bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Fully Integrated Switch-Mode One-Cell Li-Ion Charger with Full USB Compliance and Accessory Power Connection Check for Samples: bq24180 FEATURES • 1 • 2 • • • • • • • Charge Faster than Linear Chargers From Current Limited Input Sources High-Accuracy Voltage and Current Regulation – Input Current Regulation Accuracy: ±5% (100mA, 500mA) – Charge Voltage Regulation Accuracy: ±0.5% (25°C), ±1% (0–125°C) – Charge Current Regulation Accuracy: ±5% Accessory Power Output (DCOUT) Input Voltage Based Dynamic Power Management Safety Limit Register for Maximum Charge Voltage and Current Limiting High-Efficiency Mini-USB/AC Battery Charger for Single-Cell Li-Ion and Li-Polymer Battery Packs 20-V Absolute Maximum and 16.5V Operation Input Voltage Rating Built-in Input Current Sensing and Limiting • • • • • • • Integrated Power FETs for Up to 1.5-A Charge Rate Programmable Charge Parameters through I2C™ compatible Interface (up to 3.4 Mbps) Synchronous Fixed-Frequency PWM Controller Operating at 3 MHz With 0% to 99.5% Duty Cycle Safety Timer and Software Watchdog Reverse Leakage Protection Prevents Battery Drainage Thermal Regulation and Protection Status Outputs for Charging and Faults 25-Pin WCSP Package APPLICATIONS • • • Mobile Phones and Smart Phones Portable Media Players Handheld Devices DESCRIPTION The bq24180 is a compact, flexible, high-efficiency, USB-friendly switch-mode charge management device for single-cell Li-ion and Li-polymer batteries used in a wide range of portable applications. The charge parameters is programmable using an I2C compatible interface. The bq24180 integrates a synchronous PWM controller, power MOSFETs, input current sensing and overvoltage protection, high-accuracy current and voltage regulation, and charge termination, into a small WCSP package. POWER FOR ACCESSORY C8 1 µF SYSTEM VBUS C1 1 µF RSNS 68 mW DCOUT VBUS SW C4 10 nF PMID C3 4.7 µF C2 10 µF BOOT TEMP PACK + PGND HOST bq24180 CSIN PACK - CSOUT DRV C7 1 µF VBUS D+ D- VBUS C5 0.1 µF PSEL TS USB PHY GND C6 1 µF VAUX R1 10 kW R2 10 kW R4 10 kW CD INT Hardware Disable STAT SCL SDA R3 4 kW 1 2 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. I2C is a trademark of Phillips Electronics. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2010, Texas Instruments Incorporated bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 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 bq24180 charges the battery in three phases: conditioning, constant current and constant voltage. Charge current is programmable using the I2C interface. Additionally, the input current can be limited to a host programmable threshold to maintain maximum charge current from current-limited sources, such as USB ports. Charge is terminated based on user-selectable minimum current level. A software watchdog provides a safety backup for I2C interface while a safety timer prevents overcharging the battery. During normal operation, bq24180 automatically restarts the charge cycle if the battery voltage falls below an internal threshold and automatically enters sleep mode or high impedance mode when the input supply is removed. The charge status is reported to the host using the I2C interface. During the charging process, the bq24180 monitors its junction temperature (TJ) and reduces the charge current if TJ increases to 125°C. The bq24180 is available in 25-pin WCSP package. ORDERING INFORMATION VOVP I2C ADDRESS bq24180YFFR 16.5 V 6B bq24180YFFT 16.5 V 6B PART NUMBER (1) (2) (1) (2) The YFF package is available in the following options: R – taped and reeled in quantities of 3,000 devices per reel. T – taped and reeled in quantities of 250 devices per reel. This product is RoHS compatible, including a lead concentration that does not exceed 0.1% of total product weight, and is suitable for use in specified lead-free soldering processes. In addition, this product uses package materials that do not contain halogens, including bromine (Br) or antimony (Sb) above 0.1% of total product weight. ABSOLUTE MAXIMUM RATINGS (1) (2) over operating free-air temperature range (unless otherwise noted) LIMITS UNIT Supply voltage range (with respect to PGND) VBUS –2 to 20 V Input voltage range (with respect to and PGND) SCL, SDA, PSEL, CSIN, CSOUT, DRV, DCOUT, INT –0.3 to 7 V PMID, STAT –0.3 to 20 SW, BOOT –0.7 to 20 Output voltage range (with respect to and PGND) Voltage difference between CSIN and CSOUT inputs (VCSIN –VCSOUT) Voltage difference between BOOT and SW inputs (VBOOT –VSW) Output sink Output current Output current (average) V ±7 V –0.3 to 7 V INT 5 STAT 10 DCOUT 1.5 A DRV 10 mA 2 A TA Operating free-air temperature range –30 to +85 °C TJ Junction temperature range –40 to +125 °C Tstg Storage temperature –45 to +150 °C (1) (2) 2 SW mA 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 © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 DISSIPATION RATINGS (1) PACKAGE RqJA RqJC TA < 25°C POWER RATING DERATING FACTOR ABOVE TA = 25°C WCSP-25 60°C/W (1) 1.57°C/W 540 mW 5.4 mW/°C Using JEDEC 2s2p PCB standard. RECOMMENDED OPERATING CONDITIONS over operating free-air temperature range (unless otherwise noted) MIN Supply voltage, VBUS MAX 4.0 Operating junction temperature range, TJ (1) NOM 16 0 UNIT (1) V 125 °C The inherent switching noise voltage spikes should not exceed the absolute maximum rating on either the BOOT or SW pins. A tight layout minimizes switching noise. ELECTRICAL CHARACTERISTICS Circuit of Figure 2, VVBUS = 5V, HZ_MODE=0, CD=0, TJ = –40°C to 125°C and TJ = 25°C for typical values (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT INPUT CURRENTS VVBUS > VVBUS(min), PWM switching IVBUS IVBUS_LEAK VVBUS supply current for control 10 mA VVBUS > VVBUS(min), PWM NOT switching 5 mA 0°C< TJ < 85°C, EN=0 or HZ_MODE=1 650 µA 5 µA 800 µA 0°C< TJ < 85°C, VCSOUT = 4.2 V, No Input connected, DCOUT disabled SCL,SDA=0V or 1.8V 30 µA 0°C< TJ < 85°C, VCSOUT = 4.2 V, High Impedance mode, DCOUT disabled, VVBUS = 5V, SCL,SDA=0V or 1.8V 60 µA V Leakage current from battery to VBUS pin 0°C< TJ < 85°C, VCSOUT = 4.2 V, No input connected IBAT_DCOUT Battery Current when using DCOUT DCOUT = enabled, VBAT = 4.2V, DCOUT_ILIM=1A, IDCOUT=750mA IBAT_HIZ Battery discharge current in High Impedance mode, (CSIN, CSOUT, SW pins) VOLTAGE REGULATION VOREG Output charge voltage programmable range Voltage regulation accuracy Operating in voltage regulation, programmable 3.5 4.44 –0.5% 0.5% –1% 1% 550 1550 VICHRG = 37.4 mV to 44.2 mV –3.5% 3.5% VICHRG > 44.2 mV –3.0% 3.0% TA = 25°C CURRENT REGULATION - FAST CHARGE IOCHARGE Output charge current programmable range Regulation accuracy for charge current across RSNS VIREG = IOCHARGE × RSNS VPRECHG ≤ VCSOUT < VOREG, VVBUS>VSLP, RSNS = 68 mΩ, Programmable mA PSEL, CD LOGIC LEVEL VIL Input low threshold level PSEL, CD falling VIH Input high threshold level PSEL, CD rising 1.2 0.4 25 V V CHARGE TERMINATION DETECTION ITERM Termination charge current VCSOUT > VOREG–VRCH , VVBUS>VSLP, RSNS = 68 MΩ, Programmable ITERM_dgl Deglitch time for charge termination Both rising and falling, 2-mV over- drive, tRISE, tFALL = 100 ns Regulation accuracy for termination current across RSNS VIREG_TERM = IOTERM × RSNS 200 30 ms VTERM = 1.7 mV –40% 40% VTERM = 3.4 mV to 6.8 mV –16% 16% VTERM = 6.8 mV to 13.6 mV –11% 11% VTERM ≥ 13.6 mV –5.5% 5.5% Battery Detection sink current before charge done mA –550 µA INPUT BASED DYNAMIC POWER MANAGEMENT Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 3 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com ELECTRICAL CHARACTERISTICS (continued) Circuit of Figure 2, VVBUS = 5V, HZ_MODE=0, CD=0, TJ = –40°C to 125°C and TJ = 25°C for typical values (unless otherwise noted) PARAMETER TEST CONDITIONS The threshold when input based DPM loop kicks in VIN_DPM MIN Charge mode, programmable DPM loop kick-in threshold tolerance TYP MAX UNIT 4.15 4.71 V –2% 2% FAULTY ADAPTER PROTECTION VVBUS (MIN) Faulty adapter threshold 3.6 Deglitch time for Faulty adapter 4.0 30 Hysteresis for faulty adapter protection VVBUS Rising 100 Current source for faulty adapter protection tINT 3.8 20 Detection Interval 30 V ms 200 mV 40 mA 2 s INPUT CURRENT LIMITING IIN_LIMIT USB charge mode, current pulled from PMID Input current limiting threshold IIN_LIMIT = 100 mA 90 95 100 IIN_LIMIT = 500 mA 450 475 500 IIN_LIMIT = 800 mA 700 755 800 mA DCOUT RDCOUT DCOUT Pass FET on-resistance IDCOUT = 500 mA 2 ILIM_DCOUT DCOUT current limit programmable range tDGL_DCOUT Deglitch time from DCOUT current-limit event to DCOUT latch-off ILIM_DCOUT 350 Programmable via I C mΩ 1400 mA 14.5 Programmable via I2C DCOUT current limit range 300 ILIM_DCOUT = 350mA 270 ILIM_DCOUT = 750mA 650 750 ILIM_DCOUT = 1050mA 800 1050 ILIM_DCOUT = 1400mA 1050 1400 100 120 ms 350 mA BATTERY RECHARGE THRESHOLD VRCH Recharge threshold voltage Below VOREG Deglitch time VCSOUT decreasing below threshold, tFALL = 100 ns, 10-mV overdrive 150 130 mV ms STAT OUTPUTS VOL(STAT) Low-level output saturation voltage, STAT IO = 10 mA, sink current High-level leakage current Voltage on STAT pin is 5V Low-level output saturation voltage, INT IO = 1 mA, sink current 0.4 V High-level leakage current Voltage on INT pin is 5V 1 µA Output low threshold level IO = 10 mA, sink current 0.4 V Input low threshold level V(pull-up) = 1.8 V, SDA and SCL 0.4 V Input high threshold level V(pull-up) = 1.8 V, SDA and SCL I(bias) Input bias current V(pull-up) = 1.8 V, SDA and SCL 1 µA fSCL SCL clock frequency VOL(INT) 0.5 V 1 µA I2C BUS LOGIC LEVELS AND TIMING CHARACTERISTICS VOL 1.2 V 3.4 MHz SLEEP COMPARATOR VSLP Sleep-mode entry threshold, VBUS-VCSOUT 2.3 V ≤ VCSOUT ≤ VOREG, VVBUS falling VSLP-EXIT Sleep-mode exit hysteresis 2.3 V ≤ VCSOUT < VOREG Deglitch time for VBUS rising above VSLP+VSLP_EXIT Rising voltage, 2-mV over drive, tRISE = 100 ns VUVLO IC active threshold voltage VVBUS rising 3.05 3.3 VUVLO_HYS IC active hysteresis VVBUS falling from above VUVLO 120 150 Internal top reverse blocking MOSFET on-resistance IIN_LIMIT = 500 mA, Measured from VVBUS to PMID 110 210 mΩ Internal top N-channel Switching MOSFET on-resistance Measured from PMID to SW 130 250 mΩ 0 40 100 mV 140 200 260 mV 30 ms UVLO 3.55 V mV PWM 4 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 ELECTRICAL CHARACTERISTICS (continued) Circuit of Figure 2, VVBUS = 5V, HZ_MODE=0, CD=0, TJ = –40°C to 125°C and TJ = 25°C for typical values (unless otherwise noted) PARAMETER Internal bottom N-channel MOSFET on-resistance fOSC TEST CONDITIONS MIN Measured from SW to PGND Oscillator frequency Maximum duty cycle DMIN Minimum duty cycle MAX UNIT 125 210 mΩ 3.0 Frequency accuracy DMAX TYP –10% MHz 10% 99.5% 0 Synchronous mode to non-synchronous mode transition current threshold (1) Low-side MOSFET cycle-by-cycle current sensing VDRV Internal bias voltage regulator IDRV = 10 mA IDRV DRV Output Current External load on DRV VDO_DRV DRV Dropout Voltage (VVBUS – VDRV) 100 5 5.2 mA 5.45 10 IVBUS = 1A, VVBUS = 5 V, IDRV = 10 mA 340 VUVLO < VVBUS<VSLP V mA 750 mV PROTECTION Input OVP threshold voltage Threshold over VVBUS to turn off converter during charge VOVP hysteresis VVBUS falling from above VOVP Input High threshold VVBUS Rising, Threshold where IBAT falls to 50 mA VIN_HIGH_USB hysteresis VVBUS falling from above VIN_HIGH tOVP-dgl OVP deglitch time VVBUS rising or falling ILIMIT Cycle-by-cycle current limit for charge Charge mode operation 1.8 2.4 3.0 Precharge to fast charge threshold VCSOUT rising 1.9 2.0 2.1 VPRECHG hysteresis VCSOUT falling from above VPRECHG Precharge charge charging current VCSOUT ≤ VSHORT and VIN_HIGH < VVBUS < VOVP VOVP VIN_HIGH VPRECHG IPRECHG TSHTDWN TCF tWATCHDOG VHOT VWARM VCOLD ITS (1) 16 9.5 Timeout for the watchdog timer Watchdog timer 33.5 50.0 Corresponds to 55°C, VTS Falling TS Hot Threshold Hysteresis VTS Rising TS Warm Threshold Corresponds to 45°C VTS Falling TS Warm Threshold Hysteresis VTS Rising TS Cold Threshold Corresponds to 5°C, VTS Rising TS Cold Threshold Hysteresis VTS Falling ms 66.5 °C °C 120 °C s 20% 0.160 0.169 0.225 1.10 95 Resistance on TS that translates to open circuit on TS 100 V mV 0.240 V mV 1.14 75 TS Bias Current mA 10 12.5 1.06 V 165 12.5 0.210 A mV 12 0.153 V mV 100 –20% TS Hot Threshold 10.1 32 Safety timer accuracy TS Open Resistance 9.8 V mV 150 Thermal hysteresis Charge current begins to taper down 17 185 Thermal trip Thermal regulation threshold 16.5 V mV 105 200 µA kΩ Bottom N-channel MOSFET always turns on for ~60 ns and then turns off if current is too low. Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 5 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com SIMPLIFIED BLOCK DIAGRAM PMID DRV 5.2V Reference Q1 VBUS BOOT Charge Pump Q2 Input Current Limit Amplifier + + DC-DC CONVERTER PWM LOGIC AND COMPENSATION VIN-DPM Amplifier SW VDRV Q3 PGND 9.8V 16.5V + + High-Input Comparator Thermal Reg Amplifier + OVP Comparator CSIN 125°C TJ IIN_LIMITV INDPM SCL V ITERM + + + - SDA Gm amp IOUTREG Amplifier Termination Comparator V ICHRG VBATREG Amplifier V OREG Recharge Comparator CD I2C and CHARGE CONTROLLER CSOUT + 130mV + - + VPRECHG Comparator Sleep Comparator + Q4 VIN VDRV VPRECHG VBAT + PSEL VHIGH Comparator Q5 VIN TMR STAT 2X SAFETY TIMERS 50mA Precharge Current Source DCOUT TIMER FAULT INT DCOUT _ILIM 400 mA max charge DISABLE REF + + + REF + Charge Pump TS COLD TS WARM TS HOT TS 100uA Figure 1. Simplified Block Diagram 6 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 DEVICE INFORMATION PIN CONFIGURATION TOP VIEW 1 2 3 4 5 A VBUS VBUS BOOT SCL SDA B PMID PMID PMID INT CD C SW SW SW PSEL STAT D PGND PGND PGND DCOUT DCOUT E CSIN TS DRV CSOUT CSOUT 2.2 mm x 2.4 mm 25-pin WCSP PIN FUNCTIONS NAME PIN NO. I/O DESCRIPTION VBUS A1, A2 I/O Charger Input Voltage. Connect to an input supply up to 16V. Bypass VBUS to PGND with a 1µF ceramic capacitor. BOOT A3 O High-Side MOSFET Gate Driver Supply. Connect a 10nF ceramic capacitor (voltage rating above 10V) from BOOT pin to SW pin to supply the gate drive for the high side MOSFET. SCL A4 I I2C interface clock. Connect SCL to the logic rail through a 10kΩ resistor. SDA A5 I/O I2C interface data. Connect SCL to the logic rail through a 10kΩ resistor. PMID B1, B2, B3 O Connection Point Between Reverse Blocking MOSFET and High-Side Switching MOSFET. Bypass PMID to PGND with a minimum of 3.3µF ceramic capacitor. Use caution when connecting an external load to PMID. The PMID output is not current limited. Any short on PMID will result in damage to the IC. INT B4 O Host Interface Status Output. INT is a low voltage open drain output used to signal charge status to the host processor. INT is pulled low during charging. When charging is complete or when charging is disabled, INT is high impedance. When a fault occurs, a 128µs pulse is sent out as an interrupt for the host. INT is enabled/disabled using the EN_STAT bit in the control register. Connect INT to a logic rail through a 10kΩ resistor to communicate with the host processor. CD B5 O Hardware Disable Input. Connect CD to GND to enable charge. Drive CD high to disable charge and place the bq24180 into high impedance mode. Toggling CD resets the safety timer when in DEFAULT mode, but does not reset the timer when in host mode. CD is pulled to PGND through a 100kΩ internal resistor. SW C1, C2, C3 O Inductor Connection. Connect the switched side of the inductor to SW. PSEL C4 I USB Source Detection Input. Drive PSEL high to indicate a USB source is connected to the input and the PC mode default values should be used. When PSEL is high, the IC starts up with a 100mA input current limit. Drive PSEL low to indicate that an AC Adapter is connected to the input. When PSEL is low, the IC starts up with no input current limit and a 1A charge current. PSEL has an internal 100kΩ pullup resistor. STAT C5 O Status Output. STAT is an open drain output that is pulled low during charging. When charging is complete or when charging is disabled, STAT is high impedance. When a fault occurs, a 128µs pulse is sent out as an interrupt for the host. STAT is enabled/disabled using the EN_STAT bit in the control register. Connect STAT to a logic rail using an LED for visual indication or through a 10kΩ resistor to communicate with the host processor. PGND D1, D2, D3 Power ground. Connect to the ground plane for the circuit. DCOUT D4, D5 O Accessory Power Output. DCOUT is connected to the battery through an internal pass FET. When enabled through I2C, DCOUT is connected to the battery. When disabled, DCOUT is high-impedance. Bypass DCOUT to PGND with at least a 1µF ceramic capacitor. CSIN I Charge Current-Sense Input. Battery current is sensed via the voltage drop across an external sense resistor. Bypass CSIN to PGND with a 0.1µF ceramic capacitor. E1 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 7 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com PIN FUNCTIONS (continued) NAME PIN NO. I/O DESCRIPTION TS E2 I Battery Pack NTC Monitor. Connect TS to a 4.7kΩ NTC thermistor. During DEFAULT mode, when VTS > VCOLD or VTS<VHOT charging is suspended. If VHOT < VTS < VWARM charging current is reduced. The faults are reported by the I2C interface. During host mode, the TS function is active, but does not affect charging. The faults are only reported by the I2C interface. DRV E3 O Gate Drive Supply. DRV is the supply for the gate drive of the internal MOSFETs. Bypass DRV to PGND with a 1µF ceramic capacitor. DRV may be used to drive external loads up to 10mA. DRV is active whenever the input is connected. I Battery voltage and Current Sense Input. Connect to the positive terminal of the battery pack. CSOUT is also the supply for the DCOUT output. Bypass CSOUT to PGND with 1µF ceramic capacitor. CSOUT E4, E5 8 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 TYPICAL APPLICATION CIRCUITS VBUS = 5V, IIN_LIMIT = 500mA, ICHARGE = 1A, VBAT = 3.5--4.44V (Adjustable), Safety Timer = 27 minute default w/ 12 seconds watchdog C8 1µF POWER FOR ACCESSORY SYSTEM VBUS C1 1 µF DCOUT VBUS RSNS 68 mW SW C4 10 nF C2 10 µF BOOT PMID C3 4.7 µF PACK+ TEMP PGND HOST bq24180 CSIN PACK- CSOUT DRV C7 1 µF VBUS PSEL C6 1 µF TS VAUX R1 10 kW R2 10 kW R4 10 kW SCL Hardware Disable CD INT GND VBUS USB PHY STAT D+ D- C5 0.1 µF SDA R3 4 kW Figure 2. I2C Controlled 1-Cell USB Charger Application Circuit Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 9 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com TYPICAL CHARACTERISTICS 5 V/div VVBUS VBAT VBAT 2 V/div IOUT 500 mA/div 2 V/div IOUT 5 V/div 200 mA/div VINT/ STAT 5 V/div VINT/ STAT “No Battery” Fault Interrupt t -Time - 2 s/div t -Time - 4 ms/div Figure 3. Adapter Insertion Figure 4. Battery Insertion/Removal 5 V/div VVBUS VVBUS 1 V/div VVBUS < 3.8 V 2 V/div VBAT IVBUS 20 mA/div 500 mA/div IOUT 5 V/div 2 V/div VINT/ STAT VINT/ STAT "Faulty Adapter" Fault Interrupt t -Time - 4 ms/div t -Time - 4 ms/div Figure 5. PWM Charging Waveforms Figure 6. Faulty Adapter Detection VVBUS = 5 V, VBAT = 3.6 V 2 V/div VVBUS 1 V/div IVBUS VSW 20 mA/div 2 V/div IL 500 mA/div VINT/ STAT "Faulty Adapter" Fault Interrupt t -Time - 2 ms/div t -Time - 1 s/div Figure 7. Faulty Adapter Detection (Showing Continuous Detection) 10 Figure 8. Cycle by Cycle Current Limit Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 TYPICAL CHARACTERISTICS (continued) VSW VSW 2 V/div VBAT 2 V/div 1 V/div VBAT 200 mA/div IVBUS 1 V/div 200 mA/div IVBUS t -Time - 400 ms/div t -Time - 400 ms/div Figure 9. Input Current Limit Transition USB500 to USB100 Figure 10. Input Current Limit Transition USB100 to USB500 VSW 1 V/div 2 V/div VBAT VSCL 1 V/div 200 mA/div 200 mA/div IOUT IVBUS t -Time - 200 ms/div t -Time - 400 ms/div Figure 11. Input Current Limit Transition USB500 to 750mA Figure 12. Charge Current Transition 550mA to 1.05A Using I2C 2 V/div VVBUS 1 V/div VBAT IVBUS VPSEL 2 V/div VBAT 1 V/div IVBUS Faulty Adapter Detection 200 mA/div 50 mA/div t -Time - 1 ms/div t -Time - 10 ms/div Figure 13. Startup Into Default Mode No Battery Connected Figure 14. PSEL Transition Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 11 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com TYPICAL CHARACTERISTICS (continued) RLOAD = 11 W to 1 W, VBAT = 4 V 2 V/div VCD 1 V/div VDCOUT 200 mA/div IDCOUT 1 V/div VBAT IVBUS 500 mA/div t -Time - 4 ms/div t -Time - 10 ms/div Figure 15. Enable/Disable Using CD Figure 16. DCOUT OCP Response VVBUS = 5.5 V to 17 V VVBUS 10 V/div 1 V/div VDCOUT IOUT 500 mA/div 500 mA/div IDCOUT ISW 5 V/div t -Time - 10 ms/div t -Time - 2 ms/div Figure 17. Hotplug 1000µF Capacitor into DCOUT Figure 18. OVP Response 400 VVBUS = 5.5 V to 10.5 V VVBUS 5 V/div IOUT 500 mA/div USB100 Trickle Charge VSW 5 V/div t -Time - 10 ms/div VDO(VBUS-DRV) - V 350 VVBUS = 5 V, IVBUS = 1 A, IDRV = 10 mA 300 250 200 150 100 -40 -20 0 20 40 60 80 100 120 140 TA - Free-Air Temperature - °C Figure 19. VINHIGH Response 12 Figure 20. DRV Dropout vs TA Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 TYPICAL CHARACTERISTICS (continued) VVBUS = 0 V to 5.5 V to 0 V VVBUS IDRV 2 V/div 10 mA/div VDRV 5.1 V Offset VDRV 2 V/div 10 mV/div t -Time - 20 ms/div t -Time - 2 ms/div Figure 21. DRV Startup/Shutdown Figure 22. DRV Load Transient 5.15 100 VVBUS = 5 V VBUS = 5.5 V 90 80 5.13 VOUT = 3.5 V Efficiency - % 70 VDRV - V 5.11 5.09 60 VOUT = 4.45 V 50 40 30 20 5.07 10 5.05 0 1 2 3 4 5 6 7 8 9 10 0 0.01 0.1 1 10 Current - A IDRV - mA Figure 23. DRV Load Regulation Figure 24. Charger Efficiency Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 13 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com DETAILED DESCRIPTION The bq24180 is a highly integrated synchronous switch-mode charger featuring integrated MOSFETs and small external components, targeted at extremely space-limited portable applications powered by 1-cell Li-Ion or Li-polymer battery pack. For current limited power source, such as a USB host or hub, the high efficiency converter is critical in fully utilizing the input power capacity and quickly charging the battery. Due to the high efficiency in a wide range of the input voltage and battery voltage, the switching mode charger is a good choice for high speed charging with less power loss and better thermal management. The bq24180 has two operation modes: charge mode and high impedance mode. In charge mode, the bq24180 supports a precision Li-ion or Li-polymer charging system for single-cell applications. In high impedance mode, the bq24180 stops charging and operates in a mode with very low current from IN and battery, to effectively reduce the power consumption when the portable device in standby mode. Through proper control, bq24180 achieves the smooth transition among different operation modes. Charge Mode Operation Adapter Plug IN Watchdog Timer Expired and Not Active, no active host communication VUVLO < VIN < VOVP? No Yes Good Adapter connected? No Wait 2s Yes Begin Safety Timer Yes VHIGH<VIN<VOVP Enable 50mA precharge current Timer 2x STAT = 0 No No VBAT > 2V? Enable 50mA precharge current STAT = 0 Yes Begin DEFAULT Mode Battery Charge Cycle Figure 25. Startup on Adapter Plug-In in DEFAULT Mode 14 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Adapter Plug IN Watchdog Active Active Host Communication VUVLO < VIN < VOVP? No Yes Hi-Z bit = 0? No Enable Hi-Z Mode Yes /CE bit = 0? No Yes Good Adapter connected? No Wait 2s Yes Begin Safety Timer Yes VHIGH<VIN<VOVP Enable 50mA precharge current Timer 2x STAT = 0 No No VBAT > 2V? Enable 50mA precharge current STAT = 0 Begin HOST Mode Battery Charging Figure 26. Startup on Adapter Plug-In in Host-Controlled Mode Charge Profile In charge mode, bq24180 has five control loops to regulate input voltage, input current, charge current, charge voltage and device junction temperature. During the charging process, all five loops are enabled and the one that is dominant will take over the control. The bq24180 supports a precision Li-ion or Li-polymer charging system for single-cell applications. Figure 27 indicates a typical charge profile without input current regulation loop and it is similar to the traditional CC/CV charge curve, while Figure 27 shows a typical charge profile when input current limiting loop is dominant during the constant current mode, and in this case the charge current is higher than the input current so the charge process is faster than the linear chargers. For bq24180, the input current limits, the charge current, termination current, and charge voltage are all programmable using I2C interface. Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 15 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Precharge Phase www.ti.com Current Regulation Phase Voltage Regulation Phase Regulation voltage Regulation Current Charge Voltage VSHORT Charge Current Termination ISHORT Precharge (Linear Charge) Fast Charge (PWM Charge ) (a) Without input current limit (default when PSEL = 1) Precharge Phase Current Regulation Phase Voltage Regulation Phase Regulation voltage Charge Voltage VSHORT Charge Current Termination I SHORT Precharge (Linear Charge) Fast Charge (PWM Charge) (b) With input current limit (default when PSEL = 0) Figure 27. Typical Charging Profile of bq24180 PWM Controller in Charge Mode The bq24180 provides an integrated, fixed 3 MHz frequency voltage-mode controller with Feed-Forward function to regulate charge current or voltage. This type of controller is used to help improve line transient response, thereby simplifying the compensation network used for both continuous and discontinuous current conduction operation. The voltage and current loops are internally compensated using a Type-III compensation scheme that provides enough phase margin for stable operation, allowing the use of small ceramic capacitors with very low ESR. There is a 0.5V offset on the bottom of the PWM ramp to allow the device to operate between 0% to 99.5% duty cycles. The bq24180 has two back to back common-drain N-channel MOSFETs at the high side and one N-channel MOSFET at low side. An input N-MOSFET (Q1) prevents battery discharge when VBUS is lower than VVBUS (MIN). The second high-side N-MOSFET (Q2) behaves as the switching control switch (see Figure 1). A charge pump circuit is used to provide gate drive for Q1, while a boot strap circuit with external boot-strap capacitor is used to boost up the gate drive voltage for Q2. 16 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Cycle-by-cycle current limit is sensed through the internal sense MOSFETs for Q2 and Q3. The threshold for Q2 is set to a nominal 2.5-A peak current. The low-side MOSFET (Q3) also has a current limit that decides if the PWM Controller will operate in synchronous or non-synchronous mode. This threshold is set to 100mA and it turns off the low-side N-channel MOSFET (Q3) before the current reverses, preventing the battery from discharging. Synchronous operation is used when the current of the low-side MOSFET is greater than 100mA to minimize power losses. Battery Charging Process At the beginning of precharge, while battery voltage is below the VPRECHARGE threshold, the bq24180 applies the 50mA precharge current, IPRECHARGE, to the battery. When the battery voltage is above VPRECHARGE and below VOREG, the charge current ramps up to fast charge current, IOCHARGE, or a charge current that corresponds to the input current of IIN_LIMIT. The slew rate for fast charge current is controlled to minimize the current and voltage over-shoot during transient. The input current limit, IIN_LIMIT, and fast charge current, IOCHARGE, are programmable by the host. Once the battery voltage is close to the regulation voltage, VOREG, the charge current is tapered down as shown in Figure 27. The voltage regulation feedback occurs by monitoring the battery-pack voltage between the CSOUT and PGND pins. The bq24180 is a fixed single-cell voltage version, with adjustable regulation voltage (3.5V to 4.44V) programmed using the I2C interface. The bq24180 monitors the charging current during the voltage regulation phase. Once the termination threshold, ITERM, is detected and the battery voltage is above the recharge threshold, the bq24180 terminates charge. The termination current level is programmable. To disable the charge current termination, the host sets the charge termination bit (TE) of charge control register to 0, refer to I2C section for details. A new charge cycle is initiated when one of the following conditions is detected: 1. The battery voltage falls below the VOREG-VRCH threshold. 2. VBUS Power-on reset (POR), if battery voltage is below the VPRECHARGE threshold 3. CE bit toggle or RESET bit is set (Host controlled) Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 17 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com HOST Mode Battery Charging Start 32 second watchdog timer Safety Timer expired? Charging suspended Enter suspended mode Fault indicated in STAT registers Yes Safety timer fault No No Term Enabled ? Yes Yes Charge Done? ICHG < ITERM No Yes Yes CV Mode? Battery Present? No STAT = Hi Update STAT bits Terminate Safety Timer No Indicate Battery Not Present Fault Reset I2C to default VBAT <VRCH? Yes No DEFAULT Mode ? Begin HOST Mode Battery Charging Yes Begin DEFAULT Mode Battery Charge Cycle 32s timer expired? Yes No No Indicate Timer Fault Reset I2C to default Received SW watchdog RESET? Yes Reset 32 second watchdog timer Begin DEFAULT Mode Battery Charge Cycle Figure 28. Host Mode Charging Process DEFAULT Mode DEFAULT mode is used when I2C communication is not available. DEFAULT mode is entered in the following situations: 1. When the charger is enabled and VBAT>3.6V before I2C communication is established 2. When the watchdog timer expires without a reset from the I2C interface and the safety timer has not expired. 3. When the device comes out of any fault condition (sleep mode, OVP, faulty adapter mode, etc.) before I2C communication is established In default mode, the I2C registers are reset to the default values. The 27 min safety timer is reset and starts when DEFAULT mode is entered. The default value for VOREG is 3.6V, and the default value for ICHARGE is 1A. The input current limit is determined by the PSEL input. If PSEL selects adapter mode, there is no input current limit. If PSEL selects PC mode, the input current limit is set to 100mA. Default mode is exited by programming the I2C interface. Startup into DEFAULT mode is shown in Figure 29. Note that if termination is enabled and charging has terminated, a new charge cycle is NOT initiated when entering DEFAULT mode. 18 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Begin DEFAULT Mode Battery Charge Cycle Reset safety timer to 27min and start Safety Timer expired? Yes Safety timer fault No Charging suspended Enter suspended mode Fault indicated in STAT registers PSEL = Hi? AC Adapter Mode (AAM) Yes No Load default values to I2C registers. No Input Current Limit STAT = 0 PC Mode Load PC default values for input current limit from I2C registers. STAT = 0 No No Load Optimized Charge Parameters? Yes Begin HOST Mode Battery Charging Figure 29. DEFAULT Mode Charging Process Safety Timer and Watchdog Timer in Charge Mode At the beginning of charging process, the bq24180 starts the safety timer. This timer is active during the entire charging process. If charging has not terminated before the safety timer expires, the IC enters suspend mode where charging is halted. The safety timer time is selectable using the I2C interface. A single 128µs pulse is sent on the STAT and INT outputs and the STATx bits of the status registers are updated in the I2C. The EN bit or power must be toggled in order to clear the safety timer fault. The safety timer duration is selectable using the TMR_X bits in the VIN-DPM Voltage/ Safety Timer Register. Changing the safety timer duration resets the safety timer. In addition to the safety timer, the bq24180 contains a watchdog timer that monitors the host through the I2C interface. Once a read/write is performed on the I2C interface, a 12-second timer (tWATCHDOG) is started. The 12-second timer is reset by the host using the I2C interface. This is done by writing a "1" to the reset bit (TMR_RST) in the control register. The TMR_RST bit is automatically set to “0” when the 12-second timer is reset. This process continues until battery is fully charged or the safety timer expires. If the 12-second timer expires, the IC enters DEFAULT mode where the default charge parameters are loaded, the safety timer restarts at 27 minutes and charging continues. The I2C may be accessed again to reinitialize the desired values and restart the watchdog timer as long as the 27 minute safety timer has not expired. Once the safety timer expires, charging is disabled. This function prevents continuous charging of a defective battery if the host fails to reset the safety timer. The watchdog timer flow chart is shown in Figure 30. Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 19 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com Start Safety Timer Safety timer expired? Yes Safety timer fault No Charge Done? ICHG < ITERM Yes STAT = Hi Update STAT bits Yes STAT = Hi Update STAT bits Charging suspended Enter suspended mode Fault indicated in STAT registers No No I2C Read/Write performed? Yes Start 12 second watchdog timer Charge Done? ICHG < ITERM Reset 12 second watchdog timer No Yes Safety timer fault Safety timer expired? No Charging suspended Enter suspended mode Fault indicated in STAT registers No Yes 12s timer expired? Yes No Received SW watchdog RESET? Reset to default values in I2C register Restart 27min safety timer Figure 30. The Watchdog Timer Flow Chart for bq24180 Power Source Selector Input (PSEL) The bq24180 contains a PSEL input that is used to program the input current limit during DEFAULT mode. Drive PSEL high to indicate a USB source is connected to the input and the PC mode default values should be used. When PSEL is high, the IC starts up with a 100mA input current limit and a 1A charge current. Drive PSEL low to indicate that an AC Adapter is connected to the input. When PSEL is high, the IC starts up with no input current limit and a 1A charge current. PSEL is internally pulled up to the DRV supply with a 100kΩ resistor. 20 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Hardware Disable Input (CD) The bq24180 contains a CD input that is used to disable the charger and place the bq24180 into high-impedance mode. Drive CD low to enable charge and enter normal operation. Drive CD high to disable charge and place the bq24180 into high-impedance mode. Driving CD high during DEFAULT mode resets the safety timer. Driving CD high during HOST mode suspends, but does NOT reset the safety timer. CD is internally pulled down to GND with a 100kΩ resistor. LDO Output (DRV) The bq24180 contains a linear regulator (DRV) that is used to supply the internal MOSFET drivers and other circuitry. Additionally, DRV supplies up to 10mA external loads to power the STAT LED or the USB transceiver circuitry. The maximum value of the DRV output is 5.5V so it ideal to protect voltage sensitive USB circuits. The LDO is on whenever a VBUS supply is connected to the bq24180. The DRV is disabled under the following conditions: 1. Faulty adapter detected or VBUS < UVLO 2. Thermal Shutdown AC Adapter Mode, Charge Current Limiting After power is connected and startup is initiated, the PSEL input is read to determine the default startup values. If PSEL is 0, AC Adapter mode is selected. In AC Adapter mode, the charge current is regulated to maximize the charging time. The default parameters in AC Adapter mode are ICHARGE=1A and VOUTREG=3.6V. These values may be changed at any time using the I2C interface. Additionally, if input current monitoring is required, this may be used during AC Adapter mode as well, but is disabled in DEFAULT mode. PC Mode, Input Current Limiting After power is connected and startup is initiated, the PSEL input is read to determine the default startup values. In PC mode, the input current is limited to maximize the charge rate of bq24180 without overloading the USB port. The input current for bq24180 can be limited to 100mA, 500mA or 800mA and is programmed in the control register. Once the input current reaches the input current limiting threshold, the charge current is reduced to prevent the input current from exceeding the programmed threshold. The input current sensing resistor and control loop are integrated into bq24180. The input current limit is disabled using I2C control; refer to the definition of control register (01H) for detail. The default parameters in USB mode are IINLIM=100mA and VOUTREG=3.6V. Charge current may be monitored in PC mode as well, but by default it is set to a maximum such that the input current limit loop is active. DCOUT Functionality The bq24180 contains a DCOUT function that is used to connect a load to the battery through a switch. DCOUT is implemented using back to back MOSFETs (Q4 and Q5 in Figure 1) to connect DCOUT to the battery. This prevents reverse feeding the battery from DCOUT when DCOUT is disabled. DCOUT is a current limited source and can provide up to 1A to power additional accessories. The current limit is programmable from 370mA to 1.5A in 4 steps using the I2C interface. Additionally, the DCOUT output is enabled or disabled using the I2C interface. If the load on DCOUT reaches the current limit, the FET that connects DCOUT to the battery is turned off after the deglitch time (tdgl_DCOUT), a single 128µs pulse is sent on the STAT and INT outputs and the FAULT_x bits of the status register are updated in the I2C. The DCOUT may be enabled after the fault using the I2C interface. External NTC Monitoring (TS) The bq24180 provides a TS input for monitoring an external NTC thermistor. A current is sourced to the NTC from the TS input and the voltage is monitored. There are 3 temperature thresholds that are monitored; the cold battery threshold (TNTC < 5°C), the warm battery threshold (45°C < TNTC < 55°C) and the hot battery threshold (TNTC > 55°C). These temperatures correspond to the VHOT, VWARM, and VCOLD thresholds when using a 4.7kΩ NTC thermistor (b=3500). The TS input is monitored at all times, however, it only affects charging during default mode. During default mode, charging is suspended and timers are suspended when TNTC < 5°C or TNTC > 55°C. When 45°C < TNTC < 55°C, the charging current is reduced to 400mA (max). In PC mode, the charge current remains at 100mA in this mode. Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 21 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com 1A 400 mA T1 (5ºC) T2 (45ºC) T3 (55ºC) Figure 31. Charge Current During TS Conditions in Default Mode When the bq24180 is not in default mode, the TS input is monitored and faults are displayed in the I2C registers. If any of the 3 TS fault conditions occur, a single 128µs pulse is sent on the STAT and INT outputs and the STATx and FAULT_x bits of the status registers are updated in the I2C. The FAULT_x bits signal a general temperature fault. The TS_FAULTX bits in the NTC Monitor Register show the exact TS fault that has occurred. INTC bq24180 TS + PACK+ TEMP VCOLD + VHOT + VWARM PACK- Figure 32. TS Circuit Thermal Regulation and Protection During the charging process, to prevent overheat of the chip, bq24180 monitors the junction temperature, TJ, of the die and begins to taper down the charge current once TJ reaches the thermal regulation threshold, TCF. The charge current is reduced to zero when the junction temperature increases about 10°C above TCF. At any state, if TJ exceeds TSHTDWN, bq24180 terminates charging and disables DCOUT in the I2C register. During thermal shutdown mode, PWM is turned off, all timers are terminated and reset, and a single 128µs pulse is sent on the STAT and INT outputs and the STATx and FAULT_x bits of the status registers are updated in the I2C. A new charging cycle begins when TJ falls below TSHTDWN by approximately 10°C. DCOUT must be enabled by the host after a thermal shutdown fault. 22 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Input Voltage Protection in Charge Mode Sleep Mode The bq24180 enters the low-power sleep mode if the voltage on VVBUS falls below sleep-mode entry threshold, VCSOUT+VSLP, and VVBUS is higher than the undervoltage lockout threshold, VUVLO. This feature prevents draining the battery during the absence of VVBUS. During sleep mode, both the reverse blocking switch Q1 and PWM are turned off. Once the input rises above the sleep threshold, the device returns to normal operation. Input Voltage Based DPM During normal charging process, if the input power source is not able to support the programmed or default charging current, VBUS voltage will decease. Once the VBUS drops to VVBUS_LOW (default 4.76V), the charge current is tapered down to prevent the further drop of VBUS. When the IC enters this mode, the charge current is lower than the set value and the DPM_STATUS bit is set (B4 in Register 05H). This feature ensures IC compatibility with adapters with different current capabilities. Faulty Adapter Detection When an input source is connected to the bq24180, the device enter faulty adapter detection mode. In this mode, the IC sources 30mA to the battery for tINT. After tINT, the input voltage is monitored. If VVBUS>VIN(MIN), the device continues the startup sequence. If VVBUS<VIN(MIN), a single 128µs pulse is sent on the STAT and INT outputs and the STATx and FAULT_x bits of the status registers are updated in the I2C and the process repeats until a good adapter is detected. High-Input and Input Over-Voltage Protection The bq24180 provides two levels over-voltage protection on the input. A high-input comparator disables the PWM operation and sources the 50mA precharge current to the battery when VHIGH < VVBUS < VOVP. This allows for unregulated adapters to be used. The 50mA pulls the adapter voltage down to the usable voltage and then normal operation begins. The built-in input over-voltage protection to protect the device and other components against damage from overvoltage on the input supply (Voltage from VVBUS to PGND). When VVBUS > VOVP, the bq24180 latches off the PWM converter, a single 128µs pulse is sent on the STAT and INT outputs and the STATx and FAULT_x bits of the status registers are updated in the I2C. Once the OVP fault is removed, the STATx and FAULT_x bits are cleared and the device returns to normal operation. Charge Status Outputs (STAT, INT) The STAT and INT outputs are used to indicate operation conditions for bq24180. STAT and INT are pulled low during charging when EN_STAT bit in the control register (00H) is set to “1”. When charge is complete or disabled, INT and STAT are high impedance. When a fault occurs, a 128-µs pulse (interrupt) is sent out to notify the host. The status of STAT and INT during different operation conditions is summarized in Table 1. STAT drives an LED for visual indication. INT is available for connecting to the logic rail for host communication. Table 1. STAT Pin Summary CHARGE STATE STAT and INT BEHAVIOR Charge in progress and EN_STAT=1 Low Other normal conditions Open-drain Charge mode faults: Timer fault, sleep mode, VBUS over voltage, VBUS UVLO, thermal shutdown 128-µs pulse, then open-drain Control Bits in Charge Mode CE Bit (Charge Enable) The bit of CE in control register is used to disable or enable the charge process. A low logic level (0) on this bit enables the charge and a high logic level (1) disables the charge. RESET Bit Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 23 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com The bit of RESET in control register is used to reset all the charge parameters. Write ‘1” to RESET bit to reset all the charge parameters to default values and RESET bit is automatically cleared to zero once the charge parameters get reset. It is designed for charge parameter reset before charge starts and it is not recommended to set RESET bit when charging or boosting in progress. Output Inductor and Capacitor Selection Guidelines The bq24180 provides internal loop compensation. With this scheme, best stability occurs when LC resonant frequency, of, is approximately 40 kHz (20 kHz to 80 kHz). Equation 1 can be used to calculate the value of the output inductor, LOUT, and output capacitor, COUT. 1 ¦o = 2p ´ LOUT ´ COUT (1) To reduce the output voltage ripple, a ceramic capacitor with the capacitance between 4.7µF and 47µF is recommended for COUT, refer to the application section for components selection. Selecting Current Sense Resistor Both the termination current range and charge current range are depending on the sensing resistor (RSNS). The termination current step (IOTERM_STEP) can be calculated using Equation 2: V IOTERM_STEP = ITERM0 RSNS (2) Table 2 shows the termination current settings with two sensing resistors. Table 2. Termination Current Settings for 68mΩ and 100mΩ Sense Resistors BIT VITERM (mV) ITERM (mA) RSNS = 68 mΩ ITERM (mA) RSNS = 100 mΩ VITERM2 6.8 100 68 VITERM1 3.4 50 43 VITERM0 1.7 25 17 Offset 1.7 25 17 The charge current step (IOCHARGE_STEP) can be calculated using Equation 3: V IOCHARG E_STEP = ICHRG0 R SNS (3) Table 3 shows the charge current settings with two sensing resistors. Table 3. Charge Current Settings for 68 mΩ and 100 mΩ Sense Resistors 24 BIT VIREG (mV) IOCHARGE (mA) RSNS = 68 mΩ IOCHARGE (mA) RSNS = 100 mΩ VICHRG3 54.4 800 544 VICHRG2 27.2 400 272 VICHRG1 13.6 200 136 VICHRG0 6.8 100 68 Offset 37.4 550 374 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 SERIAL INTERFACE DESCRIPTION I2C is a 2-wire serial interface developed by Philips Semiconductor (see I2C-Bus Specification, Version 2.1, January 2000). The bus consists of a data line (SDA) and a clock line (SCL) with pull-up structures. When the bus is idle, both SDA and SCL lines are pulled high. All the I2C compatible devices connect to the I2C bus through open drain I/O pins, SDA and SCL. A master device, usually a microcontroller or a digital signal processor, controls the bus. The master is responsible for generating the SCL signal and device addresses. The master also generates specific conditions that indicate the START and STOP of data transfer. A slave device receives and/or transmits data on the bus under control of the master device. The bq24180 device works as a slave and is compatible with the following data transfer modes, as defined in the I2C Bus™ Specification: standard mode (100 kbps), fast mode (400 kbps), and high-speed mode (up to 3.4 Mbps in write mode). The interface adds flexibility to the battery charge solution, enabling most functions to be programmed to new values depending on the instantaneous application requirements. Register contents remain intact as long as battery voltage remains above 2.5 V (typical). The I2C circuitry is powered from VBUS when a supply is connected. If the VBUS supply is not connected, the I2C circuitry is powered from the battery through CSOUT. The battery voltage must stay above 2.5V with no input connected in order to maintain proper operation. The data transfer protocol for standard and fast modes is exactly the same; therefore, they are referred to as the F/S-mode in this document. The protocol for high-speed mode is different from the F/S-mode, and it is referred to as the HS-mode. The bq24150/1 device only supports 7-bit addressing. The device 7-bit address is defined as ‘1101011’ (6BH). F/S Mode Protocol The master initiates data transfer by generating a start condition. The start condition is when a high-to-low transition occurs on the SDA line while SCL is high, as shown in Figure 33. All I2C -compatible devices should recognize a start condition. DATA CLK START Condition STOP Condition Figure 33. START and STOP Condition The master then generates the SCL pulses, and transmits the 8-bit address and the read/write direction bit R/W on the SDA line. During all transmissions, the master ensures that data is valid. A valid data condition requires the SDA line to be stable during the entire high period of the clock pulse (see Figure 34). All devices recognize the address sent by the master and compare it to their internal fixed addresses. Only the slave device with a matching address generates an acknowledge (see Figure 34) by pulling the SDA line low during the entire high period of the ninth SCL cycle. Upon detecting this acknowledge, the master knows that communication link with a slave has been established. DATA CLK Data Line Stable; Data Valid Charge of Data Allowed Figure 34. Bit Transfer on the Serial Interface The master generates further SCL cycles to either transmit data to the slave (R/W bit 1) or receive data from the slave (R/W bit 0). In either case, the receiver needs to acknowledge the data sent by the transmitter. So an acknowledge signal can either be generated by the master or by the slave, depending on which one is the Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 25 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com receiver. the 9-bit valid data sequences consisting of 8-bit data and 1-bit acknowledge can continue as long as necessary. To signal the end of the data transfer, the master generates a stop condition by pulling the SDA line from low to high while the SCL line is high (see Figure 35). This releases the bus and stops the communication link with the addressed slave. All I2C compatible devices must recognize the stop condition. Upon the receipt of a stop condition, all devices know that the bus is released, and wait for a start condition followed by a matching address. If a transaction is terminated prematurely, the master needs sending a STOP condition to prevent the slave I2C logic from remaining in a incorrect state. Attempting to read data from register addresses not listed in this section will result in FFh being read out. Data Output by Transmitter Not Acknowledge Data Output by Receiver Acknowledge SCL From Master Clock Pulse for Acknowledgement START Condition Figure 35. Acknowledge on the I2C Bus Figure 36. Bus Protocol F/S Mode Protocol When the bus is idle, both SDA and SCL lines are pulled high by the pull-up devices. The master generates a start condition followed by a valid serial byte containing HS master code '00001XXX'. This transmission is made in F/S mode at no more than 400 Kbps. No device is allowed to acknowledge the HS master code, but all devices must recognize it and switch their internal setting to support 3.4-Mbps operation. 26 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 The master then generates a repeated start condition (a repeated start condition has the same timing as the start condition). After this repeated start condition, the protocol is the same as F/S mode, except that transmission speeds up to 3.4 Mbps are allowed. A stop condition ends the HS mode and switches all the internal settings of the slave devices to support the F/S mode. Instead of using a stop condition, repeated start conditions should be used to secure the bus in HS mode. If a transaction is terminated prematurely, the master needs sending a STOP condition to prevent the slave I2C logic from remaining in a incorrect state. Attempting to read data from register addresses not listed in this section results in FFh being read out. Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 27 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com REGISTER DESCRIPTION blank paragraph for spacer Status/Control Register (READ/WRITE) – Memory location: 00, Reset state: x1xx 0xxx BIT NAME Read/Write FUNCTION B7(MSB) TMR_RST Read/Write Write: TMR_RST function, write "1" to reset the watchdog timer (auto clear) Read: 0 – PSEL indicates low, 1- PSEL indicates high B6 EN_STAT Read/Write 1-Enable STAT function, 0-Disable STAT function (default 1) B5 STAT2 Read only B4 STAT1 Read only B3 NA Read only B2 FAULT_3 Read only B1 FAULT_2 Read only B0(LSB) FAULT_1 Read only 00-Ready, 01-Charge in progress, 10-Charge done, 11-Fault NA Charge mode: 000-Normal, 001-VBUS OVP, 010-Sleep mode, 011- Faulty Adapter or VBUS<VUVLO, 100-DCOUT Current Limit tripped, 101-Thermal shutdown or TS Fault, 110-Timer fault, 111-No battery blank paragraph for spacer Control Register (READ/WRITE) – Memory location: 01, Reset state: 0011 0000 BIT NAME Read/Write FUNCTION B7(MSB) Iin_Limit_2 Read/Write B6 Iin_Limit_1 Read/Write 00-USB host with 100-mA current limit, 01-USB host with 500-mA current limit, 10-USB host/charger with 800-mA current limit, 11-No input current limit (default 00(1)) B5 DCOUT_ILIM1 Read/Write B4 DCOUT_ILIM2 Read/Write B3 TE Read/Write 1-Enable charge current termination, 0-Disable charge current termination (default 0) B2 CE Read/Write 1-Charger is disabled, 0-Charger enabled (default 0) B1 HZ_MODE Read/Write 1-High impedance mode, 0-Not high impedance mode (default 0) B0 (LSB) DCOUT_EN Read/Write 1-DCOUT Enabled, 0-DCOUT Disabled. (default 0) 00-DCOUT 350mA current limit, 01- DCOUT 750mA current limit, 10- DCOUT 1050mA current limit, 11- DCOUT 1400mA current limit (default 11) (1) When in DEFAULT mode, the PSEL input determines the input current limit. Control/Battery Voltage Register (READ/WRITE) – Memory location: 02, Reset state: 0001 01XX BIT NAME Read/Write FUNCTION B7(MSB) VOREG5 Read/Write Battery Regulation Voltage: 640mV (default 0) B6 VOREG4 Read/Write Battery Regulation Voltage: 320mV (default 0) B5 VOREG3 Read/Write Battery Regulation Voltage: 160mV (default 0) B4 VOREG2 Read/Write Battery Regulation Voltage: 80mV (default 1) B3 VOREG1 Read/Write Battery Regulation Voltage: 40mV (default 0) B2 VOREG0 Read/Write Battery Regulation Voltage: 20mV (default 1) B1 NA Read/Write NA B0(LSB) NA Read/Write NA blank paragraph for spacer • Charge voltage range is 3.5V–4.44V with the offset of 3.5V and step of 20mV (default 3.6V). blank paragraph for spacer 28 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Vender/Part/Revision Register (READ only) – Memory location: 03, Reset state: 0100 0000 BIT NAME Read/Write B7(MSB) Vender2 Read only FUNCTION Vender Code: bit 2 (default 0) B6 Vender1 Read only Vender Code: bit 1 (default 1) B5 Vender0 Read only Vender Code: bit 0 (default 0) B4 PN1 Read only B3 PN0 Read only B2 Revision2 Read only B1 Revision1 Read only B0(LSB) Revision0 Read only For I2C Address 6BH: 00 – bq24180 000: Revision 1.0; 001: Revision 1.1 010-111: Future Revisions Battery Termination/Fast Charge Current Register (READ/WRITE) Memory location: 04, Reset state: 1010 1011 BIT NAME Read/Write B7(MSB) Reset Write only FUNCTION Write: 1-Charger in reset mode, 0-No effect Read: always get "1" B6 VICHRG3 Read/Write Charge current sense voltage: 54.4mV— (default 0) B5 VICHRG2 Read/Write Charge current sense voltage: 27.2mV—(default 1) B4 VICHRG1 Read/Write Charge current sense voltage: 13.6mV— (default 0) B3 VICHRG0 Read/Write Charge current sense voltage: 6.8mV (default 1) B2 VITERM2 Read/Write Termination current sense voltage: 6.8mV (default 0) B1 VITERM1 Read/Write Termination current sense voltage: 3.4mV (default 1) B0(LSB) VITERM0 Read/Write Termination current sense voltage: 1.7mV (default 1) blank paragraph for spacer • Charge current sense voltage offset is 37.4mV and default charge current is 1050mA, if 68mΩ sense resistor is used. • Termination threshold voltage offset is 1.7mV and default termination current is 100mA if a 68mΩ sense resistor is used. blank paragraph for spacer VIN-DPM Voltage/ Safety Timer Register – Memory location: 05, Reset state: XX0X X111 • BIT NAME Read/Write FUNCTION B7(MSB) NA Read/Write NA B6 NA Read/Write NA B5 LOW_CHG Read/Write 1 – Low charge current sense voltage of 23.8mV, 0 – Normal charge current sense voltage at 04H (default 0) B4 DPM_STATUS Read Only 1 – VIN-DPM mode is active, 0 – VIN-DPM mode is not active B3 CD_STATUS Read Only 1 – CD high, Charger disabled, 0 – CD low, Charger enabled B2 VINDPM2 Read/Write VIN-DPM voltage: 320 mV (default 1) B1 VINDPM1 Read/Write VIN-DPM voltage: 160 mV (default 1) B0(LSB) VINDPM0 Read/Write VIN-DPM voltage: 80 mV (default 1) VIN-DPM voltage offset is 4.15V and default VIN-DPM threshold is 4.71V. blank paragraph for spacer Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 29 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com Safety Limit Register (READ/WRITE, Write only once after reset!) Memory location: 06, Reset state: 0101 0000 BIT NAME Read/Write FUNCTION B7(MSB) VMCHRG3 Read/Write Maximum charge current sense voltage: 54.4mV (default 0) B6 VMCHRG2 Read/Write Maximum charge current sense voltage: 27.2mV (default 1) B5 VMCHRG1 Read/Write Maximum charge current sense voltage: 13.6mV (default 0) B4 VMCHRG0 Read/Write Maximum charge current sense voltage: 6.8mV (default 1) B3 VMREG3 Read/Write Maximum battery regulation voltage: 160mV (default 0) B2 VMREG2 Read/Write Maximum battery regulation voltage: 80mV (default 0) B1 VMREG1 Read/Write Maximum battery regulation voltage: 40mV (default 0) B0(LSB) VMREG0 Read/Write Maximum battery regulation voltage: 20mV (default 0) • Maximum charge current sense voltage offset is 550mA (default at 950mA) and the maximum charge current option is 1.55A, if 68-mΩ sensing resistor is used. Maximum battery regulation voltage offset is 4.2V (default at 4.2V) and maximum battery regulation voltage option is 4.44V. Memory location 06 resets only when VBAT voltage drops below VSHORT threshold (typ. 2.0V) goes to logic '0'. During reset, the maximum values in 06H keep the default value regardless of the write action to this register. After reset (VBAT>VSHORT), the maximum values for battery regulation voltage and charge current can be programmed many times until any writing to other register locks the safety limits. Programmed values exclude higher values from memory locations 02 (battery regulation voltage), and from memory location 04 (Fast charge current). If host accesses (write command) to some other register before Safety limit register, the default values hold! • • blank paragraph for spacer NTC Monitor Register (READ/WRITE) – Memory location: 07, Reset state: 100X 0000 BIT NAME Read/Write FUNCTION B7(MSB) 2XTMR_EN Read/Write 1 – Timer slowed by 2x when in thermal regulation or VIN_HIGH protection, 0 – Timer not slowed at any time (default 1) B6 TMR_1 Read/Write B5 TMR_2 Read/Write Safety Timer Time Limit 00 – 27 minute fast charge, 01 – 3 hour fast charge, 10 – 6 hour fast charge, 11 – Disable safety timers (default 00) B4 NA Read/Write NA B3 TS_/EN Read/Write 1 – TS function disabled, 0 – TS function enabled (default 0) B2 TS_FAULT2 Read only B1 TS_FAULT1 Read only B0(LSB) TS_FAULT0 Read only TS Fault Mode: 000 – TS temp < 5°C or TS temp > 55°C, 010 – Normal, No TS fault, 011 – 45°C < TS temp < 55°C, 100–111 – TS Open 30 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 POWER TOPOLOGIES System Load After Sensing Resistor One of the simple high-efficiency topologies connects the system load directly across the battery pack, as shown in Figure 37. The input voltage has been converted to a usable system voltage with good efficiency from the input. When the input power is on, it supplies the system load and charges the battery pack at the same time. When the input power is off, the battery pack powers the system directly. SW VBUS L1 VIN + - Isys Isns Rsns Ichg bq24180 C1 PMID + PGND C4 C3 System Load BAT C2 Figure 37. System Load After Sensing Resistor The advantages: • When the AC adapter is disconnected, the battery pack powers the system load with minimum power dissipations. Consequently, the time that the system runs on the battery pack can be maximized. • It saves the external path selection components and offers a low-cost solution. • Dynamic power management (DPM) can be achieved. The total of the charge current and the system current can be limited to a desired value by adjusting charge current. When the system current increases, the charge current drops by the same amount. As a result, no potential over-current or over-heating issues are caused by excessive system load demand. • The total of the input current can be limited to a desired value by setting input current limit value. So USB specifications can be met easily. • The supply voltage variation range for the system can be minimized. • The input current soft-start can be achieved by the generic soft-start feature of the IC. Design considerations and potential issues: • If the system always demands a high current (but lower than the regulation current), the charging never terminates. Thus, the battery is always charged, and the lifetime may be reduced. • Because the total current regulation threshold is fixed and the system always demands some current, the battery may not be charged with a full-charge rate and thus may lead to a longer charge time. • If the system load current is large after the charger has been terminated, the voltage drop across the battery impedance may cause the battery voltage to drop below the refresh threshold and start a new charge. The charger would then terminate due to low charge current. Therefore, the charger would cycle between charging and terminating. If the load is smaller, the battery has to discharge down to the refresh threshold, resulting in a much slower cycling. • In a charger system, the charge current is typically limited to about 10mA, if the sensed battery voltage is below 2V short circuit protection threshold. This results in low power availability at the system bus. If an external supply is connected and the battery is deeply discharged, below the short circuit protection threshold, the charge current is clamped to the short circuit current limit. This then is the current available to the system during the power-up phase. Most systems cannot function with such limited supply current, and the battery supplements the additional power required by the system. Note that the battery pack is already at the depleted condition, and it discharges further until the battery protector opens, resulting in a system shutdown. • If the battery is below the short circuit threshold and the system requires a bias current budget lower than the short circuit current limit, the end-equipment will be operational, but the charging process can be affected depending on the current left to charge the battery pack. Under extreme conditions, the system current is Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 31 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 • www.ti.com close to the short circuit current levels and the battery may not reach the fast-charge region in a timely manner. As a result, the safety timers flag the battery pack as defective, terminating the charging process. Because the safety timer cannot be disabled, the inserted battery pack must not be depleted to make the application possible. For instance, if the battery pack voltage is too low, highly depleted, or totally dead or even shorted, the system voltage is clamped by the battery and it cannot operate even if the input power is on. System Load Before Sensing Resistor The second circuit is very similar to first one; the difference is that the system load is connected before the sense resistor, as shown in Figure 38. Isys SW VBUS Isns L1 VIN + - Rsns Ichg bq24180 C1 PMID + PGND C4 C3 System Load BAT C2 Figure 38. System Load Before Sensing Resistor The advantages of system load before sensing resistor to system load after sensing resistor: • The charger controller is based only on the current goes through the current-sense resistor. So, the constant current fast charge and termination functions work well, and are not affected by the system load. This is the major advantage of it. • A depleted battery pack can be connected to the charger without the risk of the safety timer expiration caused by high system load. • The host charger can disable termination and keep the converter running to keep battery fully charged, or let the switcher terminate when the battery is full and then run off of the battery via the sense resistor. Design considerations and potential issues: • The total current is limited by the IC input current limit, or peak current protection, or the thermal regulation but not the charge current setting. The charge current does not drop when the system current load increases until the input current limit is reached. This solution is not applicable if the system requires a high current. • Efficiency declines when discharging through the sense resistor to the system. DESIGN EXAMPLE FOR TYPICAL APPLICATION CIRCUITS Systems Design Specifications: • VBUS = 5 V • V(BAT) = 4.2 V (1-Cell) • I(charge) = 1.25 A • Inductor ripple current = 30% of fast charge current 1. Determine the inductor value (LOUT) for the specified charge current ripple: L OUT = VBAT ´ (VBUS - VBAT) VBUS ´ f ´ D IL , the worst case is when battery voltage is as close as to half of the input voltage. 32 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 LOUT = 2.5 ´ (5 - 2.5) 5 ´ (3 ´ 106 ) ´ 1.25 ´ 0.3 (4) LOUT = 1.11 mH Select the output inductor to standard 1 mH. Calculate the total ripple current with using the 1-mH inductor: DIL = DIL = VBAT ´ (VBUS - VBAT) VBUS ´ f ´ LOUT (5) 2.5 ´ (5 - 2.5) 5 ´ (3 ´ 106 ) ´ (1 ´ 10-6 ) (6) ΔIL = 0.42 A Calculate the maximum output current: DIL ILPK = IOUT + 2 ILPK = 1.25 + (7) 0.42 2 (8) ILPK = 1.46 A Select 2.5mm by 2.0mm 1-mH 1.5-A surface mount multi-layer inductor. The suggested inductor part numbers are shown as following. Table 4. Inductor Part Numbers PART NUMBER INDUCTANCE SIZE MANUFACTURER LQM2HPN1R0MJ0 1 mH 2.5 x 2.0 mm muRata MIPS2520D1R0 1 mH 2.5 x 2.0 mm FDK MDT2520-CN1R0M 1 mH 2.5 x 2.0 mm TOKO CP1008 1 mH 2.5 x 2.0 mm Inter-Technical 2. Determine the output capacitor value COUT using 40 kHz as the resonant frequency: fo = 1 2p ´ COUT = COUT = LOUT ´ COUT (9) 1 4p2 ´ f02 ´ LOUT 1 (10) 4p2 ´ (40 ´ 103 )2 ´ (1 ´ 10-6 ) (11) COUT = 15.8 mF Select two 0603 X5R 6.3V 10-mF ceramic capacitors in parallel i.e., muRata GRM188R60J106M. 3. Determine the sense resistor using the following equation: V(RSNS) R(SNS) = I(CHARGE) (12) The maximum sense voltage across sense resistor is 85 mV. In order to get a better current regulation accuracy, V(RSNS) should equal 100mV, and calculate the value for the sense resistor. 85mV R(SNS) = 1.25A (13) R(SNS) = 68 mΩ Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 33 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com This is a standard value. If it is not a standard value, then choose the next close value and calculate the real charge current. Calculate the power dissipation on the sense resistor: P(RSNS) = I(CHARGE) 2 × R(SNS) P(RSNS) = 1252 × 0.068 P(RSNS) = 0.106 W Select 0805 0.25-W 68-mΩ 2% sense resistor, i.e. Sosomu RL122OT-R068-G or RL0816T-R068-F 68-mΩ, 0.125W, 0603, 1%. PCB LAYOUT CONSIDERATION It is important to pay special attention to the PCB layout. The following provides some guidelines: • To obtain optimal performance, the power input capacitors, connected from input to PGND, should be placed as close as possible to the bq24180. The output inductor should be placed close to the IC and the output capacitor connected between the inductor and PGND of the IC. The intent is to minimize the current path loop area from the SW pin through the LC filter and back to the PGND pin. To prevent high frequency oscillation problems, proper layout to minimize high frequency current path loop is critical (see Figure 39). The sense resistor should be adjacent to the junction of the inductor and output capacitor. Route the sense leads connected across the RSNS(R1) back to the IC, close to each other (minimize loop area) or on top of each other on adjacent layers (do not route the sense leads through a high-current path, see Figure 40). • Place all decoupling capacitor close to their respective IC pin and as close as to PGND (do not place components such that routing interrupts power stage currents). All small control signals should be routed away from the high current paths. • The PCB should have a ground plane (return) connected directly to the return of all components through vias (two vias per capacitor for power-stage capacitors, two vias for the IC PGND, one via per capacitor for small-signal components). A star ground design approach is typically used to keep circuit block currents isolated (high-power/low-power small-signal) which reduces noise-coupling and ground-bounce issues. A single ground plane for this design gives good results. With this small layout and a single ground plane, there is no ground-bounce issue, and having the components segregated minimizes coupling between signals. • The high-current charge paths into VBUS, PMID and from the SW pins must be sized appropriately for the maximum charge current in order to avoid voltage drops in these traces. The PGND pins should be connected to the ground plane to return current through the internal low-side FET. • Place 4.7mF input capacitor as close to PMID pin and PGND pin as possible to make high frequency current loop area as small as possible. Place 1mF input capacitor as close to VBUS pin and PGND pin as possible to make high frequency current loop area as small as possible (see Figure 41). L1 VBUS R1 SW V BAT High Frequency BAT V IN PMID C1 Current Path PGND C3 C2 Figure 39. High Frequency Current Path 34 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 bq24180 www.ti.com SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 Charge Current Direction R SNS To Inductor To Capacitor and battery Current Sensing Direction CSOUT must be as large as possible to avoid error when using DCOUT To CSIN and CSOUT pin Figure 40. Sensing Resistor PCB Layout VBUS Vin+ PMID SW 1uF Vin4.7uF PGND Figure 41. Input Capacitor Position and PCB Layout Example PACKAGE SUMMARY WCSP PACKAGE (Top View) CHIP SCALE PACKAGE (Top Side Symbol For bq24180) VBUS VBUS BOOT SCL SDA PMID PMID PMID INT CD SW SW SW PSEL STAT PGND PGND PGND DCOUT DCOUT CSIN TS DRV CSOUT CSOUT D TI YMLLLLS bq24180 E 0-Pin A1 Marker, TI-TI Letters, YM- Year Month Date Code, LLLL-Lot Trace Code, S-Assembly Site Code CHIP SCALE PACKAGING DIMENSIONS TM The bq24180 devices are available in a 20-bump chip scale package (YFF, NanoFree ). The package dimensions are: · D = 2.2 ± 0.05 mm · E = 2.4 ± 0.05 mm Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 35 bq24180 SLUSA02 A – FEBRUARY 2010 – REVISED FEBRUARY 2010 www.ti.com REVISION HISTORY Changes from Original (February 2010) to Revision A • 36 Page Changed ±7 to "-0.3 to 7 V" for "Voltage difference between BOOT and SW inputs (VBOOT –VSW)" parameter of the Absolute Maximum Ratings table. .................................................................................................................................. 2 Submit Documentation Feedback Copyright © 2010, Texas Instruments Incorporated Product Folder Link(s): bq24180 PACKAGE OPTION ADDENDUM www.ti.com 12-Mar-2010 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty BQ24180YFFR ACTIVE DSBGA YFF 25 3000 Green (RoHS & no Sb/Br) Call TI Level-1-260C-UNLIM BQ24180YFFT ACTIVE DSBGA YFF 25 250 Call TI Level-1-260C-UNLIM 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. 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