bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 Li-Ion or Li-Polymer Battery Charger with Low Iq and Accurate Trickle Charge Check for Samples :bq24741 bq24742 FEATURES APPLICATIONS • • • • • • • • SW REGN LODR PGND 28 27 26 25 24 23 22 CE 1 21 DPMDET ACN 2 20 CELLS ACP 3 19 CSP 18 CSN 17 BAT bq24741/2 bq24741 QFN-28 LPMOD 4 ACDET 5 ACSET 6 16 ISET LPREF 7 15 IADAPT 8 9 10 11 12 13 14 EXTPWR FSET TOP VIEW VADJ • • Text for space VDAC • • • Text for space HIDRV • The bq24741/2 charges two, three, or four series Li+ cells, supporting up to 10 A of charge current, and is available in a 28-pin, 5x5-mm2 thin QFN package. VREF • The bq24741/2 is a high-efficiency, synchronous battery charger with integrated compensation, offering low component count for space-constrained Li-ion or Li-polymer battery charging applications. Ratiometric charge current and voltage programming allows high regulation accuracies, and can be either hardwired with resistors or programmed by the system power-management microcontroller using a DAC or GPIOs. BTST • DESCRIPTION AGND • Notebook and Ultra-Mobile PC Portable Data Capture Terminals Portable Printers Medical Diagnostics Equipment Battery Bay Chargers Battery Back-up Systems PVCC • • • NMOS-NMOS Synchronous Buck Converter Resistor-Programmable Switching Frequency between 300 kHz and 800 kHz 9 V-24 V Input Voltage Operation Range Support Two to Four Cells Analog Inputs with Ratiometric Programming via Resistors or DAC/GPIO – Charge Voltage (4-4.512 V/cell) – Charge Current (up to 10 A) – Adapter Current Limit for DPM High-Accuracy Voltage and Current Regulation – ±0.5% Charge Voltage Accuracy – ±3% Charge Current Accuracy – ±3% Adapter Current Accuracy – ±2% Input Current Sense Amp Accuracy 150 mA Trickle-charge Current with ±33% Accuracy Down to Zero Battery Voltage Safety Protection – Input Overvoltage Protection – Battery Overvoltage Protection – Charger Overcurrent Protection – Thermal Shutdown Protection – FET/Inductor/Battery Short Protection Status and Monitoring Outputs – Adapter Present Indicator – Programmable Input Power Detect with Adjustable Threshold – Dynamic Power Management (DPM) with Status Indicator – Current Drawn from Input Source Charge Enable Pin Internal Soft-Start and Loop Compensation 25 ns Minimum Driver Dead-Time and 99.5% Maximum Effective Duty Cycle 28-pin, 5x5-mm2 QFN package Energy Star Low Quiescent Current Iq – < 10 μA Off-State Battery Discharge Current – < 1.5 mA Off-State Input Quiescent Current TRICKL 1 1 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2009, Texas Instruments Incorporated bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. DESCRIPTION (CONTINUED) The bq24741/2 features resistor-programmable PWM switching frequency and accurate 150mA trickle charge (with 20 mΩ sensing resistor), which can be enabled via the TRICKLE pin. The bq24741/2 also features Dynamic Power Management (DPM) and input power limiting. These features reduce battery charge current when the input power limit is reached to avoid overloading the AC adapter when supplying the load and the battery charger simultaneously. A high-accuracy current sense amplifier enables accurate measurement of input current from the AC adapter, allowing monitoring the overall system power. If the adapter current is above the programmed low-power threshold, a signal is sent to host so that the system optimizes its power performance according to what is available from the adapter. Text for space Text for space R16 10 Ω SYSTEM ADAPTER + ADAPTER - R11 2Ω C1 2.2 µF P P Q1 (ACFET) Q2 (ACFET) SI4435 SI4435 Controlled by HOST C2 R1 0.1 µF 432 kΩ 1% RAC 0.010 Ω C6 10 µF C7 10 µF D2 BAT54 C3 0.1 µF ACN PVCC Q3(BATFET) SI4435 Controlled by HOST C8 0.1 µF ACP ACDET AGND R3 10 kΩ Q4_A FDS8978 HIDRV VREF SW EXTPWR EXTPWR N R2 66.5 kΩ 1% C9 BTST VREF R5 10 kΩ C4 1 µF D1 bq24741/2 REGN DPMDET GPIO HOST CELLS CE CSP VDAC CSN ISET BAT 10 kΩ 120 kΩ ISET_PWM (D = 0.72, Vpeak = VDAC) R14 Q4_B FDS8978 VREF C13 100 nF ADC LPREF IADAPT C5 100 pF C13 0.1 µF PGND VREF R12 102 kΩ 1% R13 64.9 kΩ 1% VREF R9 60.4 kΩ 1% ACSET VADJ PowerPad FSET C12 10 µF C11 10 µF LODRV LPMOD R15 PACK+ C10 1 µF TRICKLE RSR 0.020 Ω 10µH BAT54 0.1 µF N R4 10 kΩ L1 P R7 73.2 kΩ 1% PACK- C14 0.1 µF C15 0.1 µF R8 26.7 kΩ 1% R10 R6 40.2 kΩ 97.6 kΩ 1% Text for space FS = 400 kHz, 90 W Adapter, VADAPTER = 19 V, VBAT = 3-cell Li-Ion (4.2V/cell), Icharge = 3.6 A, Iadapter_limit = 4.0 A Figure 1. Typical System Schematic, Voltage, and Current Programmed by Resistor Text for space Text for space Text for space Text for space 2 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 Text for space R16 10 Ω SYSTEM ADAPTER + C1 2.2 µF RAC 0.010 Ω P P Q1 (ACFET) Q2 (ACFET) SI4435 SI4435 Controlled by HOST C2 R1 0.1 µF 432 kΩ 1% D2 BAT54 C7 10 µF C3 0.1 µF ACN PVCC Q3 (BATFET) SI4435 Controlled by HOST C8 0.1 µF ACP ACDET R2 66.5 kΩ 1% C6 10 µF bq24741/2 AGND EXTPWR SW EXTPWR C4 1 µF D1 REGN DPMDET LPMOD HOST 10 kΩ 120 kΩ ISET_PWM R14 (D = 0.72, Vpeak = VDAC) C13 0.1 µF LODRV PGND CE CSP VDAC CSN ISET BAT LPREF ACSET IADAPT PowerPad PACK- C14 0.1 µF C15 0.1 µF R8 26.7 kΩ 1% VADJ ADC Q4_B FDS8978 VREF R7 73.2 kΩ 1% C13 100 nF DAC PACK+ C12 10 µF C11 10 µF CELLS R15 RSR 0.020 Ω 4.7 µH C10 1 µF TRICKLE GPIO BAT54 0.1 µF N R5 10 kΩ L1 C9 BTST VREF R4 10 kΩ P Q4_A FDS8978 HIDRV VREF R3 10 kΩ N ADAPTER - R11 2Ω FSET R6 56.2 kΩ C5 100 pF Text for space (1) Pull-up rail could be either VREF or other system rail. (2) SRSET/ACSET could come from either DAC or resistor dividers. FS = 650 kHz, 90 W Adapter, VADAPTER = 19 V, VBAT = 3-cell Li-Ion (4.2V/cell), Icharge = 3.6 A, Iadapter_limit = 4.0 A Figure 2. Typical System Schematic, Voltage and Current Programmed by DAC ORDERING INFORMATION Part number Package bq24741 28-PIN 5 x 5 mm2 QFN Ordering Number (Tape and Reel) Quantity bq24741RHDR 3000 28-PIN 5 x 5 mm2 QFN bq24742 bq24741RHDT 250 bq24742RHDR 3000 bq24742RHDT 250 PACKAGE THERMAL DATA PACKAGE QFN – RHD (1) (1) (2) (2) θJA TA = 25°C POWER RATING DERATING FACTOR ABOVE TA = 25°C 39°C/W 2.36 W 0.028 W/°C For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI Web site at www.ti.com. This data is based on using the JEDEC High-K board and the exposed die pad is connected to a Cu pad on the board. This is connected to the ground plane by a 2x3 via matrix. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 3 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com Table 1. Pin Functions – 28-Pin QFN PIN NAME DESCRIPTION NO. CE 1 Charge-enable active-HIGH logic input. HI enables charge. LO disables charge. It has an internal 1 MΩ pull-down resistor. A 10 KΩ external resistor is required to connect the CE pin to the external pull-up rail other than VREF. ACN 2 Adapter current sense resistor, negative input. A 0.1 μF ceramic capacitor is placed from ACN to ACP to provide differential-mode filtering. An optional 0.1 μF ceramic capacitor is placed from ACN pin to AGND for common-mode filtering. ACP 3 Adapter current sense resistor, positive input. A 0.1 μF ceramic capacitor is placed from ACN to ACP to provide differential-mode filtering. A 0.1 μF ceramic capacitor is placed from ACP pin to AGND for common-mode filtering. LPMOD 4 Low-power-mode-detect active-LOW open-drain logic output. Place a 10kohm pull-up resistor from LPMOD pin to the pull-up voltage rail. The output is HI when IADAPT pin voltage is lower than LPREF pin voltage. The output is LOW when IADAPT pin voltage is higher than LPREF pin voltage. Internal 6% hysteresis. ACDET 5 Adapter detected voltage set input. Program the adapter detect threshold by connecting a resistor divider from adapter input to ACDET pin to AGND pin. Adapter voltage is detected if ACDET pin voltage is greater than 2.4 V. IADAPT current sense amplifier is active when ACDET pin voltage is greater than 0.6V and PVCC > VUVLO. ACOV is input over-voltage protection; it disables charge when ACDET > 3.1 V. ACOV does not latch, and normal operation resumes when ACDET < 3.1 V. ACSET 6 Adapter current set input. The voltage ratio of ACSET voltage versus VDAC voltage programs the input current regulation set-point during Dynamic Power Management (DPM). Program by connecting a resistor divider from VDAC to ACSET to AGND; or by connecting the output of an external DAC to the ACSET pin and connect the DAC supply to the VDAC pin. LPREF 7 Low power voltage set input. Connect a resistor divider from VREF to LPREF, and AGND to program the reference for the LOPWR comparator. The LPREF pin voltage is compared to the IADAPT pin voltage and the logic output is given on the LPMOD open-drain pin. Connect LPREF to ACSET through a resistor divider to track the adapter power. TRICKLE 8 Trickle current enable logic input. When CE is HIGH, a HIGH level on this pin enables accurate 150 mA trickle charge with 20 mΩ sense resistor. A LOW level on this pin enables the ISET pin to program the charge current. It has an internal 1MΩ pull-down resistor. AGND 9 Analog ground. Ground connection for low-current sensitive analog and digital signals. On PCB layout, connect to the analog ground plane, and only connect to PGND through the PowerPad underneath the IC. VREF 10 3.3 V regulated voltage output. Place a 1 μF ceramic capacitor from VREF to AGND pin close to the IC. This voltage could be used for ratio-metric programming of voltage and current regulation and for programming the LPREF threshold. VREF is also the voltage source for the internal circuit. VDAC 11 Charge voltage set reference input. Connect the VREF or external DAC voltage source to VDAC pin. Battery voltage, charge current, and input current are programmed as a ratio of the VDAC pin voltage versus the voltage on VADJ, and ACSET pin voltages, respectively. Place resistor dividers from VDAC to VADJ, ISET, and ACSET pins to AGND for programming. A DAC could be used by connecting the DAC supply to VDAC and connecting the output to VADJ, ISET, or ACSET. VADJ 12 Charge voltage set input. The voltage ratio of VADJ voltage versus VDAC voltage programs the battery voltage regulation set-point. Program by connecting a resistor divider from VDAC to VADJ, to AGND; or, by connecting the output of an external DAC to VADJ pin and connect the DAC supply to VDAC pin. EXTPWR 13 Valid adapter active-low detect logic open-drain output. Pulled LO when Input voltage is above ACDET programmed threshold OR input current is greater than 1.25 A with 10 mΩ sense resistor. Connect a 10 kΩ pull-up resistor from EXTPWR pin to pull-up supply rail. FSET 14 PWM switching frequency (Fs) program pin. Program the switching frequency by placing a resistor to AGND on this pin. IADAPT 15 Adapter current sense amplifier output. IADAPT voltage is 20 times the differential voltage across ACP-ACN. Place a 100pF (max) or less ceramic decoupling capacitor from IADAPT to AGND. ISET 16 Charge current set input. The voltage ratio of ISET voltage versus VDAC voltage programs the charge current regulation set-point. Program by connecting a resistor divider from VDAC to ISET, to AGND; or, by connecting the output of an external DAC to ISET pin and connect the DAC supply to VDAC pin. BAT 17 Battery voltage remote sense. Directly connect a kelvin sense trace from the battery pack positive terminal to the BAT pin to accurately sense the battery pack voltage. Place a 0.1 μF capacitor from BAT to AGND close to the IC to filter high frequency noise. CSN 18 Charge current sense resistor, negative input. A 0.1 μF ceramic capacitor is placed from CSN to CSP to provide differential-mode filtering. An optional 0.1 μF ceramic capacitor is placed from CSN pin to AGND for common-mode filtering. CSP 19 Charge current sense resistor, positive input. A 0.1 μF ceramic capacitor is placed from CSN to CSP to provide differential-mode filtering. A 0.1 μF ceramic capacitor is placed from CSP pin to AGND for common-mode filtering. CELLS 20 2, 3 or 4 cells selection logic input. Logic Lo programs 3–cell. Logic HI programs 4-cell. Floating programs 2–cell. 4 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 Table 1. Pin Functions – 28-Pin QFN (continued) PIN NAME DESCRIPTION NO. DPMDET 21 Dynamic power management (DPM) input current loop active, open-drain output status. Logic low (LO) indicates input current is being limited by reducing the charge current. Connect 10-kohm pull-up resistor from DPMDET pin to VREF or a different pull-up supply rail. PGND 22 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 in put and output capacitors of the charger. Only connect to AGND through the PowerPad underneath the IC. LODRV 23 PWM low side driver output. Connect to the gate of the low–side power MOSFET with a short and wide trace. REGN 24 PWM low side driver positive supply output. Connect a 1 μF ceramic capacitor from REGN to PGND pin, close to the IC. Use for low side driver and high-side driver bootstrap voltage by connecting a small signal Schottky diode from REGN to BTST. REGN is disabled when CE is LOW. SW 25 PWM high side driver negative supply. Connect to the Phase switching node (junction of the low-side power MOSFET drain, high-side power MOSFET source, and output inductor). Connect the 0.1 μF bootstrap capacitor from SW to BTST. HIDRV 26 PWM high side driver output. Connect to the gate of the high-side power MOSFET with a short trace. BTST 27 PWM high side driver positive supply. Connect a 0.1 μF bootstrap ceramic capacitor from BTST to SW. Connect a bootstrap Schottky diode from REGN to BTST. A optional 2.0Ω - 5.1Ω bootstrap resistor can be inserted between the BTST pin and the common point of the bootstrap capacitor and bootstrap diode, thus dampening the SW node voltage ring and spike. PVCC 28 IC power positive supply. Connect to the adapter input through a schottky diode. Place a 0.1 uF ceramic capacitor from PVCC to PGND pin close to the IC. PowerPad Exposed pad beneath the IC. AGND and PGND star-connected only at the PowerPad plane. Always solder PowerPad to the board, and have vias on the PowerPad plane connecting to AGND and PGND planes. It also serves as a thermal pad to dissipate the heat. ABSOLUTE MAXIMUM RATINGS over operating free-air temperature range (unless otherwise noted) (1) (2) VALUE PVCC, ACP, ACN, CSP, CSN, BAT Voltage range SW –1 to 30 REGN, LODRV, VADJ, ACSET, ISET, ACDET, FSET, IADAPT, LPMOD, LPREF, CE, CELLS, EXTPWR, DPMDET, TRICKLE –0.3 to 7 VDAC, VREF –0.3 to 3.6 BTST, HIDRV with respect to AGND and PGND –0.3 to 36 AGND, PGND Maximum difference voltage UNIT –0.3 to 30 V –1 to 1 ACP–ACN, CSP–CSN -0.5 to 0.5 Junction temperature range –40 to 155 °C Storage temperature range –55 to 155 °C (1) (2) 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. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 5 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com RECOMMENDED OPERATING CONDITIONS over operating free-air temperature range (unless otherwise noted) MIN SW Voltage range NOM –0.8 MAX UNIT 24 V PVCC, ACP, ACN, CSP, CSN, BAT 0 24 V REGN, LODRV 0 6.5 V VREF 3.3 V VDAC 3.6 V VADJ, ACSET, ISET, ACDET, FSET, IADAPT, LPMOD, LPREF, CE, CELLS, EXTPWR, DPMDET, TRICKLE 0 5.5 V BTST, HIDRV with respect to AGND and PGND 0 30 V V AGND, PGND –0.3 0.3 Maximum difference voltage: ACP–ACN, CSP–CSN –0.3 0.3 V Junction temperature range –40 125 °C Storage temperature range –55 150 °C ELECTRICAL CHARACTERISTICS 9.0 V ≤ VPVCC ≤ 24 V, 0°C < TJ < +125°C, Fs=600 kHz, typical values are at TA = 25°C, with respect to AGND (unless otherwise noted) (1) (2) (3) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT OPERATING CONDITIONS VPVCC_OP PVCC input voltage operating range 9 24 V CHARGE VOLTAGE REGULATION VBAT_REG_RNG BAT voltage regulation range VVDAC_OP VDAC reference voltage range VVADJ_OP VADJ voltage range 4-4.512 V per cell, times 2,3,4 cells Charge voltage regulation accuracy 8 18.048 V 2.6 3.6 V 0 VDAC V 8 V, 8.4 V, 9.024 V –0.5 0.5 12 V, 12.6 V, 13.536 V –0.5 0.5 16 V, 16.8 V, 18.048 V –0.5 0.5 0 100 0 VDAC VIREG_CHG = 40 mV –3% 3% VIREG_CHG = 20 mV –5% 5% VIREG_CHG = 5 mV –25% 25% VIREG_CHG = 3 mV (VBAT ≥ 4 V) –33% 33% VIREG_CHG = 3 mV (VBAT < 4 V) –50% 50% VBAT ≥ 4 V –1.0 1.0 VBAT < 4 V –1.5 1.5 –33% 33% –1.0 1.0 % CHARGE CURRENT REGULATION (ENABLE CE & DISABLE TRICKLE) VIREG_CHG Charge current regulation differential voltage range VISET_OP SRSET voltage range Charge current regulation accuracy Off-set Voltage of Amplifier VIREG_CHG = VCSP – VCSN mV V mV TRICKLE CHARGE CURRENT REGULATION (ENABLE CE & TRICKLE) Charge Current Regulation Accuracy VIREG_CHG = 3 mV Off-set Voltage of Amplifier (1) (2) (3) 6 mV Verified by design Deglitch time and delay are proportional to the period of oscillator, unless specified. When CE=HIGH, the internal oscillator frequency is equal to external setting Fs; when CE=LOW, the internal oscillator frequency is fixed internal setting 700 kHz. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 ELECTRICAL CHARACTERISTICS (continued) 9.0 V ≤ VPVCC ≤ 24 V, 0°C < TJ < +125°C, Fs=600 kHz, typical values are at TA = 25°C, with respect to AGND (unless otherwise noted) (1) (2) (3) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 0 100 mV 0 VDAC VIREG_DPM = 40 mV –3% 3% VIREG_DPM = 20 mV –5% 5% VIREG_DPM = 5 mV –25% 25% VIREG_DPM = 1.5 mV –33% 33% -500 500 INPUT CURRENT REGULATION VIREG_DPM Adapter current regulation differential voltage range VACSET_OP ACSET voltage range VIREG_DPM = VACP – VACN Input current regulation accuracy Off-set Voltage of Amplifier V μV VREF REGULATOR VVREF_REG VREF regulator voltage VACDET > 0.6 V, 0-30 mA IVREF_LIM VREF short current limit VVREF = 0 V, VACDET > 0.6 V 3.267 35 3.3 3.333 VREGN_REG REGN regulator voltage VACDET > 0.6 V, 0-75 mA, PVCC > 10 V 5.6 6.2 V IREGN_LIM REGN short current limit VREGN = 0 V, VACDET > 0.6 V 90 145 mA 0 24 0 2 80 V mA REGN REGULATOR 5.9 ADAPTER CURRENT SENSE AMPLIFIER VACP/N_OP Input common mode range VIADAPT IADAPT output voltage range Voltage on ACP/ACN IIADAPT IADAPT output current AIADAPT Current sense amplifier voltage gain 0 AIADAPT = VIADAPT / VIREG_DPM Adapter current sense accuracy 1 20 –2% VIREG_DPM = 20 mV –4% 4% VIREG_DPM = 5 mV –25% 25% VIREG_DPM = 1.5 mV –33% 33% Output short current limit VIADAPT = 0 V CIADAPT_MAX Maximum output load capacitance For stability with 0 mA to 1 mA load mA V/V VIREG_DPM = 40 mV IIADAPT_LIM V 2% 1 mA 100 pF ACDET COMPARATOR (INPUT UNDER_VOLTAGE, ACVGOOD) VACDET_CHG ACDET adapter-detect rising threshold Min voltage to enable charging, VACDET rising VACDET_CHG_HYS ACDET falling hysteresis VACDET falling, PVCC>8V 40 mV ACDET rising deglitch to turn on EXTPWR FET (4) VACDET rising, PVCC>8V 1.2 ms VACDET rising, PVCC>8V, CE=HIGH ACDET rising deglitch to enable charge TACDET_EXTPWR (4) 2.376 2.40 2.424 V 333 ms ACDET falling deglitch to turn off EXTPWR VACDET falling, PVCC>8V FET (4) 80 μs ACDET falling deglitch to disable charge (4) VACDET falling, PVCC>8V 80 Power-up delay from VACDET>2.4V to EXTPWR FET turn-on (4) First time power up, Fs = 300 kHz – 800 kHz μs 2 ms 300 mV AC CURRENT DETECT COMPARATOR (INPUT UNDER_CURRENT, ACIGOOD) VACIDET Adapter current detect falling threshold VACI = 20 X IAC x RAC, falling edge VACIDE_HYS Adapter current detect hysteresis Rising edge 50 mV IADAPT rising 10 μs IADAPT falling 10 μs Adapter current detect deglitch (4) 200 250 Verified by design Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 7 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com ELECTRICAL CHARACTERISTICS (continued) 9.0 V ≤ VPVCC ≤ 24 V, 0°C < TJ < +125°C, Fs=600 kHz, typical values are at TA = 25°C, with respect to AGND (unless otherwise noted) (1) (2) (3) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 24 V 850 900 950 mV 200 225 250 mV PVCC / BAT COMPARATOR VPVCC_BAT_OP Differential Voltage from PVCC to BAT VPVCC-BAT_FALL PVCC to BAT falling threshold VPVCC-BAT__HYS PVCC to BAT hysteresis -20 VPVCC – VBAT to disable charge PVCC to BAT rising deglitch VPVCC – VBAT > VPVCC-BAT_RISE 4.5 ms PVCC to BAT falling deglitch VPVCC – VBAT < VPVCC-BAT_FALL 10 μs BAT OVERVOLTAGE COMPARATOR VOV_RISE Overvoltage rising threshold (5) As percentage of VBAT_REG 104% VOV_FALL Overvoltage falling threshold (5) As percentage of VBAT_REG 102% BATSHORT COMPARATOR VBATSHORT_RISE Battery rising voltage for BATSHORT exit VBATSHORT_FALL Battery falling voltage for BATSHORT entry 2 V/Cell 1.7 V/Cell CHARGE OVERCURRENT COMPARATOR VOC_peak Peak charge over-current threshold V(CSP- CSN), when VISET / VDAC < 0.8 90 110 130 mV V(CSP- CSN), when VISET / VDAC ≥ 0.8 100 125 150 mV MOSFET SHORT PROTECTION COMPARATOR VHS High-side Threshold (bq24741) Measured on ACP-SW 120 250 455 mV VHS High-side Threshold (bq24742) Measured on ACP-SW 475 750 1065 mV VLS Low-side Threshold Measured on SW-AGND 90 160 320 mV CHARGE UNDERCURRENT PROTECTION COMPARATOR (UCP) VUCP Charge under-current threshold, falling edge V(CSP- CSN) from synchronous to non-synchronous operation 25 30 35 mV Charge under-current threshold, rising edge V(CSP-CSN) from non-synchronous to synchronous operation 35 40 45 mV Charge under-current rising deglitch 10 μs Charge under-current falling deglitch 320 μs INPUT OVERVOLTAGE COMPARATOR (ACOV) VACOV AC over-voltage rising threshold on ACDET Measure on ACDET pin 3.007 3.1 3.193 V VACOV_HYS AC over-voltage deglitch (rising edge) 650 μs AC over-voltage deglitch (falling edge) 650 μs INPUT UNDERVOLTAGE LOCK-OUT COMPARATOR (UVLO) VUVLO AC under-voltage rising threshold VUVLO_HYS AC under-voltage hysteresis Measured on PVCC pin 7 8 9 260 V mV INPUT LOW POWER MODE COMPARATOR (LPMOD) VACLP_HYS AC low power mode comparator internal hysteresis VACLP_OFFSET AC low power mode comparator offset voltage 5% 7% 1 mV 155 °C 20 °C THERMAL SHUTDOWN COMPARATOR TSHUT Thermal shutdown rising temperature TSHUT_HYS Thermal shutdown hysteresis, falling Temperature Increasing PWM HIGH SIDE DRIVER (HIDRV) RDS_HI_ON High side driver turn-on resistance VBTST – VSW = 5.5 V, tested at 100 mA 6 Ω RDS_HI_OFF High side driver turn-off resistance VBTST – VSW = 5.5 V, tested at 100 mA 1.4 Ω VBTST_REFRESH Bootstrap refresh comparator threshold voltage VBTST – VSW when low side refresh pulse is requested IBTST_LEAK BTST leakage current High side is on; charge enabled (5) 8 4 V 200 μA Verified by design Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 ELECTRICAL CHARACTERISTICS (continued) 9.0 V ≤ VPVCC ≤ 24 V, 0°C < TJ < +125°C, Fs=600 kHz, typical values are at TA = 25°C, with respect to AGND (unless otherwise noted) (1) (2) (3) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT PWM LOW SIDE DRIVER (LODRV) RDS_LO_ON Low side driver turn-on resistance REGN = 6 V, tested at 100 mA 6 Ω RDS_LO_OFF Low side driver turn-off resistance REGN = 6 V, tested at 100 mA 1.2 Ω PWM DRIVERS TIMING Driver Dead Time between HIDRV and LODRV 25 ns PWM OSCILLATOR FS Programmable PWM switching frequency range RFSET=130 kΩ - 45 kΩ 300 PWM switching frequency accuracy 800 -20% kHz 20% RAMP amplitude 1.33 V DC offset of RAMP 300 mV QUIESCENT CURRENT Total off-state quiescent current into pins: CSP, CSN, BAT, BTST, SW, PVCC, ACP, ACN VBAT = 16.8 V, VACDET < 0.6 V, VPVCC > 8 V, TJ = 0 to 125°C Total off-state battery current from ACP, ACN VBAT = 16.8 V, VACDET < 0.6 V, VPVCC > 8 V, TJ = 0 to 125°C Battery on-state quiescent current VBAT = 16.8 , 0.6 V < VACDET < 2.4 V, VPVCC > 8V IBATQ_CD Total quiescent current into CSP, CSN, BAT, PVCC, BTST, SW Adapter present, VACDET > 2.4 V, charge disabled IAC Adapter quiescent current VPVCC = 20 V, charge disabled IOFF_STATE IBAT_ON 7 11 μA 1 μA 1 mA 100 200 μA 1 1.5 mA INTERNAL SOFT START (8 steps to regulation current) Soft start steps 8 Soft start time of each step (512 PWM cycles) step μs 853 LOGIC INPUT PIN CHARACTERISTICS (CE, TRICKLE) VIN_LO Input low threshold voltage VIN_HI Input high threshold voltage RPULLDOWN PIN pull down resistance inside IC TCE_ENCHARGE 0.8 2.1 Delay from CE=HIGH to charge enable (6) V V = 0 to VREGN 1 MΩ Fs=300 kHz - 800 kHz 2 ms LOGIC INPUT PIN CHARACTERISTICS (CELLS) VIN_LO Input low threshold voltage, 3 cells CELLS voltage falling edge Input float threshold voltage, 2 cells CELLS voltage rising for MIN, CELLS voltage falling for MAX 0.8 VIN_HI Input high threshold voltage, 4 cells CELLS voltage rising 2.5 IBIAS_FLOAT Input bias float current for 2 cell selection VCE = 0 to VREGN –1 VIN_FLOAT 0.5 1.8 V 1 μA OPEN-DRAIN LOGIC OUTPUT PIN CHARACTERISTICS ( EXTPWR, DPMDET, LPMOD) VOUT_LO Output low saturation voltage Sink Current = 5 mA Leakage current Pull up to 3.3 v DPMDET delay, both edge (6) 0.5 V 1 μA 5 ms Verified by design Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 9 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com TYPICAL CHARACTERISTICS Table 2. Table of Graphs (1) Fs=400 kHz, Ta = 25 °C Y X Figure VREF Load and Line Regulation vs Load Current Figure 3 REGN Load and Line Regulation vs Load Current Figure 4 BAT Voltage vs VADJ/VDAC Ratio Figure 5 BAT Voltage Regulation Accuracy vs Setpoint Figure 6 Charge Current vs ISET/VDAC Ratio Figure 7 Charge Current Regulation Accuracy vs V(CSP-CSN) Setpoint Figure 8 Input Current vs ACSET/VDAC Radio Figure 9 DPM Accuracy vs V(ACP-ACN) Setpoint Figure 10 BAT Voltage Regulation Accuracy vs Charge Current Figure 11 V_IADAPT Accuracy vs V(ACP-ACN) Voltage Figure 12 Trickle Charge Current vs BAT Voltage Figure 13 DPM and Charge Current vs System Current Figure 14 REF, REGN, and EXTPWR Startup (CE=HIGH) Figure 15 Transient System Load (DPM) Response Transition Figure 16 Transient Response of IADAPT and LPMOD Figure 17 Battery Overcurrent Protection (OCP) Figure 18 Battery to Ground Short Transition Figure 19 Battery to Ground Short Protection Figure 20 Charge Enable and Current Soft-Start Figure 21 Charge Disable Figure 22 Trickle Disable and Current Soft-Start Figure 23 Synchronous to Non-synchronous Transition Figure 24 Non-synchronous to Synchronous Transition Figure 25 Continuous Conduction Mode Switching Waveforms Figure 26 Near 100% Duty Cycle Bootstrap Recharge Pulse Figure 27 Efficiency vs Battery Charge Current Figure 28 Switch Frequency vs Setting Resistor Figure 29 (1) 10 Test results based on Figure 2 application schematic. VIN = 20 V, VBAT = 3-cell Li-Ion, ICHG = 3 A, IADAPTER_LIMIT = 4 A, TA = 25°C, unless otherwise specified. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 VREF LOAD AND LINE REGULATION vs Load Current REGN LOAD AND LINE REGULATION vs LOAD CURRENT 0 0.50 -0.50 Regulation Error - % Regulation Error - % 0.40 0.30 PVCC = 10 V 0.20 0.10 0 -1 -1.50 PVCC = 10 V -2 PVCC = 20 V -0.10 -2.50 -0.20 -3 PVCC = 20 V 0 10 20 30 VREF - Load Current - mA 40 50 0 30 40 50 60 REGN - Load Current - mA 70 Figure 4. BAT VOLTAGE vs VADJ/VDAC RATIO BAT VOLTAGE REGULATION ACCURACY vs SETPOINT 80 0.06 3-Cell 13.4 0.05 0.04 13.2 Regulation Error (%) Voltage Regulation - V 20 Figure 3. 13.6 13 12.8 12.6 12.4 0.03 0.02 0.01 0 -0.01 12.2 12 10 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 -0.02 12 1 12.2 12.4 12.6 12.8 13 13.2 13.4 13.6 VBAT_reg Setpoint (V) VADJ/VDAC Ratio Figure 5. Figure 6. CHARGE CURRENT vs ISET/VDAC CHARGE CURRENT REGULATION ACCURACY vs V(CSP-CSN) SETPOINT 5 25 4.5 20 3.5 Regulation Error - % Input Current Regulation - A 3-Cell 4 3 2.5 2 1.5 1 15 10 5 0.5 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 0 10 20 ACSET/VDAC Ratio 30 40 50 60 70 80 90 100 ICHG_reg Setpoint (mV) Figure 7. Figure 8. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 11 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com INPUT CURRENT vs ACSET/VDAC RATIO DPM ACCURACY vs V(ACP-ACN) SETPOINT 2 10 9 0 Regulation Error - % Input Current Regulation - A 3-Cell 8 7 6 5 4 3 2 -2 -4 -6 -8 1 -10 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 0 1 10 30 20 VACSET/VDAC 40 50 60 70 IIN_reg Setpoint (mV) Figure 9. Figure 10. BAT VOLTAGE REGULATION ACCURACY vs CHARGE CURRENT V_IADAPT ACCURACY vs V(ACP-ACN) VOLTAGE 0.030 80 90 100 0.00% 0.025 -1.00% V_IADAPT Error Regulation Voltage Accuracy (%) -0.50% 0.020 0.015 0.010 -1.50% -2.00% -2.50% -3.00% -3.50% -4.00% 0.005 -4.50% -5.00% 0.000 0 0.5 1.5 1 3 2.5 2 3.5 0 4 10 30 20 Charge Current (A) 60 70 Figure 12. TRICKLE CHARGE CURRENT vs BAT VOLTAGE DPM and CHARGE CURRENT vs SYSTEM CURRENT 80 90 100 4.5 4 VBAT 0 V to 12.6 V 3.5 0.16 Ichrg & Iin (A) Trickle Charge Current (A) 50 Figure 11. 0.165 0.155 0.15 Input Current 3 2.5 2 Charge Current 1.5 1 VBAT 12.6 V to 0 V 0.5 0.145 0 0 2 4 6 8 10 12 14 0 0.5 BAT Voltage (V) 1 1.5 2 2.5 3 3.5 4 System Current (A) Figure 13. 12 40 V(ACP-ACN) (mV) Figure 14. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 TRANSIENT SYSTEM LOAD (DPM) RESPONSE TRANSITION 2 A/div 20 V/div REF, REGN, and EXTPWR STARTUP (CE=HIGH) Isys 5 v/div 2 V/div 2 A/div 2 V/div 2 A/div EXTPWR IIN Ibat Time = 200 μs/div Figure 16. TRANSIENT RESPONSE of IADAPT and LPMOD BATTERY OVERCURRENT PROTECTION (OCP) 5 V/div Figure 15. VBAT 2 A/div ISYS IL LPMOD 20 V/div Iadapt SW 5 v/div 2 V/div 0.2 V/div 2 A/div Time =400 μs/div LODRV Time = 20 μs/div Figure 18. BATTERY TO GROUND SHORT TRANSITION BATTERY TO GROUND SHORT PROTECTION 2 A/div Figure 17. IL 10 V/div 10 V/div 2 A/div Time = 100 μs/div Vbat VBAT SW 20 V/div 5 v/div 20 V/div SW 5 V/div IL LODRV LODRV Time = 10 μs/div Time = 2 ms/div Figure 19. Figure 20. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 13 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com CHARGE ENABLE and CURRENT SOFT-START 2 V/div 2 A/div IL 2 A/div 20 V/div 5 V/div 20 V/div 20 V/div CE 5 V/div CHARGE DISABLE SW LODRV Time = 4 μs/div 5 V/div Time = 2 ms/div Figure 21. Figure 22. TRICKLE DISABLE and CURRENT SOFT-START SYNCHRONOUS to NON-SYNCHRONOUS TRANSITION TRICKLE 5 V/div LODRV LODRV 1 A/div 1 A/div 20 V/div SW 5 V/div 10 V/div SW IL IL Time = 2 ms/div Figure 23. Figure 24. NON-SYNCHRONOUS to SYNCHRONOUS TRANSITION CONTINUOUS CONDUCTION MODE SWITCHING WAVEFORMS 2 A/div 20 V/div 5 V/div 10 V/div 10 V/div SW LODRV 1 A/div 5 V/div Time = 2 μs/div IL HIDRV LODRV SW IL Time = 200 ns/div Time = 2 μs/div Figure 25. 14 Figure 26. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 EFFICIENCY vs BATTERY CHARGE CURRENT 100 VPH 4-Cell 16.8 V 95 VHIDRV Efficiency (%) 2 A/div 5 V/div 20 V/div 20 V/div NEAR 100% DUTY CYCLE BOOTSTRAP RECHARGE PULSE VLODRV 3-Cell 12.6 V 90 85 IL 80 0 0.5 1 Time = 4 ms/div Figure 27. 1.5 2.5 2 Charge Current (A) 3 3.5 4 Figure 28. SWITCH FREQUENCY vs SETTING RESISTOR 1200 Measurment Calculation 1000 Fsw (kHz) 800 600 400 200 0 0 50 100 150 R_FET (kOhm) 200 250 300 Figure 29. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 15 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com FUNCTIONAL BLOCK DIAGRAM ENA_BIAS_CMP - 0.6V EXTPWR ACGOOD + VREFGOOD 3.3V LDO ENA_BIAS VAC20X PVCC 250mV +- + - UVLO AC_IGOOD PVCC-BAT ACP FBO + 20X - + IIN_REG - EAO VAC20X PVCC + EAI + - ACDET VREF AC_VGOOD - 2.4V + BAT 900mV IIN_ER CE COMP ERROR AMPLIFIER - ACN 1 MΩ BTST CE + BAT VBAT_REG BAT_ER 1V + LEVEL SHIFTER - HIDRV CSP 20 µA 3.5 mA + 20X - VSR20X ICH_ER + BAT_SHORT - CSN DC-DC CONVERTER PWM LOGIC SW PVCC-BAT 3.5 mA SYNCH 20 µA PVCC AC_VGOOD CHRG_ON REGN 6V LDO CLK IBAT_ REG 60mV VREFGOOD CE TRICKLE - BTST + 4V _ OSC CLK SW ACSET PGND IC Tj + 155 °C - TSHUT + VAC20X SRSET VBATSET IBATSET IINSET VADJ LODRV + 1 MΩ FSET REFRESH CBTST RATIO PROGRAM V(IADAPT) VBAT_REG IBAT_REG 104% X VBAT_REG - BAT + 2.08 V / 2.5 V - VSR20X + ACDET + IADAPT BAT_OVP IIN_REG DPMDET DPM_LOOP_ON CHG_OCP VDAC CELLS + ACOV - VSR20X + 30mV - 1.7 V + BAT - SYNCH 3.1V VAC20X LPREF + PVCC LPMOD - UVLO BAT_SHORT AGND + 8V +- PGND bq24741/2 16 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 DETAILED DESCRIPTION Converter Operation The synchronous buck PWM converter uses a programmable-frequency (300 kHz to 800 kHz) voltage mode 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 should be selected to give a nominal resonant frequency within 8 kHz to 12.5 kHz to have good loop compensation. Where resonant frequency, fo, is give by: 1 fo = 2p Lo Co (1) Where Lo, Co are the total output filter inductance and capacitance 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 fixed 1.33 V. The ramp is offset by 300 mV in order 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 SW pin voltage falls below 4 V, 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 SW node down and recharge the BTST capacitor. Then the high-side driver returns to 100% duty-cycle operation until the (BTST-SW) voltage is detected to fall low again due to leakage current discharging the BTST capacitor below the 4 V, and the reset pulse is reissued. The 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. The charge current sense resistor RSR should be placed with at least half or more of the total output capacitance placed before the sense resistor contacting both sense resistor and the output inductor; and the other half or remaining capacitance placed after the sense resistor. The output capacitance should be divided and placed onto both sides of the charge current sense resistor. A ratio of 50:50 percent gives the best performance; but the node in which the output inductor and sense resistor connect should have a minimum of 50% of the total capacitance. This capacitance provides sufficient filtering to remove the switching noise and give better current sense accuracy. The type III compensation provides Phase boost near the cross-over frequency, giving sufficient Phase margin. Synchronous and Non-Synchronous Operation The charger operates in non-synchronous mode when the sensed charge current is below the charge under-current comparator threshold (30 mV). Otherwise, the charger operates in synchronous mode. This part is designed for 20 mΩ charge current sense resistor and the SYNC/NON-SYNC threshold is 1.5 A. If 10 mΩ is used, the SYNC/NON-SYNC threshold will be 3 A. During synchronous mode, the low-side n-channel power MOSFET is on, when the high-side n-channel power MOSFET is off. The internal gate drive logic ensures there is break-before-make switching to prevent shoot-through currents. During the 25 ns dead time where both FETs are off, the back-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 operates in Continuous Conduction Mode (CCM), creating a fixed two-pole system. During non-synchronous operation, the low side MOSFET will stay off during the off-time unless the voltage on the bootstrap capacitor drops below 4 V. If this occurs, the high side FET will be turned off and the 80ns low-side MOSFET recharge pulse will be initiated. The 80 ns pulse pulls the SW node (connection between high and low-side MOSFET) 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. The inductor current is blocked by the off low-side MOSFET, and the inductor current will become discontinuous. This mode is called Discontinuous Conduction Mode (DCM). Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 17 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com 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. At very low currents during non-synchronous operation, there may be a small amount of negative inductor current during the 80ns recharge pulse. The charge should 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 (no 80ns recharge pulse) either, and there is no discharge from the battery. Battery Voltage Regulation The bq24741/2 uses a high-accuracy voltage regulator for charging voltage. The regulation voltage is ratio-metric with respect to VDAC. The ratio of VADJ and VDAC provides extra 12.5% adjust range on VBATT regulation voltage. By limiting the adjust range to 12.5% of the regulation voltage, the external resistor mismatch error is reduced from ±1% to ±0.1%. Therefore, an overall voltage accuracy as good as 0.5% is maintained, while using 1% mis-match resistors. Ratio-metric conversion also allows compatibility with D/As or microcontrollers (μC). The battery voltage is programmed through VADJ and VDAC using the following equation: é æ öù V VBATT = cell count ´ ê 4 V + ç 0.512 ´ VADJ ÷ ú V VDAC ø ú è ëê û (2) The input voltage range of VDAC is between 2.6V and 3.6V. VADJ is set between 0 and VDAC. CELLS pin is the logic input for selecting cell count. Connect CELLS to charge 2, 3, or 4 Li+ cells. When charging other cell chemistries, use CELLS to select an output voltage range for the charger. Table 3. Cell-Count Selection CELLS CELL COUNT Float 2 AGND 3 VREF 4 The per-cell battery termination voltage is function of the battery chemistry. Consult the battery manufacturer to determine this voltage. The BAT pin is used to sense the battery voltage for voltage regulation and should be connected as close to the battery as possible, or directly on the output capacitor. A 0.1μF ceramic capacitor from BAT to AGND is recommended to be as close to the BAT pin as possible to decouple high frequency noise. Battery Current Regulation The ISET input sets the maximum charging current. Battery current is sensed by resistor RSR connected between CSP and CSN. The full-scale differential voltage between CSP and CSN is 100 mV. Thus, for a 0.020 Ω sense resistor, the maximum charging current is 5 A. ISET is ratio-metric with respect to VDAC using the following equation: ICHARGE = VISET 0.10 ´ VVDAC R SR (3) The input voltage range of ISET is between 0 and VDAC, up to 3.6 V. The CSP and CSN pins are used to sense across RSR with default value of 20 mΩ. However, resistors of other values can also be used. For a larger the sense resistor, you get a larger sense voltage, and a higher regulation accuracy; but, at the expense of higher conduction loss. 18 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 Trickle Charge Current Regulation The TRICKLE pin is provided to allow accurate current regulation at very low charge current. When CE is set to HIGH, a logic HIGH level is applied to the TRICKLE pin, the charger will regulate 3 mV from CSP to CSN (150 mA with a 20 mΩ sense resistor), regardless of the voltage applied to the ISET pin. When TRICKLE is LOW, ISET is used to program the charge current. Input Adapter Current Regulation The total input current from an AC adapter or other DC sources is a function of the system supply current and the battery charging current. System current normally fluctuates as portions of the systems are powered up or down. Without Dynamic Power Management (DPM), the source must be able to supply the maximum system current and the maximum charger input current simultaneously. By using DPM, the input current regulator reduces the charging current when the input current exceeds the input current limit set by ACSET. The current capacity of the AC adapter can be lowered, reducing system cost. Similar to setting battery-regulation current, adapter current is sensed by resistor RAC connected between ACP and ACN. Its maximum value is set by ACSET, which is ratiometric with respect to VDAC, using Equation 4. IADAPTER = VACSET 0.10 ´ VVDAC R AC (4) The input voltage range of ACSET is between 0 and VDAC, up to 3.6 V. The ACP and ACN pins are used to sense RAC with a default value of 10 mΩ. However, resistors of other values can also be used. A larger sense-resistor value yields a larger sense voltage, and a higher regulation accuracy. However, this is at the expense of a higher conduction loss. Adapter Detect and Power Up An external resistor voltage divider attenuates the adapter voltage before it goes to ACDET. The adapter detect threshold should typically be programmed to a value greater than the maximum battery voltage and lower than the minimum allowed adapter voltage. The ACDET divider should be placed before the ACFET in order to sense the true adapter input voltage whether the ACFET is on or off. If ACDET is below 0.6 V but PVCC is above 8 V, part of the bias is enabled, including a crude bandgap reference, IADAPT is disabled and pulled down to GND. The total quiescent current is less than 10 μA. Once ACDET rises above 0.6 V and PVCC is above 8 V, all the bias circuits are enabled and VREF goes to 3.3 V; and REGN output goes to 6 V if CE is HIGH. IADAPT becomes valid to proportionally reflect the adapter current. When ACDET keeps rising and passes 2.4 V, a valid AC adapter is present. 8 ms later, charge is allowed to turn on. Programming the PWM Switching Frequency To program the PWM switching frequency, place a resistor from the FSET pin to ground, according to the following formula: R FSET = 41 ´ 103 - 6.25 (k W ) Fs (5) Where RFSET (kΩ) is the resistor from the FSET pin to ground, and Fs (kHz) is the desired switching frequency. The switching frequency should be programmed between 300 kHz and 800 kHz. Enable and Disable Charging The following conditions must be valid before the charge function is enabled: • CE is HIGH • Adapter is detected • Adapter voltage is higher than PVCC-BAT threshold • Adapter is not over voltage • The VREF and REGEN regulators are above 90% of the final values Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 19 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 • • www.ti.com Thermal Shut (TSHUT) is not active The PWM frequency is programmed inside the allowable range There’s a 2ms charge enable delay from when adapter is detected to when the charger is allowed to turn on. One of the following conditions will stop on-going charging: • CE is LOW • Adapter is removed • Adapter Voltage is lower than PVCC-BAT threshold • Adapter is over voltage • Adapter is over current • TSHUT IC temperature threshold is reached (155 °C on rising-edge with 20 °C hysteresis). Automatic Internal Soft-Start Charger Current The charger automatically soft-starts the charger regulation current every time the charger is enabled 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 around 1ms, for a typical rise time of 8ms. No external components are needed for this function. High Accuracy IADAPT Using Current Sense Amplifier (CSA) An industry standard, high accuracy current sense amplifier (CSA) is used to monitor the input current by the host or some discrete logic through the analog voltage output of the IADAPT pin. The CSA amplifies the input sensed voltage of ACP–ACN by 20x through the IADAPT pin. The IADAPT output is a voltage source 20 times the input differential voltage. Once PVCC is above 8 V and ACDET is above 0.6 V, IADAPT no longer stays at ground, but becomes active. If the user wants to lower the voltage, they could use a resistor divider from IOUT to AGND, and still achieve accuracy over temperature as the resistors can be matched their thermal coefficients. Input Overvoltage Protection (ACOV) ACOV provides protection to prevent system damage due to high input voltage. Once the adapter voltage is 30% above adapter detect voltage, (ACDET pin voltage is 30% above 2.4 V (2.4 V X 130% = 3.1 V), charge is disabled. ACOV does not latch, and normal operation resumes when ACDET < 3.1 V. Input Undervoltage Lock Out (UVLO) The system must have a typical 8 V PVCC voltage to allow proper operation. This PVCC voltage could come from an input adapter . When the PVCC voltage is below 8 V the bias circuits REGN and VREF stay inactive, even with ACDET above 0.6 V. Battery Overvoltage Protection The converter will 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. Charge Overcurrent Protection The charger has a secondary over-current protection. It monitors the charge current, and prevents the current from exceeding 6.25A peak value with a 20 mΩ sensing resistor. The high-side gate drive turns off when the over-current is detected, and automatically resumes at the next switching cycle that occurs after the current falls below the OCP threshold. When the BAT-GND short is detected, the charger will be automatically shut down immediately and then restarts again 100 μs later. 20 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 Short-Circuit Protection The charger has a secondary short-circuit protection. It monitors the voltage-drop (detect ACP-SW for protecting high-side MOSFET and detect SW-AGND for protecting low-side MOSFET) to prevents the short-circuit current from exceeding a certain value to damage the charger. It will be monitored after typical blanking time of 100ns. The MOSFET gate driver signal turns off when the short-circuit current is detected in every switching cycle. The charger will shut-down and latch off after this occurs 7 times. POR or toggling CE pin can resume normal charge function. Thermal Shutdown Protection The QFN package has low thermal impedance, which provides good thermal conduction from the silicon to the ambient, to keep junctions temperatures low. As added level of protection, the charger converter turns off and self-protects whenever the junction temperature exceeds the TSHUT threshold of 155 °C. The charger stays off until the junction temperature falls below 135 °C, then the charger will soft-start again if all other enable charge conditions are valid. Input Low Power Detection In order to optimize the system performance, the HOST keeps an eye on the adapter current. Once the adapter current is above a threshold set via LPREF, the LPMOD pin sends a signal to the HOST. The signal alarms the host that input power has exceeded the programmed limit. The LPMOD pin is an open-drain output. Connect a pull-up resistor to LPMOD. The LPMOD output is logic LOW when the 20X current sense voltage (20 x V(ACP-ACN)) is higher than the LPREF input voltage. The LPREF threshold may be set by an external resistor divider using VREF, or may be programmed from a resistor divider off of ACSET to maintain an LPREF voltage proportional to the adapter current. The LPMOD comparator has an internal 6% hysteresis built in. ACDET 2.4 V + - AC_VGOOD ACVDET Comparator EXTPWR ACP 1 kΩ Adaptor Current Sense Amplifier + - ACN ACIDET Comparator 250 mV AC_IGOOD (1.25 A) + IADAPT Error Amplifier Disable 20 kΩ + 20xV(ACP-ACN) IADAPT IADAPT Disable IADAPT OUTPUT BUFFER LPMOD Comparator + LPREF - LPMOD LOPWR_DET Hysteresis = 6% Figure 30. EXTPWR , LPREF, and LPMOD Logic Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 21 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com Status Outputs ( EXTPWR , LPMOD , DPMDET Pin) Three status outputs are available, and they all require external pull up resistors to pull the pins to system digital rail for a high level. EXTPWR open-drain output goes low under each of the three conditions: 1. ACDET is above 2.4 V 2. Adapter current is above 1.25 A using a 10mohm sense resistor (IADAPT voltage above 250 mV) Internally, the AC current detect comparator looks between the output of the 20x adapter current amplifier and an internal 250mV threshold. EXTPWR indicates a good adapter is connected because of valid voltage or current. LPMOD output goes low when the input current is higher than the programmed threshold via LPREF pin. Hysteresis is internally set to 6% of the programmed LPMOD threshold. DPMDET open-drain output goes low when the DPM loop is active to reduce the battery charge current. Table 4. Component List for Typical System Circuit of Figure 1 PART DESIGNATOR QTY DESCRIPTION Q1, Q2, Q3 3 P-channel MOSFET, -30V,-6A, SO-8, Vishay-Siliconix, Si4435 Q4 1 N-channel Dual-MOSFET, 30V, 7.5A, SO-8, Fairchild, FDS8978 D1, D2 2 Diode, Dual Schottky, 30V, 200mA, SOT23, Fairchild, BAT54C RAC 1 Sense Resistor, 10mΩ, 1%, 1W, 2010, Vishay-Dale, WSL2010R0100F RSR 1 Sense Resistor, 20mΩ, 1%, 1W, 2010, Vishay-Dale, WSL2010R0200F L1 1 Inductor, 10μH, 24.8mΩ Vishay-Dale, IHLP5050CE-01 C1 1 Capacitor, Ceramic, 2.2μF, 35V, 20%, X5R, 1206, Panasonic, ECJ-3YB1E225M C6, C7, C11, C12 4 Capacitor, Ceramic, 10μF, 35V, 20%, X5R, 1206, Panasonic, ECJ-3YB1E106M C4, C10 2 Capacitor, Ceramic, 1μF, 25V, 10%, X7R, 2012, TDK, C2012X7R1E105K C13 1 Capacitor, Ceramic, 100nF, 25V, 10%, X7R, 0805, Kemet, C0805C104K5RACTU C2, C3, C8, C9, C13, C14, C15, C16 6 Capacitor, Ceramic, 0.1μF, 50V, 10%, X7R, 0805, Kemet, C0805C104K5RACTU C5 1 Capacitor, Ceramic, 100pF, 25V, 10%, X7R, 0805, Kemet, C0805C101K5RACTU R1 1 Resistor, Chip, 464kΩ, 1/16W, 1%, 0402 R2 1 Resistor, Chip, 66.5kΩ, 1/16W, 1%, 0402 R3, R4, R5, R15 4 Resistor, Chip, 10kΩ, 1/16W, 5%, 0402 R6 1 Resistor, Chip, 97.6kΩ, 1/16W, 1%, 0402 R7 1 Resistor, Chip, 73.2kΩ, 1/16W, 1%, 0402 R8 1 Resistor, Chip, 26.7kΩ, 1/16W, 1%, 0402 R9 1 Resistor, Chip, 60.4kΩ, 1/16W, 1%, 0402 R10 1 Resistor, Chip, 40.2kΩ, 1/16W, 1%, 0402 R11 1 Resistor, Chip, 2Ω, 1W, 5%, 2012 R12 1 Resistor, Chip, 102kΩ, 1/16W, 1%, 0402 R13 1 Resistor, Chip, 64.9kΩ, 1/16W, 1%, 0402 R14 1 Resistor, Chip, 120kΩ, 1/16W, 1%, 0402 22 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 APPLICATION INFORMATION Inductor Selection The bq24741/2 can program the switching frequency between 300k and 800kHz for different applications. Higher switching frequency allows the use of smaller inductor and capacitor values. Inductor saturation current should be higher than the charging current (ICHG) plus half the ripple current (IRIPPLE): ISAT ³ ICHG + (1/2) IRIPPLE (6) The 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 (7) The maximum inductor ripple current happens with D = 0.5 or close to 0.5. For example, the battery charging voltage range is from 9V to 12.6V for 3-cell battery pack. For 20V adapter voltage, 10V battery voltage gives the maximum inductor ripple current. Another example is 4-cell battery, the battery voltage range is from 12V to 16.8V, and 12V battery voltage gives the maximum inductor ripple current. Usually inductor ripple is designed in the range of (20–40%) maximum charging current as a trade-off between inductor size and efficiency for a practical design. The bq24741/2 has charge under current protection (UCP) by monitoring charging current sensing resistor. The Typical UCP threshold is 30mV falling edge and 40mV rising edge corresponding to 1.5A falling edge and 2A rising edge for a 20mΩ charging current sensing resistor. To prevent negative inductor current, the inductance must be high enough so that peak to peak ripple current is less than 3A (for a 20mΩ charging current sensing resistor) when charging current tapers down. Considering UCP threshold tolerance for worst case, peak to peak ripple current less than 2.5A for a 20mΩ charging current sensing resistor is preferred. Input Capacitor Input capacitor should have enough ripple current rating to absorb input switching ripple current. The worst case 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 occurs where the duty cycle is closest to 50% and can be estimated by the following equation: ICIN = ICHG ´ D ´ (1 - D) (8) Low ESR ceramic capacitor such as X7R or X5R is preferred for input decoupling capacitor and should be placed to the drain of the high side MOSFET and source of the low side MOSFET as close as possible. Voltage rating of the capacitor must be higher than normal input voltage level. 25V rating or higher capacitor is preferred for 19-20V input voltage. 10-20µF capacitance is suggested for typical of 3-4A charging current. Output Capacitor Output capacitor also should have enough ripple current rating to absorb output switching ripple current. The output capacitor RMS current is given: I ICOUT = RIPPLE » 0.29 ´ IRIPPLE 2 ´ 3 (9) The bq24741/2 has internal loop compensator. To get good loop stability, the resonant frequency of the output inductor and output capacitor should be designed between 8 kHz and 12.5 kHz. The preferred ceramic capacitor is 25V, X7R or X5R for output capacitor. 10-20µF capacitance is suggested for practical application. Two capacitors, one capacitor is located before and another one after charging current sensing resistor to get the best average charge current regulation accuracy. 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 5.9V of gate drive voltage. 30V or higher voltage rating MOSFETs are preferred for 19-20V input voltage. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 23 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com Figure-of-merit (FOM) is usually used for selecting proper MOSFET based on a tradeoff between the conduction loss and switching loss. For top side MOSFET, FOM is defined as the product of a MOSFET's on-resistance, RDS(ON), and the gate-to-drain charge, QGD. For bottom side MOSFET, FOM is defined as the product of the MOSFET's on-resistance, RDS(ON), and the total gate charge, QG. FOM top = RDS(on) ´ QG D FOMbottom = RDS(on) ´ QG (10) The lower the FOM value, the lower the total power loss. Usually lower RDS(ON) has higher cost with the same package size. The top-side MOSFET loss includes conduction loss and switching loss. It is a function of duty cycle (D=VOUT/VIN), charging current (ICHG), MOSFET's on-resistance ®DS(ON)), input voltage (VIN), switching frequency (F), turn on time (ton) and turn off time (ttoff): 1 Ptop = D ´ ICHG2 ´ RDS(on) + ´ VIN ´ ICHG ´ (t on + t off ) ´ fS 2 (11) The first item represents the conduction loss. Usually MOSFET RDS(ON) increases by 50% with 100ºC junction temperature rise. The second term represents the switching loss. The MOSFET turn-on and turn off times are given by: Q Q ton = SW , t off = SW Ion Ioff (12) where Qsw is the switching charge, Ion is the turn-on gate driving current and Ioff is the turn-off gate driving current. If the switching charge is not given in MOSFET datasheet, it can be estimated by gate-to-drain charge (QGD) and gate-to-source charge (QGS): 1 QSW = QGD + ´ QGS 2 (13) Gate driving current total can be estimated by REGN voltage (VREGN), MOSFET plateau voltage (Vplt), total turn-on gate resistance (Ron) and turn-off gate resistance ®off) of the gate driver: VREG N - Vplt Vplt Ion = , Ioff = Ron Roff (14) The conduction loss of the bottom-side MOSFET is calculated with the following equation when it operates in synchronous continuous conduction mode: Pbottom = (1 - D) ´ ICHG 2 ´ RDS(on) (15) When charger operates in non-synchronous mode, the bottom-side MOSFET is off. As a result all the freewheeling current goes through the body-diode of the bottom-side MOSFET. The body diode power loss depends on its forward voltage drop (VF), non-synchronous mode charging current (INONSYNC), and duty cycle (D). PD = VF ´ INO NSYNC ´ (1 - D) (16) The maximum charging current in non-synchronous mode can be up to 2.25A for a 20mΩ charging current sensing resistor considering IC UCP threshold tolerance. The minimum duty cycle happens at lowest battery voltage. Choose the bottom-side MOSFET with either an internal Schottky or body diode capable of carrying the maximum non-synchronous mode charging current. Input Filter Design During adapter hot plug-in, the parasitic inductance and input capacitor from the adapter cable form a second order system. The voltage spike at PVCC pin maybe beyond IC maximum voltage rating and damage IC. The input filter must be carefully designed and tested to prevent over voltage event on PVCC pin. There are several methods to damping or limit the over voltage spike during adapter hot plug-in. An electrolytic capacitor with high ESR as an input capacitor can damp the over voltage 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 have low cost or small size. 24 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 A cost effective and small size solution is shown in Figure 31. The R1 and C1 is composed of a damping RC network to damp the hot plug-in oscillation. As a result the over voltage spike is limited to a safe level. D1 is used for reverse voltage protection for PVCC pin. C2 is PVCC pin decoupling capacitor and it should be place to PVCC pin as close as possible. C2 value should be much less than C1 value so R1 can dominant the equivalent ESR value to get enough damping effect. R2 is used to limit inrush current of D1 to prevent D1 getting damage when adapter hot plug-in. R1 has high inrush current. R1 package must be sized enough to handle inrush current power loss according to resistor manufacturer’s datasheet. The filter components value always need to be verified with real application and minor adjustments may need to fit in the real application circuit. D1 R1 2W Adapter connector R2 (1206) 4.7 -30W (2010) PVCC pin C1 2.2 mF C2 0.1-1 mF Figure 31. Input Filter bq24741/2 Design Guideline The bq24741/2 has a unique short circuit protection feature. Its cycle-by-cycle current monitoring feature is achieved through monitoring the voltage drop across Rdson of the MOSFETs after a certain amount of blanking time. In case of MOSFET short or inductor short circuit, the over current condition is sensed by two comparators and two counters will be triggered. After seven times of short circuit events, the charger will be latched off. The way to reset the charger from latch-off status is to toggle the CE pin or IC power on reset. Figure 32 shows the bq24741/2 short circuit protection block diagram. Adapter RAC ACN ACP R PCB BTST High-Side MOSFET SCP1 L SW R SR REGN COMP1 COMP2 Count to 7 Charge Enable Function CLR SCP2 Battery Low-Side MOSFET Latch off Charger Figure 32. Block Diagram of bq24741/2 Short Circuit Protection In normal operation, low side MOSFET current is from source to drain which generates negative voltage drop when it turns on, as a result the over current comparator can not be triggered. When high side switch short circuit or inductor short circuit happens, the large current of low side MOSFET is from drain to source and can trig low side switch over current comparator. the bq24741/2 senses low side switch voltage drop by SW pin and AGND pin. The high-side FET short is detected by monitoring the voltage drop between ACP and SW. As a result, it not only monitors the high side switch voltage drop, but also the adapter sensing resistor voltage drop and PCB trace voltage drop from ACN terminal of RAC to charger high side switch drain. Usually, there is a long trance between input sensing resistor and charger converting input, a careful layout will minimize the trace effect. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 25 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com To prevent unintentional charger shut down in normal operation, MOSFET RDS(on) selection and PCB layout is very important. Figure 33 shows a need improve PCB layout example and its equivalent circuit. In this layout, system current path and charger input current path is not separated, as a result, the system current causes voltage drop in the PCB copper and is sensed by IC. The worst layout is when a system current pull point is after charger input; as a result all system current voltage drops are counted into over current protection comparator. The worst case for IC is the total system current and charger input current sum equals DPM current. When system pull more current, the charger IC tries to regulate RAC current as a constant current by reducing charging current. RAC IDPM System Path PCB Trace System current RAC Charger input current Charger Input PCB Trace ACP ISYS R PCB ACN ICHRGIN Charger IBAT To ACN To ACP (a) PCB Layout (b) Equivalent Circuit Figure 33. Need Improve PCB Layout Example Figure 34 shows the optimized PCB layout example. The system current path and charge input current path is separated, as a result the IC only senses charger input current caused PCB voltage drop and minimized the possibility of unintentional charger shut down in normal operation. This also makes PCB layout easier for high system current application. RAC System Path PCB Trace IDPM System current Single point connection at R ISYS R AC AC R PCB ICHRGIN Charger input current ACP To ACP To ACN ACN Charger IBAT Charger Input PCB Trace (a) PCB Layout (b) Equivalent Circuit Figure 34. Optimized PCB Layout Example The total voltage drop sensed by IC can be express as the following equation. Vtop = R AC ´ IDPM + RPCB ´ (ICHRGIN + (IDPM ) - ICHRGIN ) ´ k + RDS(on) ´ IPEAK (17) where the RAC is the AC adapter current sensing resistance, IDPM is the DPM current set point, RPCB is the PCB trace equivalent resistance, ICHRGIN is the charger input current, k is the PCB factor, RDS(on) is the high side MOSFET turn on resistance and IPEAK is the peak current of inductor. Here the PCB factor k equals 0 means the best layout shown in Figure 34 where the PCB trace only goes through charger input current while k equals 1 means the worst layout shown in Figure 33 where the PCB trace goes through all the DPM current. The total voltage drop must below the high side short circuit protection threshold to prevent unintentional charger shut down in normal operation. PCB Layout The switching node rise and fall times should be minimized for minimum switching loss. Proper layout of the components to minimize high frequency current path loop (see Figure 35) is important to prevent electrical and magnetic field radiation and high frequency resonant problems. Here is a PCB layout priority list for proper layout. Layout PCB according to this specific order is essential. 1. Place input capacitor as close as possible to switching MOSFET’s supply and ground connections and use shortest copper trace connection. These parts should be placed on the same layer of PCB instead of on different layers and using vias to make this connection. 2. The IC should be placed close to the switching MOSFET’s gate terminals and keep the gate drive signal traces short for a clean MOSFET drive. The IC can be placed on the other side of the PCB of switching 26 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 bq24741, bq24742 www.ti.com SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 MOSFETs. 3. Place inductor input terminal to switching MOSFET’s output terminal as close as possible. 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 should be placed right next to the inductor output. Route the sense leads connected across the sensing resistor back to the IC in same layer, close to each other (minimize loop area) and do not route the sense leads through a high-current path (see Figure 36 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. Use 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. 8. Route analog ground separately from power ground. Connect analog ground to AGND and connect power ground to PGND separately. Connect analog ground and power ground together using power pad as the single ground connection point. Or using a 0Ω resistor to tie analog ground to power ground (power pad should tie to analog ground in this case). 9. Decoupling capacitors should be placed next to the IC pins and make trace connection as short as possible. 10. It is critical that the exposed power 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. 11. The via size and number should be enough for a given current path. SW L1 V BAT R1 High Frequency VIN BAT Current C1 Path PGND C2 C3 Figure 35. High Frequency Current Path Charge Current Direction R SNS To Inductor To Capacitor and battery Current Sensing Direction To CSP - CSN pin or ACP - ACN pin Figure 36. Sensing Resistor PCB Layout Refer to the EVM design (SLUU284) for the recommended component placement with trace and via locations. For the QFN information, refer to SCBA017 and SLUA271. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 27 bq24741, bq24742 SLUS875B – MARCH 2009 – REVISED OCTOBER 2009 www.ti.com REVISION HISTORY Changes from Revision A (March 2009) to Revision B Page • Changed 8 V to 9 V .............................................................................................................................................................. 1 • Changed "Cells pin support two to for Li-Ion cells up to 18 V battery voltage" to Support two to four cells ........................ 1 • Added "FET/Inductor/Battery Short Protection" .................................................................................................................... 1 • Added "Loop Compensation" ................................................................................................................................................ 1 • Deleted "Internal Loop Compensation" bullet ....................................................................................................................... 1 • Added "Quiescent Current" ................................................................................................................................................... 1 • Added 10Ω R16 to top of schematic ..................................................................................................................................... 2 • Added 10Ω R16 to top of schematic ..................................................................................................................................... 3 • Changed bq24742RHDR to bq24742RHDT ......................................................................................................................... 3 • Changed 8.0 V to 9.0 V in condition values ......................................................................................................................... 6 • Changed min voltage from 8 to 9 for VPVCC_OP parameter .................................................................................................... 6 • Deleted VBAT_OP parameter from this section ................................................................................................................... 6 • Changed 8.0 V to 9.0 V in condition values ......................................................................................................................... 7 • Changed 8.0 V to 9.0 V in condition values ......................................................................................................................... 8 • Changed "Short Circuit" to "MOSFET short" ........................................................................................................................ 8 • Changed VLS max value from 280 to 320 ........................................................................................................................... 8 • Changed all instances of VPH to VSW in following section ..................................................................................................... 8 • Changed 8.0 V to 9.0 V in condition values ......................................................................................................................... 9 • Deleted VCC pin ................................................................................................................................................................... 9 • Added graph: "Near 100% Duty Cycle.." ............................................................................................................................ 15 • Changed polarity of IIN_ER, BAT_ER, and ICH_ER op amps ........................................................................................... 16 • Added text note under equation .......................................................................................................................................... 17 • Changed 8ms to 2ms .......................................................................................................................................................... 20 • Changed "This PVCC voltage could come from either input adapter or battery, using a diode-OR input." ....................... 20 • Added then the charger will soft-start again if all other enable change conditions are valid. ............................................. 21 • Added added text, equations and illustrations from Inductor Selection to PCB Layout ..................................................... 23 28 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s) :bq24741 bq24742 PACKAGE OPTION ADDENDUM www.ti.com 8-Dec-2009 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty BQ24741RHDR ACTIVE VQFN RHD 28 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR BQ24741RHDT ACTIVE VQFN RHD 28 250 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR BQ24742RHDR ACTIVE VQFN RHD 28 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR BQ24742RHDT ACTIVE VQFN RHD 28 250 CU NIPDAU Level-2-260C-1 YEAR Green (RoHS & no Sb/Br) Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release. In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis. Addendum-Page 1 PACKAGE MATERIALS INFORMATION www.ti.com 1-Dec-2011 TAPE AND REEL INFORMATION *All dimensions are nominal Device Package Package Pins Type Drawing SPQ Reel Reel A0 Diameter Width (mm) (mm) W1 (mm) B0 (mm) K0 (mm) P1 (mm) W Pin1 (mm) Quadrant BQ24741RHDR VQFN RHD 28 3000 330.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24741RHDR VQFN RHD 28 3000 330.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24741RHDT VQFN RHD 28 250 180.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24741RHDT VQFN RHD 28 250 180.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24742RHDR VQFN RHD 28 3000 330.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24742RHDR VQFN RHD 28 3000 330.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24742RHDT VQFN RHD 28 250 180.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 BQ24742RHDT VQFN RHD 28 250 180.0 12.4 5.3 5.3 1.5 8.0 12.0 Q2 Pack Materials-Page 1 PACKAGE MATERIALS INFORMATION www.ti.com 1-Dec-2011 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) BQ24741RHDR VQFN RHD 28 3000 346.0 346.0 29.0 BQ24741RHDR VQFN RHD 28 3000 346.0 346.0 29.0 BQ24741RHDT VQFN RHD 28 250 210.0 185.0 35.0 BQ24741RHDT VQFN RHD 28 250 210.0 185.0 35.0 BQ24742RHDR VQFN RHD 28 3000 346.0 346.0 29.0 BQ24742RHDR VQFN RHD 28 3000 346.0 346.0 29.0 BQ24742RHDT VQFN RHD 28 250 210.0 185.0 35.0 BQ24742RHDT VQFN RHD 28 250 210.0 185.0 35.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. 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