UC2909 UC3909 Switchmode Lead-Acid Battery Charger FEATURES DESCRIPTION • Accurate and Efficient Control of Battery Charging The UC3909 family of Switchmode Lead-Acid Battery Chargers accurately controls lead acid battery charging with a highly efficient average current mode control loop. This chip combines charge state logic with average current PWM control circuitry. Charge state logic commands current or voltage control depending on the charge state. The chip includes undervoltage lockout circuitry to insure sufficient supply voltage is present before output switching starts. Additional circuit blocks include a differential current sense amplifier, a 1.5% voltage reference, a –3.9mV/°C thermistor linearization circuit, voltage and current error amplifiers, a PWM oscillator, a PWM comparator, a PWM latch, charge state decode bits, and a 100mA open collector output driver. • Average Current Mode Control from Trickle to Overcharge • Resistor Programmable Charge Currents • Thermistor Interface Tracks Battery Requirements Over Temperature • Output Status Bits Report on Four Internal Charge States • Undervoltage Lockout Monitors VCC and VREF BLOCK DIAGRAM Pin numbers refer to J, N, DW packages. 1/99 Powered by ICminer.com Electronic-Library Service CopyRight 2003 UDG-95007-1 UC2909 UC3909 ABSOLUTE MAXIMUM RATINGS Supply Voltage (VCC), OUT, STAT0, STAT1 . . . . . . . . . . . 40V Output Current Sink . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.1A CS+, CS- . . . . . . . . . . . . . . . . . . . . . . . . . . -0.4 to VCC (Note 1) Remaining Pin Voltages. . . . . . . . . . . . . . . . . . . . . . -0.3V to 9V Storage Temperature . . . . . . . . . . . . . . . . . . . -65°C to +150°C Junction Temperature . . . . . . . . . . . . . . . . . . . -55°C to +150°C Lead Temperature (Soldering, 10 sec.) . . . . . . . . . . . . . +300°C All currents are positive into, negative out of the specified terminal. Consult Packaging Section of Databook for thermal limitations and considerations of packages. Note 1: Voltages more negative than -0.4V can be tolerated if current is limited to 50mA. CONNECTION DIAGRAMS DIL-20, (Top View) J or N, DW Packages LCC-28, PLCC-28 (Top View) L, Q Packages ELECTRICAL CHARACTERISTICS: Unless otherwise stated these specifications apply for TA = –40°C to +85°C for UC2909; °0C to +70°C for UC3909; CT = 330pF, RSET = 11.5k, R10 = 10k, RTHM = 10k, VCC = 15V, Output no load, RSTAT0 = RSTAT1 = 10k, CHGENB = OVCTAP = VLOGIC, TA = TJ. PARAMETER Current Sense AMP (CSA) Section DC Gain TEST CONDITIONS MIN TYP MAX UNITS CS– = 0, CS+ = -50mV; CS+ = –250mV 4.90 5 5.10 V/V CS+ = 0, CS– = 50mV; CS–- = 250mV 4.90 5 5.10 V/V 15 mV VID = CS+ – CS– VOFFSET (VCSO – VCAO) CS+ = CS– = 2.3V, CAO = CA– CMRR VCM = –0.25 to VCC – 2, 8.8 < VCC < 14 50 VCM = –0.25 to VCC, 14 < VCC < 35 50 VOL VID = –550mV, –0.25V < VCM < VCC–2, IO = 500µA VOH VID = +700mV, –0.25V < VCM < VCC–2, IO = –250µA Output Source Current VID = +700mV, CSO = 4V Output Sink Current VID = –550mV, CSO = 1V 3dB Bandwidth VID = 90mV, VCM = 0V Powered by ICminer.com Electronic-Library Service CopyRight 2003 2 dB dB 0.3 0.6 V 5.2 5.7 6.2 V –1 –0.5 mA 3 4.5 200 mA kHz UC2909 UC3909 ELECTRICAL CHARACTERISTICS: Unless otherwise stated these specifications apply for TA = –40°C to +85°C for UC2909; °0C to +70°C for UC3909; CT = 330pF, RSET = 11.5k, R10 = 10k, RTHM = 10k, VCC = 15V, Output no load, RSTAT0 = RSTAT1 = 10k, CHGENB = OVCTAP = VLOGIC, TA = TJ. PARAMETER TEST CONDITIONS MIN TYP MAX UNITS Current Error Amplifier (CEA) Section IB 8.8V < VCC < 35V, VCHGENB = VLOGIC VIO (Note 2) 8.8V < VCC < 35V, CAO = CA– 0.1 0.8 µA 10 mV AVO 1V < VAO < 4V 60 90 dB GBW TJ = 25°C, F = 100kHz 1 1.5 MHz VOL IO = 250µA VOH IO = –5mA Output Source Current CAO = 4V Output Sink Current CAO = 1V ICA–, ITRCK_CONTROL VCHGENB = GND 0.4 4.5 0.6 5 –25 V V –12 2 3 8.5 10 11.5 1 mA mA µA Voltage Amplifier (CEA) Section IB Total Bias Current; Regulating Level 0.1 VIO (Note 2) 8.8V < VCC < 35V, VCM = 2.3V, VAO = VA– 1.2 µA mV AVO 1V < CAO < 4V GBW TJ = 25°C, F = 100kHz 60 90 dB 0.25 0.5 MHz VOL IO = 500µA VOH IO = –500µA Output Source Current CAO = 4V –2 –1 mA Output Sink Current CAO = 1V 2 2.5 mA VAO Leakage: High Impedance State VCHGENB = GND, STAT0 = 0 & STAT1 = 0, VAO = 2.3V –1 Maximum Duty Cycle CAO = 0.6V 90 95 100 % Modulator Gain CAO = 2.5V, 3.2V 63 71 80 %/V 4.75 0.4 0.6 V 5 5.25 V 1 µA Pulse Width Modulator Section OSC Peak 3 V OSC Valley 1 V Oscillator Section Frequency Thermistor Derived Reference Section Initial Accuracy, VAO (RTHM = 10k) 8.8V < VCC < 35V 198 220 242 kHz VID = 0, R10 = RTHM =10k (Note 3) 2.2655 2.3 2.3345 V VID = 0, R10 = RTHM =10k, –40°C ≤TA < 0°C (Note 3) 2.254 2.3 2.346 V 3 10 mV 2.458 2.495 2.532 V VID = VRTHM – VR10 Line Regulation VCC = 8.8V to 35V VAO RTHM = 138k, R10 = 10k RTHM = 138k, R10 = 10k, -40°C ≤ TA < 0°C 2.445 2.495 2.545 V RTHM = 33.63k, R10 = 10k 2.362 2.398 2.434 V RTHM = 33.63k, R10 = 10k, -40°C ≤ TA < 0°C 2.350 2.398 2.446 V RTHM = 1.014k, R10 = 10k 2.035 2.066 2.097 V RTHM = 1.014k, R10 = 10k, -40°C ≤ TA < 0°C 2.025 2.066 2.107 V 1.01 V/V Charge Enable Comparator Section (CEC) Threshold Voltage As a function of VA– 0.99 1 Input Bias Current CHGENB = 2.3V –0.5 –0.1 Powered by ICminer.com Electronic-Library Service CopyRight 2003 3 µA UC2909 UC3909 ELECTRICAL CHARACTERISTICS: Unless otherwise stated these specifications apply for TA = –40°C to +85°C for UC2909; °0C to +70°C for UC3909; CT = 330pF, RSET = 11.5k, R10 = 10k, RTHM = 10k, VCC = 15V, Output no load, RSTAT0 = RSTAT1 = 10k, CHGENB = OVCTAP = VLOGIC, TA = TJ. PARAMETER TEST CONDITIONS MIN TYP MAX UNITS STAT0 = 0, STAT1 = 0, Function of VREF 0.945 0.95 0.955 V/V STAT0 = 1, STAT1 = 0, Function of VREF 0.895 0.9 0.905 V/V 1.01 V/V Voltage Sense Comparator Section (VSC) Threshold Voltage Over Charge Taper Current Comparator Section (OCTIC) Threshold Voltage Function of 2.3V REF, CA- = CAO 0.99 1 Input Bias Current OVCTAP = 2.3V –0.5 –0.1 VLOGIC VCC = 15V 4.875 5.0 5.125 V Line Regulation 8.8V < VCC < 35V 3 15 mV Load Regulation 0 < IO < 10mA µA Logic 5V Reference Section (VLOGIC) Reference Comparator Turn-on Threshold Short Circuit Current VREF = 0V 30 3 15 mV 4.3 4.8 V 50 80 mA Output Stage Section ISINK Continuous 50 mA IPEAK 100 mA VOL IO=50mA Leakage Current VOUT=35V 1 1.3 V 25 µA STAT0 & STAT1 Open Collector Outputs Section Maximum Sink Current VOUT = 8.8V Saturation Voltage IOUT = 5mA Leakage Current VOUT = 35V 6 10 0.1 mA 0.45 V 25 µA STATLV Open Collector Outputs Section Maximum Sink Current VOUT = 5V Saturation Voltage IOUT = 2mA Leakage current VOUT = 5V 2.5 5 0.1 mA 0.45 V 3 µA UVLO Section Turn-on Threshold 6.8 7.8 8.8 V Hysteresis 100 300 500 mV 19 mA ICC Section ICC (run) (See Fig. 1) 13 ICC (off) VCC = 6.5V 2 mA Note 2: VIO is measured prior to packaging with internal probe pad. Note 3: Thermistor initial accuracy is measured and trimmed with respect to VAO; VAO = VA–. PIN DESCRIPTIONS CA–: The inverting input to the current error amplifier. CSO: The output of the current sense amplifier which is internally clamped to approximately 5.7V. CAO: The output of the current error amplifier which is internally clamped to approximately 4V. It is internally connected to the inverting input of the PWM comparator. CHGENB: The input to a comparator that detects when battery voltage is low and places the charger in a trickle charge state. The charge enable comparator makes the output of the voltage error amplifier a high impedance while forcing a fixed 10µA into CA– to set the trickle charge current. CS–, CS+: The inverting and non-inverting inputs to the current sense amplifier. This amplifier has a fixed gain of five and a common-mode voltage range of from –250mV to +VCC. Powered by ICminer.com Electronic-Library Service CopyRight 2003 4 UC2909 UC3909 PIN DESCRIPTIONS (cont.) GND: The reference point for the internal reference, all thresholds, and the return for the remainder of the device. The output sink transistor is wired directly to this pin. OVCTAP: The overcharge current taper pin detects when the output current has tapered to the float threshold in the overcharge state. OSC: The oscillator ramp pin which has a capacitor (CT) to ground. The ramp oscillates between approximately 1.0V to 3.0V and the frequency is approximated by: frequency = 1 1. 2 • CT • R SET Figure 1. ICC vs. temperature. OUT: The output of the PWM driver which consists of an open collector output transistor with 100mA sink capability. STAT1: This open collector pin is the second decode bit used to decode the charge states. R10: Input used to establish a differential voltage corresponding to the temperature of the thermistor. Connect a 10k resistor to ground from this point. STATLV: This bit is high when the charger is in the float state. RSET: A resistor to ground programs the oscillator charge current and the trickle control current for the oscillator ramp. The oscillator charge current is approximately VA–: The inverting input to the voltage error amplifier. VAO: The output of the voltage error amplifier. The upper output clamp voltage of this amplifier is 5V. 1.75 . R SET VCC: The input voltage to the chip. The chip is operational between 7.5V and 40V and should be bypassed with a 1µF capacitor. A typical ICC vs. temperature is shown in Figure 1. The trickle control current (ITRCK_CONTROL) is approxi0115 . mately . R SET VLOGIC: The precision reference voltage. It should be bypassed with a 0.1µF capacitor. RTHM: A 10k thermistor is connected to ground and is thermally connected to the battery. The resistance will vary exponentially over temperature and its change is used to vary the internal 2.3V reference by –3.9mV/°C. The recommended thermistor for this function is part number L1005-5744-103-D1, Keystone Carbon Company, St. Marys, PA. Charge State Decode Chart STAT0 and STAT1 are open collector outputs. The output is approximately 0.2V for a logic 0. Trickle Charge Bulk Charge Over Charge Float Charge STAT0: This open collector pin is the first decode bit used to decode the charge states. Powered by ICminer.com Electronic-Library Service CopyRight 2003 5 STAT1 0 0 1 1 STAT0 0 1 0 1 UC2909 UC3909 APPLICATION INFORMATION A Block Diagram of the UC3909 is shown on the first page, while a Typical Application Circuit is shown in Figure 2. The circuit in Figure 2 requires a DC input voltage between 12V and 40V. The VEA, VOH = 5V clamp saturates the voltage loop and consequently limits the charge current as stated in Equation 1. During the trickle bias state the maximum allowable charge current (ITC) is similarly determined: The UC3909 uses a voltage control loop with average current limiting to precisely control the charge rate of a lead-acid battery. The small increase in complexity of average current limiting is offset by the relative simplicity of the control loop design. ITC = Current Sense Amplifier Current Error Amplifier This amplifier measures the voltage across the sense resistor RS with a fixed gain of five and an offset voltage of 2.3V. This voltage is proportional to the battery current. The most positive voltage end of RS is connected to CSensuring the correct polarity going into the PWM comparator. The current error amplifier (CA) compares the output of the current sense amplifier to the output of the voltage error amplifier. The output of the CA forces a PWM duty cycle which results in the correct average battery current. With integral compensation, the CA will have a very high DC current gain, resulting in effectively no average DC current error. For stability purposes, the high frequency gain of the CA must be designed such that the magnitude of the down slope of the CA output signal is less than or equal to the magnitude of the up slope of the PWM ramp. CSO = 2.3V when there is zero battery current. RS is chosen by dividing 350mV by the maximum allowable load current. A smaller value for RS can be chosen to reduce power dissipation. Maximum Charge Current, Ibulk, is set by knowing the maximum voltage error amplifier output, VOH = 5V, the maximum allowable drop across RS, and setting the resistors RG1 and RG2 such that; CHARGE ALGORITHM Refer to Figure 3 in UC3906 Data Sheet in the data book. (1) A) Trickle Charge State STAT0 = STAT1 = STATLV = logic 0 When CHGNB is less than VREF (2.3V – 3.9mV/°C), STATLV is forced low. This decreases the sense voltage divider ratio, forcing the battery to overcharge (VOC). The maximum allowable drop across RS is specified to limit the maximum swing at CSO to approximately 2.0V to keep the CSO amplifier output from saturating. VOC = (VREF ) • No charge/load current: VCSO = 2.3V, (RS1 + RS 2 + RS 3 | | RS 4) (RS 3 || RS 4) (3) During the trickle charge state, the output of the voltage error amplifier is high impedance. The trickle control current is directed into the CA– pin setting the maximum trickle charge current. The trickle charge current is defined in Equation 2. Max charge/load current: Vmax(CSO) = 2.3V–2.0V = 0.3V Voltage Error Amplifier: The voltage error amplifier (VEA) senses the battery voltage and compares it to the 2.3V – 3.9mV/°C thermistor generated reference. Its output becomes the current command signal and is summed with the current sense amplifier output. A 5.0V voltage error amplifier upper clamp limits maximum load current. During the trickle charge state, the voltage amplifier output is opened (high impedance output) by the charge enable comparator. A trickle bias current is summed into the CA– input which sets the maximum trickle charge current. Powered by ICminer.com Electronic-Library Service CopyRight 2003 (2) RS • 5 ITRCK_CONTROL is the fixed control current into CA–. ITRCK_CONTROL is 10µA when RSET = 11.5k. See RSET pin description for equation. CONTROL LOOP 5 • VRS 5 • VRS RG1 = = = RG 2 VLOGIC – CA – 5V – 2 .3V 5 • VRS = 1.852 • IBULK • RS 2 .7V ITRICK _ CONTROL • RG1 B) Bulk Charge State STAT1 = STATLV = logic 0, STAT0 = logic 1 As the battery charges, the UC3909 will transition from trickle to bulk charge when CHGENB becomes greater than 2.3V. The transition equation is VT = VREF • (RS1 + RS 2 + RS 3 || RS 4) (RS 2 + RS 3 || RS 4) STATLV is still driven low. 6 (4) UC2909 UC3909 Pin numbers refer to J, N, DW packages. APPLICATION INFORMATION (cont.) UDG-95008-1 Figure 2. Typical application circuit Powered by ICminer.com Electronic-Library Service CopyRight 2003 7 UC2909 UC3909 APPLICATION INFORMATION (cont.) D) Float State STAT0 = STAT1 = STATLV = logic 1 During the bulk charge state, the voltage error amplifier is now operational and is commanding maximum charge current (IBULK) set by Equation 1. The voltage loop attempts to force the battery to VOC. The battery charge current tapers below its OVCTAP threshold, and forces STATLV high increasing the voltage sense divider ratio. The voltage loop now forces the battery charger to regulate at its float state voltage (VF). C) Overcharge State STAT0 = STATLV = logic 0, STAT1 = logic 1 VF = (VREF ) The battery voltage surpasses 95% of VOC indicating the UC3909 is in its overcharge state. (6) RS 3 If the load drains the battery to less than 90% of VF, the charger goes back to the bulk charge state, STATE 1. During the overcharge charge state, the voltage loop becomes stable and the charge current begins to taper off. As the charge current tapers off, the voltage at CSO increases toward its null point of 2.3V. The center connection of the two resistors between CSO and VLOGIC sets the overcurrent taper threshold (OVCTAP). Knowing the desired overcharge terminate current (IOCT), the resistors ROVC1 and ROVC2 can be calculated by choosing a value of ROVC2 and using the following equation: ) • IOCT • RS • ROVC 2 ROVC1 = (18518 . (RS1 + RS 2 + RS 3 ) OFF LINE APPLICATIONS For off line charge applications, either Figure 3 or Figure 4 can be used as a baseline. Figure 3 has the advantage of high frequency operation resulting in a small isolation transformer. Figure 4 is a simpler design, but at the expense of larger magnetics. (5) UDG-95009 Figure 3. Off line charger with primary side PWM Powered by ICminer.com Electronic-Library Service CopyRight 2003 8 UC2909 UC3909 APPLICATION INFORMATION (cont.) UDG-95010 Figure 4. Isolated off line charger UNITRODE CORPORATION 7 CONTINENTAL BLVD. • MERRIMACK, NH 03054 TEL. (603) 424-2410 • FAX (603) 424-3460 Powered by ICminer.com Electronic-Library Service CopyRight 2003 9 IMPORTANT NOTICE Texas Instruments and its subsidiaries (TI) reserve the right to make changes to their products or to discontinue any product or service without notice, and advise customers to obtain the latest version of relevant information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale supplied at the time of order acknowledgement, including those pertaining to warranty, patent infringement, and limitation of liability. TI warrants performance of its semiconductor products to the specifications applicable at the time of sale in accordance with TI’s standard warranty. Testing and other quality control techniques are utilized to the extent TI deems necessary to support this warranty. Specific testing of all parameters of each device is not necessarily performed, except those mandated by government requirements. CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE (“CRITICAL APPLICATIONS”). TI SEMICONDUCTOR PRODUCTS ARE NOT DESIGNED, AUTHORIZED, OR WARRANTED TO BE SUITABLE FOR USE IN LIFE-SUPPORT DEVICES OR SYSTEMS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF TI PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER’S RISK. In order to minimize risks associated with the customer’s applications, adequate design and operating safeguards must be provided by the customer to minimize inherent or procedural hazards. TI assumes no liability for applications assistance or customer product design. TI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or other intellectual property right of TI covering or relating to any combination, machine, or process in which such semiconductor products or services might be or are used. TI’s publication of information regarding any third party’s products or services does not constitute TI’s approval, warranty or endorsement thereof. Copyright 1999, Texas Instruments Incorporated Powered by ICminer.com Electronic-Library Service CopyRight 2003