BQ24650RVAT

Order Now Product Folder Support & Community Tools & Software Technical Documents BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 BQ24650 Stand-Alone Synchronous Buck Battery Charge Controller for Solar Power With Maximum Power Point Tracking 1 Features 2 Applications • • • • • • 1 • • • • • • • • • • • • Maximum Power Point Tracking (MPPT) capability by input Voltage regulation Programmable MPPT setting 5-V to 28-V Input solar panel 600-kHz NMOS-NMOS Synchronous buck controller Resistor programmable float voltage Accommodates Li-Ion/Polymer, LiFePO4, lead acid chemistries Accuracy – ±0.5% Charge voltage regulation – ±3% Charge current regulation – ±0.6% Input voltage regulation High Integration – Internal loop compensation – Internal digital soft start Safety – Input overvoltage protection – Battery temperature-sensing – Battery absent detection – Thermal shutdown Charge status outputs for LED or host processor Charge enable on MPPSET pin Automatic sleep mode for low power consumption – < 15-μA OFF-state battery discharge current Small 3.5 × 3.5 mm2 16-pin QFN package Solar-powered applications Remote monitoring stations Portable handheld instruments 12-V to 24-V Automotive systems Current-limited power source 3 Description The BQ24650 device is a highly integrated switchmode battery charge controller. It provides input voltage regulation, which reduces charge current when input voltage falls below a programmed level. When the input is powered by a solar panel, the input regulation loop lowers the charge current so that the solar panel can provide maximum power output. The BQ24650 offers a constant-frequency synchronous PWM controller with high accuracy current and voltage regulation, charge preconditioning, charge termination, and charge status monitoring. Device Information(1) PART NUMBER BQ24650 PACKAGE BODY SIZE (NOM) VQFN (16) 3.50 mm × 3.50 mm (1) For all available packages, see the orderable addendum at the end of the data sheet. Typical Application Solar Cell Half Panel D1 VIN R6 R5 C1 VCC BQ24650 VREF C3 R9 C2 C4 R3 REGN BTST MPPSET Pack Thermistor R10 Q3 Q1 C6 HIDRV TS CE D2 L C5 PH R4 TERM_EN RSR Q2 LODRV C8 Battery Pack C9 GND VIN R7 D3 R8 C10 R2 SRP STAT1 C7 STAT2 Thermal Pad SRN R1 VFB D4 1 An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications, intellectual property matters and other important disclaimers. PRODUCTION DATA. BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Table of Contents 1 2 3 4 5 6 7 Features .................................................................. Applications ........................................................... Description ............................................................. Revision History..................................................... Description (continued)......................................... Pin Configuration and Functions ......................... Specifications......................................................... 7.1 7.2 7.3 7.4 7.5 7.6 8 1 1 1 2 3 4 5 Absolute Maximum Ratings ...................................... 5 ESD Ratings.............................................................. 5 Recommended Operating Conditions....................... 5 Thermal Information .................................................. 6 Electrical Characteristics........................................... 6 Typical Characteristics ............................................ 10 Detailed Description ............................................ 12 8.1 Overview ................................................................. 12 8.2 Functional Block Diagram ....................................... 12 8.3 Feature Description................................................. 12 8.4 Device Functional Modes........................................ 21 9 Application and Implementation ........................ 23 9.1 Application Information............................................ 23 9.2 Typical Application ................................................. 23 10 Power Supply Recommendations ..................... 29 11 Layout................................................................... 29 11.1 Layout Guidelines ................................................. 29 11.2 Layout Example .................................................... 30 12 Device and Documentation Support ................. 31 12.1 12.2 12.3 12.4 12.5 12.6 Device Support...................................................... Receiving Notification of Documentation Updates Support Resources ............................................... Trademarks ........................................................... Electrostatic Discharge Caution ............................ Glossary ................................................................ 31 31 31 31 31 31 13 Mechanical, Packaging, and Orderable Information ........................................................... 31 4 Revision History Changes from Revision A (April 2016) to Revision B Page • Changed Title ........................................................................................................................................................................ 1 • Deleted Component Values from Typical Application on Page 1. ......................................................................................... 1 Changes from Original (July 2010) to Revision A Page • Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information section. ................................................................................................. 1 • Removed Ordering Information table .................................................................................................................................... 1 2 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 5 Description (continued) The BQ24650 charges the battery in three phases: pre-conditioning, constant current, and constant voltage. Charge is terminated when the current reaches 1/10 of the fast charge rate. The pre-charge timer is fixed at 30 minutes. The BQ24650 automatically restarts the charge cycle if the battery voltage falls below an internal threshold and enters a low quiescent current sleep mode when the input voltage falls below the battery voltage. The BQ24650 supports a battery from 2.1 V to 26 V with VFB set to a 2.1-V feedback reference. The charge current is programmed by selecting an appropriate sense resistor. The BQ24650 is available in a 16 -pin, 3.5 mm × 3.5 mm2 thin QFN package. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 3 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com 6 Pin Configuration and Functions PH LODRV 13 3 10 SRP 4 9 SRN 7 8 VFB TS 14 GND TERM_EN STAT1 HIDRV 11 ThermalPad 6 2 15 REGN VREF MPPSET BTST 12 5 1 STAT2 VCC 16 RVA Package 16-Pin VQFN Top View Pin Functions PIN NO. NAME TYPE DESCRIPTION 1 VCC P IC power positive supply. Place a 1-μF ceramic capacitor from VCC to GND and place it as close as possible to IC. Place a 10-Ω resistor from input side to VCC pin to filter the noise. 2 MPPSET I Input voltage set point. Use a voltage divider from input source to GND to set voltage on MPPSET to 1.2 V. To disable charge, pull MPPSET below 75 mV. 3 STAT1 O Open-drain charge status output to indicate various charger operation. Connect to the cathode of LED with 10 kΩ to the pullup rail. LOW or LED light up indicates charge in progress. Otherwise stays HI or LED stays off. When any fault condition occurs, both STAT1 and STAT2 are HI, or both LEDs are off. 4 TS I Temperature qualification voltage input. Connect to a negative temperature coefficient thermistor. Program the hot and cold temperature window with a resistor divider from VREF to TS to GND. A 103AT2 thermister is recommended. 5 STAT2 O Open-drain charge status output to indicate various charger operation. Connect to the cathode of LED with 10 kΩ to the pullup rail. LOW or LED light up indicates charge is complete. Otherwise, stays HI or LED stays off. When any fault condition occurs, both STAT1 and STAT2 are HI, or both LEDs are off. 6 VREF P 3.3-V reference voltage output. Place a 1-μF ceramic capacitor from VREF to GND pin close to the IC. This voltage could be used for programming voltage on TS and the pullup rail of STAT1 and STAT2. 7 TERM_EN I Charge termination enable. Pull TERM_EN to GND to disable charge termination. Pull TERM_EN to VREF to allow charge termination. TERM_EN must be terminated and cannot be left floating. 8 VFB I Charge voltage analog feedback adjustment. Connect the output of a resistor divider powered from the battery terminals to this node to adjust the output battery voltage regulation. 9 SRN I Charge current sense resistor, negative input. A 0.1-μF ceramic capacitor is placed from SRN to SRP to provide differential-mode filtering. An optional 0.1-μF ceramic capacitor is placed from SRN to GND for common-mode filtering. 10 SRP P/I Charge current sense resistor, positive input. A 0.1-μF ceramic capacitor is placed from SRN to SRP to provide differential-mode filtering. A 0.1-μF ceramic capacitor is placed from SRP to GND for commonmode filtering. 11 GND P Power ground. Ground connection for high-current power converter node. On PCB layout, connect directly to source of low-side power MOSFET, to ground connection of input and output capacitors of the charger. Only connect to GND through the thermal pad underneath the IC. 4 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Pin Functions (continued) PIN TYPE DESCRIPTION NO. NAME 12 REGN P PWM low-side driver positive 6-V supply output. Connect a 1-μF ceramic capacitor from REGN to GND, close to the IC. Use to drive low-side driver and high-side driver bootstrap Schottky diode from REGN to BTST. 13 LODRV O PWM low-side driver output. Connect to the gate of the low-side N-channel power MOSFET with a short trace. 14 PH P Switching node, charge current output inductor connection. Connect the 0.1-μF bootstrap capacitor from PH to BTST. 15 HIDRV O PWM high-side driver output. Connect to the gate of the high-side N-channel power MOSFET with a short trace. 16 BTST P PWM high-side driver positive supply. Connect the 0.1-µF bootstrap capacitor from PH to BTST. — Thermal Pad — Exposed pad beneath the IC. The thermal pad must always be soldered to the board and have the vias on the thermal pad plane star-connecting to GND and ground plane for high-current power converter. It also serves as a thermal pad to dissipate heat. 7 Specifications 7.1 Absolute Maximum Ratings over operating free-air temperature range (unless otherwise noted) (1) (2) (3) MIN MAX –0.3 33 PH –2 36 VFB –0.3 16 REGN, LODRV, TS, MPPSET, TERM_EN –0.3 7 BTST, HIDRV with respect to GND –0.3 39 VREF –0.3 3.6 SRP–SRN VCC, STAT1, STAT2, SRP, SRN Voltage (with respect to GND) Maximum difference voltage UNIT V –0.5 0.5 V Junction temperature, TJ –40 155 °C Storage temperature, Tstg –55 155 °C (1) (2) (3) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. All voltages are with respect to GND if not specified. Currents are positive into, negative out of the specified terminal. Consult Packaging Section of the data book for thermal limitations and considerations of packages. Must have a series resistor between battery pack to VFB if battery pack voltage is expected to be greater than 16 V. Usually the resistor divider top resistor takes care of this. 7.2 ESD Ratings VALUE V(ESD) (1) (2) Electrostatic discharge Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1) ±2000 Charged-device model (CDM), per JEDEC specification JESD22-C101 (2) ±500 UNIT V JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. 7.3 Recommended Operating Conditions VCC, STAT1, STAT2, SRP, SRN PH Voltage range (with respect to GND) MIN MAX –0.3 28 –2 30 VFB –0.3 14 REGN, LODRV, TS, MPPSET, TERM_EN –0.3 6.5 BTST, HIDRV with respect to GND –0.3 34 VREF UNIT V 3.3 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 5 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Recommended Operating Conditions (continued) Maximum difference voltage SRP–SRN Junction temperature, TJ MIN MAX –0.2 0.2 UNIT V –40 125 °C 7.4 Thermal Information BQ24650 THERMAL METRIC (1) RVA (VQFN) UNIT 16 PINS RθJA Junction-to-ambient thermal resistance (2) 43.8 °C/W RθJC(top) Junction-to-case (top) thermal resistance 81 °C/W RθJB Junction-to-board thermal resistance 16 °C/W ψJT Junction-to-top characterization parameter (3) 0.6 °C/W ψJB Junction-to-board characterization parameter (4) 15.77 °C/W RθJC(bot) Junction-to-case (bottom) thermal resistance 4 °C/W (1) (2) (3) (4) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report, SPRA953. The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as specified in JESD51-7, in an environment described in JESD51-2a The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted from the simulation data for obtaining RθJA, using a procedure described in JESD51-2a (sections 6 and 7). The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted from the simulation data for obtaining RθJA, using a procedure described in JESD51-2a (sections 6 and 7). 7.5 Electrical Characteristics 5 V ≤ VVCC ≤ 28 V, –40°C < TJ + 125°C, typical values are at TA = 25°C, with respect to GND (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT OPERATING CONDITIONS VVCC_OP VCC input voltage operating range 5 28 V 15 µA VCC > VBAT, VCC > VUVLO, CE = LOW 5 µA VCC > VBAT, VCC > VVCCLOWV, CE = HIGH, Charge done 5 µA 0.7 1 mA 2 3 mA QUIESCENT CURRENTS Total battery discharge current (sum of currents into VCC, BTST, PH, SRP, VCC < VBAT, VCC > VUVLO (SLEEP) SRN, VFB), VFB ≤ 2.1V IBAT Battery discharge current (sum of currents into BTST, PH, SRP, SRN, VFB), VFB ≤ 2.1V VCC > VBAT, VCC > VUVLO, CE = LOW VCC > VBAT, VCC > VVCCLOWV, Adapter supply current (sum of current CE = HIGH, charge done into VCC pin) VCC > VBAT, VCC > VVCCLOWV, CE = HIGH, Charging, Qg_total = 10 nC [1] IAC 25 mA CHARGE VOLTAGE REGULATION VREG Feedback regulation voltage 2.1 Charge voltage regulation accuracy IVFB Leakage current into VFB pin V TJ = 0°C to 85°C –0.5% 0.5% TJ = –40°C to 125°C –0.7% 0.7% VFB = 2.1 V 100 nA CURRENT REGULATION – FAST CHARGE VIREG_CHG SRP-SRN current sense voltage range VIREG_CHG = VSRP – VSRN Charge current regulation accuracy VIREG_CHG = 40 mV 40 –3% mV 3% CURRENT REGULATION – PRE-CHARGE VPRECHG 6 Precharge current sense voltage range VIREG_PRCHG = VSRP – VSRN Submit Documentation Feedback 4 mV Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Electrical Characteristics (continued) 5 V ≤ VVCC ≤ 28 V, –40°C < TJ + 125°C, typical values are at TA = 25°C, with respect to GND (unless otherwise noted) PARAMETER TEST CONDITIONS Precharge current regulation accuracy VIREG_PRECH = 4 mV MIN TYP –25% MAX UNIT 25% CHARGE TERMINATION VTERMCHG Termination current sense voltage range VITERM = VSRP – VSRN Termination current accuracy VITERM = 4 mV 4 –25% Deglitch time for termination (both edges) tQUAL IQUAL Termination qualification time VBAT > VRECH and ICHG < ITERM Termination qualification current Discharge current once termination is detected mV 25% 100 ms 250 ms 2 mA INPUT VOLTAGE REGULATION VMPPSET MPPSET regulation voltage 1.2 Input voltage regulation accuracy –0.6% IMPPSET Leakage current into MPPSET pin VMPPSET_CD MPPSET shorted to disable charge VMPPSET_CE MPPSET released to enable charge V 0.6% VMPPSET = 7 V, TA = 0 – 85°C 1 µA 75 mV 175 mV INPUT UNDERVOLTAGE LOCKOUT COMPARATOR (UVLO) VUVLO AC undervoltage rising threshold VUVLO_HYS AC undervoltage hysteresis, falling Measure on VCC 3.65 3.85 4 V 350 mV 4.1 V 4.35 V VCC LOWV COMPARATOR VVCC LOWV_fall Falling threshold, disable charge VVCC LOWV_rise Rising threshold, resume charge Measure on VCC SLEEP COMPARATOR (REVERSE DISCHARGING PROTECTION) VSLEEP _FALL VSLEEP_HYS SLEEP falling threshold VVCC – VSRN to enter SLEEP 40 SLEEP hysteresis SLEEP rising shutdown deglitch VCC falling below SRN SLEEP falling powerup deglitch VCC rising above SRN, Delay to exit SLEEP mode 100 150 mV 500 mV 100 ms 30 ms BAT LOWV COMPARATOR VLOWV Precharge to fast charge transition (LOWV threshold) VLOWV_HYS LOWV hysteresis Measure on VFB pin 1.54 1.55 1.56 V 100 mV LOWV rising deglitch VFB falling below VLOWV 25 ms LOWV falling deglitch VFB rising above VLOWV + VLOWV_HYS 25 ms RECHARGE COMPARATOR VRECHG Recharge threshold (with respect to VREG) Measure on VFB pin Recharge rising deglitch VFB decreasing below VRECHG 10 ms Recharge falling deglitch VFB increasing above VRECHG 10 ms 35 50 65 mV BAT OVERVOLTAGE COMPARATOR VOV_RISE Overvoltage rising threshold As percentage of VFB 104% VOV_FALL Overvoltage falling threshold As percentage of VFB 102% INPUT OVERVOLTAGE COMPARATOR (ACOV) VACOV AC overvoltage rising threshold on VCC VACOV_HYS AC overvoltage falling hysteresis 31 32 33 V 1 V AC overvoltage deglitch (both edges) Delay to changing the STAT pins 1 ms AC overvoltage rising deglitch Delay to disable charge 1 ms Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 7 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Electrical Characteristics (continued) 5 V ≤ VVCC ≤ 28 V, –40°C < TJ + 125°C, typical values are at TA = 25°C, with respect to GND (unless otherwise noted) PARAMETER TEST CONDITIONS AC overvoltage falling deglitch MIN TYP MAX UNIT Delay to resume charge 20 ms Temperature increasing 145 °C 15 °C Thermal shutdown rising deglitch Temperature increasing 100 µs Thermal shutdown falling deglitch Temperature decreasing 10 ms THERMAL SHUTDOWN COMPARATOR TSHUT Thermal shutdown rising temperature TSHUT_HYS Thermal shutdown hysteresis THERMISTOR COMPARATOR VLTF Cold temperature rising threshold VLTF_HYS Rising hysteresis 72.5% 73.5% 74.5% VHTF Hot temperature rising threshold VTCO Cut-off temperature rising threshold 0.2% As percentage to VVREF 0.4% 0.6% 46.7% 47.5% 48.3% 44.3% Deglitch time for temperature out of range detection VTS < VLTF, or VTS < VTCO, or VTS < VHTF Deglitch time for temperature in valid range detection VTS > VLTF – VLTF_HYS or VTS >VTCO, or VTS > VHTF 45% 45.7% 400 ms 20 ms 80 mV CHARGE OVERCURRENT COMPARATOR (CYCLE-BY-CYCLE) VOC Charge overcurrent rising threshold Current rising, in synchronous mode measure (VSRP – VSRN) CHARGE UNDERCURRENT COMPARATOR (CYCLE-BY-CYCLE) VISYNSET Charge undercurrent falling threshold Switch from CCM to DCM, VSRP > 2.2V 1 5 9 mV BATTERY-SHORTED COMPARATOR (BATSHORT) VBATSHT BAT short falling threshold, forced non-synchronous mode VBATSHT_HYS BAT short rising hysteresis tBATSHT_DEG Deglitch on both edges VSRP falling 2 V 200 mV 1 µs 1.25 mV 1.25 mV 1 µs LOW CHARGE CURRENT COMPARATOR VLC Low charge current falling threshold VLC_HYS Low charge current rising hysteresis tLC_DEG Deglitch on both edges Measure V(SRP-SRN) VREF REGULATOR VVREF_REG VREF regulator voltage VVCC > VUVLO, 0 – 35 mA load 3.267 IVREF_LIM VREF current limit VVREF = 0 V, VVCC > VUVLO 35 3.3 3.333 V mA REGN REGULATOR VREGN_REG REGN regulator voltage VVCC > 10 V, MPPSET > 175 mV 5.7 IREGN_LIM REGN current limit VREGN = 0 V, VVCC > VUVLO, MPPSET < 75 mV 40 6.0 6.3 V mA BATTERY DETECTION tWAKE Wake timer Max time charge is enabled 500 IWAKE Wake current RSENSE = 10 mΩ tDISCHARGE Discharge timer Max time discharge current is applied IDISCHARGE 50 125 ms 200 mA 1 sec Discharge current 6 mA IFAULT Fault current after a timeout fault 2 mA IQUAL Termination qualification current 2 mA tQUAL Termination qualification time 250 ms VWAKE Wake threshold (with respect to VREG) Voltage on VFB to detect battery absent during wake 50 mV VDISCH Discharge threshold Voltage on VFB to detect battery absent during discharge 1.55 8 Submit Documentation Feedback V Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Electrical Characteristics (continued) 5 V ≤ VVCC ≤ 28 V, –40°C < TJ + 125°C, typical values are at TA = 25°C, with respect to GND (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 3.3 6 Ω 1 1.4 Ω PWM HIGH-SIDE DRIVER (HIDRV) RDS_HI_ON High-side driver (HSD) turnon resistance RDS_HI_OFF High-side driver turnoff resistance VBTST_REFRESH Bootstrap refresh comparator threshold Voltage VBTST – VPH = 5.5 V VBTST – VPH when low side refresh pulse is requested 4.0 4.2 V PWM LOW-SIDE DRIVER (LODRV) RDS_LO_ON Low-side driver (LSD) turn-on resistance RDS_LO_OFF Low-side driver turn-off resistance 4.1 7 Ω 1 1.4 Ω PWM DRIVERS TIMING Dead time when switching between LSD and HSD, No load at LSD and HSD Driver dead-time 30 ns PWM OSCILLATOR VRAMP_HEIGHT PWM ramp height As percentage of VCC 7% PWM switching frequency 510 600 690 kHz INTERNAL SOFT START (8 STEPS TO REGULATION CURRENT ICHG) Soft-start steps Soft-start step time 8 step 1.6 ms 1.5 s CHARGER SECTION POWER-UP SEQUENCING Charge-enable delay after power-up Delay from MPPSET > 175 mV to charger is allowed to turn on LOGIC IO PIN CHARACTERISTICS (STAT1, STAT2, TERM_EN) VOUT_LOW STAT1, STAT2 output low saturation voltage Sink current = 5 mA 0.5 V IOUT_HI Leakage current V = 32 V 1.2 µA VIN_LOW TERM_EN input low threshold voltage 0.4 V VIN_HI TERM_EN input high threshold voltage IIN_BIAS TERM_EN bias current 1.6 VTERM_EN = 0.5 V V 60 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 µA 9 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com 7.6 Typical Characteristics VCC = 25 V, BQ24650 application circuit, TA = 25°C unless otherwise noted MPPSET 1V/div VCC 10V/div LODRV 5V/div VREF 2V/div PH 20V/div REGN 5V/div STAT1 20V/div IBAT 1A/div 800 ms/div 400 ms/div Figure 1. Power Up on VCC Figure 2. Charge Start on MPPSET MPPSET 1V/div MPPSET 1V/div LODRV 5V/div LODRV 5V/div PH 20V/div PH 20V/div IBAT 1A/div IBAT 1A/div 10 ms/div 4 ms/div Figure 3. Charge Soft Start on MPPSET Figure 4. Charge Stop on MPPSET HIDRV 20V/div HIDRV 20V/div PH 20V/div PH 20V/div LODRV 5V/div LODRV 5V/div IL 1A/div IL 1A/div 100 ns/div 200 ns/div Figure 5. Switching in Continuous Conduction Mode 10 Figure 6. Switching in Discontinuous Conduction Mode Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Typical Characteristics (continued) VCC = 25 V, BQ24650 application circuit, TA = 25°C unless otherwise noted HIDRV 20V/div HIDRV 20V/div PH 20V/div PH 20V/div LODRV 5V/div LODRV 5V/div IL 1A/div IL 1A/div 400 ms/div 100 ns/div Figure 7. Switching at 100% Duty Cycle Figure 8. Recharge the BTST-PH Capacitor Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 11 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com 8 Detailed Description 8.1 Overview The BQ24650 is a highly integrated solar input Li-ion or Li-polymer battery charge controller. 8.2 Functional Block Diagram BQ24650 VREF VOLTAGE REFERENCE VCC - SRN+100 mV + SLEEP VREF 3.3V LDO UVLO VCC VCC - VUVLO + SLEEP UVLO VCC 175 mV + FBO MPPSET 1.2 V COMP ERROR AMPLIFIER + 2.1 V CE + + 1V + VFB BTST EAO - EAI PWM - LEVEL SHIFTER 20uA SRP SRP-SRN + SYNCH PH + 20X - V(SRP-SRN) 0.8V PWM CONTROL LOGIC + 5 mV - + - SRN BTST _+ PH 20 uA VCC 6V LDO REFRESH - CE 4V LODRV V(SRP-SRN) - 200% X IBAT_REG + 2 mA CHG_OCP GND 8 mA FAULT 30 Minute Precharge Timer CHARGE DISCHARGE TERM_EN 0.8V STAT 1 IC Tj + 145°C - TSHUT CHARGE STAT1 VFB - 104% X 2.1V + BAT_OVP STATE MACHINE LOGIC IBAT_ REG 0.8V 10 STAT2 STAT 2 LOWV 1.5V +- - LOWV BATTERY DETECTION LOGIC DISCHARGE VREF + VCC + LTF ACOV - + VFB REGN + FAULT VFB HIDRV BAT_OVP TS + 32V - SUSPEND RCHRG HTF + + - 2.05V +RCHRG V(SRP - SRN) 0.8V 10 + TERM TERM TCO + - TERMINATE CHARGE Copyright © 2016, Texas Instruments Incorporated 8.3 Feature Description 8.3.1 Battery Voltage Regulation The BQ24650 uses a high accuracy voltage regulator for the charging voltage. The charge voltage is programmed through a resistor divider from the battery to ground, with the midpoint tied to the VFB pin. The voltage at the VFB pin is regulated to 2.1 V, giving Equation 1 for the regulation voltage: 12 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Feature Description (continued) é R2 ù VBAT = 2.1 V ´ ê1+ ë R1 úû where • • R2 is connected from VFB to the battery and R1 is connected from VFB to GND. (1) Li-Ion, LiFePO4, and sealed lead acid are widely used battery chemistries. Most commercial Li-ion cells can now be charged to 4.2 V/cell. A LiFePO4 battery allows a much higher charge and discharge rate, but the energy density is lower. The typical cell voltage is 3.6 V. The charge profile of both Li-Ion and LiFePO4 is preconditioning, constant current, and constant voltage. For maximum cycle life, the end-of-charge voltage threshold could be lowered to 4.1 V/cell. Although the energy density is much lower than Li-based chemistry, lead acid is still popular due to its low manufacturing cost and high discharge rates. The typical voltage limit is from 2.3 V to 2.45 V. After the battery has been fully charged, a float charge is required to compensate for the self-discharge. The float charge limit is 100 mV to 200 mV below the constant voltage limit. Regulation Voltage VRECH Regulation Current Precharge Current Regulation Phase Fastcharge Current Regulation Phase Fastcharge Voltage Regulation Phase Termination Charge Current Charge Voltage VLOWV IPRECH & ITERM Figure 9. Typical Charging Profile 8.3.2 Input Voltage Regulation A solar panel has a unique point on the V-I or V-P curve, called the Maximum Power Point (MPP), at which the entire photovoltaic (PV) system operates with maximum efficiency and produces its maximum output power. The constant voltage algorithm is the simplest Maximum Power Point Tracking (MPPT) method. The BQ24650 automatically reduces charge current so the maximum power point is maintained for maximum efficiency. If the solar panel or other input source cannot provide the total power of the system and BQ24650 charger, the input voltage drops. When the voltage sensed on the MPPSET pin drops below 1.2 V, the charger maintains the input voltage by reducing the charge current. If the MPPSET pin voltage is forced below 1.2 V, the BQ24650 stays in the input voltage regulation loop while the output current is zero. The STAT1 pin is LOW and STAT2 pin is HIGH. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 13 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Feature Description (continued) The voltage at the MPPSET pin is regulated to 1.2 V, giving Equation 2 for the regulation voltage: é R3 ù VMPPSET = 1.2 V ´ ê1+ ú ë R4 û (2) The MPPSET pin is also used as charge enable control. If the voltage on MPPSET is pulled down below 75 mV, charge is disabled. Charge resumes if the voltage on MPPSET goes back above 175 mV. 8.3.3 Battery Current Regulation Battery current is sensed by resistor RSR connected between SRP and SRN. The full-scale differential voltage between SRP and SRN is fixed at 40 mV. Thus, for a 20-mΩ sense resistor, the charging current is 2 A. For charging current, refer to Equation 3: 40 mV ICHARGE = RSR (3) 8.3.4 Battery Precharge On power-up, if the battery voltage is below the VLOWV threshold, the BQ24650 applies the precharge current to the battery. This feature is intended to revive deeply discharged cells. If the VLOWV threshold is not reached within 30 minutes of initiating precharge, the charger turns off and a FAULT is indicated on the status pins. The precharge current is determined as 1/10 of the fast charge current according to Equation 4: 4 mV IPRECHARGE = RSR (4) 8.3.5 Charge Termination and Recharge The BQ24650 monitors the charging current during the voltage regulation phase. Termination is detected while the voltage on the VFB pin is higher than the VRECH threshold and the charge current is less than the ITERM threshold (1/10 of fast charge current), as calculated in Equation 5: 4 mV ITERM = RSR (5) A • • • new charge cycle is initiated when one of the following conditions occurs: The battery voltage falls below the recharge threshold A power-on-reset (POR) event occurs MPPSET falls below 75 mV to reset charge enable The TERM_EN pin may be taken LOW to disable termination. If TERM_EN is pulled above 1.6 V, the BQ24650 allows termination. 8.3.6 Power Up The BQ24650 uses a SLEEP comparator to determine the source of power on the VCC pin, because VCC can be supplied either from a battery or an adapter. If the VCC voltage is greater than the SRN voltage, and all other conditions are met for charging, the BQ24650 then attempts to charge a battery (see Enable and Disable Charging). If SRN voltage is greater than VCC, indicating that a battery is the power source, the BQ24650 enters low quiescent current (< 15 µA) SLEEP mode to minimize current drain from the battery. If VCC is below the UVLO threshold, the device is disabled, and VREF LDO turns off. 14 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Feature Description (continued) 8.3.7 Enable and Disable Charging The following conditions have to be valid before charging is enabled: • Charge is allowed (MPPSET > 175 mV) • Device is not in undervoltage lockout (UVLO) mode and VCC is above the VCCLOWV threshold • Device is not in SLEEP mode (that is, VCC > SRN) • VCC voltage is lower than AC overvoltage threshold (VCC < VACOV) • 30-ms delay is complete after initial power-up • REGN LDO and VREF LDO voltages are at correct levels • Thermal Shut (TSHUT) is not valid • TS fault is not detected One of the following conditions stops on-going charging: • Charge is disabled (MPPSET < 75 mV) • Adapter is removed, causing the device to enter VCCLOWV or SLEEP mode • Adapter voltage is less than 100 mV above battery • Adapter is over voltage • REGN or VREF LDO voltage is not valid • TSHUT IC temperature threshold is reached • TS voltage goes out of range indicating the battery temperature is too hot or too cold 8.3.8 Automatic Internal Soft-Start Charger Current The charger automatically soft-starts the charger regulation current every time the charger goes into fast-charge to ensure there is no overshoot or stress on the output capacitors or the power converter. The soft-start consists of stepping-up the charge regulation current into 8 evenly divided steps up to the programmed charge current. Each step lasts approximately 1.6 ms, for a typical rise time of 13 ms. No external components are needed for this function. 8.3.9 Converter Operation The synchronous buck PWM converter uses a fixed frequency voltage mode with feed-forward control scheme. A type III compensation network allows using ceramic capacitors at the output of the converter. The compensation input stage is connected internally between the feedback output (FBO) and the error amplifier input (EAI). The feedback compensation stage is connected between the error amplifier input (EAI) and error amplifier output (EAO). The LC output filter must be selected to give a resonant frequency of 12 kHz – 17 kHz for the BQ24650, where resonant frequency, fo, is given by: 1 fo = 2p L o Co (6) An internal saw-tooth ramp is compared to the internal EAO error control signal to vary the duty-cycle of the converter. The ramp height is 7% of the input adapter voltage making it always directly proportional to the input adapter voltage. This cancels out any loop gain variation due to a change in input voltage and simplifies the loop compensation. The ramp is offset by 300 mV to allow zero percent duty-cycle when the EAO signal is below the ramp. The EAO signal is also allowed to exceed the saw-tooth ramp signal in order to get a 100% duty-cycle PWM request. Internal gate drive logic allows achieving 99.98% duty-cycle while ensuring the N-channel upper device always has enough voltage to stay fully on. If the BTST pin to PH pin voltage falls below 4.2 V for more than 3 cycles, then the high-side N-channel power MOSFET is turned off and the low-side N-channel power MOSFET is turned on to pull the PH node down and recharge the BTST capacitor. Then the high-side driver returns to 100% duty-cycle operation until the (BTST-PH) voltage is detected to fall low again due to leakage current discharging the BTST capacitor below 4.2 V, and the reset pulse is reissued. The fixed-frequency oscillator keeps tight control of the switching frequency under all conditions of input voltage, battery voltage, charge current, and temperature, simplifying output filter design and keeping it out of the audible noise region. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 15 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Feature Description (continued) 8.3.10 Synchronous and Non-Synchronous Operation The charger operates in synchronous mode when the SRP-SRN voltage is above 5 mV (0.5-A inductor current for a 10-mΩ sense resistor). During synchronous mode, the internal gate drive logic ensures there is breakbefore-make complimentary switching to prevent shoot-through currents. During the 30-ns dead time where both FETs are off, the body-diode of the low-side power MOSFET conducts the inductor current. Having the low-side FET turn on keeps power dissipation low, and allows safe charging at high currents. During synchronous mode the inductor current is always flowing and the converter operates in continuous conduction mode (CCM), creating a fixed two-pole system. The charger operates in non-synchronous mode when the SRP-SRN voltage is below 5 mV (0.5-A inductor current for a 10-mΩ sense resistor). In addition, the charger is forced into non-synchronous mode when battery voltage is lower than 2 V or when the average SRP-SRN voltage is lower than 1.25 mV. During non-synchronous operation, the body-diode of the low-side MOSFET can conduct the positive inductor current after the low-side N-channel power MOSFET turns off. When the load current decreases and the inductor current drops to zero, the body diode is naturally turned off and the inductor current becomes discontinuous. This mode is called Discontinuous Conduction Mode (DCM). During DCM, the low-side N-channel power MOSFET turns on when the bootstrap capacitor voltage drops below 4.2 V, then the low-side power MOSFET turns off and stays off until the beginning of the next cycle, where the high-side power MOSFET is turned on again. The lowside MOSFET on time is required to ensure the bootstrap capacitor is always recharged and able to keep the high-side power MOSFET on during the next cycle. This is important for battery chargers, where unlike regular DC-DC converters, there is a battery load that maintains a voltage and can both source and sink current. The low-side pulse pulls the PH node (connection between high and low-side MOSFETs) down, allowing the bootstrap capacitor to recharge up to the REGN LDO value. After the refresh pulse, the low-side MOSFET is kept off to prevent negative inductor current from occurring. At very low currents during non-synchronous operation, there may be a small amount of negative inductor current during the recharge pulse. The charge must be low enough to be absorbed by the input capacitance. Whenever the converter goes into zero percent duty-cycle, the high-side MOSFET does not turn on, and the lowside MOSFET does not turn on (except for recharge pulse) either, and there is almost no discharge from the battery. During DCM mode the loop response automatically changes and has a single pole system at which the pole is proportional to the load current, because the converter does not sink current, and only the load provides a current sink. This means at very low currents the loop response is slower, as there is less sinking current available to discharge the output voltage. 8.3.11 Cycle-by-Cycle Charge Undercurrent In the BQ24650, if the SRP-SRN voltage decreases below 5 mV, the low-side FET is turned off for the remainder of the switching cycle to prevent negative inductor current. During DCM, the low-side FET only turns on when the bootstrap capacitor voltage drops below 4.2 V to provide refresh charge for the bootstrap capacitor. This is important to prevent negative inductor current from causing a boost effect in which the input voltage increases as power is transferred from the battery to the input capacitors and lead to an overvoltage stress on the VCC node and potentially cause damage to the system. 8.3.12 Input Overvoltage Protection (ACOV) ACOV provides protection to prevent system damage due to high input voltage. Once the adapter voltage reaches the ACOV threshold, charge is disabled. 8.3.13 Input Undervoltage Lockout (UVLO) The system must have a minimum VCC voltage to allow proper operation. This VCC voltage could come from either input adapter or battery, since a conduction path exists from the battery to VCC through the high-side NMOS body diode. When VCC is below the UVLO threshold, all circuits on the IC, including VREF LDO, are disabled. 16 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Feature Description (continued) 8.3.14 Battery Overvoltage Protection The converter does not allow the high-side FET to turn on until the BAT voltage goes below 102% of the regulation voltage. This allows one-cycle response to an over-voltage condition – such as occurs when the load is removed or the battery is disconnected. A current sink from SRP to GND is on to discharge the stored energy on the output capacitors. 8.3.15 Cycle-by-Cycle Charge Overcurrent Protection The charger has a secondary cycle-to-cycle over-current protection. It monitors the charge current and prevents the current from exceeding 200% of the programmed charge current. The high-side gate drive turns off when overcurrent is detected and automatically resumes when the current falls below the overcurrent threshold. 8.3.16 Thermal Shutdown Protection The QFN package has low thermal impedance, which provides good thermal conduction from the silicon to the ambient, to keep junction temperatures low. As an added level of protection, the charger converter turns off and self-protects whenever the junction temperature exceeds the TSHUT threshold of 145°C. The charger stays off until the junction temperature falls below 130°C. 8.3.17 Temperature Qualification The controller continuously monitors battery temperature by measuring the voltage between the TS pin and GND. A negative temperature coefficient thermistor (NTC) and an external voltage divider typically develop this voltage. The controller compares this voltage against its internal thresholds to determine if charging is allowed. To initiate a charge cycle, the battery temperature must be within the VLTF to VHTF thresholds. If battery temperature is outside of this range, the controller suspends charge and waits until the battery temperature is within the VLTF to VHTF range. During the charge cycle the battery temperature must be within the VLTF to VTCO thresholds. If battery temperature is outside of this range, the controller suspends charge and waits until the battery temperature is within the VLTF to VHTF range. The controller suspends charge by turning off the PWM charge FETs. Figure 10 summarizes the operation. VREF VREF CHARGE SUSPENDED CHARGE SUSPENDED VLTF VLTFH VLTF VLTFH TEMPERATURE RANGE TO INITIATE CHARGE TEMPERATURE RANGE DURING A CHARGE CYCLE VHTF VTCO CHARGE SUSPENDED CHARGE SUSPENDED GND GND Figure 10. TS Pin, Thermistor Sense Thresholds Assuming a 103AT NTC thermistor on the battery pack as shown in Figure 15, the values of RT1 and RT2 can be determined by using Equation 7 and Equation 8: æ 1 1 ö VVREF ´ RTHCOLD ´ RTHHOT ´ ç ÷ VLTF VTCO ø è RT2 = æV ö æV ö RTHHOT ´ ç VREF - 1÷ - RTHCOLD ´ ç VREF - 1÷ V V è LTF ø è TCO ø (7) Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 17 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Feature Description (continued) VVREF -1 VLTF RT1 = 1 1 + RT2 RTHCO LD (8) VREF RT1 BQ24650 TS RTH 103AT RT2 Copyright © 2016, Texas Instruments Incorporated Figure 11. TS Resistor Network 8.3.18 Charge Enable MPPSET is used to disable or enable the charge process. A voltage above 175 mV on this pin enables charge, provided all other conditions for charge are met (see Enable and Disable Charging). A voltage below 75 mV on this pin also resets all timers and fault conditions. 8.3.19 Inductor, Capacitor, and Sense Resistor Selection Guidelines The BQ24650 provides internal loop compensation. With this scheme, the best stability occurs when the LC resonant frequency, fo, is approximately 12 kHz – 17 kHz for the BQ24650. Table 1 provides a summary of typical LC components for various charge currents. Table 1. Typical Inductor, Capacitor, and Sense Resistor Values as a Function of Charge Current CHARGE CURRENT 0.5 A 1A 2A 4A 8A 10 A Output inductor low 22 µH 15 µH 10 µH 6.8 µH 3.3 µH 3.3 µH Output capacitor CO 7 µF 10 µF 15 µF 20 µF 40 µF 40 µF Sense resistor 80 mΩ 40 mΩ 20 mΩ 10 mΩ 5 mΩ 4 mΩ 8.3.20 Charge Status Outputs The open-drain STAT1 and STAT2 outputs indicate various charger operations as listed in Table 2. These status pins can be used to drive LEDs or communicate with the host processor. NOTE OFF indicates that the open-drain transistor is turned off. Table 2. STAT Pin Definition for BQ24650 STAT1 STAT2 Charge in progress CHARGE STATE ON OFF Charge complete OFF ON Charge suspend, overvoltage, sleep mode, battery absent OFF OFF 18 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 8.3.21 Battery Detection For applications with removable battery packs, the BQ24650 provides a battery absent detection scheme to reliably detect insertion or removal of battery packs. POR or RECHARGE The battery detection routine runs on power up, or if VFB falls below VRECH due to removing a battery or discharging a battery Apply 8mA discharge current, start 1s timer VFB < VLOWV No Yes 1s timer expired No Yes Battery Present, Begin Charge Disable 6mA discharge current Enable 125mA Charge, Start 0.5s timer VFB > VRECH Yes Disable 125mA Charge No 0.5s timer expired No Yes Battery Present, Begin Charge Battery Absent Figure 12. Battery Detection Flowchart When the device has powered up, a 6-mA discharge current is applied to the SRN terminal. If the battery voltage falls below the LOWV threshold within 1 second, the discharge source is turned off, and the charger is turned on at low charge current (125 mA). If the battery voltage gets up above the recharge threshold within 500 ms, there is no battery present and the cycle restarts. If either the 500 ms or 1 second timer time out before the respective thresholds are hit, a battery is detected and a charge cycle is initiated. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 19 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Battery not detected VREG VRECH (VWAKE) Battery inserted VLOWV (VDISCH) Battery detected tLOWV_DEG tWAKE tRECH_DEG Figure 13. Battery Detect Timing Diagram Take care that the total output capacitance at the battery node is not so large that the discharge current source cannot pull the VFB voltage below the LOWV threshold during the 1 second discharge time. The maximum output capacitance can be calculated according to Equation 9: ´ tDISCH I CMAX = DISCH é R ù 0.5 ´ ê1+ 2 ú ë R1 û where • • • • CMAX is the maximum output capacitance, IDISCH is the discharge current, tDISCH is the discharge time, and R2 and R1 are the voltage feedback resistors from the battery to the VFB pin. (9) The 0.5 factor is the difference between the RECHARGE and the LOWV thresholds at the VFB pin. 8.3.21.1 Example For a 3-cell Li+ charger, with R2 = 500 kΩ, R1 = 100 kΩ (giving 12.6 V for voltage regulation), IDISCH = 6 mA, tDISCH = 1 second. 6 mA ´ 1 sec CMAX = = 2000 μF é 500 kW ù 0.5 ´ ê1+ ú ë 100 kW û (10) Based on these calculations, no more than 2000 µF must be allowed on the battery node for proper operation of the battery detection circuit. 20 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 8.4 Device Functional Modes 8.4.1 Converter Operation The synchronous buck PWM converter uses a fixed-frequency voltage mode with a feed-forward control scheme. A type-III compensation network allows using ceramic capacitors at the output of the converter. The compensation input stage is connected internally between the feedback output (FBO) and the error amplifier input (EAI). The feedback compensation stage is connected between the error amplifier input (EAI) and error amplifier output (EAO). The LC output filter is selected to give a resonant frequency of 17 kHz to 25 kHz for the BQ24650, where the resonant frequency, fo, is given by Equation 11: 1 fo = 2p Lo Co (11) An internal sawtooth ramp is compared to the internal EAO error control signal to vary the duty-cycle of the converter. The ramp height is 7% of the input adapter voltage, making it always directly proportional to the input adapter voltage. This cancels out any loop gain variation due to a change in input voltage, and simplifies the loop compensation. The ramp is offset by 300 mV to allow zero-percent duty cycle when the EAO signal is below the ramp. The EAO signal is also allowed to exceed the saw-tooth ramp signal in order to get a 100% duty-cycle PWM request. Internal gate-drive logic allows achieving 99.5% duty cycle while ensuring the N-channel upper device always has enough voltage to stay fully on. If the BTST pin to PH pin voltage falls below 4.2 V for more than 3 cycles, then the high-side N-channel power MOSFET is turned off and the low-side N-channel power MOSFET is turned on to pull the PH node down and recharge the BTST capacitor. Then the high-side driver returns to 100% duty-cycle operation until the (BTST–PH) voltage is detected to fall low again due to leakage current discharging the BTST capacitor below 4.2 V, and the reset pulse is reissued. The fixed-frequency oscillator keeps tight control of the switching frequency under all conditions of input voltage, battery voltage, charge current, and temperature, simplifying output filter design and keeping it out of the audible noise region. 8.4.2 Synchronous and Non-Synchronous Operation The charger operates in synchronous mode when the SRP-SRN voltage is above 5 mV (0.5-A inductor current for a 10-mΩ sense resistor). During synchronous mode, the internal gate-drive logic ensures there is breakbefore-make complementary switching to prevent shoot-through currents. During the 30-ns dead time where both FETs are off, the body-diode of the low-side power MOSFET conducts the inductor current. Having the low-side FET turn on keeps the power dissipation low, and allows safely charging at high currents. During synchronous mode, the inductor current is always flowing and the converter operates in continuous-conduction mode (CCM), creating a fixed two-pole system. The charger operates in non-synchronous mode when the SRP-SRN voltage is below 5 mV (0.5-A inductor current for a 10-mΩ sense resistor). The charger is forced into non-synchronous mode when battery voltage is lower than 2 V or when the average SRP-SRN voltage is lower than 1.25 mV. During non-synchronous operation, the body diode of the low-side MOSFET can conduct the positive inductor current after the high-side N-channel power MOSFET turns off. When the load current decreases and the inductor current drops to zero, the body diode is naturally turned off and the inductor current becomes discontinuous. This mode is called discontinuous-conduction mode (DCM). During DCM, the low-side N-channel power MOSFET turns on for around 80 ns when the bootstrap capacitor voltage drops below 4.2 V; then the lowside power MOSFET turns off and stays off until the beginning of the next cycle, where the high-side power MOSFET is turned on again. The 80-ns low-side MOSFET ON-time is required to ensure the bootstrap capacitor is always recharged and able to keep the high-side power MOSFET on during the next cycle. This is important for battery chargers, where unlike regular DC-DC converters, there is a battery load that maintains a voltage and can both source and sink current. The 80-ns low-side pulse pulls the PH node (connection between high and low-side MOSFETs) down, allowing the bootstrap capacitor to recharge up to the REGN LDO value. After the 80 ns, the low-side MOSFET is kept off to prevent negative inductor current from occurring. At very low currents during non-synchronous operation, there may be a small amount of negative inductor current during the 80-ns recharge pulse. The charge must be low enough to be absorbed by the input capacitance. Whenever the converter goes into zero-percent duty cycle, the high-side MOSFET does not turn on, and the low-side MOSFET does not turn on (only 80-ns recharge pulse) either, and there is almost no discharge from the battery. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 21 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Device Functional Modes (continued) During the DCM mode, the loop response automatically changes and has a single-pole system at which the pole is proportional to the load current, because the converter does not sink current, and only the load provides a current sink. This means at very low currents the loop response is slower, as there is less sinking current available to discharge the output voltage. POR SLEEP MODE VCC > SRN No Indicate SLEEP Yes Enable VREF LDO & Chip Bias Indicate battery absent Initiate battery detect algorithm Battery present? No See Enabling and Disabling Charge Section Yes Conditions met for charge? Indicate NOT CHARGING, Suspend timers No No Conditions met for charge? No Yes Yes Regulate precharge current VFB < VLOWV Start 30 minute precharge timer Yes Indicate ChargeIn-Progress Start Fastcharge timer No Indicate NOT CHARGING, Suspend timers VFB < VLOWV Yes No Regulate fastcharge current No Conditions met for charge? Yes Precharge timer expired? Yes Indicate ChargeIn-Progress No Turn off charge, Enable IDISCHG for 1 second Yes Indicate Charge In Progress VFB > VRECH & ICHG < ITERM FAULT Enable IFAULT No Fastcharge Timer Expired? Yes Indicate FAULT No Charge Complete VFB > VRECH VFB < VRECH No Yes Indicate DONE Battery Removed Yes Indicate BATTERY ABSENT Figure 14. Operational Flowchart for BQ24650 22 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 9 Application and Implementation NOTE Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality. 9.1 Application Information The evaluation module (BQ24650EVM-639) is a complete charger module for evaluating a stand-alone multi-cell Li-ion solar power charger using the BQ24650 device. 9.2 Typical Application Solar Cell Half Panel D1 VIN R6 R5 C1 VCC BQ24650 VREF C3 R9 C2 C4 R3 REGN BTST MPPSET Pack Thermistor R10 Q3 Q1 C6 HIDRV TS CE D2 L C5 PH R4 TERM_EN RSR Q2 LODRV C8 Battery Pack C9 GND VIN R7 D3 R8 C10 R2 SRP STAT1 C7 STAT2 Thermal Pad SRN R1 VFB D4 Solar Panel 21 V, MPPT = 18 V, 2-cell, ICHARGE = 2 A, IPRECHARGE = ITERM = 0.2 A, TS = 0 – 45°C Figure 15. Typical System Schematic 9.2.1 Design Requirements This design requires a 21-V solar panel charger for 2_cell and 2A Li-ion battery charger. 9.2.2 Detailed Design Procedure 9.2.2.1 Inductor Selection The BQ24650 has a 600-kHz switching frequency to allow the use of small inductor and capacitor values. Inductor saturation current must be higher than the charging current (ICHG) plus half the ripple current (IRIPPLE): ISAT ³ ICHG +(1/2)IRIPPLE (12) Inductor ripple current depends on input voltage (VIN), duty cycle (D = VOUT/VIN), switching frequency (fs), and inductance (L): V ´ D ´ (1 - D) IRIPPLE = IN fs × L (13) Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 23 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Typical Application (continued) The maximum inductor ripple current happens with D = 0.5 or close to 0.5. Usually inductor ripple is designed in the range of 20% to 40% of the maximum charging current as a trade-off between inductor size and efficiency for a practical design. 9.2.2.2 Input Capacitor The input capacitor should have enough ripple current rating to absorb input switching ripple current. The worstcase RMS ripple current is half of the charging current when duty cycle is 0.5. If the converter does not operate at 50% duty cycle, then the worst case capacitor RMS current ICIN occurs where the duty cycle is closest to 50% and can be estimated by Equation 14: ICIN = ICHG ´ D ´ (1 - D) (14) A low ESR ceramic capacitor such as X7R or X5R is preferred for the input decoupling capacitor and must be placed as close as possible to the drain of the high-side MOSFET and source of the low-side MOSFET. The voltage rating of the capacitor must be higher than the normal input voltage level. A 25-V rating or higher capacitor is preferred for a 20-V input voltage. A 20-μF capacitance is suggested for a typical 3-A to 4-A charging current. 9.2.2.3 Output Capacitor The output capacitor also should have enough ripple current rating to absorb output switching ripple current. The output capacitor RMS current ICOUT is given as: I ICOUT = RIPPLE » 0.29 ´ IRIPPLE 2 ´ 3 (15) The output capacitor voltage ripple can be calculated in Equation 16: DVO = VOUT æ V ç 1 - OUT 2 ç VIN 8LCfs è ö ÷ ÷ ø (16) At certain input/output voltages and switching frequencies, the voltage ripple can be reduced by increasing the output filter inductor and capacitor values. The BQ24650 has an internal loop compensator. To achieve good loop stability, the resonant frequency of the output inductor and output capacitor must be designed between 12 kHz and 17 kHz. The preferred ceramic capacitor has a 35 V or higher rating, X7R or X5R. Ceramic capacitors show a de-bias effect. This effect reduces the effective capacitance when a DC-bias voltage is applied across a ceramic capacitor, as on the output capacitor of a charger. The effect may lead to a significant capacitance drop, especially for high voltages and small capacitor packages. See the manufacturer’s datasheet about performance with a DC bias voltage applied. It may be necessary to choose a higher voltage rating or nominal capacitance value to achieve the required value at the operating point. 9.2.2.4 Power MOSFETs Selection Two external N-channel MOSFETs are used for a synchronous switching battery charger. The gate drivers are internally integrated into the IC with 6 V of gate drive voltage. 30 V or higher voltage rating MOSFETs are preferred for 20-V input voltage, and 40 V or higher rating MOSFETs are preferred for 20-V to 28-V input voltage. Figure-of-merit (FOM) is usually used for selecting a proper MOSFET based on a tradeoff between conduction loss and switching loss. For a top-side MOSFET, FOM is defined as the product of the MOSFET's on-resistance, RDS(on), and the gate-to-drain charge, QGD. For a bottom-side MOSFET, FOM is defined as the product of the MOSFET's on-resistance, RDS(on), and the total gate charge, QG. FOMtop = RDS(on) ´ QGD ; FOMbottom = RDS(ON) ´ QG (17) The lower the FOM value, the lower the total power loss. Usually a lower RDS(on) has a higher cost with the same package size. 24 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Typical Application (continued) Top-side MOSFET loss includes conduction loss and switching loss. It is a function of duty cycle (D = VOUT/VIN), charging current (ICHG), the MOSFET's on-resistance RDS(on), input voltage (VIN), switching frequency (F), turnon time (ton) and turnoff time (toff): 1 Ptop = D ´ ICHG2 ´ RDS(ON) + ´ VIN ´ ICHG ´ (t on + t off ) ´ F 2 (18) The first item represents the conduction loss. Usually MOSFET RDS(ON) increases by 50% with 100°C junction temperature rise. The second term represents switching loss. The MOSFET turnon and turnoff times are given by: Q Q t on = SW ; t off = SW Ion Ioff where • • • QSW is the switching charge, Ion is the turnon gate driving current, and Ioff is the turnoff gate driving current. (19) If the switching charge is not given in the MOSFET datasheet, it can be estimated by gate-to-drain charge (QGD) and gate-to-source charge (QGS): 1 QSW = QGD + ´ QGS 2 (20) The gate driving current total can be estimated by the REGN voltage (VREGN), MOSFET plateau voltage (VPLT), total turnon gate resistance (Ron), and turnoff gate resistance (Roff) of the gate driver: VREGN - Vplt Vplt Ion = ; Ioff = Ron Roff (21) The conduction loss of the bottom-side MOSFET is calculated in Equation 22 when it operates in synchronous continuous conduction mode: Pbottom = (1 - D) ´ ICHG2 ´ RDS(ON) (22) If the SRP-SRN voltage decreases below 5 mV (the charger is also forced into non-synchronous mode when the average SRP-SRN voltage is lower than 1.25 mV), the low-side FET is turned off for the remainder of the switching cycle to prevent negative inductor current. As a result, all of the freewheeling current goes through the body diode of the bottom-side MOSFET. The maximum charging current in non-synchronous mode can be up to 0.9 A (0.5 A typical) for a 10-mΩ charging current sensing resistor, considering the IC tolerance. Choose a bottom-side MOSFET with either an internal Schottky or body diode capable of carrying the maximum non-synchronous mode charging current. MOSFET gate driver power loss contributes to dominant losses on the controller IC, when the buck converter is switching. Choosing a MOSFET with a small Qg_total reduces power loss to avoid thermal shutdown. PICLOSS_Driver = VIN ´ Qg_total ´ fs where • Qg_total is the total gate charge for both the upper and lower MOSFETs at 6V VREGN. (23) 9.2.2.5 Input Filter Design During adapter hot plug-in, the parasitic inductance and the input capacitor from the adapter cable form a second order system. The voltage spike at the VCC pin may be beyond the IC maximum voltage rating and damage the IC. The input filter must be carefully designed and tested to prevent an overvoltage event on the VCC pin. There are several methods to damping or limiting the over-voltage spike during adapter hot plug-in. An electrolytic capacitor with high ESR as an input capacitor can damp the overvoltage spike well below the IC maximum pin voltage rating. A high current capability TVS Zener diode can also limit the over-voltage level to an IC safe level. However, these two solutions may not be lowest cost or smallest size. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 25 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Typical Application (continued) A cost-effective and small size solution is shown in Figure 16. R1 and C1 are composed of a damping RC network to damp the hot plug-in oscillation. As a result, the overvoltage spike is limited to a safe level. D1 is used for reverse voltage protection for the VCC pin. C2 is the VCC pin decoupling capacitor and it must be placed as close as possible to the VCC pin. R2 and C2 form a damping RC network to further protect the IC from high dv/dt and high voltage spike. The C2 value must be less than the C1 value so R1 can dominant the equivalent ESR value to get enough damping effect for hot plug-in. R1 and R2 must be sized enough to handle in-rush current power loss according to the resistor manufacturer’s datasheet. The filter component values always need to be verified with a real application. Table 3 lists the components for the typical application. D1 Adapter Connector R1(2010) 2W R2(1206) 4.7 - 30 W C1 2.2 mF VCC pin C2 0.1 - 1 mF Copyright © 2016, Texas Instruments Incorporated Figure 16. Input Filter Table 3. Component List for the Typical System Circuit in Figure 15 PART DESIGNATOR QTY DESCRIPTION Q1, Q2 2 N-channel MOSFET, 40-V, 10-A, PowerPAK SO-8, Vishay-Siliconix, Si7288 D2 1 Diode, Dual Schottky, 30-V, 200-mA, SOT-23, Fairchild, BAT54C D3, D4 2 LED Diode, Green, 2.1-V, 20-mA, LTST-C190GKT RSR 1 Sense Resistor, 20-mΩ, Vishay-Dale, WSL1206R0200DEA L1 1 Inductor, 10-µH, 7-A, Vishay-Dale IHLP-2525CZ C6, C8 2 Capacitor, Ceramic, 10-μF, 35-V, 20%, X7R, 1210, Panasonic C9 1 Capacitor, Ceramic, 4.7-μF, 35-V, 20%, X7R, 1210, Panasonic C2, C3, C4 3 Capacitor, Ceramic, 1-μF, 35-V, 10%, X7R, 0805, Kemet C5, C7 2 Capacitor, Ceramic, 0.1-μF, 35-V, 10%, X7R, 0805, Kemet C1 1 Capacitor, Ceramic, 2.2-μF, 35-V, 10%, X7R, 1210, Kemet C10 1 Capacitor, Ceramic, 22-pF, 35-V, 10%, X7R, 0603 Kemet R1 1 Resistor, Chip, 100-kΩ, 1/16-W, 0.5%, 0402 R2, R3 2 Resistor, Chip, 499-kΩ, 1/16-W, 0.5%, 0402 R4 1 Resistor, Chip, 36-kΩ, 1/16-W, 0.5%, 0402 R9 1 Resistor, Chip, 5.23-kΩ, 1/16-W, 1%, 0402 R10 1 Resistor, Chip, 30.1-kΩ, 1/16-W, 1%, 0402 R7, R8 2 Resistor, Chip, 10-kΩ, 1/16-W, 5%, 0402 R6 1 Resistor, Chip, 10-Ω, 1/4-W, 5%, 1206 R5 1 Resistor, Chip, 2-Ω, 1-W, 5%, 2012 D1 1 Diode, Schottky Rectifier, 40-V, 10-A, PDS1040 Q3 1 N-Channel MOSFET, 60-V, 115-mA, SOT-23, 2N7002DICT 9.2.2.6 MPPT Temperature Compensation A typical solar panel comprises of a lot of cells in a series connection, and each cell is a forward-biased p-n junction. So, the open-circuit voltage (VOC) of a solar cell has a temperature coefficient that is similar to a common p-n diode, or about –2 mV/°C. A crystalline solar panel specification always provides both open-circuit voltage VOC and peak power point voltage VMP. The difference between VOC and VMP can be approximated as fixed and temperature-independent, so the temperature coefficient for the peak power point is similar to that of VOC. Normally, panel manufacturers specify the 25°C values for VOC and VMP, and the temperature coefficient for VOC, as shown in Figure 17. 26 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 Panel Voltage - V VOC VMP 5 15 25 45 35 55 TA - Free-Air Temperature - °C Figure 17. Solar Panel Output Voltage Temperature Characteristics The BQ24650 employs a feedback network to the MPPSET pin to program the input regulation voltage. Because the temperature characteristic for a typical solar panel VMP voltage is almost linear, a simple solution for tracking this characteristic can be implemented by using an LM234 3-terminal current source, which can create an easily programmable, linear temperature dependent current to compensate the negative temperature coefficient of the solar panel output voltage. R21: 20W VIN Solar Panel R20 2Ω C21 2.2mF C21 0.47mF LM234 VCC R3 I1 RSET ISET VREG MPPSET R4 I2 BQ24650 Copyright © 2016, Texas Instruments Incorporated Figure 18. Feedback Network In the circuit shown in Figure 18, for the LM234 temperature sensor, 227 μV/ °K ISET = ´ Temp RSET (24) Thus, 0.0677V RSET (25) The current node equation is Equation 26: V V - VREG I2 = REG = I1 + ISET = IN + ISET R4 R3 (26) ISET (25°C) = To have a zero temperature coefficient on VREG, Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 27 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com d(VIN - VREG ) dI dI2 1 = × + SET = 0 dT dT R3 dT (27) æ -dVIN /dT ö 2mV × number of solar cells in series R3 = ç ÷ = RSET × dI /dT 227μV è SET ø VREG × R3 VMPPSET × R3 R4 = = æ (VIN + R3 × ISET ) - VREG 0.0677V ö ç VMP (25°C) + R3 × ÷ - VMPPSET RSET ø è (28) (29) For example, given a common 18-cell solar panel that has the following specified characteristics: Open-circuit voltage (VOC) = 10.3 V Maximum power voltage (VMP) = 9V Open-circuit voltage temperature coefficient (VOC) = –38 mV/°C Applying the following parameters into the equations of R3 and R4: 1. Temperature coefficient for VMP (same as that of VOC) of –38 mV/°C 2. Peak power voltage of 9 V 3. MPPSET regulation voltage of 1.2 V And choosing RSET = 1000 Ω. The resistor values are RSET = 1 kΩ, R3 = 167.4 kΩ, and R4=10.6 kΩ. Selecting standard 1% accuracy resistors and RSET = 1 kΩ, R3 = 169 kΩ, and R4=10.7 kΩ. 9.2.3 Application Curves MPPT Regulation Point VIN 5V/div VIN 20V/div VBAT 5V/div PH 20V/div IBAT 0.5A/div IL 1A/div 10 ms/div 1 s/div Figure 19. MPPT Regulation During Soft Start Figure 20. Battery Insertion and Removal VIN 20V/div VIN 20V/div VBAT 5V/div VBAT 5V/div PH 20V/div PH 20V/div IL 1A/div IL 1A/div 10 ms/div 400 ms/div Figure 21. Short Battery Response 28 Figure 22. Charge Reset During Battery Short Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 100 95 Efficiency - % ICHG 2A ICHG 1A 90 85 80 0 5 10 VO - Output Voltage - V 15 20 VCC = 25 V Figure 23. Efficiency vs Output Voltage 10 Power Supply Recommendations The BQ24650 requires a voltage source between 5 V and 28 V connected to VCC. and VCC can be supplied either from the battery or the adapter. If the VCC voltage is greater than the SRN voltage, BQ24650 exits the SLEEP mode. If the SRN voltage is greater than VCC, BQ24650 enters a low-quiescent current (< 15 μA) SLEEP mode to minimize current drain from the battery. 11 Layout 11.1 Layout Guidelines The switching node rise and fall times must be minimized for minimum switching loss. Proper layout of the components to minimize the high frequency current path loop (see Figure 24) is important to prevent electrical and magnetic field radiation and high frequency resonant problems. The following is a PCB layout priority list for proper layout. Layout of the PCB according to this specific order is essential. 1. Place input capacitor as close as possible to the switching MOSFET supply and ground connections and use the shortest copper trace connection. These parts must be placed on the same layer of the PCB instead of on different layers and using vias to make this connection. 2. The IC should be placed close to the switching MOSFET gate terminals, and the gate drive signal traces kept short for a clean MOSFET drive. The IC can be placed on the other side of the PCB of the switching MOSFETs. 3. Place the inductor input terminal as close as possible to the switching MOSFET output terminal. Minimize the copper area of this trace to lower electrical and magnetic field radiation but make the trace wide enough to carry the charging current. Do not use multiple layers in parallel for this connection. Minimize parasitic capacitance from this area to any other trace or plane. 4. The charging current sensing resistor must be placed right next to the inductor output. Route the sense leads connected across the sensing resistor back to the IC in the same layer, close to each other (minimize loop area) and do not route the sense leads through a high-current path (see Figure 25 for Kelvin connection for best current accuracy). Place decoupling capacitor on these traces next to the IC. 5. Place output capacitor next to the sensing resistor output and ground. 6. Output capacitor ground connections need to be tied to the same copper that connects to the input capacitor ground before connecting to system ground. 7. Route analog ground separately from power ground and use a single ground connection to tie charger power ground to charger analog ground. Just beneath the IC use analog ground copper pour but avoid power pins to reduce inductive and capacitive noise coupling. Connect analog ground to the GND pin. Use the thermal pad as a single ground connection point to connect analog ground and power ground together, or use a 0-Ω resistor to tie analog ground to power ground (thermal pad should tie to analog ground in this case). A starconnection under the thermal pad is highly recommended. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 29 BQ24650 SLUSA75B – JULY 2010 – REVISED JANUARY 2020 www.ti.com Layout Guidelines (continued) 8. It is critical that the exposed thermal pad on the backside of the IC package be soldered to the PCB ground. Ensure that there are sufficient thermal vias directly under the IC, connecting to the ground plane on the other layers. 9. Decoupling capacitors must be placed next to the IC pins and make trace connection as short as possible. 10. The number and physical size of the vias must be enough for a given current path. L1 SW R1 VBAT High Frequency VIN BAT Current C1 Path C2 PGND C3 Copyright © 2016, Texas Instruments Incorporated Figure 24. High Frequency Current Path 11.2 Layout Example Charge Current Direction R SNS To Inductor To Battery Current Sensing Direction To SRP and SRN pin Copyright © 2016, Texas Instruments Incorporated Figure 25. Sensing Resistor PCB Layout 30 Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 BQ24650 www.ti.com SLUSA75B – JULY 2010 – REVISED JANUARY 2020 12 Device and Documentation Support 12.1 Device Support 12.1.1 Third-Party Products Disclaimer TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE. 12.2 Receiving Notification of Documentation Updates To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper right corner, click on Alert me to register and receive a weekly digest of any product information that has changed. For change details, review the revision history included in any revised document. 12.3 Support Resources TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight from the experts. Search existing answers or ask your own question to get the quick design help you need. Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. 12.4 Trademarks E2E is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. 12.5 Electrostatic Discharge Caution These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. 12.6 Glossary SLYZ022 — TI Glossary. This glossary lists and explains terms, acronyms, and definitions. 13 Mechanical, Packaging, and Orderable Information The following pages include mechanical, packaging, and orderable information. This information is the most current data available for the designated devices. This data is subject to change without notice and revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation. Submit Documentation Feedback Copyright © 2010–2020, Texas Instruments Incorporated Product Folder Links: BQ24650 31 PACKAGE OPTION ADDENDUM www.ti.com 6-Feb-2020 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan Lead/Ball Finish MSL Peak Temp (2) (6) (3) Op Temp (°C) Device Marking (4/5) BQ24650RVAR ACTIVE VQFN RVA 16 3000 Green (RoHS & no Sb/Br) NIPDAU Level-2-260C-1 YEAR -40 to 85 PAS BQ24650RVAT ACTIVE VQFN RVA 16 250 Green (RoHS & no Sb/Br) NIPDAU Level-2-260C-1 YEAR -40 to 85 PAS (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of