ACT2861QI Rev 2.0, 27-Apr-2018 30V Buck-Boost Charger with Integrated MOSFETs and OTG GENERAL DESCRIPTION BENEFITS and FEATURES The ACT286x is a buck-boost charger with 4 integrated MOSFETs. It offers a high efficiency, low component counts, compact solution for 2 to 5 cell battery charging application. It can operate from an input voltage range from 3.9V to 29V. The 4 internal low resistance NMOS switches minimize the size of the application circuit and reduce power losses to maximize efficiency. Internal high side gate drivers, which require only the addition of two small external capacitors, further simplify the design process. An advanced switch control algorithm allows the buckboost converter to maintain output voltage regulation with input voltages that are above, below or equal to the output voltage. Transitions between these operating modes are seamless and free of transients and subharmonic switching. The ACT286x has been optimized to reduce input current in shipping, shutdown, and standby for applications which are sensitive to quiescent current draw, such as battery-powered devices. Both the input side and output side voltages and currents can be configured by resistors or the I2C serial interface. The system can be monitored and configured by I2C as well. The build-in ADC can be read for the information of input/output voltages and currents, and the die temperature. With a MCU, it can easy to charge a multi cell battery pack from a variety of input power sources. The IC provides various safety features for system operation. The thermal regulation reduces output current when the junction temperature exceeds 120°C (programmable). The ACT286x is available in 32-pin, 4x4 mm QFN package. • Wide VIN Range: 3.9V to 29V (No Dead Zone) • Supports 2 to 5 Cell Lithium-ion Batteries • Supports OTG Function (5V ~ 22.5V Input) with wide range of output voltages • OTG output supports QC3.0 / USB PD + PPS output levels and transition times • Programmable Frequency: 125KHz, 250KHz, 500kHz, and 1MHz • 2V ~ 5V/100mA Programmable Output LDO • Precision 0.5% Voltage Reference • +/-4% Output Constant Current Regulation • < 5 μA Leakage Current from Battery in Shipping Mode • Programmable Charge Voltage via I2C • Programmable Charge Current via Pin and I2C • Programmable Soft-Start • Programmable Safety Timer • Battery Path Impedance Compensation • JEITA Compliant • Cycle-by-Cycle Current Limit • Built in ADC for Temperature, Input and Output Voltage and Current monitoring • Thermal Regulation and Protection • 25mΩ FET from VIN to SW1 • 25mΩ FET from SW2 to VOUT • 35mΩ FET from SW1 to PGND • 35mΩ FET from SW2 to PGND • Low Output Ripple • Thermally Enhanced 32-Lead 4mx4mm QFN APPLICATIONS • • • • • • • • • • Multi Cell Battery Charger Portable Battery-Powered Devices Car Charger Power Bank 24V Industrial Applications Automotive Power Systems Multiple Power Source Supplies DC UPS Solar Powered Devices Solid-State Lighting Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2017 Active-Semi, Inc. 1 ACT2861QI Rev 2.0, 27-Apr-2018 FUNCTIONAL BLOCK DIAGRAM SW1 VIN VREG SW2 VBAT LDO OSRP Q4 Q1 INTBP OSRN Q2 Q3 HSB1 ISRP Gate Driver ISRN HSB2 Current Sense CC Loop IORef nIRQ OLIM CC Loop EN_CHG IinRef OTP Control ILIM OCOMP A2D_IN nCHG SDA Ref SCL IFB nOTG ICO MP TH SHIPM AGND Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi PGND www.active-semi.com Copyright © 2018 Active-Semi, Inc. 2 ACT2861QI Rev 2.0, 27-Apr-2018 ORDERING INFORMATION PART NUMBER Cell Count Termination Voltage OTG Voltage LDO Fsw JEITA PACKAGE ACT2861QI201-T 2 8.40V 5.1V 5.0V 500kHz Enabled FCQFN4x4-32 ACT2861QI301-T 3 12.6V 5.1V 5.0V 500kHz Enabled FCQFN4x4-32 ACT2861QI401-T 4 16.8V 5.1V 5.0V 500kHz Enabled FCQFN4x4-32 A CT286 1QIxx x-T Product Number Package Code Pin Count CMI Option Tape and Reel Note 1: Standard product options are identified in this table. Contact factory for custom options, minimum order quantity required. Note 2: All Active-Semi components are RoHS Compliant and with Pb-free plating unless specified differently. The term Pb-free means semiconductor products that are in compliance with current RoHS (Restriction of Hazardous Substances) standards. Note 3: Package Code designator “Q” represents QFN Note 4: Pin Count designator “I” represents 32 pins Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 3 ACT2861QI Rev 2.0, 27-Apr-2018 SW2 VBAT SW2 SW1 VIN Exposed PAD 31 1 2 3 4 5 6 7 8 AGND TH INTBP VREG PGND SDA SCL nOTG 32 16 SW2 33 15 PGND 34 HSB2 14 SW1 35 VBAT OSRP 13 SW1 17 OSRN 12 VIN 18 30 EN_CHG 19 29 A2D ICOMP 20 28 ILIM 21 27 nCHG 22 VBATS 11 26 ISRN 23 OLIM 10 25 ISRP 24 nIRQ 9 HSB1 VIN PIN CONFIGURATION SHIPM Figure 1: Pin Configuration – Top View – QFN4x4-32 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 4 ACT2861QI Rev 2.0, 27-Apr-2018 PIN DESCRIPTIONS PIN NAME 1 AGND DESCRIPTION Analog Ground. Kelvin connect AGND to the PGND plane. 2 TH Battery temperature sensing input. Connect a negative temperature coefficient thermistor from TH to AGND. This pin provides a constant current output and the voltage at this pin is used for temperature calculation. If temperature sensing is not used, leave TH open and set register bit “DIS_TH” to a 1 3 INTBP Internal Voltage Bypass - Connect a 100nF ceramic capacitor between INTBP and AGND 4 VREG Internal VREG LDO output. The output voltage is programmable from 2V to 5V. Connect a 1.0uF between VREG and AGND. The maximum current capability for this pin is 100mA. 5, 20 PGND Power Ground. Connect to large ground plane on PCB with thermal vias. 6 SDA I2C Data Input and Output. Needs an external pull up resistor. 7 SCL I2C Clock Input. Needs an external pull up resistor. 8 nOTG OTG Enable Input. The OTG mode is active when this pin is pulled low and the EN_OTG bit = 1. In OTG mode, the converter works in reverse operation mode, and power is transferred from battery to VIN. 9 SHIPM Shipping Mode input. Shorting this pin to GND for 32ms enables the IC. If not used, connect SHIPM to AGND. 10 nIRQ Interrupt Open-Drain Output. nIRQ goes low to indicate a fault condition. nIRQ is referenced to AGND. 11 OLIM Output Fast charge current setting pin. Connect a resistor from OLIM to AGND to program the output current in normal charge mode. 12 VBATS VBAT Sense Input – Kelvin connect close the battery to sense the battery voltage. 13 OSRN Output current sense resistor negative input. 14 OSRP Output current sense resistor positive input. 15 HSB2 High Side Bias Boot-strap pin. This provides power to the internal high-side MOSFET gate driver circuitry. Connect a 47nF capacitor from HSB2 to SW2 pin 16, 17 VBAT Charging Power Output pin. Connect this pin to 22uF-100uF ceramic capacitors placed as close to the IC as possible. 18, 19, 33 SW2 Power switching output to external inductor. 21, 22, 34 SW1 Power switching output to external inductor. 23, 24, 35 VIN Input voltage pin. Place a 22uF to 44uF decoupling capacitor between VIN and PGND. 25 HSB1 High Side Bias Boot-strap pin. This provides power to the internal high-side MOSFET gate driver circuitry. Connect a 47nF capacitor from HSB1 to SW1 pin 26 ISRP Input current sense resistor positive input. 27 ISRN Input current sense resistor negative input 28 nCHG Open drain charge status indicator. nCHG = L indicates charging is in progress. nCHG = HI-Z indicates charge complete or charger disabled. nCHG = H to L at 1Hz indicates a fault condition. 29 ILIM Input current limit and OTG output current setting pin. Connect a resistor from ILIM to AGND to program the input current when operating in normal mode and to program the output current when operating in OTG Mode. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 5 ACT2861QI Rev 2.0, 27-Apr-2018 30 A2D 31 ICOMP/GPIO 32 EN_CHG Exposed Pad PGND A2D input pin OTG mode Error Amplifier Output. This pin is used to compensate the converter when operating in OTG mode. Charge Enable pin. Charging is enabled when EN_CHG is above 0.8V. Connect a resistor divider to EN_CHG to program charging input UVLO. Power Ground. Connect to large ground plane on PCB with thermal vias. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 6 ACT2861QI Rev 2.0, 27-Apr-2018 ABSOLUTE MAXIMUM RATINGS PARAMETER VALUE UNIT -0.3 to +31 V -0.3 to VIN + 0.3 V -0.3 to +23 V OSRP, OSRN -0.3 to VBAT + 0.3 V VBATS -0.3 to OSRN + 0.3 V SW1 -0.3 to VIN + 0.3 V SW2 -0.3 to VBAT + 0.3 V HSB1 VSW1 - 0.3 to VSW1 + 5.5 V HSB2 VSW2 - 0.3 to VSW2 + 5.5 V -0.3 to +6 V -0.3 to +0.3 V 35 °C/W Operating Junction Temperature (TJ) -40 to 150 °C Operating Ambient Temperature Range (TA) -40 to 85 °C -55 to 150 °C 300 °C VIN ISRP, ISRN VBAT SCL, SDA, VREG, nCHG, EN_CHG, nOTG, TH, nIRQ, ICOMP, ILIM, OLIM, SHIPM, A2D AGND to PGND Junction to Ambient Thermal Resistance (θJA) Store Temperature Lead Temperature (Soldering, 10 sec) Note1: Measured on Active-Semi Evaluation Kit Note2: Do not exceed these limits to prevent damage to the IC. Exposure to absolute maximum rating conditions for long periods may affect IC reliability. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 7 ACT2861QI Rev 2.0, 27-Apr-2018 SYSTEM CHARACTERISTICS (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNIT 29 V 31 V Input Voltage Input voltage Range Input Over Voltage Protection VIN VIN_OVP 4 Rising Measured at VIN Pin 29 30 Input Over Voltage Hysteresis Input Over Voltage Response Time TVIN_OVP VIN step from 20V to 31V VIN UVLO Threshold VIN_UVLO VIN Rising Measured at VIN Pin VIN UVLO Hysteresis VIN_UVLO_HYST EN_CHG INPUT Threshold VEN_IN EN_CHG Rising EN_CHG INPUT Hysteresis VEN_IN_HYST EN_CHG Falling 2 V 250 ns 3.725 VIN Falling 3.9 4.075 200 Measured at VIN Pin 0.7 0.8 V mV 0.9 160 V mV CURRENT REGULATION - VIN INPUT AND CURRENT REGULATION IN CHARGE MODE Input Voltage Regulation Accuracy Input Current Regulation Range Input Current Regulation Accuracy Measured from VIN Pin to AGND Pin VINLIM_REG_ACC Relative to the factory default Register Setting -2 IINLIM_RANGE With IIN_LIM=100% register setting 0.5 IIN_ILIM IIN_LIM = 0.5A to 1A Rsense = 0.01Ohms -20 IIN_ILIM IIN_LIM = 1A to 2A Rsense = 0.01Ohms IIN_ILIM IIN_LIM > 2A Rsense = 0.01Ohms VINLIM +2 % 5 A IIN_ILIM +20 % -15 IIN_ILIM +15 % -10 IIN_ILIM +10 % VIN INPUT QUIESCENT CURRENTS IIN_HIZ1 VIN=12V, VBAT=8.4V, EN Low, converter off, I2C on, VREG is OFF 35 A IIN_HIZ2 VIN=12V, VBAT=8.4V, EN Low, converter off, I2C on, VREG is ON 50 A IIN_HIZ3 VIN=12V, VBAT=8.4V, EN Low, converter off, I2C on, VREG is on, A2D Enabled, Fault Monitor Enabled, TH Enabled 1000 A IIN_NOLOAD VIN=5V, Charger Mode, converter switching, I2C on, VREG on, no load, 500kHz 1 mA Input Supply Current HIZ Input Supply Current at No Load VBAT INPUT QUIESCENT CURRENTS Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 8 ACT2861QI Rev 2.0, 27-Apr-2018 VBAT = 8.4V, no VIN, Shipping mode, Converter off, I2C off, VREG off, SHIPM Pin Enabled 1 IBAT_HIZ1 VBAT=8.4V, VIN < VBAT, Converter off, I2C on, VREG off 20 A IBAT_HIZ2 VBAT=8.4V, VIN < VBAT, Converter off, I2C on, VREG on 35 A IBAT_HIZ3 VBAT=8.4V, VIN < VBAT, Converter off, I2C on, VREG on, A2D Enabled, Fault Monitor Enabled, TH Enabled 1100 A IBAT_OTG VBAT=8.4V, VOTG_OUT=5V 1 mA RDSONQ1 TJ = 25C 25 mΩ SW1 to PGND FET Resistance RDSONQ2 TJ = 25C 35 mΩ SW2 to PGND FET Resistance RDSONQ3 TJ = 25C 35 mΩ VBAT to SW2 FET Resistance RDSONQ4 TJ = 25C 25 mΩ Battery Current Ship Mode IBAT_SHIP Battery Current in HIZ Battery Current OTG 2.5 A INTERNAL MOSFETS VIN to SW1 FET Resistance Cycle By Cycle Current Limit IFET_ILIM FET_ILIM=0 Q1, Q2, Q3, or Q4 in any mode 6.5 8.5 10.5 A FET_ILIM=1 Q1, Q2, Q3, or Q4 in any mode 7.75 10 12.25 A Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 9 ACT2861QI Rev 2.0, 27-Apr-2018 BATTERY CHARGER (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNIT Battery Regulation Voltage Accuracy VBAT_REG_ACC VBAT = VBAT Register Setting Measured at VBATS Pin -0.5 0.5 % Fast Charge Current Range IFCHG_REG_RANGE With ICHG=100% register setting 0.5 5 A VBAT= VBATLOW, ICHG=2A -5 +5 % VBAT= VBATLOW, ICHG=1A -10 +10 % VBAT= VBATLOW ICHG=500mA -20 +20 % VBAT= VBATLOW, ICHG=250mA -30 +30 % VBAT= VBATLOW, ICHG=125mA -40 +40 % VBATSHORT<VBAT<VBATLOW ITERM = 250mA -30 +30 % VBATSHORT<VBAT<VBATLOW ISHRT=200mA 120 200 280 mA VBAT < VBATSHORT -100mV VBAT > 3V ISHRT=400mA 300 400 400 mA 3.75 3.9 4.15 V -3.3 VBATLOW + 3.3 % 3.3 6 8.6 % + 2.5 % Fast Charge Current Regulation Accuracy IFCHG_REG_ACC (10mΩ current sensing resistor) Pre-charge Current Regulation Accuracy IPRECHG_ACC (10mΩ current sensing resistor) Termination Voltage Accuracy (default factory setting) VTERM_ACC Battery Short Charge Current (default factory setting for ISHRT and VBATSHORT) Minimum Battery Voltage for Active I2C ISHRT VBAT_UVLOZ VBAT rising Measured at VBATS Pin Pre-Charge to Fast Charge with VBAT Rising Battery LOW Threshold VBATLOW Relative to the factory default VBATLOW Register Setting Measured at VBATS Pin Fast Charge to Pre-Charge with VBAT Falling Battery LOW Hysteresis VBATLOW_HYST Relative to the factory default VBATLOW Register Setting Referenced to actual VBATLOW measurement Measured at VBATS Pin BAT Short Charge level to PreCharge level with VBAT rising Battery Short Voltage VBATSHORT Relative to the factory default VBATSHORT Register Setting –2.5 VBATSHOR T Measured at VBATS Pin BAT Pre-Charge to Short Charge level with VBAT Falling Battery Short Voltage Hysteresis VBATSHORT_HYST Relative to the actual VBATSHORT measurement 4 5 6 % -3% VBAT_GOO +3% % Measured at VBATS Pin Battery Good Voltage VBATGOOD VBAT Rising Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 10 ACT2861QI Rev 2.0, 27-Apr-2018 Relative to the factory default VBATGOOD Register Setting D Measured at VBATS Pin VBAT falling Relative to the actual VBATGOOD measurement Battery Good Voltage Hysteresis VBATGOOD_HYST 3 4 5 % Measured at VBATS Pin Battery SHORT to Precharge and Pre-Charge to Short Deglitch Time Battery voltage rising and falling at VBATSHORT threshold 16 ms Battery Pre-Charge to Fast Charge and Fast Charge to Pre- tVBATLOW Charge deglitch time Battery voltage rising and falling at VBATLOW threshold 16 ms Battery Charge Termination CurtVBATTERM rent detection delay Termination current below and above ITERM threshold 750 ms Battery Good Detection deglitch tVBATGOOD Time Battery voltage rising and falling at VBATGOOD threshold 16 ms tVBATSHORT ICHG = 1A At default programmed setting for RVBAT_PATH_COMP Battery Path Compensation -20 ICHG = 2A RBAT_COMP At default programmed setting for RVBAT_PATH_COMP -15 ICHG = 3A At default programmed setting for RVBAT_PATH_COMP Battery Path Compensation Voltage Clamp VBAT_COMP_CLAMP Dead Battery Voltage VDBATTERY Measured at VBATS Pin Dead Battery Hysteresis VDBATTERY_HYST Measured at VBATS Pin Dead Battery Current IDBATTERY Charge Current from VBAT pin Enable Measured at VBATS Pin -10 -20 2.8 RVBAT_PA TH_COMP RVBAT_PA TH_COMP RVBAT_PA TH_COMP VBAT_COM P_CLAMP 3 +20 % +15 % +10 % +20 mV 3.2 V 100 mV 5 10 20 mA 102 104 106 % BATTERY OVER-VOLTAGE PROTECTION Battery over-voltage threshold VBATOVP Battery over-voltage hysteresis VBATOVP_HYST Battery over-voltage deglitch time to disable charge tBATOVP VBAT rising, as percentage of VBAT_REG Measured at VBATS Pin VBAT falling, as percentage of VBAT_REG 2 % VBAT_OV_DEGLITCH_EN Register =0 5 us VBAT_OV_DEGLITCH_EN Register =1 40 msec Measured at VBATS Pin PWM OPERATION Programmable Frequency Range FSW 125 1000 kHz Operation Frequency Accuracy FSW -10 +10 % Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 11 ACT2861QI Rev 2.0, 27-Apr-2018 Maximum PWM Duty Cycle DMAX 97 % LDO (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNIT 2 5.1 V -2 2 % 300 mV 93 % Normal Mode VREG Regulation Voltage VREG VREG Regulation Accuracy VREGACC At Default Factory Setting VREG Dropout VREGDROPOUT IOUT = 100mA VREG UVLO Threshold VREGUVLO VREG Falling VREG UVLO Hysteresis VREGUVLO_HYST VREG Current Limit VREGILIM VVIN = 12V, VREG = 5V VREG Current Limit Deglitch VREGILIM_DG In current limit 50 us VREG Current Limit Off Time VREGILIM_OFF After Deglitch Time 100 ms VREG Soft Start VREGSS 250 us 84 88 2 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi 100 175 % 250 mA www.active-semi.com Copyright © 2018 Active-Semi, Inc. 12 ACT2861QI Rev 2.0, 27-Apr-2018 OTG (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified) PARAMETER SYMBOL CONDITIONS MIN OTG Output Voltage VOTG_REG_ACC Internal Feedback Mode VOTG_I2C Register = 0 Relative to the factory default setting. OTG output in PWM Mode. Measured at VIN Pin OTG Reference Voltage VOTG_REF_ACC External Feedback VOTG_I2C Register = 1 1.99 OTG Battery Cut Off Voltage VOTG_BAT_CUTOFF VBAT Rising Relative to the factory default VOTG_VBAT_CUTOFF Register setting Measured at VBATS Pin -3.0 OTG Battery Cut Off Voltage Hysteresis VBAT Falling VOTG_BAT_CUTOFF_ Relative to the actual VOTG_VBAT_CUTOFF voltage HSYT Measured at VBATS Pin OTG Battery OV Threshold VOTG_BAT_OV VBAT Rising Measured at VBATS Pin OTG Battery OV Hysteresis VOTG_BAT_OV_HYST VBAT Falling Measured at VBATS Pin OTG Output Current Range IOTG_RANGE With ICHG = 100% register setting 0.5 IOTG_OCP = 0.5A to 1A -20 TYP -1 2 VOTG_VBA T_CUTOFF MAX UNIT 1 % 2.01 V 3.0 % 3 4 5 % 22.75 23.5 24.25 V 300 mV 5 A IOTG +20 % OTG Mode Output Constant CurIOTG_OCP rent (measured at ISRN and ISRP pins using 10mΩ current sensing resistor) IOTG_OCP = 1A to 2A -15 IOTG +15 % IOTG_OCP > 2A -10 IOTG +10 % OTG Mode Output Constant Current Undervoltage Protection VOTG_UVP Threshold VOTG Falling Enters Hiccup Mode Measured at VIN pin 2.62 2.72 2.82 V OTG Mode Output Constant Current Undervoltage Protection tOTG_UVP Deglitch Time VOTG Falling 7 us OTG Hiccup Mode Off-Time tOTC_HICCUP Off-time after VOTG falls below VOTG_UVP 3 secs OTG Overvoltage Threshold VOTG_OVP_INT Reference to OTG_VOUT Register Setting 105 108 111 % Measured at VIN Pin OTG Overvoltage Threshold Hysteresis VOTG_OVP_HYS Falling Threshold OTG Soft Start Time tOTG_SS Relative to the factory default OTG_SS Register Setting. 2 -30 From 0 to 100% OTG_SS Setting % 30 % OTG Pulldown Current Source IOTG_PD VOTG Output > 2.0V 30 65 120 mA OTG Off-Delay Timer tOTG_OFF_DLY OFF DLY is enabled -10 OTG_O FF_DLY +10 % Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 13 ACT2861QI Rev 2.0, 27-Apr-2018 Setting OTG Off-Delay Current IOTG_OFF_LOAD OTG Output Slew Accuracy OTG Battery ILIM VBAT > VOTG + 0.5V 3 4 6 mA -15 OTG_C ORD_C OMP Setting +15 % +20 % VOTG_CC OTG Cord Compensation Enabled OTG_CORD_COMP: 00: Disabled 01: 100mV 10: 200mV 11: 300mV Measured at VIN Pin tOTG_SLEW OTG Output Slew Setting OTG_OUTPUT_SLEW 00: 1.0V/ms 01: 0.5V/ms 10: 0.3V/ms 11: 0.1V/ms Internal Feedback Only VOTG_I2C Register = 0 -20 IOTG_BAT = 0.5A to 1A -20 IOTG_BAT +20 % IOTG_BAT = 1A to 2A -15 IOTG_BAT +15 % IOTG_BAT > 2A -10 IOTG_BAT +10 % MIN TYP MAX UNIT -20 TREG +20 °C OTG Cord Compensation Accuracy OTG in Buck Mode Only and OTG Output less than 6V IOTG_BAT OTG_O UTPUT _SLEW Setting THERMAL PROTECTION (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified.) SYMBOL PARAMETER CONDITIONS Thermal Regulation and Shutdown Charger Mode Junction TemperTREG ature Regulation Accuracy 00: Disabled 01: 80 °C 10: 100 °C 11: 120 °C Thermal Shutdown Rising Temperature TSHUT Temperature Increasing Thermal Shutdown Hysteresis TSHUT_HYS Thermal Shutdown Deglitch Enter or Exit Thermal Shutdown 160 C 30 C 32 us NTC Thermistor Input NTC TH Current Source ITH NTC TH Current Source Leakage ITH_DISABLE When TH Pin Enabled 64.8 67.5 When TH Pin Disable 70.2 uA 1 uA NTC TH -10°C Voltage VTH-10C 2.770 2.870 2.970 V NTC TH 0°C Voltage VTH0C 1.780 1.840 1.900 V NTC TH 10°C Voltage VTH10C 1.165 1.21 1.255 V NTC TH 45°C Voltage VTH45C 0.317 0.332 0.347 V Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 14 ACT2861QI Rev 2.0, 27-Apr-2018 NTC TH 55°C Voltage VTH55C 0.223 0.238 0.253 V NTC TH 60°C Voltage VTH60C 0.188 0.203 0.218 V NTC TH 65°C Voltage VTH65C 0.160 0.175 0.190 V Deglitch time for each range transition 16 TH Detect Battery or Very Cold Temp Threshold VTH_NO_BAT TH Detect Battery or Very Cold Temp Threshold Hysteresis VTH_NO_BAT_HYST When TH Pin Enabled ms INTBP When TH Pin Enabled mV -150 50 mV ADC CONVERTER (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNIT Total Error A2DERROR 12 Bit Range 0.5 LSB Conversion Time A2DtCONV All 6 Channels 100 ms Conversion Time A2DtCONV 1 Channel 15 ms Input Capacitance A2DCIN 5 pF A2D Full Scale Input EXT_IN A2DFS 2.5 V A2D Full Scale VIN A2DVIN Measurement input at VIN pin A2D Full Scale VBAT A2DVBAT Measurement input at VBATS Pin A2D Full Scale OLIM, ILIM A2DOLIM, A2DILIM A2D Full Scale TH A2DTH 0 32.5 V 1.5 25 V 2.5 Battery NTC Voltage Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi V 3.5 V www.active-semi.com Copyright © 2018 Active-Semi, Inc. 15 ACT2861QI Rev 2.0, 27-Apr-2018 SHIP MODE (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified.) SYMBOL PARAMETER SHIPM Deglitch Time Exit tSHIPM_EXIT CONDITIONS Ship Mode Enabled MIN TYP MAX UNIT 12 32 60 ms 1 1.35 2 MΩ From SHIPM pin or VIN threshold SHIPM Pullup Resistor Exit RSHIPM_PU Ship Mode Enabled SHIPM Pullup Voltage Exit VSHIPM_PU Ship Mode Enabled SHIPM Input low threshold Exit VSHIPM_L Ship Mode Enabled 1.5 V SHIPM Input Hysteresis Exit VSHIPM_HYST Ship Mode Enabled 100 mV SHIPM VIN Threshold Exit VSHIP_VIN Ship Mode Enabled SHIPM Pull Down Resistor RSHIPM_PD Ship Mode Disabled 3 V 3.9 0.7 1 V 1.3 4.5 MΩ V SHIPM Enter Voltage to Re-enter VSHIP_ENTER Ship Mode Voltage on SHIPM Pin SHIPM Deglitch Time to Re-enter tSHIPM_ENTER Ship Mode Ship Mode Disabled 20 32 45 ms SHIPM Delay entering Ship Mode using I2C Register Bit Ship Mode Disabled 0.8 1 1.2 s MIN TYP MAX UNIT 0.4 V tSHIPM_ENTER_I2C Ship Mode Disabled LOGIC PIN CHARACTERISTICS – NOTG, NCHG, NIRQ, GPIO (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified.) SYMBOL PARAMETER CONDITIONS nOTG, GPIO Input low threshold VILO nOTG, GPIO Input high threshold VIHI 1.25 nCHG, nIRQ , GPIO Output Low VOL Voltage Sink Current = 5 mA nCHG, nIRQ, GPIO High Level Leakage Current Output = 5V IOH Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi V 0.4 V 1 uA www.active-semi.com Copyright © 2018 Active-Semi, Inc. 16 ACT2861QI Rev 2.0, 27-Apr-2018 I2C INTERFACE ELECTRICAL CHARACTERISTICS (VIN = 12V, VBAT = 7.6V, TA = 25°C, unless otherwise specified.) PARAMETER SYMBOL CONDITIONS SCL, SDA Input Low VILO VIO = 1.8V SCL, SDA Input High VIHI VIO = 1.8V SDA Leakage Current IOH SDA = 5V 1 µA SDA Output Low VOL IOL = 5mA 0.4 V SCL Clock Frequency fSCL 1000 kHz SCL Low Period tSCL_LOW 0.5 us SCL High Period tSCL_HI 0.26 us SDA Data Setup Time tSU 50 ns SDA Data Hold Time tHD 0 ns Start Setup Time tST 260 ns Stop Setup Time tSP 260 ns Capacitance on SCL or SDA PIN CIN 10 pF Noise suppression on SCL and SDA tDEGLITCH 50 ns I2C Timeout Function tout MIN TYP MAX UNIT 0.4 V 1.25 V 0 Total time required for I2C communication to cause I2C state machine to reset 100 ms Note1: Comply with I2C timings for 1MHz operation - “Fast Mode Plus”. Note2: No internal timeout for I2C operations, however, I2C communication state machine will be reset when entering UV/POR State. Note3: This is an I2C system specification only. Rise and fall time of SCL & SDA not controlled by the IC. Note4: IC Address is factory configurable to 7’h24, 7’h66. tSCL SCL tST tHD tSU tSP SDA Start condition Stop condition Figure 2: I2C Data Transfer Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 17 ACT2861QI Rev 2.0, 27-Apr-2018 FUNCTIONAL DESCRIPTION operation. Refer to each specific CMI for the IC’s slave address General ACT2861 is a buck-boost charger with integrated MOSFETs. It provides a high efficiency, low external component count, minimal size solution for 2 to 5 cell battery charging applications. Its wide input operating range of 3.9V to 29V allows charging from many input sources. Table 1: ACT2861 I2C Addresses 7-Bit Slave Address 0x24h 0x66h The ACT2861 also operates in OTG (On-The-Go) mode where it operates in reverse operation by converting the battery voltage to a regulated output voltage on the VIN pin. It autonomously switches between buck, buckboost, and boost modes depending on the input and output voltages. It is optimized for minimum quiescent current in shipping, shutdown, and standby modes. This makes is ideal for battery powered applications. SHIP mode reduces the total quiescent current to 1uA. It automatically resumes normal operation when the SHIPM pin is pulled low or power is applied to VIN. 010 0100b 110 0110b 8-Bit Write Address 0x48h 0xCCh 8-Bit Read Address 0x49h 0xCDh The I2C packet processing state machine has a 100ms timeout function for each I2C command. If there is greater than 100ms between a start bit and a stop bit, the ACT2861 resets the I2C packet processing and sets the I2C_FAULT bit in register 0x06h. Any time the I2C state machine receives a start bit command, it immediately resets the packet processing, even if it is in the middle of a valid packet. The I2C functionality is operational in all states except RESET. I2C commands are communicated using the SCL and SDA pins. SCL is the I2C serial clock input. SDA is the data input and output. SDA is open drain and must have a pull-up resistor. Signals on these pins must meet timing requirements in the Electrical Characteristics. For more information regarding the I2C 2-wire serial interface, refer to the NXP website: http://www.nxp.com. The ACT2861 can be operated in both stand-alone and host-controlled applications. External resistor set the fast charge current, input current limit, and OTG current limit. Using host controlled I2C operation, the user has full control over voltage, current, and fault settings. The IC can be configured to charge any battery chemistry. I2C operation gives the host full control of operating parameters as well as full knowledge of the operating parameters and fault conditions. A built in ADC provides input voltage, output voltage, input current, output current, and die temperature. The ADC also has one general purpose input to measure an external analog signal. I2C Registers The ACT2861 has an array of internal registers that contain the IC’s basic instructions for setting up the IC configuration, output voltages, switching frequency, fault thresholds, fault masks, etc. These registers give the IC its operating flexibility. The two types of registers are described below. The ACT2861 is highly flexible and contains many I2C configurable functions. The IC’s default functionality is defined by its default CMI (Code Matrix Index), but much of this functionality can be changed via I2C. I2C functionality includes OV and UV fault thresholds, switching frequencies, current limits, precharge and fast charge current settings, charging termination voltage, JEITA settings, and more. The CMI Options section shows the default settings for each available CMI option. Contact [email protected] for additional information about other configurations. Basic Volatile – These are R/W (Read and Write) and RO (Read only). After the IC is powered, the user can modify the R/W register values to change IC functionality. Changes in functionality include things like masking certain faults. The RO registers communicate IC status such as fault conditions. Any changes to these registers are lost when power is recycled. The default values are fixed and cannot be changed by the factory or the end user. I2C Serial Interface Basic Non-Volatile – These are R/W and RO. After the IC is powered, the user can modify the R/W register values to change IC functionality. Changes in functionality include things like output voltage settings, startup delay time, and current limit thresholds. Any changes to these registers are lost when power is recycled. The default values can be modified at the factory to optimize IC functionality for specific applications. Please consult To ensure compatibility with a wide range of systems, the ACT2861 uses standard I2C commands. It supports clock speeds up to 1MHz. The ACT2861 always operates as a slave device, and can be factory configured to one of two 7-bit slave addresses. The 7-bit slave address is followed by an eighth bit, which indicates whether the transaction is a read-operation or a write- Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 18 ACT2861QI Rev 2.0, 27-Apr-2018 [email protected] for custom options and minimum order quantities. CHARGE STATE MACHINE When the ACT2861 is in CHARGE MODE, it follows a dedicated charging state machine that autonomously handles complete battery charge control. This state machine is pre-configured for Li-Ion batteries. The ACT2861 can be configured to charge any battery topology using I2C. When modifying only certain bits within a register, take care to not inadvertently change other bits. Inadvertently changing register contents can lead to unexpected IC behavior. STATE MACHINE Reset State (RESET) ACT2861 contains an internal state machine with four internal states: SHIP MODE, HIZ, OTG MODE, and CHARGE MODE. All charging starts in the RESET State. In this state, all charging is completely disabled. The IC waits until the VIN voltage is within specification and then starts the Startup Delay timer. This timer is controlled by I2C bits VIN_STRT_DLY[1:0] in register 0x0Dh. SHIP MODE State SHIP MODE is the IC’s lowest power state. The ACT2861 always starts up in SHIP MODE. This mode is designed to reduce battery current during shipping. In this state, the IC is completely disabled except for the SHIPM pin and the input voltage detection circuitry. This results in 1uA of quiescent current from the battery. The IC can enter SHIP MODE via I2C, the SHIPM pin, or after a full power down of both input and battery voltage. See the SHIP MODE section for more details. During this state the nCHG pin is pulled low to indicate charging is in progress. The Low Battery Safety timer and the Fast Charge Safety Timer are both held in reset in this state. Dead Battery Condition State (SCOND_DB) This charging state protects against dead batteries or battery packs where the internal battery FET has opened. The ACT2861 always enters this state after a valid input voltage is applied and the Startup Delay timer is expired. If the total battery voltage is less than 3V, the IC stays in this state and sources 10mA to the battery. In many cases, the internal battery FET is opened and the 10mA source current will reset the battery FET. The IC exits this state when the battery voltage increases above 3V for > 256us. The Low Battery Safety Timer runs in this mode. HIZ State HIZ mode is a low power state with the switching converter disabled. In this mode, I2C is active and the IC configuration can be changed. The IC enters HIZ from SHIP MODE and then either stays in HIZ or transitions to OTG MODE or CHARGE MODE depending on the external voltages, the EN_CHG pin, and the nOTG pin settings. Note that the HIZ Register overrides the EN_CHG and nOTG pin settings and holds the IC in HIZ mode. See the HIZ section for more details. During this state the nCHG pin is pulled low to indicate charging is in progress. CHARGE MODE Battery Short Condition State (SCOND) In CHARGE MODE, the ACT2861 transfers power from VIN to VBAT to charge the battery. The IC follows the Charge State Machine. While in CHARGE MODE, the nOTG pin is ignored until charge mode is disabled. See the CHARGE MODE section for more details. This state also protects against dead batteries. It provides a reduced charge current to protect over-discharged batteries. The default charging current is 100mA, but this can be modified via I2C bits VBAT_SHORT_CURRENT in register 0x0Bh. OTG MODE During normal charging, the charger enters SCOND when the battery voltage is greater than 3V for 16ms. In OTG MODE, the ACT2861 transfers power from VBAT to VIN to provide a regulated supply from the battery. The IC enters this mode with the nOTG Pin or the OTG_EN_OVERRIDE register. Once in OTG Mode, the IC follows the OTG State Machine. While in OTG MODE, the EN_CHG input is ignored. See the OTG MODE section for more details. The system continuously monitors the battery voltage and if the battery voltage is greater than the VBATSHORT voltage threshold for 16ms, the charger exits the SCOND state and moves to the Precondition state. The battery short detection voltage, VBAT_SHORT, is adjustable by I2C bits VBAT_SHORT in register 0x0Bh. Note: If the battery Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 19 ACT2861QI Rev 2.0, 27-Apr-2018 Figure 3: Operating Modes State Machine During this state, the VIN voltage and VIN Current regulation loops are active to ensure the input supply power ratings are not exceeded. Additionally, the thermal regulation loop is active to keep the ACT2861 junction temperature at or below the desired maximum junction temperature. See the appropriate sections for more details. voltage is above the VBATSHORT voltage when entering this state, the charger still charges at the ISHRT current for 16ms before moving to the Precondition state. During this state, the Low Battery Safety Timer is running to detect fault conditions or bad battery. See the Charge Safety Timers section for further details. The Low Battery Safety Timer is a cumulative timer for the SCOND, and PCOND states and is fixed at 2 hours. During this state the nCHG pin is pulled low to indicate charging is in progress. Battery Short Condition Temp Suspend (SCSUSPEND) A Safety Timer timeout or Battery OV during this state causes the charger to move to the Fault State, which disables charging. An input voltage OV or UV condition also moves the state machine into the Fault state. Finally, a fault on the VREG LDO, which is not masked with the DIS_CHG_VREG_FLT register also moves the state machine into the Fault state. This state prevents charging when the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold. All switching stops and charging is suspended. The state machine only enters SCSUSPEND from the SCOND state. The charger transitions back to the SCOND state and Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 20 ACT2861QI Rev 2.0, 27-Apr-2018 resumes charging when the temperature returns to allowable levels. The system can force the IC out of the SCSUSPEND state by disabling the TH input via I2C. Battery Precondition BAT Temp Suspend (PCSUSPEND) This state prevents charging when the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold. The state machine only enters PCSUSPEND from the PCOND state. The charger transitions back to the PCOND state and resumes charging when the temperature returns to allowable levels. The system can force the IC out of the PCSUSPEND state by disabling the TH input via I2C. In this state, the Low Battery Safety Timer is suspended, but held at its current value, in SCSUSPEND state. The timer resumes counting when charging resumes. During this state the nCHG output pin blinks at 1HZ to indicate a fault condition. Battery Precondition Condition State (PCOND) The PCOND state preconditions the battery with a low charge current to avoid damage to fully discharged batteries. In this state the charger charges the battery at the IPRECHG level. The default precharge current is 10% of the fast charge current which is set by the OLIM resistor. It is adjustable between 5% and 20% of the fast charge current using the I2C bits IPRECHG[3:0] in register 0x19h. In this state, the Low Battery Safety Timer is suspended, but held at its current value. The timer resumes counting when charging resumes. During this state the nCHG output pin blinks at 1HZ to indicate a fault condition. Battery Fast Charge State (FASTCHG) The Fast Charge state is the state where charger provides full charging current to the battery. The ACT2861 voltage and temperature protections ensure that the battery only enters the Fast Charge state when the conditions are safe for fast charging. During normal charging, the charger enters PCOND when the battery voltage is greater than VBATSHORT for 16ms. The system continuously monitors the battery voltage and if the battery voltage is greater than the VBATLOW voltage threshold for 16ms, the charger exits the PCOND state and moves to the Fast Charge state. Note: If the battery voltage is above the VBATLOW voltage when entering this state, the charger still charges at the IPRECHG current for 16ms before moving to the Fast Charge state. During normal charging, the charger enters FASTCHG when the battery voltage is greater than VBATLOW for 16ms. If the charge current drops below ITERM for 750ms, the charger assumes the battery is charged and the state machines moves to either Charge Termination state or the Charge Full State. During this state, the Low Battery Safety Timer is running to detect a fault conditions or bad battery. See the Fast Charge Safety Timers section for further details. The Low Battery Safety Timer is a cumulative timer for the SCOND and PCOND states and is fixed at 2 hours. In the FASTCHG state, the charger regulates the constant charging current, ICHG, until the battery voltage reaches the VBAT_REG voltage. Then it regulates the battery voltage to a constant voltage. If in voltage regulation mode and current is pulled from the battery causing its voltage to drop below VBAT_REG, the charger seamlessly switches back into constant current mode. When the battery voltage reaches the VBAT_REG voltage, the current slowly decays as the battery “tops off”. When the current drops to the termination current, ITERM, the battery is fully charged. A Low Battery Safety Timer timeout or Battery OV fault during this state causes the charger to move to the Fault State, and disable charging. An input voltage UV or OV condition also moves the state machine into the Fault state. Finally, a fault on the VREG LDO, which is not masked with the DIS_CHG_VREG_FLT register moves the state machine into the Fault state. The VBAT_REG battery voltage can be adjusted using the I2C bits VTERM[10:0] bits in registers 0x11h and 0x12h. During this state, the VIN voltage and VIN Current regulation loops are active to ensure the input supply power ratings are not exceeded. Additionally, the thermal regulation loop is active to keep the ACT2861 junction temperature at or below the desired maximum junction temperature. See the appropriate sections for more details. The ICHG current can be controlled with the external resistor on the OLIM pin and by the I2C bits IFCHG[6:0] in register 0x18h. The I2C current adjustable is programmed as a percentage of the full current level set by the OLIM resistor. During this state the nCHG pin is pulled low to indicate charging is in progress. The termination current can be adjusted using the I2C bits ITERM[3:0] in register 0x19h. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 21 ACT2861QI Rev 2.0, 27-Apr-2018 In this state, the Low Battery Safety Timer is turned off and reset. The Fast Charge Safety Timer starts running at the nominal rate to detect faults with battery charging. This timer can be adjusted between 30 minutes and 16 hours, using the I2C bits FC_SAFETY_TIMER in register 0x1Bh. If a battery temperature fault condition is detected, the charger moves to the FAULT state. See the Charge Safety Timers section for further details. During normal charging, the charger enters CHGFULL state from the FASTCHG state when the charging current drops below ITERM for greater than 750ms AND the I2C bit EN_TERM = 0. If the charge current exceeds the ITERM current for 16ms, or if the battery voltage drops below VBAT_GOOD for 16ms, the IC exits the Charge Full state and moves back to the FASTCHG state. A Fast Charge Safety Timer timeout or Battery OV fault during this state causes the charger to move to the Fault State, and disable charging. An input voltage UV or OV condition also moves the state machine into the Fault state. Finally, a fault on the VREG LDO, which is not masked with the DIS_CHG_VREG_FLT register moves the state machine into the Fault state. A Battery Temp or Battery OV fault during this state causes the charger to move to the Fault state and disable charging. An input UV or OV condition also moves the state machine into the Fault state. Finally, a fault on the VREG LDO, which is not masked with the DIS_CHG_VREG_FLT register moves the state machine into the Fault state. If the battery voltage drops below the VBATLOW voltage for 16ms, the charger goes back into the Battery Precondition state. In this state, the Fast Charge Safety Timer and the Low Battery Safety Timer are reset and held at 0. During this state the nCHG pin is HIZ to indicate the charging has completed and the Fast Charge Safety Timer is reset and held at 0. During this state, the VIN voltage and VIN Current regulation loops are active to ensure the input supply power ratings are not exceeded. Additionally, the thermal regulation loop is active to keep the ACT2861 junction temperature at or below the desired maximum junction temperature. See the appropriate sections for more details. Charge Full Suspend (CFSUSPEND) This state prevents charging when the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold. The state machine only enters CFSUSPEND from the CHGFULL state. The charger transitions back to the CHGFULL state and resumes charging when the temperature returns to allowable levels. The system can force the IC out of the CFSUSPEND state by disabling the TH input via I2C. During this state the nCHG pin is pulled low to indicate charging is in progress. Fast Charge Temp Suspend (FCSUSPEND) This state prevents charging when the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold. The state machine only enters FCSUSPEND from the FASTCHG state. The charger transitions back to the FASTCHG state and resumes charging when the temperature returns to allowable levels. The system can force the IC out of the FCSUSPEND state by disabling the TH input via I2C. In this state, the Fast Charge Safety Timer is still held at 0. During this state the nCHG output blinks at 1HZ to indicate a fault condition. Battery Termination State (CHGTERM) In this state, the Fast Charge Safety Timer is suspended, but held at its current value. The timer resumes counting when charging resumes. In this state, the charger is disabled and does not supply any current to the battery. It monitors the battery voltage to check for the condition when the battery voltage drops to VTERM-VRECHARGE. The VRECHARGE voltage is typically 100mV or 150mV per cell. Once the battery voltage drops below the threshold, the IC enters the Fast Charge state and recharges the battery. During this state the nCHG output blinks at 1HZ to indicate a fault condition. Charge Full State (CHGFULL) The Charge Full state functionality is the same as the FASTCHG state. The charger can stay in the CHGFULL state indefinitely. It keeps a fully charged battery regulated to the VBAT_REG voltage. If something pulls current from the battery, the charger supplies current to maintain the battery voltage at VBAT_REG. The maximum charge current is still limited by the external OLIM resistor and the IFCHG[6:0] register. During normal charging, the charger enters this state when the charging current drops below ITERM for greater than 750ms AND the I2C bit EN_TERM = 1. In this state, the Fast Charge Safety Timer and the Low Battery Safety Timer are reset and held at 0. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 22 ACT2861QI Rev 2.0, 27-Apr-2018 Figure 4: Charger State Machine Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 23 ACT2861QI Rev 2.0, 27-Apr-2018 A Battery Temp or Battery OV fault during this state causes the charger to move to the Fault state and disable charging. An input UV or OV condition also moves the state machine into the Fault state. Finally, a fault on the VREG LDO, which is not masked with the DIS_CHG_VREG_FLT register moves the state machine into the Fault state. charger to the RESET state to start charging again. The Low Battery Safety Timer can be reset by setting the I2C bit DIS_SAFETY_TIMER = 1. The charger also exits the FAULT state if the IC is enters HIZ or SHIPMODE. Refer to the Operating Modes State Machine Diagram for more details. 3. VBAT OV Fault – This fault can be latching or nonlatching depending on the I2C bit DIS_BAT_OVP in register 0x01h setting. If DIS_BAT_OVP=0, then a battery overvoltage fault is latching. This requires the IC to exit the Charge state to exit the charger FAULT state. Exit the Charge state with the EN_CHG pin or any other method shown in the Operating Modes State Machine Diagram The nCHG pin is HIZ to indicate the charging has completed and the Fast Charge Safety Timer is reset and held at 0. Charge Termination Suspend (CTSUSPEND) This state prevents charging when the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold. The state machine only enters CTSUSPEND from the CHGTERM state. The charger transitions back to the CHGTERM state and resumes charging when the temperature returns to allowable levels. The system can force the IC out of the CTSUSPEND state by disabling the TH input via I2C. If DIS_BAT_OVP=1, then a battery overvoltage fault is not latching. The charger exits the FAULT state and returns to the RESET state when the overvoltage fault clears. A 40msec deglitch timer is available to prevent false OV fault detection due to noise or short battery voltage transients The I2C bit VBAT_OV_DEGLITCH_EN in register 0x0Bh sets the deglitch time. Setting this bit = 1 gives a 40ms deglitch time. Setting it = 0 gives a 5us deglitch time. In this state, the Fast Charge Safety Timer is still held at 0. During this state the nCHG output blinks at 1HZ to indicate a fault condition. 4. VIN OV or VIN UV Fault – If the VIN voltage exceeds the UVLO or OVLO thresholds, the charger stops charging and enters the FAULT state. Once the input voltage returns to an acceptable level, the IC returns to the RESET state to restart the charging process. Fault Mode (FAULT) This state protects the battery against all system level faults by disabling the charger and preventing any additional current to go to the battery. 5. VREG LDO Fault – If the VREG LDO is not within regulation or in an overcurrent condition, the charger enters the FAULT state. Once the fault condition has been removed from the LDO, the charger returns to the RESET state to restart the charging process. This fault can be ignored, if I2C bit DIS_CHG_VREG_FLT in register 0x0Dh = 1. If this bit = 1, the charger does NOT go to the FAULT state with a VREG LDO fault. The charger enters the FAULT state if any of the following occurs: 1. Fast Charge Safety Timer Timeout – If the timer exceeds the setting in the FC_SAFETY_TIMER[4:0] register 0x1Bh, then the charger enters the FAULT state. It stays in the FAULT state until this timer is reset with the I2C bit DIS_SAFETY_TIMER in register 0x1Bh. Any condition that clears the Fast Charge Safety timer makes the charger exit the FAULT state and returns the charger to the RESET state to start charging again. The Fast Charge Safety timer can be reset by setting the I2C bit DIS_SAFETY_TIMER = 1. The charger also exits the FAULT state if the IC is enters HIZ or SHIPMODE. Refer to the Operating Modes State Machine Diagram for more details. 6. Die Thermal Shutdown (TSD) – If the die temperature exceeds TSHUT (160°C) the charger moves into the FAULT state until it cools down by the thermal hysteresis, TSHUT_HYST (30°C). This fault cannot be cleared or masked. The IC must cool down before exiting the FAULT state. Once the IC cools down, it automatically clears this fault, exits the FAULT state, and returns to the RESET state to resume charging. 2. Low Battery Safety Timer Timeout – If the timer exceeds 120 minutes for the states when VBAT is less than VBAT LOW, then the charger enters the FAULT state. It stays in the FAULT state until this timer is reset with the I2C bit DIS_SAFETY_TIMER in register 0x1Bh. Any condition that clears the Low Battery Safety Timer makes the charger exit the FAULT state and returns the 7. Watchdog Fault – If the watchdog timer is enabled and the timer ties out, the Watchdog fault holds the charger in the FAULT state until the watchdog timer is reset or cleared. It can be reset by writing a 1 to the I2C bit WATCHDOG_RESET or by disabling the Watchdog timer with I2C bit WATCHDOG[1:0]=00. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 24 ACT2861QI Rev 2.0, 27-Apr-2018 8. FET_OC – If any of the FET currents reach the overcurrent limit threshold for 16 cycles in a row, the IC enters FET_OC fault. The fault latches and the IC must EXIT the Charge state to clear the latch. Exit the Charge state with the EN_CHG pin or any other method shown in the Operating Modes State Machine Diagram clears when the watchdog timer is reset or cleared. It can be reset by writing a 1 into the I2C bit WATCHDOG_RESET in register 0x00h. It can be cleared by disabling the watchdog timer by setting I2C bits WATCHDOG[1:0] = 0x01h. During this state, the Fast Charge Safety and Low Battery Safety Timer timers are suspended and held at their current value. When the IC is in the FAULT state, the switching charger is disabled and the charge current to the battery is 0A. FET Overcurrent Fault: This fault is set if a switching FET exceeds the cycle-by-cycle current limit for 8 (or 16) consecutive cycles. The FET_OC fault is latched. To clear this latch, the IC must exit the OTG mode and enter HIZ mode. This is typically accomplished by toggling the nOTG pin or setting the HIZ register to 1. When in the FAULT state, the nCHG pin blinks at a 1HZ rate to indicate a fault condition. OTG STATE MACHINE The ACT2861 has a dedicated OTG state machine. This state machine handles the startup, normal operation and fault conditions in OTG mode. VBAT Overvoltage: This fault is set if VBAT exceeds the VOTG_BAT_OV voltage. The OV fault self-clears when VBAT drops below VOTG_BAT_OV and the IC exits the OTG_RST state. OTG Reset State (OTG_RST) The OTG state machine always starts from the OTG_RST state. All OTG operation starts from this state. In this state, the switcher is disabled and the state machine is waiting for all the required conditions to move to the OTG_SS state. Die Thermal Shutdown (TSD): This fault is active when die temperature exceeds the TSHUT (160°C) temperature. This fault self-clears when the die temperature cools down by the temperature hysteresis, TSHUT_HYST (30°C). This fault cannot be cleared or masked. The IC must cool down before exiting the OST_RST state. After all the following fault conditions are cleared, the IC starts the OTG Enable Delay Timer. This timer is controlled by I2C bit OTG_EN_DLY[1:0] in register 0x0Fh. Once the timer has expired, the state machine moves to the OTG_SS state. OTG Softstart State (OTG_SS) In this state, the IC enables the converter and softstarts the OTG output voltage. OTG Reset Faults: The state machine enters OTG_SS from the OTG_RST state when all faults are cleared. The state machine transitions to the OTG_REG state after the OTG output is softstarted an in regulation. OTG_VBAT_CUTOFF voltage: This fault is active when the battery voltage is lower than the programmed OTG battery cutoff voltage. The cutoff voltage is set by I2C bit OTG_VBAT_CUTOFF in register 0x0Fh. This fault self-clears when VBAT is higher than the OTG battery cutoff voltage. The softstart time is controllable by the I2C bit OTG_SS in register 0x0Eh. If a fault occurs during the softstart, the state machine jumps back to the OTG_RST state and disables the converter. Once the soft start is done, the IC jumps to the OTG_REG state. VREG LDO OK – This fault is set when an LDO fault is detected. This includes the 100msec timeout period. This fault automatically clears when the VREG LDO has exited the faulted condition. Note: This fault can be masked to allow the state machine to exit OTG_RST while there is a fault on the VREG LDO by using the I2C bit DIS_OTG_VREG_FLT in register 0x10 Bit 1. OTG Regulation State (OTG_REG) The normal regulation occurs in the ORG_REG state. If a major fault occurs during the IC will jump back to the reset state and disable the converter. During this state, the converter can be disabled with light load condition. Additionally, if the output drops below VOTG_UVP (3.0V), the IC will go into a hiccup mode to protect the output in a shorted condition. OTG HOT or OTG COLD: This fault is active if the battery temperature as detected on the TH pin is above or below the programmed temperature thresholds. This fault self-clears when the battery temperature goes back into the allowable range. Watchdog Timer Fault: This fault is active if the watchdog timer is enabled and the timer ties out. This fault Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 25 ACT2861QI Rev 2.0, 27-Apr-2018 Figure 5: OTG State Machine Diagram OTG Light Load Disable State (OTG_LL_DIS) it drops below VOTG_UVP (3.0V), the converter is disabled for 3s. After 3s, it automatically moves to OTG_RST and restarts. If there is a fault on the output, this cycle continues until the fault is removed. In the state, the converter is disabled to minimize load on the battery. It prevents the converter from switching with no load. The state machine enters OTG_LL_DIS when it senses a light load for longer than the light load time out time. This time is set by I2C bit OTG_OFF_DLY[1:0] in register 0x0Eh. Note that the converter only enters OTG_LL_DIS when operating in buck mode. It does not enter OTG_LL_DIS when in boost or buck-boost mode. The state machine can only exit OTG_LL_DIS when the IC exits the OTG Mode by the nOTG pin or HIZ register. OTG Hiccup / Vout Fault State (OTG_HICCUP) This state is a fault state that minimized overall IC power dissipation in extreme output overload conditions. The state machine enters this state when the OTG output cannot support the load. When the OTG output reaches the maximum programmed output current, it clamps the current and the voltage starts to drop. If the load increases, the output voltage drops even further. If Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 26 ACT2861QI Rev 2.0, 27-Apr-2018 PIN FUNCTIONS OSRP VIN OSRP is the positive sense pin for battery charge current sensing when the ACT2861 is in Charge mode. It is the negative sense pin for the input battery current sensing when the IC in in OTG mode. OSRP requires an input RC filter. Refer to the Setting Charge Current section for more details. OSRP must be Kelvin connected to the battery charge current sense resistor. Connect the battery charge current sense resistor between OSRP and OSRN. VIN is the ACT2861 input power pin when in CHARGE mode. It is also the input voltage sense input. VIN is the ACT2861 output power pin when in OTG mode. The OTG output voltage is regulated at the VIN pin. Connect input bypass capacitors directly between VIN and PGND. ISRP OSRN ISRP is the positive sense pin for input current sensing when the ACT2861 is in Charge mode. It is the negative sense pin for output current sensing when the IC in in OTG mode. ISRP requires an input RC filter. Refer to the Setting Charge Current section for more details. ISRP must be Kelvin connected to the input current sense resistor. Connect the input current sense resistor between ISRP and ISRN. OSRN is the negative sense pin for battery charge current sensing when the ACT2861 is in Charge mode. It is the positive sense pin for input battery current sensing when the IC in in OTG mode. OSRN requires an input RC filter. Refer to the Setting Charge Current section for more details. OSRN must be Kelvin connected to the battery charge current sense resistor. Connect the battery charge current sense resistor between OSRP and OSRN. ISRN ISRN is the negative sense pin for input current sensing when the ACT2861 is in Charge mode. It is the positive sense pin for output current sensing when the IC in in OTG mode. ISRN requires an input RC filter. Refer to the Setting Charge Current section for more details. ISRN must be Kelvin connected to the input current sense resistor. Connect the input current sense resistor between ISRP and ISRN. ILIM ILIM sets the maximum input current in CHARGE mode. It sets the maximum output current in OTG mode. Connect a resistor between ILIM and AGND to set the current limits. The ILIM current limit can be scaled using I2C. In some operating conditions, ILIM requires additional RC compensation. Refer to the Charging – Maximum Current Input section for more details. SW1, SW2 OLIM SW1 and SW2 are the switch nodes for the internal buck-boost converter. SW1 switches between VIN and PGND when the IC operates in buck and buck-boost modes. SW2 switches between VBAT and PGND when the IC operates in buck-boost and boost modes. Connect the inductor between the SW1 and SW2 pins. OLIM sets the maximum battery charge current in CHARGE mode. It sets the maximum battery input current in OTG mode. Connect a resistor between OLIM and AGND to set the current limits. The OLIM current limit can be scaled using I2C. In some operating conditions, OLIM requires additional RC compensation. Refer to the Setting Charge Current section for more details. HSB1, HSB2 HSB1 and HSB2 provide power to the internal high-side MOSFET gate driver circuitry. Connect a 47nF capacitor from HSB1 to SW1. Connect a 47nF capacitor from HSB2 to SW2. INTBP INTBP is the internal bias voltage output pin. INTPB is supplied by an internal linear regulator. Do not power external circuity from the INTBP pin. Connect a 100nF ceramic capacitor between INTBP and AGND. VBAT VBAT is the battery charger output power pin when in CHARGE mode. Is the input power pin in OTG mode Connect input bypass capacitors directly between VBAT and PGND. VREG VREG is the internal LDO output pin. The internal LDO is programmable between 2V and 5V. Its maximum output current capability 100mA. Connect a 1uF ceramic capacitor between VREG and AGND VBATS VBATS is the battery voltage sense pin. The battery voltage is regulated at the VBATS pin. Kelvin connect input VBATS as close to the battery input terminals as possible. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 27 ACT2861QI Rev 2.0, 27-Apr-2018 TH SHIPM TH is the battery temperature sense input. Connect a negative temperature coefficient thermistor from TH to AGND. This pin provides a constant current output and the voltage at this pin is used to calculate the battery temperature. If temperature sensing is not used, leave TH open and set register bit “DIS_TH” to a 1 SHIPM is the SHIP mode pin. If the IC is in SHIP mode, pulling it low for 32ms moves the state machine to the HIZ state which enables IC to startup into either CHARGE mode or OTG mode. If not used, connect SHIPM to AGND. SCL, SDA nOTG nOTG is the active low OTG enable input. Pulling nOTG low enables OTG mode when I2C bit EN_OTG is set. The nOTG polarity is configurable via NVM to make it active low or active high. Active low is the default. nOTG is 5V compliant. SCL and SDA are the I2C clock and data pins to the IC They have standard I2C functionality. They are opendrain outputs and each require a pull-up resistor. The pull-up resistor is typically tied to the system’s uP IO pins. The pullup voltage can range from 1.8V to 5.0V. SCL and SDA are open drain and are 5V compliant. EN_CHG PGND EN_CHG is the active high charge enable input. Pulling EN_CHG high enables the charger. EN_CHG is 5V compliant. The PGND pin is the buck-boost converters’ power ground. The internal FETs connect directly to the PGND pins. The power supply input and output capacitors must connect to the PGND pins. nCHG AGND nCHG is an open drain charge status pin. It indicates the charger status. It goes low to indicate that charging is in progress. It goes HI-Z to indicate charging is complete or disabled. When fault condition occurs, nCHG blinks at 1HZ. See Charge Status Pin (nCHG) section for list of faults and further description. The AGND pin is the IC’s analog ground pin. It is a “quiet” ground pin that is separate and isolated from the high power, high current carrying PGND ground plane. Connect the non-power components to AGND. AGND must be Kelvin connected to the PGND pin in a single location. ICOMP/GPIO Exposed PAD ICOMP/GPIO is a dual function pin. It is the OTG mode compensation pin. Connect the compensation components between ICOMP/GPIO and AGND. If OTG mode is not used, this pin can be programmed to be a GPIO via I2C. The Exposed pad is connected directly to the PGND pins and must be soldered to the top side ground plane. Place thermal vias under the Exposed PAD to improve the IC’s thermal performance. A2D This is the A2D input. Connect this pin directly to the voltage to be measured. Note that the ADC full scale input voltage is 2.5V. nIRQ ACT2861 has an interrupt pin to inform the host of any fault conditions. In general, any IC function with a status bit asserts nIRQ pin low if the status changes. The status changes can be masked by setting their corresponding register bits. If nIRQ is asserted low, the fault must be read before the IC deasserts nIRQ. If the fault remains after reading the status bits, nIRQ remains asserted. Refer to the nIRQ Interrupt Pin (nIRQ) section for more details. nIRQ is an open-drain output and should be pulled up to an appropriate supply voltage with a 10kΩ or greater pull-up resistor. nIRQ is 5V compliant Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 28 ACT2861QI Rev 2.0, 27-Apr-2018 BUCK-BOOST OPERATION The ACT2861 is a monolithic buck-boost charger with On-The-Go (OTG). As a result, it can operate in both charge mode and OTG mode. In charge mode, the IC converts power from VIN to VBAT to charge a 2S to 5S battery. In OTG mode, it converts power from the battery to VIN to provide a regulated output voltage. Four internal, low resistance, NMOS switches minimize the application circuit size and reduce power losses to maximize efficiency. Internal high side gate drivers, which require only two small external capacitors, further simplify the design process. An advanced switch control algorithm allows the buck-boost converter to maintain charge or OTG output voltage regulation with input voltages that are above, equal to, or below the regulated output voltage. The ACT2861 automatically transitions between these three operating modes, depending on the input to output voltage ratios. SW2 SW1 VIN Q1 VBAT L Q4 Q3 Q2 Figure 6: 4-Switch Buck-Boost Power Stage Table 2: Buck-Boost Switch Configuration CHARGE MODE BUCK BUCKBOOST BOOST Q1 SWITCHING SWITCHING ON Q2 SWITCHING SWITCHING OFF Q3 OFF SWITCHING SWITCHING Q4 ON SWITCHING SWITCHING Power Stage Figure 6 shows the 4-switch, buck-boost power stage. The converter operates with current mode control. The internal control algorithm reconfigures the IC between a buck, a boost, and a buck-boost topology as needed. This reduces power dissipation and maximizes efficiency because only two FETs switch when in it operates in buck or boost mode. Table 2 shows the switch configuration in each topology. Note that this table is valid for Charge mode. In OTG mode, power flows in the opposite direction, so the switching modes are reversed. The voltage transition between buck to buckboost and from buck-boost to boost modes is set by I2C bits XOVER_ADJ_BUCK and XOVER_ADJ_BOOST. With a fixed input voltage and an increasing battery voltage, the IC switches from buck mode to buck-boost mode when VIN – VBAT < XOVER_AJD_BUCK, which is typically 1V. It switches from buck-boost to boost mode when VBAT – VIN > XOVER_ADJ_BOOST, which is typically 2V. These values are set at the factory to optimize efficiency and performance for each CMI. Figure 7 shows the power stage operating modes. A typical example of how the converter switches between modes can be explained with an example using a 15V input source to charge a 4S Li-Ion battery. When fully discharged, the battery voltage is 12V. With VIN=15V and VBAT=12V, the control loop operates in Buck mode at point A. As the battery charges, the operating mode maintains buck mode until it crosses the threshold between buck mode and buck-boost mode. When the batteries are charged at 15V, the control loop operates at point B in Buck-Boost mode. The 4S battery reaches charge termination voltage at 17.4V. In this case, the control loop operates at point C, which is still BuckBoost mode. If the input voltage dropped from 15V to 12V, the control loop will move to point D and operate in Boost mode. The power stage is bi-directional and provides power in both directions. When charging, power flows from VIN to VBAT. In OTG mode, power flows from VBAT to VIN. Q1-Q4 are all internal, N-ch MOSFETs to minimize size and maximize efficiency. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 29 ACT2861QI Rev 2.0, 27-Apr-2018 GENERAL DESCRIPTION 30V Startup Buck Mode When power is first applied, the ACT2861 always starts up in SHIP mode. If only a battery is present, the IC remains in SHIP mode until the SHIPM pin is pulled to ground. The IC then enters HIZ mode where its internal LDO, VREG, is enabled. In HIZ mode, the IC can communicate via I2C. VIN 20V A B If power is applied to VIN, the ACT2861 powers up into SHIP mode and then transitions to HIZ mode when the voltage goes above 3.9V. At this time, the internal POK, power ok, signal is released and all registers are reset to their default values. C D 10V Depending on the EN_CHG and nOTG inputs, the IC then either stays in HIZ mode or moves to the OTG or CHARGE modes. Boost Mode VREG LDO 10V The ACT2861 contains a 100mA internal linear regulator that can be used to power other circuity in the system. VREG is enabled when the IC enters HIZ mode and the following two conditions are valid: 20V VBAT Figure 7: ACT2861 Operating Modes VIN is above UVLO (3.9V) or VBAT is above VBATUVLO (3.9V) PFM/PWM Operation I2C bit VREG_DIS in register 0x01h = 0. This register bit can be programmed Hi or Low from the factory to match system level requirements. At light loads, the ACT2861 operates in the PFM (pulse skipping) mode to reduce switching losses in Charge mode and OTG mode. PFM mode can be disabled by the I2C bit OTG_DIS_PFM/CHG_DIS_PFM in register 0x10h. Setting this bit to 0 enables PFM mode. Setting this bit to 1 forces PWM mode. This bit controls both Charge mode and OTG mode. The VREG output voltage is programmable between 2.0V and 5.1V in 100mV steps via I2C bits VREG[4:0] in register 0x11h. VVREG = 2.0V + 0.1V * VREG[4:0]. Where VREG[4:0] is the decimal equivalent of the value in this register. For example, if VREG[4:0] = 01101b (13 decimal), the output voltage = 2.0V + 0.1V * 13 = 3.3V. Out-of-Audio Mode When the IC operates in PFM mode, it reduces the switching frequency. At very light loads, the IC can switch in the audio range. The ACT2861 features an Out-of-Audio mode that prevents switching below 31.25kHz. Set the I2C bit AudioFreqLimit = 1 to enable this feature. The VREG input can come from either the VIN pin or the VBAT pin. The ACT2861 contains a Smart Diode Selector input that minimizes power dissipation by selecting the lower of these two input sources. When the IC operates in OTG Mode or Charger Mode, the IC powers VREG from the lower of the VIN or VBAT pins. However, if the lower voltage pin cannot provide the headroom needed to regulate VREG, it selects the higher voltage pin. When the converter is in HIZ mode, VREG is powered from VIN when possible. If VIN is not present or is not high enough to support the programmed output voltage, VREG is powered from VBAT. The Smart Diode Selector can be overridden and manual control can be selected using the I2C bits VREG_OVERRIDE and VREG_SELECT in register Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 30 ACT2861QI Rev 2.0, 27-Apr-2018 0x0Bh. When VREG_OVERRIDE = 0, the Smart Diode Selector is active. When VREG_OVERRIDE = 1, the VREG input is determined by VREG_SELECT. When VREG_SELECT = 0, the input is VBAT. When VREG_SELECT = 1, the input is VIN. 2. VREG LDO Overcurrent or Under-voltage Lockout - Any time the VREG LDO is in overcurrent or under-voltage lockout, nIRQ is asserted. This is a level sensitive function. VREG must be in regulation AND a 1 must be written into nIRQ_CLEAR to deassert nIRQ. If the VREG LDO is in the 100ms shutdown wait period, it will not clear the nIRQ output. This fault is detected in HIZ mode, Charge Mode, and OTG Mode. If VREG LDO is overloaded or not within spec, the buckboost converter shuts down, and I2C fault bit VREG_OC_UVLO in register 0x05h is set to 1. Additionally, if VREG is held in current limit for more than 90us, it shuts down for 100ms to prevent damage. It tries to restart after 100ms. It continues this cycle until the current limit condition is removed. VREG also contains UVLO detection, which is set to 88% of the programmed output voltage. 3. Battery voltage is lower than VBAT_GOOD – Any time the VBAT pin voltage falls below the VBAT_GOOD threshold, nIRQ is asserted. This is an edge triggered function after a 16ms deglitch. Write 1 to into nIRQ_CLEAR to deassert nIRQ. VBAT_GOOD is not checked in HIZ mode, so nIRQ is not triggered in HIZ mode. If VBAT is lower than VBAT_GOOD in HIZ mode, nIRQ is not triggered, but it is immediately triggered when the IC moves into the Charge or OTG modes. If the VREG output is in current limit for 90usec, or below the UVLO threshold while the IC is in Charge mode, the charger state machine moves to the FAULT state and stops charging. If in OTG mode, the OTG state machine moves to the OTG_RST state. In both cases, the buck-boost converter stops switching. VREG can be programmed to ignore an overvoltage or undervoltage fault with I2C bits DIS_CHG_VREG_FLT in register 0x0Dh and DIS_OTG_VREG_FLT in register 0x10h. If these bits are set to 1, Charge or OTG mode continue to operate through the fault condition. 4. Over Temperature Shut Down - Any time the die temperature exceeds the TSHUT (160°C) threshold, nIRQ is asserted. This is a level sensitive function. The die temperature must be below the TSHUT_HYST AND a 1 must be written into nIRQ_CLEAR to deassert nIRQ. Die TSD is active in all modes. VREG requires a high quality, low-ESR, ceramic output capacitor. A 1uF is typically suitable, but this value can be increased without limit. The output capacitor should be a X5R, X7R, or similar dielectric. The effective output capacitance must be greater than 0.7uF to ensure LDO stability. 5. FET Overcurrent Fault – If the IC is disabled from switching because of a FET overcurrent fault, nIRQ is asserted. This is a level sensitive function. This fault is latched, so the latch must cleared by manually going into HIZ Mode AND a 1 must be written into nIRQ_CLEAR to deassert nIRQ. This fault can only be triggered in CHG or OTG mode. VREG contains a fixed 250us soft-start to reduce inrush current. Interrupt Output Pin (nIRQ) 6. ADC Data Ready – If the ADC is enabled, and a conversion is completed, nIRQ is asserted. This is an edge triggered event. A 1 must be written into nIRQ_CLEAR to deassert nIRQ. This is active in all modes when the ADC is enabled. The nIRQ output pin can be used to signal a fault or other system effects. The conditions below can assert the nIRQ pin. All fault conditions can be individually masked using the I2C nIRQ Control Registers 0x1Eh, 0x1Fh, and 0x20h. To clear the interrupt and de-assert the nIRQ pin, write a 1 into I2C bit nIRQ_CLEAR in register 0x05h. nIRQ_CLEAR is a self-clearing register bit. nIRQ_CLEAR always returns a 0 when read, even after it is set to 1. 7. HIZ Enter – The ACT2861 asserts nIRQ wen it enters HIZ mode. This is an edge triggered event. 1 must be written into nIRQ_CLEAR to deassert nIRQ. The IC asserts nIRQ when entering HIZ mode to signal a fault or other condition that might have caused the IC to jump out of charge mode or OTG mode un-expectantly. General nIRQ Fault Conditions 1. Watchdog Expired - If the watchdog timer expires at any time, it asserts nIRQ. This is a level sensitive function. The watchdog timer must be reset or disabled and a 1 must be written into nIRQ_CLEAR to de-asserted nIRQ. 8. I2C Fault – If an I2C command takes more than 100ms between the start bit and the stop bit, nIRQ is asserted. This is an edge triggered Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 31 ACT2861QI Rev 2.0, 27-Apr-2018 event. The I2C state machine clears out any partial data, resets, and waits for another start bit for another I2C command. The state machine clears and restarts the 100ms timer when it receives the next start bit. must be written into nIRQ_CLEAR to deassert nIRQ. OTG Mode nIRQ Conditions 1. OTG Mode Battery Cutoff – If the VBAT pin voltage is below the VOTG_VBAT_CUTOFF threshold, nIRQ is asserted. This is a level triggered event. VBAT must be in the valid range AND 1 must be written into nIRQ_CLEAR to deassert nIRQ. 9. Input VIN OV (30V) – If VIN is above VIN_OVP (30V), nIRQ is asserted. This is a level triggered event. This fault is detected in HIZ mode, Charge Mode, and OTG Mode. 2. OTG Light Load Disable State - Any time the IC enters the OTG_LL_DIS state, nIRQ is asserted. This is an edge triggered event. A 1 must be written into nIRQ_CLEAR to deassert nIRQ. The IC does not need to exit the OTG_LL_DIS state to de-assert nIRQ. 10. VBAT Above VOTG_VBAT_OV (23.5V) - If VBAT is above VOTG_VBAT_OV (23.5V), nIRQ is asserted. This is a level triggered event. 1 must be written into nIRQ_CLEAR to deassert nIRQ. This fault is detected in HIZ mode, Charge Mode, and OTG Mode. 3. OTG Hiccup Mode / Vout Fault State - Any time the IC enters the OTG_HICCUP state, nIRQ is asserted. This is an edge triggered event. A 1 must be written into nIRQ_CLEAR to deassert nIRQ. Charge Mode nIRQ Conditions 1. Input Undervoltage - Any time VIN is below VIN_UVLO (3.9V) threshold, nIRQ is asserted. This is a level triggered event. VIN must be in the valid range and high AND 1 must be written into nIRQ_CLEAR to deassert nIRQ. 4. Battery Temperature – If the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold and causes the OTG state machine to move to the OTG_RST state, nIRQ is asserted. This is an edge triggered event. A 1 must be written into nIRQ_CLEAR to deassert nIRQ. 2. Fast Charge Safety Timer Expired – If the Low Battery Safety Timer expires or the Fast Charge Safety Timer expires during charge mode, nIRQ is asserted. This is level triggered event. The safety timers must be cleared AND 1 must be written into nIRQ_CLEAR to deassert nIRQ. The fault timers can be cleared via I2C or by exiting and re-entering Charge mode. Die Thermal Regulation The ACT286x monitors the internal junction temperature, TJ, to avoid overheating When TJ exceeds the maximum thermal regulation limit set by I2C bits TREG [1:0], the IC reduces the output current to lower the die temperature. This function works in both Charge mode and OTG mode. In Charge mode, the IC reduces the charging current. This has no effect other than to lengthen the charging time. In OTG mode, it reduces the output current limit value. If the load current is not reduced, the OTG output voltage will drop and generate an OTG undervoltage fault. The maximum operating junction temperature is programmable to 80ºC, 100ºC, or 120ºC to allow the user to optimize their system thermal performance. This function can be disabled by setting TREG[1:0] = 00. 3. Charge Completed – When the IC’s Charge state machine moves from the FASTCHG state to the CHGFULL or CHGTERM states, nIRQ is asserted. This is an edge triggered event. 1 must be written into nIRQ_CLEAR to deassert nIRQ. Note that the state machine can stay in the CHGFULL or CHGTERM states without reasserting nIRQ. 4. Battery Overvoltage - If the VBAT pin voltage exceeds the VBAT Overvoltage threshold VBATOVP during Charge mode, nIRQ is asserted. This is a level triggered function. The battery voltage must be below VBAT OVP AND a 1 must be written into nIRQ_CLEAR to deassert nIRQ. When Thermal Regulation is active in Charge mode, the Low Battery Safety and Fast Charge Safety Timers both run at ½ speed to increase the overall safety timeout window. 5. Battery Temp Suspend – If the battery temperature measured by the TH pin exceeds the JEITA or Battery Temp registers settings for Hot or Cold and causes the Charging state machine to move to a suspend mode, nIRQ is asserted. This is an edge triggered event. A 1 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 32 ACT2861QI Rev 2.0, 27-Apr-2018 the IC stays in HIZ state indefinitely. Refer to the Charging and OTG sections for the details to transition from HIZ mode to those modes. SHIP MODE The ACT2861 contain a SHIP MODE feature that reduces battery current consumption to 1uA. This is especially useful when a battery powered application is shipped to the store and sits on the shelf for long periods of time. In SHIP MODE the IC turns off all functions except the SHIPM pin and the VIN voltage detection circuitry. The IC state machine always starts in SHIP MODE state. There are two ways to exit SHIP MODE. To enter HIZ mode from SHIP mode, pull VIN pin high or pull the SHIPM pin low for > 32ms. The IC enters HIZ mode from OTG or Charge modes when OTG or charging are disabled or if a 1 is written into I2C bit HIZ in register 0x00h. Thermal Shutdown Apply a valid input voltage to the VIN pin for more than 32ms. The ACT2861 has thermal shutdown protection that disables the buck-boost converter when IC junction temperature exceeds TSHUT (160°C). The fault register TSD is set to 1 and latched when a TSD fault is detected. In Charge Mode and OTG Mode, the converter restarts automatically after the junction temperature falls below TSHUT - TSHUT_HYST, or approximately 160°C - 30°C = 130°C. After the system restarts, the TSD bit is latched until it is read by I2C. Pull the SHIPM pin to ground for greater than 32ms. IC always transitions to the HIZ MODE before moving to the CHARGE or OTG modes. After the IC has exited SHIP MODE, there are three ways it can be put back into SHIP MODE. 1. The IC automatically enters Ship mode when the VIN and VBAT voltages drop below 1V. FET Over Current Protection bit SHIPM_ENTER in register 2. Write a 1 into 0x00h. After the write command is complete, the IC stays enabled for 1s to allow the system to properly power down. After 1s, the IC enters SHIP MODE and the SHIPM_ENTER bit is reset to 0. During the 1s timer count down, the SHIPM_ENTER bit stays high. Writing a 0 into SHIPM_ENTER before the 1s timer expires resets the timer and cancels the command. The ACT286x closely monitors the HSFETs and LSFETs currents for safe operation. If any FET exceeds the maximum cycle-by-cycle current limit threshold set by I2C bit FET_ILIMIT in register 0x01h, the FET is immediately turned off for that switching cycle. Two thresholds of 8.5A and 10A are available. If a FET detects the current limit for eight continuous cycles, the buck-boost converter is latched off. This protection is valid in both Charger Mode and OTG Mode. 3. Pull the SHIPM pin above 4.5V for 32ms. This function is immediately edge triggered after 32ms, and there no 1s delay. After FET Overcurrent protection is triggered, there are two ways to clear the fault to let the converter resume normal operation. First is to set I2C bit DIS_OCP_SHUTDOWN = 1 in register 0x01h. It can also be cleared by putting the IC into HIZ mode. In OTG mode, toggle the nOTG pin to put the IC into HIZ mode and then restart OTG mode. In Charge mode, toggle the EN_CHG pin. I2 C While in SHIP MODE, the SHIPM pin is pulled up to approximately 3V with a 1M pullup resistor. Once IC has exited SHIP MODE, the SHIPM pin is pulled to GND with a 1Meg resistor to reduce quiescent current. If SHIP MODE is not required, connect the SHIPM pin to GND. With this configuration, when power is applied to VIN or VBAT, the IC powers up into SHIP MODE for 32ms and then moves into HIZ mode. Note that the SHIPM pin has a 1.5V logic threshold (1.5V) so it can be diode OR’ed with a diode to external circuitry like a Push Button or digital output from an external GPIO. Overcurrent protection can be disabled by setting the I2C bit DIS_OCP_SHUTDOWN = 1. Watchdog Timer The ACT2861 contains a watchdog timer to detect system level communication failures. The watchdog timer requires the host to periodically write a 1 into I2C bit WATCHDOG_RESET in register 0x00h. If the host latches up or is unable to perform the write command before the watchdog timer times out, the IC enters FAULT mode and disables the switching converter. The timer resets after each write to WATCHDOG_RESET. WATCHDOG_RESET is an auto-clearing register. It automatically resets back to 0 after it is set to 1. HIZ Mode The ACT2861 HIZ mode is a low power state where the buck-boost converter is disabled. The LDO can be enabled or disabled by I2C bit VREG_EN in register 0x01h. The IC always starts up in SHIP MODE and then transitions to HIZ mode before going to either OTG or Charge mode. If OTG or Charge modes are not enabled, Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 33 ACT2861QI Rev 2.0, 27-Apr-2018 The timeout value is controlled by I2C bit WATCHDOG[1:0] in register 0x01h. It can be set between 80s and 320s. If the IC is used in stand-alone operation, the watchdog timer can be disabled by setting WATCHDOG[1:0] = 00. hardware and I2C conditions required to enter Charge mode. Note that in all cases, the I2C bit HIZ in register 0x00h must be = 0 to enter Charge mode. When the HIZ bit = 1, the IC is forced into HIZ mode and both OTG mode and Charge mode are disabled. WATCHDOG is always disabled in HIZ Mode and cannot be enabled in HIZ. In addition, the timer is reset to 0 when entering HIZ mode and automatically starts counting when exiting HIZ mode into OTG or Charge Mode. HIZ Bit = 0 EN_CHG pin = 1 OVERRIDE_EN_CHG bit = 1 Battery Charge Management The ACT2861 charges 2 ~ 5 cell Li-Ion battery with up to 5A charge current for high capacity batteries. The default charging profile is configured for Li-Ion batteries, but the ACT2861 I2C configurability allows the IC to charge any battery chemistry. HIZ to Charge Mode nOTG pin = 1 OTG_EN_OVERRIDE bit = 0 Figure 8: Conditions to Enter Charge Mode from HIZ Mode Autonomous (stand-alone) Charging Cycle After the IC is in Charge mode, the conditions to exit charge mode change. While in Charge mode, the nOTG pin and I2C bits cannot be used to exit Charge mode. When the charger is disabled, the IC state machine must go to HIZ mode or to SHIP mode. To disable the charger and go to HIZ mode, pull the EN_CHG pin low and set bit OVERRIDE_EN_CHG = 0. Setting bit HIZ = 1 overrides all other settings and disables the charger and puts the IC into HIZ mode. The IC must go to HIZ mode before going to OTG mode. The charger can also be disabled by putting the IC into SHIP mode. With battery charging enabled at POR, the ACT2861 autonomously charges a 2 ~ 5 cell Li-Ion battery. The IC automatically detects the battery’s state of charge and starts charging in the proper charge state. It completes full or partial charging cycles without host intervention. Note that when performing stand-alone charging, the IC’s default CMI must match the battery requirements. This includes the number of cells being charged, their termination voltage, fastcharge current, precharge current, and shorted battery current. The CMI Options section shows the default settings for each available CMI option. Contact [email protected] for additional information about other configurations. Note that the WATCHDOG bits must be set to 00 to disable the watchdog timer in stand-alone charging mode. HIZ Bit = 1 EN_CHG pin = 0 OVERRIDE_EN_CHG bit = 0 Charger Enable / Disable Charge to HIZ Mode Figure 9: Conditions to Enter HIZ Mode from Charge Mode The ACT2861 can only enter Charge mode from HIZ mode. Note that if the IC is commanded to enter both OTG mode and Charge mode at the same time, OTG mode takes precedence. When in HIZ mode, the charger can be enabled with the EN_CHG pin or by I2C. To enable the charger with the EN_CHG pin, pull the pin above 0.8V. To disable the charger, pull it below 0.8V. EN_CHG connects to a comparator with a 0.8V threshold. The EN_CHG pin is 5V compliant, so it can be pulled up to 5V even when power is not applied to the IC. Connect a resistor divider to EN_CHG to set up a UVLO threshold to start charging. This is useful when the system should not start charging until the input voltage goes above a specific value. The charger can also be enabled with the I2C bit OVERRIDE_EN_CHG bit in register 0x00h. Setting this bit = 1 overrides the EN_CHG pin and forces the IC into Charge mode. When this bit = 0, the EN_CHG pin is used to enter Charge mode. Figure 8 shows both the Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 34 ACT2861QI Rev 2.0, 27-Apr-2018 the decimal equivalent value in this register. For example, if IOLIM, is programmed to 4A and IFCHG[6:0] = 1001011b (75% decimal), the final charge current = 4A * 0.75 = 3A. Battery Charging Profile The IC follows the standard Li-Ion battery charge profile with four charging phases: dead battery, preconditioning, constant current, and constant voltage. The battery charge current is a function the battery voltage and the IC’s hardware and register settings. Table 3 shows these settings. Note that IFCHG[6:0] is a 7 bit register and can be programmed between 0x00h and 0x7Fh (0% and 127%). If a value of 0x00h is written to the register, the register retains 0x00h, but the IC sets the charge current to 1%. If a value above 0x64h (100%) is written to the register, the IC retains the written value, but sets the charge current to 100%. Table 3: Charging Current Setting Charging Current VBAT < VBATDEAD VBATDEAD ~ VBATSHORT VBATSHORT ~ VBATLOW IDBATTERY > VBATLOW ICHG > VTERM 0A ISHORT IPRECHG Current set by Fixed at 10mA I2C Configurable: 1%, 2%, 4%, 8% of IOLIM current I2C Configurable: 5% to 20% of IOLIM current I2C and Hardware Configurable None ROSRN OSRN COSR ROSRP OSRP RCS_OUT VBAT To Battery OLIM Voltage Current RCS_COMP VTERM ROLIM Battery Voltage IFASTCHARGE CCS_COMP Charge Current Figure 11: Charge Current Circuitry VBATLOW Regulate V TERM after charge complete VDBATTERY ITERM IDBATTERY Dead Battery Trickle Charge PreCharge IPRECHARGE ISHRT Fast Charge and Voltage Regulation Figure 10: Battery Charging Profile The current sense resistor and OLIM resistor set the IOLIM current. 1000 ∗ Setting Charge Current Where ROLIM is the resistor from the OLIM pin to AGND in ohms and RCS_OUT is the current sense resistor value in ohms. The term 1000V^2/A is a constant with the units volts^2/Ampere. The battery charging current, ICHG, is set by a combination of a current sense resistor, an OLIM resistor, and a scaling factor defined by I2C bits IFCHG[6:0] in register 0x18h. The maximum allowable charge current is 5A. Figure 11 shows the hardware circuitry that sets IOLIM. IOLIM is the maximum charge current set by hardware. The actual battery charge current, ICHG, can be scaled from 1% to 100% of IOLIM in 1% steps. The following equation defines the final charge current. I I _ The current sense resistor, RCS_OUT, value should be chosen to give a maximum current sense voltage between 20mV and 50mV. 50mV is the absolute maximum allowable voltage. Using lower voltages reduces the resistor’s power dissipation, but decreases accuracy. At lower charging currents, additional RC compensation must be placed in parallel with ROLIM. Table 4 gives recommended resistor values for different values of IOLIM current. Contact [email protected] for compensation information if other configurations are required. ∗ IFCHG 6: 0 Where IOLIM is the hardware programmed charging current and IFCHG[6:0] is the scaling factor. IFCHG[6:0] is Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 35 ACT2861QI Rev 2.0, 27-Apr-2018 Table 4: Charge Current Component Selection When in the PCOND mode (precharge), the charger supplies the “precharge” current, IPRECHG. IPRECHG is a fixed percentage of ICHG which is set by the I2C bits IPRECHG in register 0x19h. IPRECHG can set the precharge current from 5% to 20% of the ICHG. Switching Frequency = 125kHz IOLIM (A) 5 4 3 2 1.5 1 RCS (mΩ) 10 10 10 10 20 20 ROLIM (kΩ) 20 25 33 50 33 50 RCS_COMP (kΩ) NA NA 10 10 10 10 CCS_COMP (nF) NA NA 330 330 330 330 Charging - Maximum Input Current Limit In Charge mode, the IC features an input current limit circuit to meet maximum input current limitations for USB sources and to avoid over loading weak input voltage sources. Figure 12 shows that the input current limiting circuitry is identical to the charge current setting circuitry. When the input current reaches current limit, the ACT2861 control circuitry starts regulating the maximum input current. When in charge mode, this effectively lowers the charge current to maintain the maximum programmed input current. The maximum allowable input current is 5A. The actual input current limit, IIN_LIM can be scaled from 1% to 100% of IILIM in 1% steps. The following equation defines the final input current limit. Switching Frequency = 250kHz, 500kHz, 1MHz IOLIM (A) 5 4 3 2 1.5 1 RCS (mΩ) 10 10 10 10 20 20 ROLIM (kΩ) 20 25 33 50 33 50 RCS_COMP (kΩ) NA NA NA 15 10 10 CCS_COMP (nF) NA NA NA 56 100 100 To eliminate noise in the current measurement circuit, the current sense voltage must be filtered. The recommended values are ROSRP = ROSRN = 30.1ohm and COSR = 100nF. These values can be scaled up or down, but ROSRP must be between 20ohm and 50ohm, and the resulting filter cutoff frequency must be between 20kHz and 30kHz. _ ∗ 6: 0 Where IILIM is the hardware programmed current limit and INLIM[6:0] is the scaling factor. INLIM[6:0] is the decimal equivalent value in this register. For example, if IILIM, is programmed to 5A and INLIM[6:0] = 0111100b (60% decimal), the final charge current = 5A * 0.60 = 3A. Note that INLIM[6:0] is a 7 bit register and can be programmed between 0x00h and 0x7Fh (0% and 127%). If a value of 0x00h is written to the register, the register retains 0x00h, but the IC sets the input current to 1%. If a value above 0x64h (100%) is written to the register, the IC retains the written value, but sets the input current to 100%. The actual charge current can be measured with the OLIM pin. The OLIM voltage is directly proportional to the charging current. The following equation calculates the charging current. 2 Input current limit can be set by the ILIM pin and IINLIM[6:0] registers. Where IOLIM is the hardware programmed 100% charging current in amps and VOLIM is the voltage measured at the OLIM pin. Note that the output current in charge mode becomes the input current in OTG mode. Charging – Dead Battery, Short Circuit, and Precharge Currents The charger operates at reduced currents when the battery voltage is low. This protects the battery chemistry and prepares it for fast charging. When in the SCOND_DB mode, the charger supplies a fixed 10mA of charge current. When in the SCOND mode, the charger supplies the “short battery” current, ISHRT. ISHRT is a fixed percentage of ICHG which is set by the I2C bits VBAT_SHORT_CURRENT in register 0x0Bh. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 36 ACT2861QI Rev 2.0, 27-Apr-2018 Note that the input current in charge mode becomes the output current in OTG mode. RISRP ISRN Charging – Minimum Input Voltage Limit The input voltage limit feature is used to prevent the charger from overloading USB or weak input power sources. If the input voltage drops due to an overloaded input source, the ACT2861 starts regulating the minimum programmed input voltage to prevent the voltage from dropping farther. When in charge mode, this effectively lowers the charge current to maintain a minimum input voltage. CISR RISRN ISRP RCS_IN VIN From Input Supply ILIM RCS_COMP The minimum input voltage threshold is programmable between 4V and 16.7V in 100mV steps via I2C bits VINLIM[6:0] in register 0x16h. The following equation sets the minimum input voltage threshold. RILIM CCS_COMP 4.0 Figure 12: Input Current Circuitry 6: 0 Where VINLIM[6:0] is the decimal equivalent of the value in this register. For example, to prevent a 12V input source from dropping below 9V, VINLIM[6:0] = 0110010b (50 decimal), the minimum input voltage = 4.0V + 0.1V * 50 = 9.0V. The current sense resistor and ILIM resistor set the IILIM current. 1000 ∗ 0.1 ∗ _ If system is in input voltage limit, the INPUT_VINLIM_STATUS bit in register 0x03h goes high. Where RILIM is the resistor from the ILIM pin to AGND and RCS_IN is the current sense resistor value in ohms. The term 1000V^2/A is a constant with the units volts^2/Ampere. While the input voltage limit is active, both the Low Battery Safety Timer and Fast Charge Safety Timer run at a half speed to increase the overall safety timer timeout. The current sense resistor, RCS_IN, has the same limitations as RCS_OUT. At lower charging currents, additional RC compensation must be placed in parallel with ROLIM. Table 4 is also valid for the input current limit circuitry. Battery Thermal Control The ACT2861 TH pin can be used to monitor the battery temperature. An NTC resistor connected between TH and AGND provides temperature information. Battery temperature monitoring is valid in both Charge mode and OTG mode. If the battery temperature is outside the programmed upper and lower thresholds, the charger reports a fault and stops charging. The input current limit circuitry, RISRP = RISRN = 30.1ohm and CISR also have the same input filter requirements as the charge circuitry. If the system operates in input current limit mode, the INPUT_IINLIM_STATUS bit in register 0x03h goes high. The ACT2861 provides two temperature monitoring algorithms. The first is the comprehensive industry standard JEITA compliance. The second is a simple I2C register based high and low temperature threshold. To enable either method, I2C bit DIS_TH in register 0x01h MUST be set to 0. If this bit is set to 1, the TH input is ignored. If thermal monitoring is not required, either connect a 10kΩ resistor between the TH pin and AGND or write a 1 into DIS_TH. While the input current limit is active, both the Low Battery Safety Timer and Fast Charge Safety Timer run at a half speed to increase the overall safety timer timeout. The actual input current can also be externally measured with the ILIM pin. The ILIM voltage is directly proportional to the charging current. The following equation calculates the actual input current. Figure 13 shows the TH pin internal circuitry. When thermal monitoring is enabled, the constant current source flows through the external NTC resistor, which gives a voltage vs temperature curve. The internal comparators give the ACT2861 information about the battery’s operating temperature. 2 Where IILIM is the hardware programmed input current limit in amps and VILIM is the voltage measured at the ILIM pin. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 37 ACT2861QI Rev 2.0, 27-Apr-2018 are fixed. To use the JEITA limits, enable thermal monitoring with bit DIS_TH = 0 and set I2C bit DIS_JEITA in register 0x1Ch = 0. ENABLE REF_60 REF_50 REF_45 Mode T0 - Tbattery < 0degC: All battery charging is suspended until the temperature goes back above 0deg C. Both the Fast Charge Safety Timer and the Low Battery Safety Timers are suspended. The T0 temperature is fixed at 0deg C and cannot be changed. NTC NTC 10K@ 25C Mode T1-T2 – 0degC < Tbattery < 10degC: Battery charging in this region is a function of the I2C bits JEITA_ISETC in register 0x1Ch. Depending on these register bits, fast charging in this region can range from fully suspended to not changed. Termination voltage is not changed. ISHORT and IPRECHARGE currents are not affected. Table 5 shows the resulting charge functionality and safety timer settings. REF_10 REF_0 Figure 13: TH Pin Resistor Network JEITA Battery Temperature Control Mode T3-T5 – 45degC < Tbattery < 60degC: Battery charging in this region is a function of the I2C bits JEITA_ISETH and JEITA_VSETH in register 0x1Ch. When JEITA_VSETH is a non-zero value, the IC reduces the termination voltage by 200mV to 750mV below the normal termination voltage. When JEITA_VSETH = 000 and JEITA_ISETH = 0, fast charge current is set to 50% of default. When JEITA_ISETH = 1, charging current and termination voltage are not changed. ISHORT and IPRECHARGE currents are not affected. To improve the safety of charging Li-ion batteries, the JEITA guideline was released on April 20, 2007. The guideline emphasizes the importance of avoiding a high charge current and high charge voltage at both extreme low and high temperature ranges. To comply with JEITA battery charging requirements, and to improve battery reliability and safety, the ACT2861 reduces the termination voltage and/or the charging current when the battery is at temperature extremes. When the battery temperature is outside the normal charging range, IC either reduces the safety timer speeds or stops the timers until the temperature goes back into the normal charging range. When stopped, the timers are not reset. They hold their value and resume normal counting when charging restarts. Refer to the Safety Timer Speed Settings table for specific details. Mode T6 – Tbattery > 60degC: All battery charging is suspended until the temperature goes back below 60deg C. Both the Fast Charge Safety Timer and the Low Battery Safety Timers are suspended. The T6 temperature is fixed at 60deg C and cannot be changed. Table 5 shows the resulting charge functionality and safety timer settings. Figure 13 shows this in graphical form. The ACT2861 contains default JEITA voltage, current, and temperature limits. These voltage and current settings are configurable via I2C. The temperature limits Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 38 ACT2861QI Rev 2.0, 27-Apr-2018 Table 5: JEITA Mode Charging Safety Timer Configuration Mode Temp T0 <0C T1 to T2 0C to 10C JEITA_ISETC 45C to 60C T3 to T5 T6 > 60C Low Battery Safety Timer JEITA_ISETH JEITA_VSETH XX 00 01 10 11 XX X X X X X X XXX XXX XXX XXX XXX NOT 000 Suspended Suspended 25% of ICHG 50% of ICHG 100% of ICHG Reduced Voltage Stopped Stopped ½ Speed ½ Speed Full Speed ½ Speed Suspended Suspended ISHRT / IPRECHG ISHRT / IPRECHG ISHRT / IPRECHG ISHRT / IPRECHG Stopped Stopped Full Speed Full Speed Full Speed Full Speed XX 1 000 Normal Full Speed ISHRT / IPRECHG Full Speed XX 0 000 50% of ICHG ½ Speed ISHRT / IPRECHG Full Speed XX X XXX Suspended Stopped Suspend Stopped [1:0] Fast Charge Safety Timer PreCharge / Short Current Fast Charge Current Battery Path Impedance Compensation The ACT2861 includes a Battery Path Impedance Compensation feature that speeds the charging cycle. This feature compensates for system level voltage drops due to PCB, connector, wiring resistances, and battery pack current sense resistances. Battery Voltage Set by REG JEITA_VSETH Charge Current Set by REG JEITA_ISETH These voltage drops effectively reduce the voltage at the battery. This results in the charger reaching the constant voltage portion of the charge cycle too soon. Staying in constant current mode longer reduces the charging time. Set by REG JEITA_ISETC 0°C 10°C 45°C 60°C Figure 13: JEITA Charging Profile The ACT286x allows the user to compensate for the system level resistances by increasing the voltage regulation set point according to a formula that is proportional to charging current and system resistance. This feature is implemented with two I2C registers: BAT_COMP_VCLAMP[2:0] and BAT_PATH_COMP[2:0] in register 0x0Ch. The BAT_COMP_VCLAMP[2:0] register sets the maximum increase in charging voltage. This can be programmed between 0mV and 420mV. The BAT_PATH_COMP[2:0] register sets the system resistance between 0mΩ and 140mΩ. Non-JEITA Battery Temperature Control The ACT2861 also includes non-JEITA battery temperature control. Enable this mode by setting I2C bit DIS_JEITA in register 0x1Ch = 1. In this mode, the IC compares the battery voltage as measured on the TH pin to two internal I2C registers: OTG_HOT[1:0] and OTG_COLD, both in register 0x1D. If the temperature is higher than OTG_HOT[1:0], all charging is suspended and the safety timers are stopped. If the temperature is lower than OTG_COLD, all charging is suspended and the safety timers are stopped. For safe operation, if one register is set to a non-zero value, the other register should also bet set to a nonzero value. The maximum battery termination voltage is set by the lower of the following two equations. OTG_HOT[1:0] selects 55degC, 60degC, or 65degC. Set this register = 11 to disable shutdown at hot temperatures. The OTG_COLD register selects between 0degC and -10degC. It is not possible to automatically disable charging at low temperatures. However, a host processor can read the battery temperature via the ADC converter and manually disable charging. _ _ ∗ _ _ _ _ _ _ Where VBAT_TERM is the new, compensated termination voltage in volts, VVTERM_I2C is the I2C battery termination voltage programmed in registers 0x12h and 0x11h, ICHG Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 39 ACT2861QI Rev 2.0, 27-Apr-2018 is the actual charging current. RBAT_PATH_COMP is the programmed system impedance in ohms, and VBAT_COMP_VCLAMP is the maximum allowable increase in battery termination voltage. reset and not active. If the Low Battery Safety timer times out, the IC goes to the Charging Fault state until it is reset – See below on how to clear the Low Battery Safety Timer. The Low Battery Safety Timer stops if the battery temperature causes the converter to stop switching and enter the SCSUSPEND or PCSUSPEND states. The Low Battery Safety Timer runs at ½ speed if the Input Voltage, Input Current, or Die Temperature regulations loops become active. This increases the overall time of 120 minute timer. Battery Full / Charging Termination The ACT286x terminates a charge cycle when the battery reaches the termination voltage and the charge current drops below the termination current. If the Input current limit, Input Voltage limit, or Thermal Regulation loop is active, the charger will not enter the Charge Full or Charge Termination states. When the Battery Voltage is above VBATLOW the Fast Charge Safety Timer is enabled and the Low Battery Safety timer is held in reset. The Fast Charge Safety Timer is controlled with the I2 C bits FC_SAFETY_TIMER[4:0] in register 0x1Bh. It is configurable between 30 minutes and 16 hours. If the Fast Charge safety timer expires, the IC goes into the Charging Fault state and charging is disabled until the Fast Charge Safety Timer is reset. Once the termination current and other requirements are met, the charger transitions from the fast charge state (FASTCHG) into either the charge full state (CHGFULL) or charge termination state (CHGTERM). When EN_TERM=0, the charger enters the CHGFULL state. The Charge Full state functionality is the same as the FASTCHG state. The charger can stay in the CHGFULL state indefinitely. It keeps a fully charged battery regulated to the VBAT_REG voltage. If something pulls current from the battery, the charger supplies current to maintain the battery voltage at VBAT_REG. The maximum charge current is still limited by the external OLIM resistor and the IFCHG[6:0] register. Both the Low Battery Safety and Fast Charge Safety Timers can be fully disabled and reset via the I2C bit DIS_SAFETY_TIMER in register 0x1Bh or manually bit SUSsuspended using the I2C PEND_SAFETY_TIMER in register 0x1Bh. Both safety timers are automatically stopped any time the charging is enabled but charging has suspended. This occurs when the battery temperature exceeds the allowable temperature limits. When EN_TERM=1, the charger enters the CHGTERM state. In this state, the charger is disabled and does not supply any current to the battery. It monitors the battery voltage to check for the condition when the battery voltage drops below VTERM-VRECHARGE. The VRECHARGE voltage is typically 100mV or 150mV per cell. Once the battery voltage drops below the threshold, the IC enters the Fast Charge state and recharges the battery. Both safety timers also run at ½ speed when VIN Input Regulation, IIN Current Regulation, or Die Thermal Regulation are active to increase the overall safety timer windows. Additionally, the Fast Charge Safety Timer runs at ½ speed in some JEITA charging modes. See the JEITA Battery Temperature Control paragraph for more details. See the state machine for more details charging and charge termination. Both safety timers are reset when any of the following occur: Charging Safety Timers 1. Charging State Machine enters RESET state The ACT2861 provides two internal charging safety timers: Low Battery Safety Timer and Fast Charge Safety Timer 2. DIS_SAFETY_TIMER register is set High 3. Charging has completed. This includes entering either the CHGFULL or CHG TERM states. When the Battery Voltage is below VBATLOW and in the charger is in the SCOND or PCOND states, a fixed 120 minute Low Battery Safety Timer is implemented. During this time, the Fast Charge Safety Timer is held in 4. IC exits the Charge Mode via the EN_CHG pin, OVERRIDE_EN_CHG, HIZ Registers, etc. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 40 ACT2861QI Rev 2.0, 27-Apr-2018 Table 6: Fast Charge Safety Timer Response Condition Charge Response Fast Charge Safety Timer Speed Normal Fast Charge NONE Full Speed VIN Input Regulation Reduced Charge Current ½ Speed IIN Input Current Regulation Reduced Charge Current ½ Speed Thermal Die Regulation Reduced Charge Current ½ Speed Battery Temp Exceed Limits Suspend Charge Suspend Battery Temp Hot or Cold Reduced Charge Current or VTERM ½ Speed Table 7: Low Battery Safety Timer Response Condition Charge Response Low Battery Safety Timer Speed Normal SCOND or PCOND Charge NONE Full Speed VIN Input Regulation Reduced Charge Current ½ Speed IIN Input Current Regulation Reduced Charge Current ½ Speed Thermal Die Regulation Reduced Charge Current ½ Speed Battery Temp Exceeds JEITA T0 or T6 Limits Suspend Charge Suspend Battery Temp Exceeds JEITA T1T2 or T3-T5 Limits NONE Full Speed Safety Timer Configuration Change C When the safety timer value needs to be changed, it is recommended that the timer is first disabled. Then change the FC_SAFETY_TIMER[4:0] register. Disable the safety timer by writing a 1 into I2C bit DIS_SAFETY_TIMER in register 0x1Bh. This procedure ensures the safety timer properly restarts after new value is configured. _ I ∗ ∗ ∗ Where CCHG_IN is the charging input capacitance (OTG output capacitance) in uF, ICHG is the charging current in Amperes, VBAT is the battery voltage in volts, VIN is the input voltage in volts, FSW is the switching frequency in Hz, and Vripple is the maximum input voltage ripple in volts. Charger – Input Capacitor Selection An additional 100uF bulk electrolytic capacitor is recommended. Note that the Charger CIN capacitors are also the OTG output capacitors. They are connected to VIN. The input capacitance should be a combination of ceramic and bulk capacitance. If the design uses OTG Mode, refer to the OTG Output Capacitor Selection. The OTG Mode capacitor requirements take precedence over Charging input capacitance. If the design only uses Charge mode and does not use OTG mode, 22uF to 47uF capacitors are typically acceptable, but the final value is application dependent. Choose the input capacitor value to keep the input voltage ripple less than ~50mV. The input capacitance can be increased without limit. Be sure to consider the input capacitor’s DC bias effects. A capacitor’s actual capacitance is strongly affected by its DC bias characteristics. The input capacitor is typically an X5R, X7R, or similar dielectric. Use of Y5U, Z5U, or similar dielectrics is not recommended. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 41 ACT2861QI Rev 2.0, 27-Apr-2018 Input capacitor placement is critical for proper operation. The input ceramic capacitor must be placed as close to the IC as possible. The traces from VIN to the capacitor and from the capacitor to PGND should as short and wide as possible. Refer to the Layout Guidelines selection and to the EVK layout for details. OTG Enable / Disable The ACT2861 can only enter OTG mode from HIZ mode. Note that if the IC is commanded to enter both OTG mode and Charge mode at the same time, OTG mode takes precedence. When in HIZ mode, OTG mode can be enabled by the nOTG pin or I2C. In either case, the I2C bit EN_OTG in register 0x0Eh must be = 1 to enable OTG mode. Then pull the nOTG pin low to enter OTG mode. The bulk capacitor should be placed on the left side of the current sense resistor. OTG Mode can also be enabled with the I2C bits OTG_EN and OTG_EN_OVERRIDE in register 0x0Eh. Setting OTG_EN = 1 enables OTG mode. Then set OTG_EN_OVERRIDE = 1 to enter OTG mode. Note that the OTG_EN_OVERRIDE bit overrides the nOTG pin. Figure 14 shows both the hardware and I2C conditions required to enter OTG mode. Charger – Output Capacitor Selection Note that the Charger COUT capacitor is also the OTG input capacitor. It is connected directly to VBAT pin. The capacitor should be dedicated high quality, low-ESR, ceramic capacitor that is optimally placed to minimize the power routing. 22uF to 47uF capacitors are typically acceptable, but the final value is application dependent. Choose the output capacitor value to keep the charger output voltage ripple less than ~50-100mV. The output capacitor can be increased without limit. C _ I ∗ Note that in all cases, the I2C bit HIZ in register 0x00h must be = 0 to enter OTG mode. When HIZ = 1, the IC is forced into HIZ mode and both OTG mode and Charge mode are disabled. ∗ ∗ HIZ bit = 0 Where CCHG_OUT is the charging output capacitance in uF, ICHG is the charging current in Amperes, VBAT is the battery voltage in volts, VIN is the input voltage in volts, FSW is the switching frequency in Hz, and Vripple is the maximum output voltage ripple in volts. HIZ to OTG Mode OTG_EN bit = 1 nOTG pin = 0 OTG_EN_OVERRIDE bit = 1 Figure 14: Conditions to Enter OTG Mode from HIZ Mode The ceramic capacitor PCB placement is critical. Refer to the Layout Guidelines selection and to the EVK layout for details. After the IC is in OTG mode, the conditions to exit OTG mode change. When OTG mode is disabled, the IC state machine must go to HIZ mode or to SHIP mode. There are several ways to disable OTG mode and go to HIZ mode. Be sure to consider the input capacitor’s DC bias effects. A capacitor’s actual capacitance is strongly affected by its DC bias characteristics. The output capacitor is typically an X5R, X7R, or similar dielectric. Use of Y5U, Z5U, or similar dielectrics is not recommended. Output capacitor placement is critical for proper operation. The output capacitor must be placed as close to the IC as possible. The traces from VBAT to the capacitor and from the capacitor to PGND should as short and wide as possible. 1. Set the I2C HIZ bit = 1 2. Set the I2C OTG_EN bit = 0 3. Pull the nOTG pin high and set the I2C OTG_EN_OVERRIDE bit = 0. 4. The IC also exits OTG mode if there is an OTG overvoltage condition for longer than 100ms. The bulk capacitor should be placed on the right side of the current sense resistor. OTG mode can also be disabled by putting the IC into SHIP mode. OTG MODE The ACT2861 supports on-the-go, OTG, mode buckboost converter operation. In this mode, the IC delivers power from the battery to power other portable devices. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 42 ACT2861QI Rev 2.0, 27-Apr-2018 OTG Mode Soft Start HIZ bit = 1 OTG_EN bit = 0 After the OTG Enable Delay has completed, the IC starts the output using a soft start function programmable by the I2C bits OTG_SS in register 0x0Eh. The softstart time is independent of the output voltage setting. OTG to HIZ Mode nOTG pin = 1 OTG_EN_OVERRIDE bit = 0 OTG_VOUT_OV bit = 1 100ms deglitch OTG Mode Constant Output Current Regulation Figure 15: Conditions to Enter HIZ Mode from OTG Mode After OTG mode soft start has completed, the IC monitors the current on VIN input side sense resistor (ISRP and ISRN) to provide constant current protection and regulation in OTG mode. When the OTG output current exceeds programmed value set by the ILIM pin and the OTG_CC register, the switching converter changes to output constant current mode and regulates a fixed output current. In this case, the output voltage may drop if the load resistance continues to decrease. OTG Output Voltage Setting The OTG output voltage is programmable between 2.96V and 23.42V in 20mV steps via by I2C bits OTG_VOUT[9:0] in registers 0x13h and 0x14h. 2.96 20 ∗ _ 9: 0 Where VOTG_VOUT[9:0] is the decimal equivalent of the value in this register. For example, if OTG_VOUT[9:0] = 0111000100b (452 decimal), the output voltage = 2.96V + 0.02V * 452 = 12.00V. The maximum OTG output current is set by the same resistor as the charger input current, Rcs_IN. Rcs_IN must be set for the larger of the charge current or OTG current. The maximum allowable OTG output current is 5A. The actual output current limit, IOTG_OUT_LIM can be scaled between 1% to 100% of IILIM in 1% steps. The following equation defines the final OTG output current limit. When changing from one OTG output voltage to another, the slew rate is programmable between 1V/ms and 0.1V/ms by I2C bits OTG_OUTPUT_SLEW[1:0] in register 0x10h. This allows the output to conform to QC2.0/QC3.0/USB PD functions for higher output voltages. _ _ ∗ _ 6: 0 Where IILIM is the hardware programmed current limit (see the Charging – Maximum Input Current section for details) and OTG_CC[6:0] is the scaling factor. OTG_CC[6:0] is the decimal equivalent value in this register. For example, if IILIM, is programmed to 5A and OTG_CC[6:0] = 0111100b (60% decimal), the final charge current = 5A * 0.60 = 3A. The battery voltage must always stay above VOTG_VBAT_CUFOFF set by I2C bits OTG_VBAT_CUTOFF[2:0] in register 0x0Fh. If the battery voltage drops below this value, the IC turns of the OTG output and goes to the OTG_RST state. OTG Active Discharge When changing the OTG output voltage to a higher level, the switcher ramps the output voltage by the programmed slew rate. When the output voltage is programmed from a higher to a lower voltage, the voltage drops at a rate determined by the output capacitance and the load current. To minimize the fall time in no-load conditions, the ACT2861 can provide a 70mA sink when the output is transitioning to a lower output voltage. Enable this feature by writing 1 into I2C bit OTG_PULLDOWN_RAMP. The 70mA load turns on until the output voltage goes into regulation. Note that OTG_CC[6:0] is a 7 bit register and can be programmed between 0x00h and 0x7Fh (0% and 127%). If a value of 0x00h is written to the register, the register retains 0x00h, but the IC sets the OTG scaling factor to 1%. If a value above 0x64h (100%) is written to the register, the IC retains the value, but sets the scaling factor to 100% The OTG regulation mode can be monitored in real time by I2C bit OTG_Output_CC in register 0x20h. When this bit = 0, the IC is regulating in output constant voltage mode. When this bit = 1, the IC is regulating in constant current mode. If the output drops below 3V, the IC assumes an output fault has occurred and disables the output for 3s. This is the OTG_HICCUP state. After 3s, the state machine goes to OTG_RST and restarts. If a short or high current fault is present after the restart, the IC cycles back to OTG_HICCUP and OTG_RST. This OTG Enable Delay Once the OTG has the valid conditions for startup, the OTG Enable Delay timer is enabled. The timer options allow a 0ms to 1s delay. The OTG startup delay is controlled by the I2C bits OTG_EN_DLY[1:0] Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 43 ACT2861QI Rev 2.0, 27-Apr-2018 cycle continues indefinitely until OTG is disabled or the fault is removed. OTG – Cord Compensation ACT286x provides cord compensation at the OTG output. This feature compensates for system level voltage drops due to PCB, connector, and wiring resistances. These resistances reduce the output voltage at the load. OTG Mode Constant Input Current Regulation At all times during OTG mode, the IC monitors the current on VBAT output side sense resistor (OSRP and OSRN) to provide battery current protection. The ACT286x features Cord Compensation which allows the user to compensate for these system level resistances by increasing the OTG voltage regulation set point proportional to the OTG output current. The output voltage increases linearly with increasing load current. The I2C OTG_CORD_COMP[1:0] bits in register 0x0F set the Cord Comp value. The maximum OTG input current is set by the same resistor as the charger output current, RCS_OUT. Unlike the RCS_IN resistor, RCS_OUT does not have to be set to the larger of the charge current or OTG input current. The maximum allowable OTG input current is 5A. The maximum OTG input current limit, IOTG_IN_LIM, is a scaled version of the programmed charge current, ICHG. IOTG_IN_LIM is scaled to 150% or 200% of ICHG. This allows a larger battery discharge current than charge current. The I2C bits OTG_BAT_ILIM[1:0] in register 0x10h scale the current. See the Setting Charge Current section for details on programming ICHG. The Cord Compensation value is normalized to RCS_IN = 10mΩ and a 2.4A OTG load current. It scales linearly with changes in current sense resistance or load current. Note that the RCS_IN resistor both the charging input current limit resistor and the OTG output current limit resistor. Table 8: OTG I2C Input Current Limit Setting OTG_BAT_ILIM[1:0] Register Setting OTG Input Current 00 OTG Disabled 01 150% of ICHG 10 200% of ICHG 11 300% of ICHG _ _ _ ∗ . ∗ _ . Ω Where VOTG_CORD_COMP is the I2C Cord Compensation value of 100mV, 200mV, or 300mV per Table 9, IOTG is the actual OTG output current in Amperes, and RCS_IN is the current sense value in Ohms. Table 9: OTG Cord Comp Setting When the OTG output current exceeds the maximum programmed value, the switching converter changes to input constant current mode and regulates a fixed input current. The OTG regulation mode can be monitored in real time by I2C bit OTG_BATTERY_CC in register 0x20h. When this bit = 0, the IC is not in OTG constant current mode. When this bit = 1, the IC is regulating in input constant current mode. If the output drops below 3V, the IC assumes an output fault has occurred and disables the output for 3s. It follows the same flow as an output current fault. OTG_CORD_COMP[1:0] Setting 00 01 10 11 Cord Comp Value 0 (Disabled) 100mV 200mV 300mV Equivalent System Resistance 0mΩ 41.7mΩ 83.3mΩ 125.0mΩ Light Load Disable The ACT2861 includes a Light Load Disable function in OTG mode. This function disables OTG mode and puts the IC into HIZ mode when the load drops very low. This condition typically happens when the ACT2861 OTG output is charging a portable device. When the portable device is fully charged, the output current drops to 0A. Light Load Disable minimizes battery current consumption and extends battery life when the OTG output is not needed. OTG Mode VIN Over-Voltage Protection When in OTG mode, the IC provides power out of the IC’s input. An input voltage should not be applied during OTG Mode. To detect a possible plug in of a higher supply on VIN during OTG mode, the IC detects an overvoltage condition on VIN (OTG output) and immediately stop switching. The OTG overvoltage threshold is fixed at 108% of the programmed OTG voltage. If the OV condition lasts for more than 100ms, the IC exits OTG Mode and enter HIZ Mode. Light Load Disable is available when the IC is operating in OTG mode, the switcher is operating in buck mode, VBAT is higher than VIN by a minimum of 0.5V, and the OTG Output Voltage is less than 6V. Enable Light Load Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 44 ACT2861QI Rev 2.0, 27-Apr-2018 Disable by setting I2C bit OTG_OFF_LOAD_EN in register 0x0Eh = 1. Setting this bit = 0 disables the feature. The minimum current is set to 4mA typical. The current must be low for longer than the time set in I2C bit OTG_OFF_DLY[1:0]. This time can get set to 10s, 20s, or 30s. OTG_STATUS[2:0] State Machine State 000 OTG_RST 001 OTG_SS 010 OTG_REG Once the OTG state machine has detected a light load condition, it enters the OTG_LL_DIS state. The IC must exit OTG mode and re-enter OTG mode to restart the converter. This is typically accomplished by toggling the nOTG pin, but can also be accomplished via I2C. 011 OTG_HICCUP 100 OTG_LL_DIS 101-111 Not Valid OTG – Output Voltage DVS OTG – Battery Temperature Protection The ACT2861 is ideally suited for many industry standard charging protocols such as USB PD3.0, QC2.0, QC3.0, etc. This includes USB PD3.0 + PPD. To achieve this compatibility, the output voltage can be dynamically changed in OTG mode. VOUT in OTG mode can be dynamically changed by writing to the OTG_VOUT[10:0] register, if internal feedback is used and OTG_VOUT_I2C is set to 0. The OTG_OUTPUT_SLEW[1:0] register is used to control the slew rate between settings when the OTG_VOUT[10:0] is changed. When the voltage is increased, the internal ramp and regulator can compensate and increase the voltage. However, when the voltage is decreased, and there is no external load on the output, the output voltage may not decrease fast enough to the meet the requirements. To speed up the transition time from higher to lower output voltages, set OTG_PULLDOWN_RAMP=1. This turns on an internal 70mA load when the output voltage is stepped to a lower voltage using the OTG_VOUT[10:0] register. The 70mA load turn off when the voltage goes into regulation. The ACT2861 provides battery temperature in OTG mode. If the battery temperature goes outside the programmed range, the IC goes to the OTG_RST state. It stays there until the temperature returns inside the programmed range or battery temperature monitoring is disabled. Note that the OTG thermal limits use the same registers as the non-JEITA charging registers. Enable OTG battery temperature monitoring by setting I2C bit DIS_TH = 0. When this feature is enabled, the IC compares the battery voltage as measured on the TH pin to two internal I2C registers: OTG_HOT[1:0] and OTG_COLD, both in register 0x1Dh. OTG - Frequency The ACT2861 OTG switching frequency is the same as the charging switching frequency. The ACT2861 can operate at 125kHz, 250kHz, 500kHz, or 1MHz. The switching frequency is set by the factory and is not user programmable. The default frequency is 500kHz to give the best tradeoff between size and efficiency, but can be programmed to the other options with a custom CMI. Note that the external component value requirements change with different switching frequencies. Contact [email protected] for additional information about other configurations. The ACT2861 also has a pulldown current that goes active during any output overvoltage condition. Enable this feature by setting the I2C bit OTG_PULLDOWN_OV = 1. OTG Mode – State Machine Status OTG – Input Capacitor Selection The I2C bits OTG_STATUS[2:0] in register 0x20h provide the user with real time status of the OTG state machine. These bits are always 000 when the IC is not in OTG mode. Note that the OTG CIN capacitor is also the charging output capacitor. It is connected directly to VBAT pin. The capacitor should be dedicated high quality, lowESR, ceramic capacitor that is optimally placed to minimize the power routing. 22uF to 47uF capacitors are typically acceptable, but the final value is application dependent. Choose the input capacitor value to keep the OTG input voltage ripple less than ~50mV. The COTG input capacitor can be increased without limit. C Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi _ I ∗ ∗ ∗ Equation 6 www.active-semi.com Copyright © 2018 Active-Semi, Inc. 45 ACT2861QI Rev 2.0, 27-Apr-2018 Where COTG_IN is the OTG input capacitance (Charging output capacitance) in uF, IOTG is the OTG output current in Amperes, VOTG is the OTG output voltage in volts, Vin is the OTG input voltage in volts, FSW is the switching frequency in Hz, and Vripple is the maximum OTG input voltage ripple in volts. Note that the Ceramic and Bulk capacitor values are recommended “Capacitor Values”. When choosing the ceramic capacitors, use X5R or X7R dielectrics and be sure to consider the capacitor’s tolerance and DC bias effects. Use of Y5U, Z5U, or similar dielectrics is not recommended. The 22uF capacitor must have at least 9uF of effective capacitance for stability. The 47uF capacitor must have 19uF of capacitance. The bulk capacitors do not have DC bias effects. If the OTG input source is a battery, no additional capacitance is needed. If the OTG input source is a power supply rail, add an additional 100uF bulk electrolytic capacitor is recommended. Output ceramic capacitor placement is critical for proper operation. The output capacitor must be placed as close to the IC as possible. The traces from VIN to the capacitor and from the capacitor to PGND should as short and wide as possible. The bulk capacitor should be placed to the left of the current sense resistor. Refer to the Layout Guidelines selection and to the EVK layout for additional details. The ceramic capacitor PCB placement is critical. Refer to the Layout Guidelines selection and to the EVK layout for details. Be sure to consider the input capacitor’s DC bias effects. A capacitor’s actual capacitance is strongly affected by its DC bias characteristics. The input capacitor is typically an X5R, X7R, or similar dielectric. Use of Y5U, Z5U, or similar dielectrics is not recommended. Input capacitor placement is critical for proper operation. The input capacitor must be placed as close to the IC as possible. The traces from VBAT to the capacitor and from the capacitor to PGND should as short and wide as possible. OTG - Inductor Selection The buck-boost regulator utilizes current-mode control and a proprietary compensation scheme to simultaneously compensate the buck, buck-boost, and boost modes of operation. The ACT2861 compensation requires a fixed inductor value that is matched to the switching frequency. Table 9 gives the required inductor value. Choose an inductor with a low DC-resistance, and avoid inductor saturation by choosing inductors with DC ratings that exceed the maximum output current by at least 30%. The inductor value must be within +30% to -30% across all operating conditions. OTG – Output Capacitor Selection Note that the OTG COUT capacitors are also the charging input capacitors. They are connected to VIN. The output capacitance must be a combination of ceramic and bulk capacitance. OTG - Compensation Table 9 gives the required capacitor values for stability. Note that the table has two output capacitor options: Standard Capacitance and Minimum Capacitance. The Standard Capacitance design requires more overall capacitance, but places no restriction on the bulk capacitor ESR. The Minimum Capacitance design results in an overall smaller design, but places restrictions on the ESR. The capacitor values can be increased without limit. The ACT2861 operates in three switching modes: buck, buck-boost, and boost mode depending on the input and output voltage ratios. The IC contains a proprietary compensation scheme to simultaneously compensate all three switching modes. The compensation values are directly tied to the switching frequency and required inductor value. Table 9 provides the required compensation values. Figure 16 shows the OTG compensation components. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 46 ACT2861QI Rev 2.0, 27-Apr-2018 Table 9: OTG Inductor and Compensation Standard Capacitance Design Inductor Switching Min / Typ / Max Frequency (uH) CICOMP1 (nF) CICOMP2 (nF) Ceramic Bulk RICOMP Capacitor Capacitor (kΩ) (uF) (uF) Minimum Capacitance Design Bulk Capacitor ESR (mΩ) Ceramic Capacitor (uF) Bulk Capacitor (uF) Bulk Capacitor ESR (mΩ) 125Khz 29 / 42 / 55 82 8.2 20.0 47 1000 N/A 22 470 30 - 100 250Khz 15 / 22 / 29 39 3.9 20.0 47 470 N/A 22 220 50 - 200 500KHz 7 / 10 / 13 22 2.2 20.0 47 220 N/A 22 100 50 - 200 1MHZ 4 / 5.6 / 7.28 10 1.0 20.0 47 100 N/A 22 100 50 - 200 Table 11: nCHG Pin State in OTG Mode ICOMP RICOMP1 CICOMP2 CICOMP1 OTG State nCHG Output Pin OTG Enabled and Output Valid LOW OTG Disabled HIZ OTG Enabled In Fault, Hiccup, or Light Load states HIZ ADC Monitoring Figure 16: OTG Compensation General Description The ACT2861 contains a built-in analog to digital converter, ADC, which can be used to monitor seven system level parameters. These include input voltage, output voltage, input current, output current, TH pin, die temperature, and the external ADC input pin. It uses a single 12 bit delta-sigma ADC that uses an analog input multiplexer to select one of seven channels for the A/D conversion. The resulting digital results are stored in seven digital registers. A seven to one multiplexer connects one of the ADC output registers to the user accessible register map. CHARGE STATUS OUTPUT PIN (NCHG) The ACT2861 indicates the Charging and OTG states on the open drain nCHG pin. The nCHG pin typically drives an LED, but can also be monitored by a microprocessor GPIO. In Charge mode, the nCHG pin function is enabled by setting I2C bit DIS_nCHG_CHG in register 0x00h = 0. Disable the function by setting it to 1. In OTG mode, the nCHG function is enabled by setting the I2C bit EN_OTG_nCHG in register 0x0Fh = 1. Disable the function by setting it to 0. Tables 10 and 11 show the nCHG state in different Charge and OTG operating conditions. ADC Configuration The ACT2861 ADC is configured through the I2C interface. It is enabled and disabled by the I2C bit EN_ADC in register 0x09h. The ADC has two conversion modes, manual single-shot conversion and automatic polling conversion. Table 10: nCHG Pin State in Charge Mode Charging State nCHG Output Pin Charging in progress LOW Charging complete HIZ Single-Shot Conversion Charge suspend or Fault Blinking at 1Hz Configure the IC for single-shot conversion mode by setting the following I2C bits in register 0x09h Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 47 ACT2861QI Rev 2.0, 27-Apr-2018 ADC_ONE_SHOT = 1. Automatic Polling Conversion ADC_CH_SCAN = 0 Configure the IC for automatic polling conversion mode by setting the following I2C bits in register 0x09h DIS_ADCBUF = 0 ADC_ONE_SHOT = 0 ADC_CH_SCAN = 1 In single shot mode, the user defines the input channel to be converted and then manually initiates the ADC conversion. I2C bits ADC_CH_CONV [2:0] in register 0x0Ah select the input channel to be converted. ADC_CH_READ [2:0] selects the ADC channel to be read. These should be set to the same channel. The user initiates an ADC read by writing a 1 into EN_ADC in register 0x09h. When ADC conversion is complete, the ADC_DATA_READY bit in register 0x0Ah is set to 1, nIRQ is asserted low, and EN_ADC bit automatically changes back to 0. The uP can then read the status bits to find that the ADC conversion is complete. The ADC data are stored in ADC_OUT [13:6] in register 0x07h and ADC_OUT[5:2] in register 0x08h. nIRQ stays asserted low and the ADC_READY_BIT stays equal to 1 until the ADC data is read. Reading the ADC data automatically deasserts nIRQ. To initiate another ADC conversion for the same channel, set EN_ADC=1. To initiate an ADC conversion for another channel, change ADC_CH_CONV and ADC_CH_READ to the appropriate channel and then set EN_ADC=1. DIS_ADCBUF = 0 Start the automatic polling by changing EN_ADC to 1. When in automatic polling mode, the ADC continuously changes the MUX inputs to read all input channels. The ADC continually overwrites the data in the output register. After all channels have been converted, the ADC_DATA_READY bit is set to 1. Note that nIRQ is not asserted low in Automatic Polling mode. Ensure that ADC data is valid and ready by reading the ADC_DATA_READY before reading ADC data. After the ADC_DATA_READY bit is set to 1, the user defines the channel to be read with the ADC_CH_CONV [2:0] bits in register 0x0Ah. Change ADC_CH_CONV to read additional channels. CH0 CH1 CH2 7 to 1 MUX ADC 12 Bit Result CH6 Clock SEL[2:0] Figure 17: ADC Block Diagram Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 48 ACT2861QI Rev 2.0, 27-Apr-2018 Table 12: ADC Channels Channel Channel Description ADC_CH_CONV[2:0] ADC_CH_READ[2:0] Value CH0 Input Current (ILIM) 000 000 IIN = (DOUT-2048)/(65000*RCS_IN) CH1 Input Voltage (VIN) 001 001 VIN = 0.02035*(DOUT-2048) CH2 Output Current (OLIM) 010 010 IOUT = (DOUT-2048)/(65000*RCS_OUT) CH3 Output Voltage (VBAT) 011 011 VOUT = 0.02035*(DOUT-2048) CH4 TH 100 100 VTH = 0.003053*(DOUT-2048) CH5 Die Temperature 101 101 TJ = 0.2707*DOUT - 809.49 CH6 ADC Input 110 110 VADC = 0.001527*(DOUT-2048) Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 49 ACT2861QI Rev 2.0, 27-Apr-2018 pins should be connected together right at the IC. PC board layout guidance Proper parts placement and PCB layout are critical to the operation of switching power supplies. Follow the following layout guidelines when designing the ACT2861 PCB. Refer to the Active-Semi ACT2861 Evaluation Kit for layout guidance. 5. Connect the exposed pad directly to the top layer PGND pins and ground plane. Connect the top layer ground plane to both internal ground planes and the PCB backside ground plane with thermal vias. Provide ground plane routing on multiple layers to allow the IC’s heat to flow into the PCB and then spread radially from the IC. Avoid cutting the ground planes or adding vias that restrict the radial flow of heat. 1. Place the ceramic input and output capacitors as close as possible to the IC. Connect the input capacitors directly between VIN and PGND pins on the top layer. Connect the output capacitors directly between VBAT and PGND pins on the top layer. Use 1206 sized capacitors to allow for proper switch pin routing. Note that the input and output capacitor placement is critical. Active-Semi strongly recommends following the EVK input capacitor and output capacitor placement and routing. The bulk input and output capacitor placement is not as critical. Bulk capacitors should be placed on the opposite side of the sense resistors from the ceramic capacitors. 6. Make Kelvin connections to the ILIM and OLIM current sense resistors. Route the current sense signals close to each other and keep them away from noisy switching signals. 7. The current sense filter capacitors and inductors should be placed directly by their respective ISRP, ISRN, OSRP, and OSRN pins. 8. Remember that all open drain outputs need pull-up resistors. 2. Minimize the switch node trace lengths between the SW1 and SW2 pins and the inductor. Optimal switch node routing is to run the traces between the input and output capacitors’ pads. Using 1206 or larger sized capacitors is recommended. Avoid routing sensitive analog signals near these high frequency, high dV/dt traces. Active-Semi strongly recommends following the EVK inductor placement and PCB routing. 9. The following components should be connected to the AGND plane. ILIM resistor OLIM resistor COMP resistor and capacitors VREG bypass capacitor INTBP bypass capacitor 3. The VBATS pin should be Kelvin connected to the battery. Keep this trace away from the SW1 and SW2 traces to prevent noise injection. The IC regulates the battery voltage to this Kelvin connection. 10. The ACT2861 footprint must connect the VIN pins 23, 34, and 35 on the top layer. It must connect the SW1 pins 21, 22, and 34 on the top layer. It must connect the SW2 pins 18, 19, and 33 on the top layer. 4. The PGND and AGND ground pins must be electrically connected together. The AGND ground plane should be isolated from the rest of the PCB power ground. These two ground Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 50 ACT2861QI Rev 2.0, 27-Apr-2018 Typical Operating Characteristics Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 51 ACT2861QI Rev 2.0, 27-Apr-2018 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 52 ACT2861QI Rev 2.0, 27-Apr-2018 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 53 ACT2861QI Rev 2.0, 27-Apr-2018 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 54 ACT2861QI Rev 2.0, 27-Apr-2018 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 55 ACT2861QI Rev 2.0, 27-Apr-2018 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 56 ACT2861QI Rev 2.0, 27-Apr-2018 CMI OPTIONS This section provides the basic default configuration settings for each available ACT2861 CMI options. CMI 201: ACT2861QI201 CMI 201 is optimized for 2 cell Li-Ion battery applications and the default settings are appropriate for most typical applications. It operates with a switching frequency of 500kHz to provide an optimal tradeoff between overall size and efficiency. Table 13 shows the default register settings. Table 13: CMI 201 Default Register Settings Parameter Battery Termination Voltage Battery Cut Off Voltage at Discharge Battery Short Voltage Battery Pre-Charge Voltage Battery Good Indicator Voltage Battery Recharge Voltage Default Battery Charge Current in Register Battery Short Current Scaling Factor Battery Pre-Charge Current Battery Termination Current Battery Termination Battery Charge Path Impedance Battery Path Impedance Compensation Voltage Clamp JEITA Support JEITA Warm (45°C-60°C) Charge Voltage JEITA Warm (45°C-60°C) Charge Current JEITA Cold (0°C-10°C) Charge Current Non-JEITA Max Battery Temp Non-JEITA Min Battery Temp Start Delay (charging) Charge Mode Softstart Battery OVP Latch off Battery OV Deglitch Time TH Pin Safety Timer OTG Output Voltage OTG Output Constant Current Limit (Register) OTG Softstart Time OTG Light Load Turn Off OTG Light Load Turn Off Current OTG Light Load Turn Off Delay OTG Start up Delay OTG Cord Compensation Input Current Limit Scaling Factor OTG Mode Battery Discharge Current Limit OTG Enable Polarity OTG Output Slew Rate PFM Mode in Charge and OTG modes Input Voltage Range Minimum Input Voltage Limit Operation Frequency OCP Shutdown (8 FET OC cycles) FET cycle by cycle current limit Input OV restart time ADC Enabled LDO Output Voltage LDO Input Select Watchdog Timer Regulated Die Temperature 7-bit I2C Slave Address Value 8.4V 5.6V 5V 6V 6.6V 8.0V 50% 4% 5% 5% Enabled Disabled Disabled Enabled 8.0V 50 50 60deg C 0deg C 220ms 5ms Disabled 40ms Enabled 16 Hr 5.1V 100% 10ms Enabled 5mA 30s 1000ms Disabled 67% 200% Active low 0.5V/ms Enabled 4V ~ 20V 4.5V 500kHz Enabled 10A 40ms Yes 5V Auto Disabled 120 deg C 0x24h Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 57 ACT2861QI Rev 2.0, 27-Apr-2018 CMI 301: ACT2861QI301 CMI 301 is optimized for 3 cell Li-Ion battery applications and the default settings are appropriate for most typical applications. It operates with a switching frequency of 500kHz to provide an optimal tradeoff between overall size and efficiency. Table 14 shows the default register settings. Table 14: CMI 301 Default Register Settings Parameter Battery Termination Voltage Battery Cut Off Voltage at Discharge Battery Short Voltage Battery Pre-Charge Voltage Battery Good Indicator Voltage Battery Recharge Voltage Default Battery Charge Current in Register Battery Short Current Scaling Factor Battery Pre-Charge Current Battery Termination Current Battery Termination Battery Charge Path Impedance Battery Path Impedance Compensation Voltage Clamp JEITA Support JEITA Warm (45°C-60°C) Charge Voltage JEITA Warm (45°C-60°C) Charge Current JEITA Cold (0°C-10°C) Charge Current Non-JEITA Max Battery Temp Non-JEITA Min Battery Temp Start Delay (charging) Charge Mode Softstart Battery OVP Latch off Battery OV Deglitch Time TH Pin Safety Timer OTG Output Voltage OTG Output Constant Current Limit (Register) OTG Softstart Time OTG Light Load Turn Off OTG Light Load Turn Off Current OTG Light Load Turn Off Delay OTG Start up Delay OTG Cord Compensation Input Current Limit Scaling Factor OTG Mode Battery Discharge Current Limit OTG Enable Polarity OTG Output Slew Rate PFM Mode in Charge and OTG modes Input Voltage Range Minimum Input Voltage Limit Operation Frequency OCP Shutdown (8 FET OC cycles) FET cycle by cycle current limit Input OV restart time ADC Enabled LDO Output Voltage LDO Input Select Watchdog Timer Regulated Die Temperature 7-bit I2C Slave Address Value 12.6V 8.4V 7.5V 9V 9.6V 12.0V 50% 4% 5% 5% Enabled Disabled VBAT + 120mV Enabled 12.0V 50 50 60deg C 0deg C 220ms 5ms Disabled 40ms Enabled 16 Hr 5.1V 100% 10ms Enabled 5mA 30s 1000ms Disabled 67% 200% Active low 0.5V/ms Enabled 4V ~ 20V 4.5V 500kHz Enabled 10A 40ms Yes 5V Auto Disabled 120 deg C 0x24h Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 58 ACT2861QI Rev 2.0, 27-Apr-2018 CMI 401: ACT2861QI401 CMI 401 is optimized for 4 cell Li-Ion battery applications and the default settings are appropriate for most typical applications. It operates with a switching frequency of 500kHz to provide an optimal tradeoff between overall size and efficiency. Table 15 shows the default register settings. Table 15: CMI 401 Default Register Settings Parameter Battery Termination Voltage Battery Cut Off Voltage at Discharge Battery Short Voltage Battery Pre-Charge Voltage Battery Good Indicator Voltage Battery Recharge Voltage Default Battery Charge Current in Register Battery Short Current Scaling Factor Battery Pre-Charge Current Battery Termination Current Battery Termination Battery Charge Path Impedance Battery Path Impedance Compensation Voltage Clamp JEITA Support JEITA Warm (45°C-60°C) Charge Voltage JEITA Warm (45°C-60°C) Charge Current JEITA Cold (0°C-10°C) Charge Current Non-JEITA Max Battery Temp Non-JEITA Min Battery Temp Start Delay (charging) Charge Mode Softstart Battery OVP Latch off Battery OV Deglitch Time TH Pin Safety Timer OTG Output Voltage OTG Output Constant Current Limit (Register) OTG Softstart Time OTG Light Load Turn Off OTG Light Load Turn Off Current OTG Light Load Turn Off Delay OTG Start up Delay OTG Cord Compensation Input Current Limit Scaling Factor OTG Mode Battery Discharge Current Limit OTG Enable Polarity OTG Output Slew Rate PFM Mode in Charge and OTG modes Input Voltage Range Minimum Input Voltage Limit Operation Frequency OCP Shutdown (8 FET OC cycles) FET cycle by cycle current limit Input OV restart time ADC Enabled LDO Output Voltage LDO Input Select Watchdog Timer Regulated Die Temperature 7-bit I2C Slave Address Value 16.8V 11.2V 10V 12V 12.8V 16V 50% 4% 5% 5% Enabled Disabled VBAT + 120mV Enabled 16.0V 50 50 60deg C 0deg C 220ms 5ms Disabled 40ms Enabled 16 Hr 5.1V 100% 10ms Enabled 5mA 30s 1000ms Disabled 67% 200% Active low 0.5V/ms Enabled 4V ~ 20V 4.5V 500kHz Enabled 10A 40ms Yes 5V Auto Disabled 120 deg C 0x24h Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 59 ACT2861QI Rev 2.0, 27-Apr-2018 I2C REGISTERS The register map section provides a basic understanding of the ACT2861 registers. Note that the default values reference the CMI 201 settings. Register 0x00 Register Name Master Control 1 Type R/W VM R/W Description Default 0x00h Configure various device options 0x01 Master Control 2 NVM R/W 0x02 0x00h General Status VM R Device status 0x00h 0x03 Charger Status VM R Charger status 0x00h 0x04 Temperature Status VM R Charger temperature status 0x00h 0x05 Fault 1 VM R 0x06 Fault 2 VM R 0x00h 0x07 ADC Output 1 VM R 0x00h 0x08 ADC Output 2 VM R 0x00h 0x09 ADC Configuration 1 VM R/W 0x00h 0x0A ADC Configuration 2 VM R/W 0x0B Charge Control VBAT Short NVM R/W Configure various charger options 0x98h 0x0C Charge Control 2 NVM R/W Configure various charger options 0x40h 0x0D Charge Control 3 NVM R/W Configure various charger options 0x49h NVM R/W NVM R/W NVM R/W 0x00h Device Faults ADC Output ADC configuration bits 0x0E 0x0F OTG Mode Control 1 RFU OTG Mode Control 2 RFU OTG Control 3 0x10 0x00h Configure OTG mode options 0xADh N/A Configure OTG mode options 0x43h N/A Configure Converter options RFU 0x78h NA 0x11 Battery Regulation Voltage 1 NVM 0x12 Battery Regulation Voltage 2 NVM R/W 0xF1h 11-bit, 2.5 ~ 22.5V, LSB = 10mV, Default = 4.2V R/W 0x54h Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 60 ACT2861QI Rev 2.0, 27-Apr-2018 0x13 0x14 OTG Output Voltage 1 RFU OTG Output Voltage 2 RFU NVM R/W 0xA0h 11-bit, 3.6 ~ 24.07V, LSB = 10mV, Default = 5V NVM R/W 0xD6h 0x15 Input Current Limit NVM R/W 7-bit, 0 ~ 100%, LSB = 1%, Default = 100% 0x43h 0x16 Input Voltage Limit NVM R/W 8-bit, 4 ~ 16.7V, LSB = 100mV, default = 4.4V 0x05h 0x17 OTG Output Current Limit NVM R/W RFU 7-bit, 0 ~ 100%, LSB = 1%, Default = 100% 0x64h N/A 0x18 Fast Charge Current NVM R/W 7-bit, 0 ~ 100%, LSB = 1%, Default = 100% 0x32h 0x19 Pre-Charge & Termination Current NVM R/W 4-bit, 0 ~ 20%, LSB = 1%, Default = 10% 0x00h 0x1A Battery Low Voltage NVM R/W 8-bit, 2.5 ~ 15.2V, LSB = 100mV, default = 3V 0x0Ah 0x1B Safety Timer NVM R/W 5-bit, 0.5 ~ 16V, LSB = 0.5Hr, default = 10Hr 0x1Fh 0x1C JEITA NVM R/W JEITA Charge Voltage/Current Setting 0x1Ah 0x1D Temperature Setting NVM R/W High/Low Temperature Thresholds 0x8Bh 0x1E IRQ Control 1 VM R/W 0x00h IRQ Mask Control 0x1F IRQ Control 2 VM R/W OTG Status 0x20 OTG Status VM RFU 0x00h R 0x00h N/A Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 61 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x00: Main Control 1 (R/W) (VM) Description Comment Bit to control if IC is in HIZ mode. 7 HIZ 0 0: Not in HIZ mode 1: In HIZ mode If set to 1, EN_CHG will NOT enable switching for charger or and nOTG pin will not enable OTG mode. In addition, the OVERRIDE_EN_CHG or the OVERRIDE_nOTG Registers will not enable the converter. 0: No effect 0: No Effect 6 OVERRIDE_EN_CHG 0 1: Override EN_CHG Input 1: This will override the EN_CHG pin and allow the charging to start, even if the EN pin is low. With this set HI, enable pin will have no effect on charging. HIZ will still need to be set to 0 to allow Charging. Write to 1 clears register after 1 sec 0: Normal Mode 0: No Change 5 SHIPM_ENTER 0 1: Device enters ship mode 1: Disables everything and device enters Ship Mode after a 1 second delay. During the 1 second countdown this bit will stay high. If user wants to cancel the enter ship mode during the 1 sec delay, write this back to 0, and ship mode will not be entered. Warning: Entering ship mode disables everything and must be re-enabled with SHIPM pin or VIN supply. 4 GPIO_OUT 0 3 DIS_nCHG_CHG 0 0: Output in HIZ GPIO output register 1: Output pulled low Only available in ACT2862 (No OTG Mode) 0: Enable If set to 1, nCHG Charge pin is always HI-Z in Charger mode. 1: Disable I2C Watchdog Timer Reset 2 WATCHDOG_RESET 0 0: Normal This must be written to 1 before Watchdog timer expires, if Watchdog timer is enabled. This is auto clearing when writing to a 1. 1: Reset 0: No limit of switching frequency 1 Audio Frequency Limit 0 0: No limit 1: Minimum 31.25kHz 1: Set minimum switching frequency to 31.25kHz to avoid audio noise For both OTG and Charge mode. 0 REGISTER_RESET 0 1: Reset Registers to Default Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Register is self-clearing. Write to 1 resets registers and set reset register back to 0. www.active-semi.com Copyright © 2018 Active-Semi, Inc. 62 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 Name DIS_TH Default Value REG 0x01: Main Control 2 (R/W) (NVM) NVM 6 DIS_OCP_SHUTDO WN NVM 5 DIS_VBAT_OVP NVM 4 FET_ILimit NVM 3 VIN_OV_RESTART_ DELAY NVM 2 VREG_EN NVM 1 WATCHDOG[1] NVM Description Comment Set 1 to disable TH output and the JEITA Control. During this mode, charger and OTG mode will always operate at full current and voltage settings. 0: Enable 1: Disable Note: This must be set to 1 to achieve the lowest possible input current. If set to 0, the device will be disabled if FET cycle by cycle current limit is detected for 8 (or 16) continuous cycles. For both Charge and OTG modes. Uses the FET_LIMIT register setting for the FET ILIM. 0: Enable 1: Disable When set to 1, a BAT_OVP fault does not latch off the charger in a fault mode. Charger will restart automatically when the OVP condition is removed. 0: Enable 1: Disable 0: 8.5A This is the cycle by cycle current limit setting for ALL FETS in any operating mode: 1: 10A 0: 40ms Delay time to restart in charger mode after Input OV fault has been removed 1: 100usec 0: Turn OFF VREG Control VREG on/off 1: Turn ON VREG Default is on. I2C Watchdog Timer Setting 00: Disable timer Watchdog timer is always disabled and reset to 0 in HIZ Mode. 01: 80s 0 WATCHDOG[0] NVM 10: 160s When Disabled, Watchdog timer is also reset to 0. 11: 320s Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 63 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x02: General Status (Read Only) (VM) Description Comment 0: Battery voltage is good 7 nVBAT_GOOD NA 6 nIRQ_PIN_Status NA 5 nOTG_PIN_STATUS NA 4 INPUT_UVLO_CHG NA 3 INPUT_OV_CHG NA 2 GPIO_IN NA 1 OPERATION_MODE[ 1] NA OPERATION_MODE[0] NA 0 Set bit when battery voltage is lower than VBAT_GOOD threshold in Charge Mode or OTG Mode This is not checked in HIZ Mode, so will be set to 0 in HIZ 1: Battery voltage is lower Mode. than VBAT_GOOD This read only register has a 16msec deglitch for rising and falling edge. Device status of IRQ output 0: Our device output drive HIZ Not actual status of the IRQ pin – Open drain output so other devices could be driving the pin low in a wired OR configuration 1: Our device output asserted Low 0: nOTG Pin Low Real time status of the nOTG Input PIN 1: nOTG Pin High 0: Input above UVLO Charge Mode Only 1: Input below UVLO Real time status – For latched fault, see the Fault Registers Charge Mode Only 0: Input below OV Real time status – For latched fault, see the Fault Registers 1: Input above OV Real Time status of GPIO Pin. 0: GPIO Input Low Only available in ACT2862, otherwise this register is always low 1: GPIO Input HI 00: HIZ Mode Current state machine status for overall system 01: Charger Mode 10: OTG Mode 11: not valid Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 64 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 Name EN_CHG_PIN_STAT US Default Value REG 0x03: Charger Status (Read only) (VM) NA Description Comment 0: EN < 0.8V Real time status of the EN_CHG Input PIN 1: EN > 0.8V Threshold shown does not include hystersis 0: Not regulation thermal Thermal Regulation Active in Charge AND OTG Mode in 6 THERMAL_ACTIVE NA 5 INPUT_IINLIM_STAT US NA 4 INPUT_VINLIM_STAT US NA 3 CHG_STATUS[3] NA 0000: RESET State machine for charger status 2 CHG_STATUS[2] NA 0001: SCOND or SCOND_DB See Section 1.2.2. for further information 1 CHG_STATUS[1] NA 1: Thermal Active regulation 0: Not in IINLIM Charger Mode Only 1: In IINLIM 0: Not in VINLIM Charger Mode Only 1: In VINLIM 0010: SCSUSPEND Notes: 0011: PCOND 1. 0100: PCSUSPEND 2. 0101: FASTCHG When not in Charge State, status is always RESET (0000) Check Register 0x06 Bit 0 to determine if Battery is below Dead Battery level. 0110: FCSUSPEND 0111: CHGFULL 0 CHG_STATUS[0] NA 1000: CFSUSPEND 1100 – 1111: Not Valid 1001: CHGTERM 1010: CTSUSPEND 1011: FAULT Bit 7 Name POK_VOUT Default Value REG 0x04: Temperature Status (Read Only) (VM) NA Description Comment 0: Output below 90% 1: Output above 92% Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Indicator for Power OK in OTG or CHG mode. Uses OTG_VOUT setting and measures VIN Pin during OTG. www.active-semi.com Copyright © 2018 Active-Semi, Inc. 65 ACT2861QI Rev 2.0, 27-Apr-2018 Uses VTERM setting and VBATS Pin during Charge Mode. 6 5 TH_BAT_DETECT OTG_COLD_DIS / CHRG DIS_JEITA=1 NA 0: No Battery detected 1: Battery detected OTG Mode OR (Charge Mode AND DIS_JEITA=1) NA 0: OK Uses the voltage on TH pin. Can be used to detect battery or battery at very cold temperature. If DIS_TH=1, then register is always 0 – No battery detected. If this bit is 1, then OTG or Charger mode is disabled caused by Battery Below 0C or -10C depending on OTG_COLD Register 1: Below 0°C / -10°C input 4 OTG_HOT_DIS / CHRG DIS_JEITA=1 OTG Mode OR ( Charge Mode AND DIS_JEITA=1 ) NA 0: OK If this bit is 1, then OTG or Charger mode is disabled caused by Battery Above 55C/60C/65C depending on OTG_HOT[1:0] Register 1: Above 55°C / 60°C / 65°C Threshold 3 CHRG_COLD NA 0: Normal Charge Mode OR DIS_JEITA=1 In charge mode, if DIS_JEITA=0, then this bit goes high when the battery temperature is less than 0°C and the 1: Charging has device is always disabled. stopped with DIS_JEITA=0 0: Normal Charge Mode OR DIS_JEITA=1 2 1 0 CHRG_COOL CHRG_WARM CHRG_HOT NA 1: Reduced current or charge suspended In charge mode, if DIS_JEITA=0, then this bit goes high when battery temperature is between 10°C and 0°C. In this mode, the device may be disabled, or reduced current. This is controlled by Register 0x1C Bit [1:0]. NA 0: Normal Charge Mode In charge mode, if DIS_JEITA=0, then this bit goes high OR DIS_JEITA=1 when battery temperature is between 45°C and 60°C. In this mode, the device may be have reduced current or 1: Reduced charge reduced VTERM. This is controlled by Register 0x1C Bit voltage and/or current [5:2]. NA 0: Normal Charge Mode In charge mode, if DIS_JEITA=0, then this bit goes high OR DIS_JEITA=1 when the battery temperature is greater than 60°C and the 1: Charging has device is always disabled. stopped Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 66 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 Name nIRQ_Clear Default Value REG 0x05: Faults 1 (Read only) (VM) Description Comment 0: Normal Status 0 1: Clear IRQ output Write this bit to 1 to clear the IRQ output. The bit will selfclear to a 0 once the write occurs. If a fault still occurs, then nIRQ pin may stay asserted low. Register 0x02 Bit 6 provides a real time status of the nIRQ output. The VBAT LOW or Fast Charge Safety timer has expired – Charge Only Mode. Read to clear this latching fault bit. 6 CHG_TIMER_EXPIRE D NA 0: No Fault Note: Reading this bit will not reset the fault timers. If the fault timers are high, this bit will get set again immediately after the read. 1: Timer Expired See the Safety Timer section on how to reset the Safety Timers. 5 CHG_VBAT_OV NA VBAT Overvoltage protection Charge Mode. 0: No Fault Read to clear this latching fault bit. 1: VBAT OV VREG_LDO Overcurrent or UVLO Charge Mode or OTG Mode. Read to clear this latching fault bit. 4 VREG_OC_UVLO NA 0: No Fault 1: VREG OC or UVLO The fault mask bits DIS_CHG_VREG_FLT and DIS_OTG_VREG_FLT registers do not affect this fault bit. It will always get indicated here to notify the user. Note: There is a 100msec restart delay for OC faults on the VREG LDO, so the delay must expire before this bit can be reset with a read to clear. 3 TSD NA 2 FET_OC NA 0: No Fault Die Thermal Shutdown in Charge mode or OTG Mode. 1: Over Temperature Read to Clear latch Bit. 0: No Fault FET Overcurrent Shutdown in Charge mode or OTG Mode. 1: Input OC Read to Clear latching Bit. VIN OV in Charge Mode 1 CHG_MODE_INPUT_ OV NA 0: No Fault Read to Clear latching Bit. 1: Input Over Voltage In Charge Mode, the OV fault time will be set by the delay time in the VIN_OV_RESTART_DELAY Register. This 40ms or 100usec delay must expire before a read to clear Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 67 ACT2861QI Rev 2.0, 27-Apr-2018 will reset this register bit. 0 CHG_MODE_INPUT_ UV VIN UV in Charge Mode 0: No Fault NA 1: Charge VIN Under Read to Clear latching Bit. Voltage Bit Name Default Value REG 0x06: Faults 2 (Read only) (VM) Description Comment Watchdog Timeout Fault Read to clear latching bit 7 WATCHDOG_FAULT NA If Watchdog is enabled, and watchdog timer times out, then this bit is set high. 0: No Fault This applies to both Charge Mode, and OTG Modes. 1: Watchdog Fault This does not clear the watchdog timer. The watchdog timer needs to be cleared with a watchdog read or disable the watchdog timer. If this bit is read and the watchdog timer has not been reset, then this bit will immediately go high again after the read. OTG Hiccup Mode Fault Read to Clear latching bit 6 OTG_VOUT_FAULT NA When operating in OTG Mode, if the VOUT enters hiccup state because current exceeds the Constant Current Mode, then this bit gets set. 0: No Fault 1: OTG VOUT Fault This register will always be set during hiccup mode when VOUT is off during the 3sec restart time and the OTG is in the OTG_HICCUP state. After it exits this state, this bit can be cleared with a read. OTG VBAT Cutoff Fault Read to Clear latching bit 5 OTG_VBAT_CUTOFF_ FLT 0: Not Fault NA If the OTG mode is enabled and the VBAT falls below the 1: OTG VBAT CUTOFF VOTG_BAT_CUTOFF Voltage specified in the Fault OTG_VBAT_CUTOFF Register (Reg 0x0F, Bits 7:5) The battery must be above the OTG_VBAT_CUTOFF voltage and then a read will clear this fault bit. 4 OTG_VOUT_OV NA 0: Not Fault OTG Vout Overvoltage Fault 1: VOUT OV Fault Read to Clear latching bit This bit will be set any time the Vout exceeds the OV threshold for external or internal feedback. The VOUT must Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 68 ACT2861QI Rev 2.0, 27-Apr-2018 be below the OV voltage and then a read will clear this fault bit. OTG Light Load State Latch 3 OTG_LIGHT_LOAD NA Read to clear latching bit 0: Not Fault OTG Mode has been disabled because of light load condition on output and it entered the OTG_LL_DIS state. The device must exit the OTG_LL_DIS state, and then a read will clear this bit. 1: OTG Off OTG VBAT Overvoltage fault 2 OTG_VBAT_OV NA 1 I2C_FAULT NA 0 DEADBATTERY NA 0: Not Fault Read to clear latching bit 1: OTG VBAT OV This bit will be set any time the VBAT exceeds the OV threshold in OTG Mode. The VBAT must be below the OV voltage and then a read will clear this fault bit. 0: Not Fault If set to 1, I2C command did not finish correctly or errors on I2C data 1: I2C Fault 0: Battery above 3V If charging and battery is below 3V, this will get set. This is a real-time indicator. 1: Battery below 3V Bit Name Default Value REG 0x07: ADC Output 1 (Read only) (VM) 7 ADC_OUT[13]/[7] 0 6 ADC_OUT[12]/[6] 0 5 ADC_OUT[11]/[5] 0 4 ADC_OUT[10]/[4] 0 3 ADC_OUT[9]/[3] 0 2 ADC_OUT[8]/[2] 0 1 ADC_OUT[7]/[1] 0 0 ADC_OUT[6]/[0] 0 Description Comment Selected data output from ADC_READ Register ADC output Upper 8 Bits of ADC output. If only 8 Bits are used, then [7:0] If all 14 Bits are used, then [13:6] Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 69 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x08: ADC Output 2 (Read only) (VM) 7 RFU 0 6 RFU 0 5 ADC_OUT[5] 0 4 ADC_OUT[4] 0 3 ADC_OUT/[3] 0 2 ADC_OUT[2] 0 1 ADC_OUT[1] 0 0 ADC_OUT[0] 0 Description Comment Selected data output from ADC_READ Register Lower 6 LSB Bits of ADC Output – May not put in final datasheet. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 70 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 6 5 Name EN_ADC ADC_ONE_SHOT ADC_CH_SCAN Default Value REG 0x09: ADC Configuration 1 (R/W) (VM) 0 0 0 Description Comment 0: ADC disabled 1: ADC enabled [ADC ONE SHOT][ADC_ CH_SCAN] = XX operation is described as below. 0: ADC continually converts data when EN_ADC=1 1: ADC performs a onetime conversion when EN_ADC=1 0: Scan single channel specified by ADC_CH_CONV 1: Scan all channels 4 DIS_ADC_BUFFER 0 3 ADC_SWAP 0 2 HW_DIE_REV[2] 0 1 HW_DIE_REV[1] 0 00 = Scan channel specified by ADC CHANNEL CONVERSION [2:0] register bits repeatedly in a loop. 01 = Scan and convert channels 0 – 7 repeatedly in a loop. 10 = Convert channel specified by ADC CHANNEL CONVERSION [2:0] once (one shot) 11 = Scan and convert channels 0 – 7 once and stop – one loop This should always be set to 0. 0: ADC Buffer is enabled 1: ADC Buffer is disabled 0: ADC Buffer is normal inputs 1: ADC Buffer swaps inputs If very accurate measurements are required, the ADC input pair can be swapped to negate input offset errors in the Buffer AMP. This requires one read with ADC_SWAP=0 and one read with ADC_SWAP=1, then average the results. HW Die Revision AZ: 000 BZ: 001 0 HW_DIE_REV[0] 0 Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 71 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x0A: ADC Configuration 2 (R/W) (VM) 7 ADC_DATA_READY 6 RFU 5 ADC_CH_I2C_READ[ 2] 0 ADC_CH_I2C_READ[ 1] 0 4 0 Description Comment 0: Data not ready Read Only - Conversion occurred and data is ready to read 1: Data is ready 000 = ILIM Pin This controls the current A2D register to output on the I2C register. The A2D can provide an I2C read on a different register while processing / converting another channel. 001 = VIN voltage Divide by 13 010 = VBAT voltage Divide by 10 011 = OLIM Pin 3 ADC_CH_I2C_READ[ 0] 100 = TH Pin Divide by 2 0 101 = Die temperature 110 = EXT Pin voltage 111 = AGND voltage 2 ADC_CH_CONV [2] 0 000 = ILIM Pin 1 ADC_CH_CONV [1] 0 001 = VIN voltage Divide by 13 This controls the current A2D conversion processing channel. The A2D can provide an I2C read on a different register while processing /converting another channel. 010 = VBAT voltage Divide by 10 011 = OLIM Pin 0 ADC_CH_CONV [0] 0 100 = TH Pin Divide by 2 101 = Die temperature 110 = EXT Pin voltage 111 = AGND voltage Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 72 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 Name Default Value REG 0x0B: Charger Control 1 (R/W) (NVM) VBAT_OV_DEGLITCH_EN 0 Description 0: No Deglitch on OV Fault VBAT_SHORT[2] 0 In charge mode, deglitch for VBAT_OV to stop charging and enter Fault Mode. 1: Deglitch of 40msec Battery Short voltage threshold 000: 4V ( 2X2V ) 6 Comment Cross over from ISHRT to 001: 5V ( 2X2.5V ) IPRECHRG Current 010: 6V ( 3X2V) 5 VBAT_SHORT[1] 0 011: 7.5V ( 3X2.5V) 100: 8V ( 4X2V ) 101: 10V ( 4X2.5V ) 4 VBAT_SHORT[0] 0 110: 10V ( 5X2V ) 111: 12.5V ( 5X2.5V) 3 VBAT_SHORT_CURRENT[1] 0 00: 1% 01: 2% 2 VBAT_SHORT_CURRENT[0] 0 Battery charge current when VBAT less than VBAT Short Voltage 10: 4% 11: 8% 1 VREG_OVERRIDE 0 0 VREG_SELECT 0 0: Device automatically selects the correct supply to use 0: Automatic Control 1: VREG uses the VREG_SELECT register to select the power input 1: Manual Control 0: VIN Supply VREG powered from VBAT or VIN PIN 1: VBAT Supply Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 73 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x0C: Charger Control 2 (R/W) (NVM) Description Comment Lower ILIM setting for lower power applications. 7 ILIM_LOW 0 0: 8.5A or 10A 1: 5.7A 0 Converter continues to operate: 6 EN_TERM 0 1: Converter is disabled when termination is reached 5 BAT_PATH_COMP_VCLAMP[2] 0 000: Disable 4 BAT_PATH_COMP_VCLAMP[1] 0 001: VBAT + 60mV 010: VBAT + 120mV If set to 0, then uses FET_ILimit (Register 0x01 Bit 4) setting. If set to 1, then FET_ILimit should be set to 1 for 5.7A setting. The bit determines what to do when charge current reduces below ITERM: 0: Converter stays on and continues to regulate VBAT output to VTERM Voltage Battery path impedance compensation voltage clamp: 011: VBAT + 180mV 100: VBAT + 240mV 3 BAT_PATH_COMP_VCLAMP[0] 0 2 BAT_PATH_COMP [2] 0 000: Disable 1 BAT_PATH_COMP[1] 0 001: 20mΩ 010: 40mΩ 101: VBAT + 300mV 110: VBAT + 360mV 111: VBAT + 420mV Battery Charging path impedance compensation: 011: 60mΩ 100: 80mΩ 0 BAT_PATH_COMP[0] 0 101: 100mΩ 110: 120mΩ 111: 140mΩ Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 74 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x0D: Charger Control 3 (R/W) (NVM) Description 000: 200mV 7 VRECHARGE[2] 0 001: 300mV 010: 400mV Comment Voltage below VTERM to restart charging when in the CHG Termination State. Allows for 2-5 Cell with 100mV or 150mV setting or 200mV up to 4 cells. 011: 450mV 6 VRECHARGE[1] 0 100: 500mV 101: 600mV 5 VRECHARGE[0] 0 110: 750mV 111: 800mV 4 VIN_STRT_DLY[1] 0 00: No delay 01: 220ms 3 VIN_STRT_DLY[0] 0 Delay time to start the charger when after the charger is enabled 10: 500ms 11: 1.3s 2 DIS_CHG_VREG_FLT 0 1 VBATGOOD[1] 0 1: Disable If set to 0, an overcurrent or UVLO fault on the VREG will stop charging mode (goes to FAULT Mode). If set to 1, charging mode will continue with fault on VREG. 00: VBATLOW + 0.4V Battery good threshold reference to VBATLOW Register setting for Charge Mode 0: Enable 01: VBATLOW + 0.6V 0 VBATGOOD[0] 0 10: VBATLOW + 0.8V 11: VBATLOW + 1.0V Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 75 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x0E: OTG Mode Control 1 (R/W) (NVM) 7 OTG_EN 0 6 OTG_EN_OVERRIDE 0 5 OTG_SS 0 4 RFU 0 3 OTG_OFF_DLY[1] 0 Description 0: Disable 1: Enable OTG_OFF_DLY[0] 0 If this bit is low, OTG mode is always disabled. If this pin is High, then either the nOTG pin or the EN_OTG_OVERRIDE bit will enable the OTG Mode. I addition, the HIZ mode bit (Reg 0x00, bit 0) must be low. 1: Enable If this bit is high, nOTG pin is over written and OTG mode is enabled, if EN_OTG is high. This allows user to enable OTG from I2C without using the PIN. 0: 1.5 ms Soft start time for OTG output voltage: 0: Disable 1: 5 ms Reserved for future use 00: Disable 01: 10 s 2 Comment 10: 20 s When light load is detected for the setting time, the OTG is disabled and latched off. The OTG must be disabled and re-enabled to turn OTG back on. This can be done with the nOTG Pin, or through the OTG_EN Register 11: 30 s 1 nOTG_PIN_POLARITY 0 0 OTG_OFF_LOAD_EN 0 0: Active Low Controls the polarity of the nOTG input pin. 1: Active High 0: Disable 1: Enable Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Enable the disable with light load function in OTG mode. When not in BUCK mode, feature is always disabled. www.active-semi.com Copyright © 2018 Active-Semi, Inc. 76 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x0F: OTG Mode Control 2 (R/W) (NVM) Description 7 OTG_VBAT_CUTOFF[2] 0 000: VBATLOW 6 OTG_VBAT_CUTOFF[1] 0 001: VBATLOW -0.2V 010: VBATLOW -0.4V Comment Battery Cut Off threshold for OTG mode to operate. Referenced from VBATLOW level. 011: VBATLOW -0.6V 100: VBATLOW -0.8V 5 OTG_VBAT_CUTOFF[0] 0 101: VBATLOW -1.0V 110: VBATLOW -1.2V 111: VBATLOW -1.4V 4 EN_OTG_nCHG 0 0: Disable 1: Enable If OTG_nCHG bit is 1, device will pull nCHG pin low in OTG mode to indicate the converter is running in OTG. If OTG is disabled for any reason, such as VIN Fault or VBAT Cuttoff level, etc, nCHG will go high. If set to 0, nCHG will always be HI-Z in OTG Mode. 3 OTG_CORD_COMP[1] 1 00: Disable 01: 100mV 2 OTG_CORD_COMP[0] 0 10: 200mV OTG Cord Compensation at 2.4A Load with 10mOhm Resistor (20mOhm resistor as option) 11: 300mV 1 OTG_EN_DLY[1] 0 00: 0 ms 01: 200 ms 0 OTG_EN_DLY[0] 1 The delay before enabling the OTG output from the nOTG pin or OTG register bit. 10: 500 ms 11: 1 s Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 77 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 Name OTG_OUTPUT_SLEW[1] Default Value REG 0x10: OTG Mode Control 3 (R/W) (NVM) 0 Description 00: 1V/ms 01: 0.5V/ms 6 OTG_OUTPUT_SLEW[0] 0 10: 0.33V/ms Comment If OTG Mode is set to internal Feedback and output voltage is changed using the OTG_VOUT register for QC2.0/3.0 or USB PD voltage ramp, this register controls the rate at which the output voltage will change. 11: 0.1V/ms 5 OTG_PULLDOWN_RAMP 0 4 OTG_PULLDOWN_OV 0 3 OTG_BAT_ILIM[1] 0 0: Disable 1: Enable 0: Disable 1: Enable 00: Disable 01: 150% of IFCHG 2 OTG_BAT_ILIM[0] 0 If OTG_RAMP_PULLDOWN is set to 1 and OTG_I2C is set to 0 for internal Feedback, an internal current source will pulldown on the OTG output during a ramp down of the output voltage. This will allow the OTG output to meet the QC 2.0/3.0 and USB PD ramp timing requirements. If OTG_PULLDOWN_OV is set to 1, the pulldown current source will pulldown on the OTG output during any OV condition on the output. OTG battery current limit proportional to the Fast Charge current setting. Measured on the OSRP and OSRN pins and set by the OLIM Resistor 10: 200% of IFCHG 11: 300% of IFCHG 1 DIS_OTG_VREG_FLT 0 OTG_DIS_PFM 0 CHG_DIS_PFM (BZ Update) 0 0: Enable 1: Disable 0: Enable If set to 0, an Overcurrent or UVLO fault on the VREG will stop OTG mode. If set to 1, OTG mode will continue with fault on VREG. Disable PFM mode in OTG OR Charge mode to reduce switching noise and follow a force PMW Mode 1: Disable Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 78 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x11: Battery Regulation Voltage 1 (R/W) (NVM) Description 7 VREG[4] 0 1600mV 6 VREG[3] 0 800mV 5 VREG[2] 0 400mV 4 VREG[1] 0 200mV 3 VREG[0] 0 100mV 2 VTERM[10] 0 10240 mV 1 VTERM[9] 0 5120 mV 0 VTERM[8] 0 2560 mV Comment VREG LDO Output Voltage Offset: 2V Range: 2V (00000) - 5.1V (11111) Charge Voltage: See Register 0x11 for details Bit Name Default Value REG 0x12: Battery Regulation Voltage 2 (R/W) (NVM) Description Comment Charge Voltage 7 VTERM[7] 0 1280 mV 6 VTERM[6] 0 640 mV 5 VTERM[5] 0 320 mV 5V: 000_0000_0000 4 VTERM4] 0 160 mV 22.5V: 110_1101_0110 3 VTERM[3] 0 80 mV 2 VTERM[2] 0 40 mV 1 VTERM[1] 0 20 mV 0 VTERM[0] 0 10 mV Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Offset: 5V Range: 5V to 22.5V Voltage over 22.5V will be set at 22.5V Range: (110_1101_0111 to (111_1111_1111) = 22.5V www.active-semi.com Copyright © 2018 Active-Semi, Inc. 79 ACT2861QI Rev 2.0, 27-Apr-2018 Name Default Value REG 0x13: OTG Output Voltage 1 (R/W) (NVM) 7 DO NOT CHANGE 0 Factory programmed default values – Do NOT overwrite 6 DO NOT CHANGE 0 Factory programmed default values – Do NOT overwrite 5 DO NOT CHANGE 0 Factory programmed default values – Do NOT overwrite 4 DO NOT CHANGE 0 Factory programmed default values – Do NOT overwrite Bit Description 0: I2C Register 1: External Resister Divider using IFB 3 OTGVOUT_I2C 0 2 OTG_VOUT[9] 0 10240 mV 1 OTG_VOUT[8] 0 5120 mV 0 OTG_VOUT[7] 0 2560 mV Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Comment When set to 0, internal resistor divider network is used and controlled by OTGVOUT registers. When set 1, external resistor divider connected to IFB is used to control the OTG output. Internal divider network Offset: 2.96V Range: 2.96V (000_0000_0000) to 23.42V (111_1111_1111) www.active-semi.com Copyright © 2018 Active-Semi, Inc. 80 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x14: OTG Output Voltage 2 (R/W) (NVM) Description 7 OTG_VOUT[6] 0 1280 mV 6 OTG_VOUT[5] 0 640 mV 5 OTG_VOUT[4] 0 320 mV 4 OTG_VOUT[3] 0 160 mV 3 OTG_VOUT[2] 0 80 mV 2 OTG_VOUT[1] 0 40 mV 1 OTG_VOUT[0] 0 20 mV 0 NA 0 No Function Comment Internal divider network Offset: 2.96V Range: 2.96V (000_0000_0000) to 23.42V (111_1111_1111) Bit Name Default Value REG 0x15: Input Current Limit (R/W) (NVM) Description 0: Enable 7 DIS_IIN_Limit 0 6 IINLIM[6] 1 64% 5 IINLIM[5] 1 32% 4 IINLIM[4] 0 16% 3 IINLIM[3] 0 8% 2 IINLIM[2] 1 4% 1 IINLIM[1] 0 2% 0 IINLIM[0] 0 1% Comment Disable input current limit 1: Disable Input Current Percentage of IINLIM which is set by ILIM pin resistor and measured at ISRN and ISRP. Range: 1% (000_0001) to 100% (110_0100) Setting 110_0100 to 111_1111 = 100% Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Setting 000_0000 to 000_0001 = 1% www.active-semi.com Copyright © 2018 Active-Semi, Inc. 81 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x16: Input Voltage Limit (R/W) (NVM) Description 0: Enable Comment Disable input voltage limit 7 DIS_VIN_Limit 0 6 VINLIM[6] 0 6400 mV Input voltage limit threshold. 5 VINLIM[5] 0 3200 mV Charge current will be reduced to regulate input voltage at setpoint when in Charge Mode. 4 VINLIM[4] 0 1600 mV 3 VINLIM[3] 0 800 mV 2 VINLIM[2] 0 400 mV 1 VINLIM[1] 1 200 mV 0 VINLIM[0] 0 100 mV 1: Disable Offset: 4.0V Range: 4.0V (000_0000) to 16.7V (111_1111) Bit Name Default Value REG 0x17: OTG Mode Output Current Limit (R/W) (NVM) Description 0: Enable 7 OTG_DIS_CC 0 6 OTG_CC[6] 1 64% 5 OTG_CC[5] 1 32% 4 OTG_CC[4] 0 16% 3 OTG_CC[3] 0 8% 2 OTG_CC[2] 1 4% 1 OTG_CC[1] 0 2% 0 OTG_CC[0] 0 1% 1: Disable Comment Set 1 to disable the output constant current limit function at OTG Mode Output Current Percentage of ILIM Resistor Setting. (VIN side measured at ISRN and ISRP) Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Range: 1% (000_0001) to 100% (110_0100) Setting 110_0100 to 111_1111 = 100% Setting 000_0000 to 000_0001 = 1% www.active-semi.com Copyright © 2018 Active-Semi, Inc. 82 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x18: Fast Charge Current (R/W) (NVM) Description Comment 7 RFU 0 6 IFCHG[6] 0 64% Fast charge current, percentage of FSTCHG which is set by OLIM pin resistor 5 IFCHG[5] 0 32% Range: 1% (000_0001) to 4 IFCHG[4] 0 16% 3 IFCHG[3] 0 8% Setting 110_0100 to 111_1111 = 100% 2 IFCHG[2] 0 4% Setting 000_0000 to 000_0001 = 1% 1 IFCHG[1] 0 2% 0 IFCHG[0] 0 1% Reserved for future use 100% (110_0100) Bit Name Default Value REG 0x19: Pre-Charge & Termination Current (R/W) (NVM) Description Comment 7 IPRECHG[3] 0 8% Pre-charge Current percentage of fast charge current set by OLIM resistor 6 IPRECHG[2] 1 4% Range: 5% (0000) ~ 20% (1111) 5 IPRECHG[1] 0 2% Default: 10% (0101) Offset: 5% 4 IPRECHG[0] 1 1% 3 ITERM[3] 0 8% Termination Current percentage of fast charge current which is set by OLIM resistor 2 ITERM[2] 1 4% Range: 5% (0000) ~ 20% (1111) 1 ITERM[1] 0 2% Default: 10% (0101) 0 ITERM[0] 1 1% Offset: 5% Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 83 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x1A: Battery Low Voltage (R/W) (NVM) Description 7 RFU 0 6 VBAT_LOW[6] 0 6400 mV 5 VBAT_LOW[5] 1 3200 mV 4 VBAT_LOW[4] 0 1600 mV 3 VBAT_LOW[3] 0 800 mV 2 VBAT_LOW[2] 0 400 mV 1 VBAT_LOW[1] 1 200 mV 0 VBAT_LOW[0] 1 100 mV Comment Reserved for future use Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Battery low voltage, where pre-charge to fast charge Offset: 5V Range: 5V (0000000) ~ 15.2V (1111111) www.active-semi.com Copyright © 2018 Active-Semi, Inc. 84 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x1B: Safety Timer (R/W) (NVM) 7 RFU 0 6 DIS_SAFETY_TIMER 0 Description 0: Enable 1: Disable 0: Counting 5 SUSPEND_SAFETY_TIMER 0 4 FC_SAFETY_TIMER[4] 1 8 hours 3 FC_SAFETY_TIMER[3] 0 4 hours 2 FC_SAFETY_TIMER[2] 1 2 hours 1 FC_SAFETY_TIMER[1] 0 1 hours 0 FC_SAFETY_TIMER[0] 0 30 mins 1: Suspend Comment Disables both the Fast Charge and VBAT Low safety timers. This will also reset both safety timers. Timers will be held in reset (at 0) when it is set to 1. When written back to 0, timers will start counting. If this is set to 1, both the Fast Charge and VBAT Low Safety Timers will stop counting at the current timer value. When written back to 0, then the counter will continue counting where it was suspended. If the counter is disabled during a suspend condition using the DIS_SAFETY_TIMER Register 0x1B Bit, the counter will be reset to 0, even if suspended. It will then be held at 0, until SUSPEND_SAFETY_TIMER is set to 0. DIS_SAFTETY_TIMER reset has priority over SUSPEND_SAFETY_TIMER. Timer setting for the Fast Charge State only. When timer is expired, Fast charging should be stop, and set Timer Expired bit, which stops charging. Range: 0.5 (00000) ~ 16 hours (11111) Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Default: 10 hours (10011) Offset: 0.5 hour www.active-semi.com Copyright © 2018 Active-Semi, Inc. 85 ACT2861QI Rev 2.0, 27-Apr-2018 Name Default Value REG 0x1C: JEITA (R/W) (NVM) DIS_LDO_TSHUT 0 Bit 7 Description 0: Enabled 1: Disabled Comment Disables the Thermal Shutdown for the LDO regulator. This should be set to 0 0: Use JEITA profile settings below 6 5 4 DIS_JEITA JEITA_VSETH [2] JEITA_VSETH[1] 0 0 0 1: Use OTG_COLD and OTG_HOT settings to disable charge modes 000: VTERM 001: VTERM200mV JEITA Warm (45°C-60°C) Temperature Voltage Setting DIS_JEITA = 0 010: VTERM300mV 011: VTERM-400mV 100: VTERM450mV 3 JEITA_VSETH[0] 0 101: VTERM500mV 110: VTERM-600mV 111: VTERM-750mV Fast Charge Current Only JEITA Warm (45°C-60°C) Temperature Current Setting Percentage with respect to ICHG register 2 JEITA_ISETH 0 0: 50% of ICHG DIS_JEITA = 0 1: 100% of ICHG Notes: 1. Result for 50% is rounded down Example: 15% IFCHG at 50% reduction results in 7% output 2. Result minimum is always 1% Example: 1% IFCHG setting at 50% reduction is still 1% 1 JEITA_ISETC[1] 0 0 JEITA_ISETC[0] 0 00: Charge Suspend Fast Charge Current 01: 25% of ICHG JEITA Low (0°C-10°C) Temperature Current Setting 10: 50% of ICHG Percentage with respect to ICHG register Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 86 ACT2861QI Rev 2.0, 27-Apr-2018 11: 100% of ICHG DIS_JEITA = 0 Notes: 1. Result for 50% and 25% is rounded down Example: 15% IFCHG setting at 50% results in 7% output 2. Result minimum is always 1% Example: 2% IFCHG setting at 25% reduction is still 1% Bit Name Default Value REG 0x1D: Temperature Setting (R/W) (NVM) Description Comment Settings: 7 6 FREQ_SEL[1] FREQ_SEL[0] 0 0 00: 125kHz 01: 250kHz 10: 500kHz 11: 1MHz Frequency Selection Note: These can NOT be changed “on the fly” and Settings for SMPS each setting requires a different inductor value and capacitors and compensation components. CARE SHOULD BE TAKEN WHEN WRITING TO THIS REGISTER TO AVOID CHANGING THE FREQUENCY WHILE OPERATING 5 DIS_SHIP_RENTER 0 4 OTG_HOT[1] 0 0: Enable re-enter ship mode 1: Disable ship mode re-enter 00: VTH55C at 55°C 01: VTH60C at 60°C If set to 0, writing to SHIPM_ENTER (Reg 0x00 Bit 5) will allow the device to re-enter ship mode. If set to 1, device will ignore the SHIPM_ENTER command. OTG mode or Disable JEITA Mode Hot Temperature Monitor TH / NTC Thresholds 10: VTH65C at 65°C 3 OTG_HOT[0] 1 2 OTG_COLD 0 1 TREG[1] 1 11: Disable shutdown 0: VTH0C at 0°C 1: VTH-10C at -10°C OTG mode or Disable JEITA Mode Cold Temperature Monitor TH / NTC Thresholds 00: Disable Die temperature regulation threshold 01: 80°C 0 TREG[0] 1 10: 100°C 11: 120°C Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 87 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 6 Name nIRQ_CHGDONE nIRQ_VBAT_GOOD Default Value REG 0x1E: IRQ Control 1 R/W (VM) 0 0 Description Comment 0: Either CHG Done If set to 0, any time the device enters the CHGTERM or CHGFULL state, it will active the nIRQ Pin state triggers nIRQ pin Setting to 1, masks CHG done states to nIRQ 1: Masks nIRQ 0: VBAT_GOOD falling edge triggers nIRQ If set to 0, VBAT_GOOD falling below threshold will active the nIRQ Pin Setting to 1, masks VBAT_GOOD to nIRQ 1: Masks nIRQ 5 nIRQ_CHG_OVUV 0 0: Charge Mode OVUV nIRQ 1: Masks nIRQ 4 3 2 nIRQ_OTG_VBAT nIRQ_SafetyTimer nIRQ_CHG_VBAT_OV 0 0 0 If set to 0, a Overvoltage or Undervoltage on VIN during charge mode will active the nIRQ Pin Setting to 1, masks the Overvoltage or Undervoltage to nIRQ 0: OTG Mode VBAT If set to 0, a VBAT below VBAT Cuttoff or VBAT Cutoff or Over Overvoltage during OTG mode will active the nIRQ Pin Votlage on nIRQ 1: Masks nIRQ Setting to 1, masks the fault to nIRQ 0: Charge Mode safety timer expired on nIRQ If set to 0, a VBAT Low safety timer expired or a Fast Charge safety timer expired during charge mode will active the nIRQ Pin 1: Masks nIRQ Setting to 1, masks the fault to nIRQ 0: Charge Mode VBAT Overvoltage on nIRQ If set to 0, a VBAT Overvoltage during charge mode will active the nIRQ Pin Setting to 1, masks the fault to nIRQ 1: Masks nIRQ 1 nIRQ_VREG_FLT 0 0: VREG LDO Overcurrent or Undervoltage indicated on nIRQ If set to 0, a VREG LDO Overcurrent or Undervoltage will active the nIRQ pin Setting to 1, masks the fault to nIRQ 1: Masks nIRQ 0 nIRQ_TSD 0 If set to 0, a device Thermal Shutdown will active the 0: Device Thermal Shutdown indicated nIRQ pin on nIRQ Setting to 1, masks the fault to nIRQ 1: Masks nIRQ Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 88 ACT2861QI Rev 2.0, 27-Apr-2018 Bit 7 6 Name nIRQ_FET_OC nIRQ_Watchdog Default Value REG 0x1F: IRQ Control 2 R/W (VM) 0 0 Description Comment 0: FET Overcurrent triggers nIRQ pin If set to 0, a FET Overcurrent condition will active the nIRQ pin 1: Masks nIRQ Setting to 1, masks CHG done states to nIRQ 0: Watchdog timer expired triggers nIRQ If set to 0, a watchdog timeout will active the nIRQ pin Setting to 1, masks the fault nIRQ 1: Masks nIRQ 5 4 nIRQ_OTG_HICCUP nIRQ_OTG_LL 0 0 0: OTG Mode enter Hiccup state nIRQ If set to 0, OTG Mode entering Hiccup state will active the nIRQ pin 1: Masks nIRQ Setting to 1, masks hiccup mode to nIRQ 0: OTG Mode enter Light Load state on nIRQ If set to 0, OTG Mode entering Light Load Disable state will active the nIRQ pin Setting to 1, masks light load disable state to nIRQ 1: Masks nIRQ 0: A2D Data Ready 3 nIRQ_A2D_DATA 0 1: Masks A2D Data Ready nIRQ 0: Enter HIZ Mode 2 1 0 nIRQ_HIZ nIRQ_CHG_SUSPEND nIRQ_OTG_BATTEMP 0 0 0 1: Masks Enter HIZ Mode nIRQ If set to 0, a rising edge on A2D Data Ready will active the nIRQ pin Setting to 1, masks the A2D Data Ready to nIRQ If set to 0, a rising edge when entering HIZ State will active the nIRQ pin Setting to 1, masks the HIZ Enter to nIRQ 0: Enter charge suspend mode If set to 0, a rising edge when entering a suspend state in charge mode will active the nIRQ pin 1: Masks Enter charge suspend mode nIRQ Setting to 1, masks the charge suspend enter to nIRQ 0: OTG BAT Temp Fault If set to 0, a rising edge caused by Battery Temp HOT or COLD in OTG Mode will active the nIRQ pin 1: Masks OTG BAT Temp Fault nIRQ Setting to 1, masks the nIRQ Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 89 ACT2861QI Rev 2.0, 27-Apr-2018 Bit Name Default Value REG 0x20: IRQ / OTG Status (R/W) (VM) Description 0: I2C Fault 7 6 5 4 nIRQ_I2C_ERROR OTG_BATTERY_CC OTG_OUTPUT_CC VBAT_CUTOFF_OTG NA NA NA NA 3 VBAT_OV_OTG NA 2 OTG_STATUS[2] NA 1 OTG_STATUS[1] NA OTG_STATUS[0] NA If set to 0, a fault on the I2C command / I2C bus will active the nIRQ Pin 1: Masks I2C Fault Setting to 1, masks the nIRQ nIRQ 0: OTG Input from battery no in current limit OTG Mode Only 1: OTG input from battery is regulating in Constant Current Mode This is the current measured on the VBAT side using OSRP and OSRN during OTG Mode controlled by the OTG_BAT_ILIM Register 0: OTG Output regulating using voltage loop OTG Mode Only 1: OTG output is regulating in Constant Current Mode This is the current measured on the VIN side using ISRP and ISRN during OTG Mode controlled by the OTC_CC Register 0: VBAT above VBAT_CUTOFF_O TG 1: VBAT below VBAT_CUTOFF_O TG 0: VBAT below OV 1: VBAT above OV 000: OTG_RST 001: OTG_SS 010: OTG_REG 0 Comment 011: OTG_HICCUP 100: OTG_LL_DIS Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi Real Time status Real Time status OTG Mode only Real time status – For latched fault, see the Fault Registers OTG Mode only Real time status – For latched fault, see the Fault Registers State machine for OTG status Note: When not in OTG State, status is always RESET (000) 101 – 111: Not Valid www.active-semi.com Copyright © 2018 Active-Semi, Inc. 90 ACT2861QI Rev 2.0, 27-Apr-2018 PACKAGE OUTLINE AND DIMENSIONS QFN4X4-32 Top View Side View All dimensions are in millimeters Dimensioning and tolerancing per JEDED MO-232 See Active Semi Application note AN-104, QFN PCB Layout Guidelines for more information on generating the ACT2861 land pattern. Innovative PowerTM ActiveSwitcherTM is a trademark of Active-Semi www.active-semi.com Copyright © 2018 Active-Semi, Inc. 91