 12.0 16.0 Q2 PACKAGE MATERIALS INFORMATION www.ti.com 14-Jul-2012 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) TPS650732TRSLRQ1 VQFN RSL 48 2500 367.0 367.0 38.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per JESD46C and to discontinue any product or service per JESD48B. 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