19-2099; Rev 0; 7/01 ILABLE N KIT AVA EVALUATIO Simple Current-Limited Switch-Mode Li+ Charger Controller The low-cost MAX1873R/S/T provides all functions needed to simply and efficiently charge 2-, 3-, or 4series lithium-ion cells at up to 4A or more. It provides a regulated charging current and voltage with less than ±0.75% total voltage error at the battery terminals. An external P-channel MOSFET operates in a step-down DC-DC configuration to efficiently charge batteries in low-cost designs. The MAX1873R/S/T regulates the battery voltage and charging current using two control loops that work together to transition smoothly between voltage and current regulation. An additional control loop limits current drawn from the input source so that AC adapter size and cost can be minimized. An analog voltage output proportional to charging current is also supplied so that an ADC or microcontroller can monitor charging current. The MAX1873 may also be used as an efficient currentlimited source to charge NiCd or NiMH batteries in multichemistry charger designs. The MAX1873R/S/T is available in a space-saving 16-pin QSOP package. Use the evaluation kit (MAX1873EVKIT) to help reduce design time. Features ♦ Low-Cost and Simple Circuit ♦ Charges 2-, 3-, or 4-Series Lithium-Ion Cells ♦ AC Adapter Input-Current-Limit Loop ♦ Also Charges Ni-Based Batteries ♦ Analog Output Monitors Charge Current ♦ ±0.75% Battery-Regulation Voltage ♦ 5µA Shutdown Battery Current ♦ Input Voltage Up to 28V ♦ 200mV Dropout Voltage/100% Duty Cycle ♦ Adjustable Charging Current ♦ 300kHz PWM Oscillator Reduces Noise ♦ Space-Saving 16-Pin QSOP ♦ MAX1873 Evaluation Kit Available to Speed Designs Ordering Information TEMP. RANGE PIN-PACKAGE MAX1873REEE -40°C to +85°C 16 QSOP Notebook Computers MAX1873SEEE -40°C to +85°C 16 QSOP Portable Internet Tablets MAX1873TEEE -40°C to +85°C 16 QSOP Applications PART 2-, 3-, or 4-cell Li+ Battery Pack Chargers Typical Operating Circuit 6-, 9-, or 10-cell Ni Battery Pack Chargers Hand-Held Instruments Portable Desktop Assistants (PDAs) Desktop Cradle Chargers SYSTEM LOAD VIN 9V TO 28V (9V MIN FOR 2CELLS) VH VL Selector Guide DCIN CSSP MAX1873 CSSN PART SERIES CELLS TO CHARGE 4V OUT PER 200mV ON RCS MAX1873REEE 2-Cell Li+ or 5- or 6-cell Ni Battery MAX1873SEEE 3-Cell Li+ or 7- or 9-cell Ni Battery ICHG/EN MAX1873TEEE 4-Cell Li+ 10-cell Ni Battery Packs REF IOUT EXT CSB BATT CCI VADJ Pin Configuration appears at end of data sheet. CCS GND CCV 2- TO 4-CELL Li+ ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. 1 MAX1873 General Description MAX1873 Simple Current-Limited Switch-Mode Li+ Charger Controller ABSOLUTE MAXIMUM RATINGS CSSP, CSSN, DCIN to GND ...................................-0.3V to +30V VL, ICHG/EN to GND................................................-0.3V to +6V VH, EXT to DCIN.......................................................-6V to +0.3V VH, EXT to GND ......................................(VDCIN + 0.3V) to -0.3V EXT to VH .................................................................+6V to -0.3V DCIN to VL..............................................................+30V to -0.3V VADJ, REF, CCI, CCV, CCS, IOUT to GND.............................................-0.3V to (VL + 0.3V) BATT, CSB to GND.................................................-0.3V to +20V CSSP to CSSN.......................................................-0.3V to +0.6V CSB to BATT..........................................................-0.3V to +0.6V VL Source Current ............................................................+50mA VH Sink Current ................................................................+40mA Continuous Power Dissipation (TA = +70°C) 16-Pin QSOP (derate 8.3mW/°C above +70°C..........+667mW Operating Temperature Range MAX1873_EEE ................................................-40°C to +85°C Junction Temperature ..................................................... +150°C Storage Temperature Range .............................-65°C to +150°C Lead Temperature (soldering, 10s) ................................ +300°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = 0°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.) PARAMETER CONDITIONS MIN TYP MAX UNITS 28 V 4 7 mA 0.1 10 µA 0.175 V 0.38 V INPUT SUPPLY AND REFERENCE DCIN Input Voltage Range DCIN Quiescent Supply Current 6 6.0V < VDCIN < 28V DCIN ≤ BATT DCIN to BATT Undervoltage Threshold CSSP = DCIN, input falling 0.05 DCIN to BATT Undervoltage Threshold CSSP = DCIN, input rising 0.22 VL Output Voltage 6.0V < VDCIN < 28V 5.15 VL Output Load Regulation IVL = 0 to 3mA REF Output Voltage IREF = 21µA (200kΩ load) REF Line Regulation 6.0V < VDCIN < 28V REF Load Regulation IREF = 0 to 1mA 4.179 5.40 5.65 V 15 50 mV 4.20 4.221 V 2 6 mV 22 65 ppm/V 6 13 mV 300 330 kHz 4 7 Ω 2.5 4.5 Ω 5.75 V SWITCHING REGULATOR PWM Oscillator Frequency 270 EXT Driver Source On-Resistance EXT Driver Sink On-Resistance VH Output Voltage DCIN - VH, 6V < VDCIN <28V, IVH = 0 to 20mA CSSN/CSSP Input Current VCSSN/VCSSP = 28V, VDCIN = 28V 70 200 µA CSSN/CSSP Off-State Leakage VDCIN = VSSN/VCSSP = 18V, VBATT = VCSB = 18V 1.5 5 µA ICHG/EN = 0 (charger disabled) 0.2 1 ICHG/EN = REF (charger enabled) 250 500 DCIN ≤ BATT (input power removed) 1.5 5 BATT, CSB Input Current BATT, CSB Input Current 2 4.75 _______________________________________________________________________________________ µA µA Simple Current-Limited Switch-Mode Li+ Charger Controller (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = 0°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.) PARAMETER BATT Overvoltage Cutoff Threshold MIN TYP MAX 2-cell version MAX1873R CONDITIONS 10.45 11 11.55 3-cell version MAX1873S 15.675 16.5 17.325 17.575 18.5 19.425 7.898 7.958 8.018 4-cell version MAX1873T (Note 1) MAX1873R (2 Li+ cells) Battery Regulation Voltage MAX1873S (3 Li+ cells) MAX1873T (4 Li+ cells) BATT Undervoltage Threshold VVADJ = 0 VVADJ = VREF/2 8.337 8.4 8.463 VVADJ = VREF (Note 1) 8.775 8.842 8.909 VVADJ = 0 11.847 11.937 12.027 VVADJ = VREF/2 12.505 12.6 12.695 VVADJ = VREF (Note 1) 13.163 13.263 13.363 VVADJ = 0 15.796 15.916 16.036 UNITS V V VVADJ = VREF/2 16.674 16.8 16.926 VVADJ = VREF (Note 1) 17.551 17.684 17.817 MAX1873R 4.8 5.0 5.2 MAX1873S 7.2 7.5 7.8 MAX1873T 9.6 10 10.4 VICHG/EN = VREF 190 200 210 VICHG/EN = VREF/4 40 50 60 5 10 15 mV 6V < VCSSP < 28V 90 100 110 mV Includes 50mV of hysteresis 500 600 700 mV 700 VREF mV For ICHG/20 trickle charge V CURRENT SENSE CSB to BATT Battery Current-Sense Voltage CSB to BATT Current-Sense Voltage when VBATT < 2.5V per Cell CSSP to CSSN Current-Sense Voltage mV CONTROL INPUTS/OUTPUTS ICHG/EN Input Threshold ICHG/EN Input Voltage Range For Charge Current Adjustment VADJ Input Current VVADJ = VREF/2 -100 100 nA ICHG/EN Input Current VICHG/EN = VREF -100 100 nA 0 VREF V VADJ Input Voltage Range IOUT Voltage Full scale VCSB - VBATT = 200mV, 0 < IOUT < 500µA 3.6 25% scale VCSB - VBATT = 50mV, 0 < IOUT < 500µA 0.9 1.0 1.1 Trickle charge VCSB - VBATT = 10mV 75 200 325 No charge current VCSB - VBATT = 0, IIOUT = sinking 20µA 40 70 90 4.0 4.4 V mV _______________________________________________________________________________________ 3 MAX1873 ELECTRICAL CHARACTERISTICS (continued) MAX1873 Simple Current-Limited Switch-Mode Li+ Charger Controller ELECTRICAL CHARACTERISTICS (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = -40°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.) PARAMETER CONDITIONS MIN MAX UNITS 6 28 V 7 mA INPUT SUPPLY AND REFERENCE DCIN Input Voltage Range DCIN Quiescent Supply Current 6.0V < VDCIN < 28V DCIN ≤ BATT 10 µA DCIN to BATT Undervoltage Threshold CSSP = DCIN, input falling 0.05 0.2 V DCIN to BATT Undervoltage Threshold CSSP = DCIN, input rising 0.22 0.38 V VL Output Voltage 6.0V < VDCIN < 28V 5.15 5.65 V VL Output Load Regulation IVL = 0 to 3mA 50 mV REF Output Voltage IREF = 21µA (200kΩ load) REF Line Regulation 6.0V < VDCIN < 28V REF Load Regulation IREF = 0 to 1mA 4.179 4.221 V 6 mV 65 ppm/V 13 mV 330 kHz SWITCHING REGULATOR PWM Oscillator Frequency 270 EXT Driver Source On-Resistance EXT Driver Sink On-Resistance VH Output Voltage DCIN - VH, 6V < VDCIN <28V, IVH = 0 to 20mA CSSN/CSSP Input Current VCSSN/VCSSP = 28V, VDCIN = 28V CSSN/CSSP Off-State Leakage VDCIN = VSSN/VCSSP = 18V VBATT = VCSB = 18V BATT, CSB Input Current BATT, CSB Input Current BATT Overvoltage Cutoff Threshold ICHG/EN = 0 (charger disabled) Ω 5.75 V 200 µA 5 µA 500 DCIN ≤ BATT (input power removed) 5 2-cell version MAX1873R 10.45 11.55 3-cell version MAX1873S 15.675 17.325 4-cell version MAX1873T (Note 1) 17.575 19.425 MAX1873S (3 Li+ cells) MAX1873T (4 Li+ cells) 4 Ω 1 ICHG/EN = REF (charger enabled) MAX1873R (2 Li+ cells) Battery Regulation Voltage 4.75 7 4.5 VVADJ = 0 7.898 8.018 VVADJ = VREF/2 8.337 8.463 VVADJ = VREF (Note 1) 8.775 8.909 VVADJ = 0 11.847 12.027 VVADJ = VREF/2 12.505 12.695 VVADJ = VREF (Note 1) 13.163 13.363 VVADJ = 0 15.796 16.036 VVADJ = VREF/2 16.674 16.926 VVADJ = VREF (Note 1) 17.551 17.817 _______________________________________________________________________________________ µA µA V V Simple Current-Limited Switch-Mode Li+ Charger Controller (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = -40°C to +85°C. Typical values are at TA = +25°C, unless otherwise noted.) PARAMETER CONDITIONS MAX1873R BATT Undervoltage Threshold For ICHG/20 trickle charge MIN MAX 4.8 5.2 UNITS MAX1873S 7.2 7.8 MAX1873T 9.6 10.4 VICHG/EN = VREF 190 210 mV VICHG/EN = VREF/4 40 60 mV 5 15 mV 6V < VCSSP < 28V 90 110 mV Includes 50mV of hysteresis 500 700 mV 700 VREF mV V CURRENT SENSE CSB to BATT Battery Current-Sense Voltage CSB to BATT Current-Sense Voltage when VBATT < 2.5V per Cell CSSP to CSSN Current-Sense Voltage CONTROL INPUTS/OUTPUTS ICHG/EN Input Threshold ICHG/EN Input Voltage Range for Charge Current Adjustment VADJ Input Current VVADJ = VREF/2 -100 100 nA ICHG/EN Input Current VICHG/EN = VREF -100 100 nA 0 VREF V VADJ Input Voltage Range IOUT Voltage Full scale VCSB - VBATT = 200mV, 0 < IOUT < 500µA 3.6 4.4 25% scale VCSB - VBATT = 50mV, 0 < IOUT < 500µA 0.9 1.1 Trickle charge VCSB - VBATT = 10mV 75 325 No charge current VCSB - VBATT = 0, IIOUT = sinking 20µA 40 90 V mV Note 1: While it may appear possible to set the Battery Regulation Voltage higher than the Battery Overvoltage Cutoff Threshold, this cannot happen because both parameters are derived from the same reference and track each other. Note 2: Specifications to -40°C are guaranteed by design, not production tested. _______________________________________________________________________________________ 5 MAX1873 ELECTRICAL CHARACTERISTICS (continued) Typical Operating Characteristics (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = +25°C, unless otherwise noted). IOUT VOLTAGE vs. CSB-BATT VOLTAGE MAX1873T (4-CELL) BATTERY VOLTAGE vs. CHARGING CURRENT MAX1873 toc02 15.0 4.0 3.5 12.5 IOUT VOLTAGE (V) BATTERY VOLTAGE (V) 4.5 MAX1873 toc01 17.5 10.0 7.5 3.0 2.5 2.0 1.5 5.0 1.0 2.5 0.5 RCSB + 0.068Ω 0 0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 0 50 CHARGING CURRENT (A) 150 200 250 RECENT VOLTAGE VS. TEMPERATURE 4.205 REFERENCE VOLTAGE (V) 17.5 17.0 16.5 16.0 MAX1873 toc04 4.210 MAX1873 toc03 18.0 BATTERY REGULATION VOLTAGE (V) 100 CSB-BATT VOLTAGE (mV) MAX1873T (4-CELL) BATTERY REGULATION VOLTAGE vs. VADJ VOLTAGE 4.200 4.195 4.190 4.185 MAX1873T 4.180 15.5 0 1 2 3 4 -50 5 0 25 50 75 TEMPERATURE (°C) RECENT VOLTAGE MAX1873R (2-CELL) EFFICIENCY vs. INPUT VOLTAGE 4.205 90 EFFICIENCY (%) 4.200 4.195 4.190 100 MAX1873 toc06 100 MAX1873 toc05 4.210 80 70 60 4.185 VBATT = 7V ICHG = 3A MAX1873T 4.180 50 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 REFERENCE VOLTAGE (mA) 6 -25 VADJ VOLTAGE (V) VS. REFERENCE CURRENT REFERENCE VOLTAGE (V) MAX1873 Simple Current-Limited Switch-Mode Li+ Charger Controller 8 12 16 20 24 INPUT VOLTAGE (V) _______________________________________________________________________________________ 28 Simple Current-Limited Switch-Mode Li+ Charger Controller MAX1873T (4-CELL) EFFICIENCY vs. INPUT VOLTAGE MAX1873S (3-CELL) EFFICIENCY vs. INPUT VOLTAGE 80 70 60 80 70 60 VBATT = 10.5V ICHG = 3A VBATT = 14V ICHG + 3A 50 50 12 16 20 24 16 28 20 22 24 26 4-CELL BATTERY VOLTAGE AND CHARGING CURRENT vs. TIME CHARGING CURRENT vs. SYSTEM LOAD CURRENT 3.0 2.5 2.5 12 2.0 10 1.5 CHARGING CURRENT 8 1.0 6 0.5 4 0 25 50 75 100 TIME (MINUTES) 125 150 CHARGING CURRENT (A) 3.0 CHARGING CURRENT (A) MAX1873 toc09 BATTERY VOLTAGE 14 3.5 28 MAX1873 toc10 INPUT VOLTAGE (V) 16 0 18 INPUT VOLTAGE (V) 18 BATTERY VOLTAGE (V) MAX1873 toc08 90 EFFICIENCY (%) 90 EFFICIENCY (%) 100 MAX1873 toc07 100 2.0 1.5 1.0 0.5 0 0 0.5 1.0 1.5 2.0 2.5 3.0 SYSTEM LOAD CURRENT (A) _______________________________________________________________________________________ 7 MAX1873 Typical Operating Characteristics (continued) (Circuit of Figure 1, VDCIN = VCSSP = VCSSN = 18V, VICHG/EN = VREF, VVADJ = VREF/2. MAX1873R: VBATT = VCSB = 8.4V; MAX1873S: VBATT = VCSB = 12.6V; MAX1873T: VBATT = VCSB = 16.8V; TA = +25°C, unless otherwise noted). Simple Current-Limited Switch-Mode Li+ Charger Controller MAX1873 Pin Description PIN 8 NAME FUNCTION 1 CSSN Source Current-Sense Negative Input. Connect a current-sense resistor between CSSP and CSSN to limit total current drawn from the input source. To disable input current sensing, connect CSSN to CSSP. 2 CSSP Source Current-Sense Positive Input. Also used for input source undervoltage sensing. 3 CCS Input-Source-Current Regulation Loop Compensation Point 4 CCV Battery Regulation Voltage Control-Loop Compensation Point. Pulling CCV high (to VL) through a 1.5kΩ resistor disables the voltage control loop for charging NiCd or NiMH batteries. 5 CCI Battery Charge Current Control-Loop Compensation Point 6 ICHG/EN Battery Charging Current Adjust/Shutdown Input. This pin can be connected to a resistive-divider between REF and GND to adjust the charge current sense threshold between CSB and BATT. When ICHG/EN is connected to REF, the CSB-BATT threshold is 200mV. Pull ICHG/EN low (below 500mV) to disable charging and reduce the supply current to 5µA. 7 IOUT Charge Current Monitor Output. Analog Voltage Output that is proportional to charging current. VIOUT = 20 (VCSB - VBATT) or 4V for a 200mV current-sense voltage (maximum load capacitance = 5nF). 8 VADJ Battery Regulation Voltage Adjust. Set the battery regulation voltage from 3.979V per cell to 4.421V per cell with 1% resistors. Output accuracy remains better than 0.75% even with 1% adjusting resistors due to reduced adjustment range. For 4.2V, the voltage-divider resistors must be equal value (nominally 100kΩ each). 9 REF 10 BATT Battery Voltage-Sense Input and Battery Current-Sense Negative Input. Bypass to GND with a 68µF for MAX1873R, 47µF for MAX1873S, and 33µF for MAX1873T. Use capacitors with ESR < 1Ω. 11 CSB Battery Current-Sense Positive Input 12 GND 13 VH 14 EXT 15 DCIN 16 VL 4.2V Reference Voltage Output. Bypass to GND with a 1µF ceramic capacitor. Ground Internal VH Regulator. VH internally supplies power to the EXT driver. Connect a 0.22µF ceramic capacitor between VH and DCIN. Drive Output for External PFET. EXT swings from VDCIN to VDCIN - 5V. Power-Supply Input. DCIN is the input supply for charger IC. Bypass to GND with a 0.22µF ceramic capacitor. Internal VL Regulator. VL powers the MAX1873’s control logic at 5.4V. Bypass to GND with a 2.2µF or larger ceramic capacitor. _______________________________________________________________________________________ Simple Current-Limited Switch-Mode Li+ Charger Controller MAX1873 D1 MBR5340 VIN 17V TO 28V (9V MIN FOR 2- CELLS) CVL 2.2µF RP 4.7Ω CVH 0.22µF VH CDCIN 0.22µF VL CSSP CP 0.01µF DCIN RN 4.7Ω RCSS 0.033Ω SYSTEM LOAD CSSN MAX1873 4V OUT PER 200mV ON RCSB 100kΩ DISABLE CCC 47nF N IOUT EXT L1 10µH CSB CCCS 47nF BATT REF CREF 1µF CCS R1 VADJ CCV RCCV 10kΩ GND CL 47µF P ICHG/EN CCI CCCVS 0.1µF D2 MBR5340 CN 0.01µF RCSB 0.068Ω CBATT 68µF LI+ BATTERY (2- TO 4-CELLS) R2 CCCVP 1nF Figure 1. Typical Application Circuit Detailed Description The MAX1873 includes all of the functions necessary to charge 2-, 3-, or 4-series cell lithium-ion (Li+) battery packs. It includes a high-efficiency step-down DC-DC converter that controls charging voltage and current. It also features input source current limiting so that an AC adapter that supplies less than the total system current in addition to charging current can be used without fear of overload. The DC-DC converter uses an external P-channel MOSFET switch, inductor, and diode to convert the input voltage to charging current or charging voltage. The typical application circuit is shown in Figure 1. Charging current is set by RCSB, while the battery voltage is measured at BATT. The battery regulation voltage limit is nominally set to 8.4V for the R version (2-cells), 12.6V for the S version (3-cells), and 16.8V for the T version (4-cells), but it can also be adjusted to other voltages for different Li+ chemistries. Voltage Regulator Li+ batteries require a high-accuracy voltage limit while charging. The battery regulation voltage is nominally set to 4.2V per cell and can be adjusted ±5.25% by setting the voltage at VADJ between REF and ground. By limiting the adjust range of the regulation voltage, an overall voltage accuracy of better than ±0.75% is maintained while using 1% resistors. An internal error amplifier maintains voltage regulation to within ±0.75%. The amplifier is compensated at CCV (see Figure 1). Individual compensation of the voltage regulation and current regulation loops allows for optimal compensation of each. A typical CCV compensation network is shown in Figure 1 and will suffice for most designs. _______________________________________________________________________________________ 9 MAX1873 Simple Current-Limited Switch-Mode Li+ Charger Controller 5.4 REGULATOR CSSN UNDERVOLTAGE COMPARATOR BATT SHUTDOWN FOR ALL BLOCKS CSSP VL DCIN VH CCS EXT DRIVER CONTROL LOGIC CCV CCI VH VOLTAGE ERROR AMP GND CSB ICHG /EN CURRENT ERROR AMP BATT IOUT 9R R REF VADJ A=1 R 4.2V REFERENCE portions of the system are powered up or put to sleep. Without the benefit of input-current regulation, the input source would have to be able to supply the maximum system current plus the maximum charger-input current. The MAX1873 input-current loop ensures that the system always gets adequate power by reducing charging current as needed. By using the input-current limiter, the size and cost of the AC adapter can be reduced. See Setting the Input-Current Limit section for design details. Input current is measured through an external sense resistor, RCSS, between CSSP and CSSN. The inputcurrent limit feature may be bypassed by connecting CSSP to CSSN. The input-current error amplifier is compensated at CCS. A 47nF capacitor from CCS to GND provides suitable performance for most applications. PWM Controller The pulse-width modulation (PWM) controller drives the external MOSFET at a constant 300kHz to regulate the charging current and voltage while maintaining low noise. The controller accepts inputs from the CCI, CCV, and CCS error amplifiers. The lowest signal of these three drives the PWM controller. An internal clamp limits the noncontrolling signals to within 200mV of the controlling signal to prevent delay when switching between the battery-voltage control, charging-current control, and input-current regulation loops. GND Shutdown Figure 2. Functional Block Diagram Charging-Current Regulator The charging-current regulator limits the battery charging current. Current is sensed by the current-sense resistor (RCSB in Figure 1) connected between BATT and CSB. The voltage on ICHG/EN can also adjust the charging current. Full-scale charging current (ICHG = 0.2V / RCSB) is achieved by connecting ICHG/EN to REF. See Setting the Charging-Current Limit section for more details. The charging-current error amplifier is compensated at CCI (Figure 1). A 47nF capacitor from CCI to GND provides suitable performance for most applications. Input-Current Regulator The input-current regulator limits the source current by reducing charging current when the input current reaches the set input-current limit. In a typical portable design, system load current will normally fluctuate as 10 The MAX1873 stops charging when ICHG/EN is pulled low (below 0.5V) and shuts down when the voltage at DCIN falls below the voltage at BATT. In shutdown, the internal resistive voltage-divider is disconnected from BATT to reduce the battery drain. When AC-adapter power is removed, or when the part is shut down, the MAX1873 typically draws 1.5µA from the battery. Source Undervoltage Shutdown (Dropout) The DCIN voltage is compared to the voltage at BATT. When the voltage at DCIN drops below BATT + 50mV, the charger turns off, preventing drain on the battery when the input source is not present or is below the battery voltage. A diode is typically connected between the input source and the charger input. This diode prevents the battery from discharging through the body diode of the high-side MOSFET should the input be shorted to GND. It also protects the charger, battery, and systems from reversed polarity adapters and negative input voltages. ______________________________________________________________________________________ Simple Current-Limited Switch-Mode Li+ Charger Controller Setting the Charging-Current Limit The charging current ICHG is sensed by the currentsense resistor RCSB between CSB and BATT, and is also adjusted by the voltage at ICHG/EN. If ICHG/EN is connected to REF (the standard connection), the charge current is given by: VIOUT = 20( VCSB − VBATT ) or VOUT = 20(RCSB × ICHG ) ICHG = 0.2V / RCSB where VCSB and VBATT are the voltages at the CSB and BATT pins, and ICHG is the charging current. IOUT can drive a load capacitance of 5nF. Design Procedure Setting the Battery-Regulation Voltage For Li+ batteries, VADJ sets the per-cell battery-regulation voltage limit. To set the VADJ voltage, use a resistive-divider from REF to GND (Figure 1). For a battery voltage of 4.2V per cell, use resistors of equal value (100kΩ each) in the VADJ voltage-divider. To set other battery-regulation voltages, see the remainder of this section. The per-cell battery regulation voltage is a function of Li+ battery chemistry and construction and is usually clearly specified by the manufacturer. If this is not clearly specified, be sure to consult the battery manufacturer to determine this voltage before charging any Li+ battery. Once the per-cell voltage is determined, the VADJ voltage is calculated by the equation: [ ] VVADJ = 9.5( VBATTR ) / N − (9VREF ) where VBATTR is the desired battery-regulation voltage (for the total series-cell stack), N is the number of Li+ battery cells, and VREF is the reference voltage (4.2V). Set VVADJ by choosing R1. R1 should be selected so that the total divider resistance (R1+ R2) is near 200kΩ. R2 can then be calculated as follows: [ ] R2 = VVADJ / ( VREF − VVADJ ) × R1 Since the full range of VADJ (from 0 to VREF) results in a ±5.263% adjustment of the battery-regulation limit (3.979V to 4.421V), the resistive-divider’s accuracy need not be as tight as the output-voltage accuracy. Using 1% resistors for the voltage-divider still provides ±0.75% battery-voltage-regulation accuracy. In some cases, common values for RCSB may not allow the desired charge-current value. It may also be desirable to reduce the 0.2V CSB-to-BATT sense threshold to reduce power dissipation. In such cases, the ICHG/EN input may be used to reduce the charge-current-sense threshold. In those cases the equation for charge current becomes: ( ) ICHG = 0.2V VICH / EN / VREF / RCSB Setting the Input-Current Limit The input-source current limit, IIN, is set by the inputcurrent sense resistor, R CSS , (Figure 1) connected between CSSP and CSSN. The equation for the source current is: IIN = 0.1V / RCSS This limit is typically set to the current rating of the input power source or AC adapter to protect the input source from overload. Short CSSP and CSSN to DCIN if the input-source current-limit feature is not used. Inductor Selection The inductor value may be selected for more or less ripple current. The greater the inductance, the lower the ripple current. However, as the physical size is kept the same, larger inductance value typically results in higher inductor series resistance and lower inductor saturation current. Typically, a good tradeoff is to choose the inductor such that the ripple current is approximately 30% to 50% of the DC average charging current. The ratio of ripple current to DC charging current (LIR) can be used to calculate the inductor value: { [ L = VBATT VDCIN(MAX) − VBATT ]} / [VDCIN(MAX) × fSW × ICHG × LIR] where f SW is the switching frequency (nominally 300kHz) and ICHG is the charging current. The peak inductor current is given by: ______________________________________________________________________________________ 11 MAX1873 Charge-Current Monitor Output IOUT is an analog voltage output that is proportional to the actual charge current. With the aid of a microcontroller, the IOUT signal can facilitate gas-gauging, indicate percent of charge, or charge-time remaining. The equation governing this output is: MAX1873 Simple Current-Limited Switch-Mode Li+ Charger Controller IPEAK = ICHG (1+ LIR / 2) For example, for a 4-cell charging current of 3A, a VDCIN(MAX) of 24V, and an LIR of 0.5, L is calculated to be 11.2µH with a peak current of 3.75A. Therefore a 10µH inductor would be satisfactory. MOSFET Selection The MAX1873 uses a P-channel power MOSFET switch. The MOSFET must be selected to meet the efficiency or power dissipation requirements of the charging circuit as well as the maximum temperature of the MOSFET. Characteristics that affect MOSFET power dissipation are drain-source on-resistance (RDS(ON)) and gate charge. Generally these are inversely proportional. To determine MOSFET power dissipation, the operating duty cycle must first be calculated. When the charger is operating at higher currents, the inductor current will be continuous (the inductor current will not drop to 0). In this case, the high-side MOSFET duty cycle (D) can be approximated by the equation: V D ≈ BATT VDCIN And the catch-diode duty cycle (D') will be 1 - D or: V − VBATT D'≈ DCIN VDCIN where VBATT is the battery-regulation voltage (typically 4.2V per cell) and VDCIN is the source-input voltage. For MOSFETs, the worst-case power dissipation due to on-resistance (PR) occurs at the maximum duty cycle, where the operating conditions are minimum sourcevoltage and maximum battery voltage. P R can be approximated by the equation: PR = VBATT(MAX) VDCIN(MIN) × RDS(ON) × ICHG2 Transition losses (P T ) can be approximated by the equation: V ×I ×f × t TR PT = DCIN CHG SW 3 where tTR is the MOSFET transition time and fSW is the switching frequency. The total power dissipation of the MOSFET is then: 12 PTOT = PR + PT Diode Selection A Schottky rectifier with a current rating of at least the charge current limit must be connected from the MOSFET drain to GND. The voltage rating of the diode must exceed the maximum expected input voltage. Capacitor Selection The input capacitor shunts the switching current from the charger input and prevents that current from circulating through the source, typically an AC wall cube. Thus the input capacitor must be able to handle the input RMS current. At high charging currents, the converter will typically operate in continuous conduction. In this case, the RMS current of the input capacitor can be approximated with the equation: ICIN ≈ ICHG D − D2 where ICIN is the input capacitor RMS current, D is the PWM converter duty cycle (typically VBATT/VDCIN), and ICHG is the battery-charging current. The maximum RMS input current occurs at 50% duty cycle, so the worst-case input-ripple current is 0.5 x ICHG. If the input-to-output voltage ratio is such that the PWM controller will never work at 50% duty cycle, then the worst-case capacitor current will occur where the duty cycle is nearest 50%. The impedance of the input capacitor is critical to preventing AC currents from flowing back into the wall cube. This requirement varies depending on the wall cube’s impedance and the requirements of any conducted or radiated EMI specifications that must be met. Low ESR aluminum electrolytic capacitors may be used, however, tantalum or high-value ceramic capacitors generally provide better performance. The output filter capacitor absorbs the inductor-ripple current. The output-capacitor impedance must be significantly less than that of the battery to ensure that it will absorb the ripple current. Both the capacitance and the ESR rating of the capacitor are important for its effectiveness as a filter and to ensure stability of the PWM circuit. The minimum output capacitance for stability is: VBATT VREF 1+ VDCIN(MIN) COUT > VBATT × fSW × RCSB ______________________________________________________________________________________ Simple Current-Limited Switch-Mode Li+ Charger Controller The maximum output capacitor ESR allowed for stability is: R ×V RESR < CSB BATT VREF where RESR is the output capacitor ESR. tings do not interfere with charging. However, the battery undervoltage-protection features remain active so charging current is reduced when VBATT is less than the levels stated in the BATT Undervoltage Threshold line in the Electrical Characteristics Table. 5- or 6-series Ni cells may be charged with the R version device, 7to 9-cells with the S version, and 10-cells with the T version. The MAX1873 contains no charge-termination algorithms for Ni cells; it acts only as a current source. A separate microcontroller or Ni-cell charge controller must instruct the MAX1873 to terminate charging. Compensation Components The three regulation loops: input current limit, charging current limit, and charging voltage limit are compensated separately using the CCS, CCI, and CCV pins, respectively. Chip Information PROCESS: BiCMOS TRANSISTOR COUNT: 1397 The charge-current loop error-amplifier output is brought out at CCI. Likewise, the source-current erroramplifier output is brought out at CCS. 47nF capacitors to ground at CCI and CCS compensate the current loops in most charger designs. Raising the value of these capacitors reduces the bandwidth of these loops. The voltage-regulating loop error-amplifier output is brought out at CCV. Compensate this loop by connecting a capacitor in parallel with a series resistor-capacitor from CCV to GND. Recommended values are shown in Figure 1. Applications Information VL, VH, and REF Bypassing The MAX1873 uses two internal linear regulators to power internal circuitry. The outputs of the linear regulators are at VL and VH. VL powers the internal control circuitry while VH powers the MOSFET gate driver. VL may also power a limited amount of external circuitry, as long as its maximum current (3mA) is not exceeded. A 2.2µF bypass capacitor is required from VL to GND to ensure stability. A 0.22µF capacitor is required from VH to DCIN. A 1µF bypass capacitor is required between REF and GND to ensure that the internal 4.2V reference is stable. In all cases, use low-ESR ceramic capacitors. Charging NiMH and NiCd Cells The MAX1873 may be used in multichemistry chargers. When charging NiMH or NiCd cells, pull CCV high (to VL) with a 1.5 kΩ resistor. This disables the voltage control loop so the Li+ battery-regulation voltage set- Pin Configuration TOP VIEW CSSN 1 16 VL CSSP 2 15 DCIN CCS 3 CCV 4 14 EXT MAX1873R/S/T 13 VH CCI 5 12 GND ICHG/EN 6 11 CSB IOUT 7 10 BATT VADJ 8 9 REF 16 QSOP ______________________________________________________________________________________ 13 MAX1873 where COUT is the total output capacitance, VREF is the reference voltage (4.2V), VBATT is the maximum battery regulation voltage (typically 4.2V per cell), VDCIN (MIN) is the minimum source-input voltage, and RCSB is the current-sense resistor (68mΩ for 3A charging current) from CSB to BATT. Simple Current-Limited Switch-Mode Li+ Charger Controller QSOP.EPS MAX1873 Package Information Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 14 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 2001 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.