ICS1722 QuickSaver® Charge Controller for Nickel-Cadmium and Nickel-Metal Hydride Batteries General Description Features • The ICS1722 is a CMOS device designed for the intelligent charge control of either nickel-cadmium (NiCd) or nickel-metal hydride (NiMH) batteries. The controller uses a pulsed-current charging technique together with voltage slope termination. The ICS1722 employs a four stage charge sequence that provides a complete recharge without overcharging. The controller has nine userselectable charge rates and six user-selectable auxiliary modes available for customized charging systems. • • • • • • The ICS1722 monitors for the presence of a battery and begins charging when a battery is installed. The ICS1722 is for applications where temperature sensing is not required by the charge controller. Applications Battery charging systems for: - Portable consumer electronics - Power tools - Audio/video equipment - Communications equipment • Charge termination methods include: Voltage slope Charge timers Four stage charge sequence: Soft start charge Fast charge Topping charge Maintenance charge Reverse-pulse charging available in all charge stages Nine programmable charge rates between 15 minutes (4C) and four hours (C/4) Continuous polling mode for battery detection Six auxiliary modes include: Discharge-before-charge Ten hour C/10 conditioning charge Direct to C/40 maintenance charge Charging system test provided through controller Adjustable open circuit (no battery) voltage reference Block Diagram RESET OPEN CIRCUIT REFERENCE POLLING MODE LED MICROCODE CONTROL CHARGE MODE LED 0.5V VOLTAGE SENSE ADC PROCESSOR MODE SELECT CHARGE SELECT RC RAM ROM OSCILLATOR OUTPUT CONTROL MAINTENANCE MODE LED CHARGE CONTROL DISCHARGE CONTROL ICS1722 Pin Configuration CHG 1 16 VDD DCHG 2 15 unused PFN 3 14 VIN MMN 4 13 OPREF CMN 5 12 AUX1 SEL0 6 11 AUX0 VSS 7 10 RC SEL1 8 9 ICS1722 MRN 16-Pin DIP or SOIC Pin Definitions Pin Number 1 Pin Name CHG Type OUT 2 3 DCHG PFN OUT OUT 4 MMN OUT 5 CMN OUT 6 7 8 9 10 11 12 13 SEL0 VSS SEL1 MRN RC AUX0 AUX1 OPREF IN 14 15 16 VIN unused VDD IN Note: Definition Active high TTL compatible signal used to turn on an external current source to provide current to charge the battery. Active high TTL compatible signal available to turn on a discharge circuit. Polling detect indicator. An active low turns on an external indicator to show the controller is polling for the presence of the battery. Maintenance mode indicator. An active low turns on an external indicator showing the battery is either in the topping charge, maintenance charge or auxiliary condition mode. The indicator flashes during the auxiliary discharge mode. Charge mode indicator. An active low turns on an external indicator to show the controller is either in a soft start charge or fast charge. Tri-level input used with the SEL1 pin to program the device for the desired charge rate. Ground. IN IN IN IN IN IN Tri-level input used with the SEL0 pin to program the device for the desired charge rate. Master reset signal. A logic low pulse greater than 700 ms initiates a device reset. An external resistor and capacitor sets the frequency of the internal clock. Tri-level input used with the AUX1 pin to program the device for an auxiliary operating mode. Tri-level input used with the AUX0 pin to program the device for an auxiliary operating mode. Open circuit (no battery) voltage reference. An external resistor divider on this pin sets the open circuit voltage reference used to detect the presence of a battery. Battery voltage normalized to one cell with an external resistor divider. Ground. Device supply =+5.0 VDC Pins 9 and 13 have an internal pull-up. Pins 6,8,11,12 float to 2.3V when unconnected. 2 ICS1722 Soft Start Charge Controller Operation Some batteries may exhibit an unusual high impedance condition while accepting the initial charging current, as shown in Figure 2. Unless dealt with, this high impedance condition can cause a voltage peak at the beginning of the charge cycle that would be misinterpreted as a fully charged battery by the voltage termination methods. Charging Stages The charging sequence consists of four stages. The application of current is shown graphically in Figure 1. The soft start stage gradually increases current levels up to the user selected fast charge rate during the first two minutes. The soft start stage is followed by the fast charge stage, which continues until termination. After termination, a two hour C/10 topping charge is applied. The topping charge is followed by a C/40 maintenance charge. Average Current (not to scale) S oft-Start Fast Charge Stage 1 0 2 min The soft start charge eases batteries into the fast charge stage by gradually increasing the current to the selected fast charge rate. The gradual increase in current alleviates the voltage peak. During this stage, only positive current pulses are applied to the battery. The duty cycle of the applied current is increased to the selected fast charge rate, as shown in Figure 3, by extending the current pulse on every cycle until the pulse is about one second in duration. The initial current pulse is approximately 200ms. The CMN indicator is activated continuously during this stage Topping Charge Stage 2 Maintenance Charge Stage 3 termination Stage 4 termination + 2 hours Time (not to scale) Figure 1: Graphical representation of average current levels during the four charging stages Figure 2: High impedance voltage spike at the beginning of charge 3 ICS1722 Initial Pulse Width Initial Pulse Width Initial Pulse Width 2 x increment time increment time cycle time cycle time cycle time Figure 3: Cycle-to-cycle increase of the soft-start current pulse widths Fast Charge The amplitude of the current pulse is determined by system parameters such as the current capability of the charging system, the desired charge rate, the cell capacity and the ability of that cell to accept the charge current. The ICS1722 can be set for nine userselectable fast charge rates from 15 minutes (4C) to four hours (C/4). Charge pulses occur approximately every second. The CMN indicator is activated continuously during this stage. In the second stage, the ICS1722 applies the charging current in a series of charge and discharge pulses. The technique consists of a positive current charging pulse followed by a high current, short duration discharge pulse. The cycle, shown with charge, discharge, rest and data acquisition periods in Figure 4, repeats every second until the batteries are fully charged. rest time rest time voltage acquisition time fast charge pulse width discharge pulse width cycle time Figure 4: Charge cycle showing charge and discharge current pulses 4 ICS1722 Topping Charge The discharge current pulse amplitude is typically set to about 2.5 times the amplitude of the charging current based on 1.4V/cell. For example, if the charge current is 4 amps, then the discharge current is set at about 10 amps. The energy removed during the discharge pulse is a fixed ratio to the positive charge rate. The amplitude of the discharge pulse does not affect the operation of the part as described in this section. The third stage is a topping charge that applies current at a rate low enough to prevent cell heating but high enough to ensure a full charge. The topping charge applies a C/10 charging current for two hours. The current consists of the same pulse technique used during the fast charge stage; however, the duty cycle of the pulse sequence has been extended as shown in Figure 5. Extending the time between charge pulses allows the same charging current used in the fast charge stage so that no changes to the current source are necessary. For example, the same charge pulse that occurs every second at a 2C fast charge rate will occur every 20 seconds for a topping charge rate of C/10. The MMN indicator is activated continuously during this stage. A voltage acquisition window immediately follows a brief rest time after the discharge pulse. No charge is applied during the rest time or during the acquisition window to allow the cell chemistry to settle. Since no current is flowing, the measured cell voltage is not obscured by any internal or external IR drops or distortions caused by excess plate surface charge. The ICS1722 makes one continuous reading of the no-load battery voltage during the entire acquisition window. The voltage that is measured during this window contains less noise and is a more accurate representation of the true state of charge of the battery. cycle time Maintenance Charge The maintenance charge is intended to offset the natural selfdischarge of NiCd or NiMH batteries by keeping the cells primed at peak charge. After the topping charge ends, the ICS1722 begins this charge stage by extending the duty cycle of the applied current pulses to a C/40 rate. The maintenance charge will last for as long as the battery voltage is greater than 0.5V at the VIN pin, or, if the ten hour timer mode is enabled, until the timer stops the controller. The MMN indicator is activated continuously during this stage. delay time cycle time Figure 5: Representative timing diagram for topping and maintenance charge 5 ICS1722 Cells that are not thoroughly conditioned or possess an unusual cell construction may not have a normal voltage profile. The ICS1722 uses an alternate method of charge termination based on a slight decrease in the voltage slope to stop charge to cells whose voltage profile is very shallow. This method looks for a flattening of the voltage slope which may indicate a shallow peak in the voltage profile. The zero slope point occurs slightly beyond the peak voltage and is shown on the voltage curve graph. Charge Termination Methods Charge termination schemes include voltage slope, fast charge timer and, if desired, a ten hour timer to limit total charge time. Voltage Slope Termination The most distinctive point on the voltage curve of a charging battery in response to a constant current is the voltage peak that occurs as the cell approaches full charge. By mathematically calculating the first derivative of the voltage, a second curve can be generated showing the change in voltage with respect to time as shown in Figure 6. The slope will reach a maximum just before the actual peak in the cell voltage. Using the voltage slope data, the ICS1722 calculates the point of full charge and accurately terminates the applied current as the battery reaches that point. The actual termination point depends on the charging characteristics of the particular battery. Charge Timer Termination The controller uses a timer to limit the fast charge duration. These times are pre-programmed, and are automatically adjusted in time duration according to the charge rate selected. Fast charge timer termination is a safety backup feature to limit the duration of the fast charge stage. The fast charge timer is always enabled and cannot be disabled. See Table 3 in the section Charge Rate Selection for more information. To limit the total charge time to ten hours, refer to the section Ten Hour Timer Mode for more information. Figure 6: Voltage and slope curves showing inflection and zero slope points 6 ICS1722 Battery Detection Discharge-to-Charge Mode Upon power-up or after a master reset, excess charge from output filter capacitors at the charging system terminals is removed with a series of discharge pulses. After the discharge pulse sequence is complete, the voltage at VIN must be greater than 0.5V when a battery is present. If the voltage at the pin is less than 0.5V, the ICS1722 assumes no battery is present, and the polling detect mode is initiated. No indicator is active during the discharge pulses. The time required for discharge depends on the energy in the battery and the discharge rate. The discharge is not limited by a timer. This allows the user to set the discharge rate. The battery is drained to 1 volt/cell as read at the VIN pin under load and then the controller enters soft start at a charge rate set by the SEL0 and SEL1 inputs. The discharge load is activated by the DCHG pin which goes low for about 400ms every second. A resistor value selected for a 2.5C discharge based on 1.4V/cell results in about a 1C discharge rate. The ICS1722 enters the polling detect mode and applies a 100ms charge pulse. During the pulse, the ICS1722 monitors the VIN pin to determine if the divided down terminal voltage is above OPREF. If the battery is present, the voltage will be clamped below the reference on OPREF while the current pulse is applied. If a battery is not present, the voltage at VIN will rise above the reference at OPREF. The discharge-to-charge mode can be entered by placing the AUX0 pin high (H) and the AUX1 pin low (L) with the SEL0 and SEL1 inputs set for the desired fast charge rate. This setting initializes the discharge sequence. The ICS1722 enters the discharge-to-charge mode at initial power-up or with a master reset. The discharge mode occurs first, to be followed by the selected fast charge mode. During discharge, the MMN indicator flashes at a one second rate, while during the soft start and fast charge stages the CMN indicator is activated continuously. The charge pulse will repeat until the battery is reinstalled. The polling detect indicator (PFN) is the only indicator active as long as the ICS1722 is in the polling detect mode. Once a battery is installed, the ICS1722 will turn off the PFN indicator and enter the soft start stage. The ICS1722 will automatically re-enter the polling detect mode if the battery is removed. Four charge modes are available after the discharge portion is complete by changing the state of the AUX inputs during the discharge portion of this mode. The available charge modes are: Fast Charge: Leave the AUX inputs open (Z). Battery Removal During the application of a charge pulse, the voltage at the VIN pin is compared to the voltage at the OPREF pin. If the voltage at VIN is greater than the voltage at OPREF during the application of the current pulse, then the battery is assumed to have been removed and the ICS1722 enters the polling detect mode. If the voltage at VIN is below the voltage at OPREF, charging continues. • When in the topping charge or maintenance charge stages, a charge pulse may not occur for several seconds. During the period between charge pulses, the voltage at VIN must be greater than 0.5V if a battery is attached. If the voltage at VIN is less than 0.5V, the ICS1722 assumes the battery has been removed, and the polling detect mode is initiated. If the battery is removed while in the discharge-to-charge mode, the ICS1722 will continually reset itself until the battery is reinstalled. See Application Information for more information. • • • Direct Maintenance Mode: Set the AUX0 low (L) and AUX1 high (H). Condition Mode: Set AUX0 high (H) and AUX1 open (Z). Ten-Hour Timer Mode: Set AUX0 high (H) and AUX1 high (H). Discharge-Only Mode The time required for discharge depends on the energy in the battery and the discharge rate. The discharge is not limited by a timer. This allows the user to set the discharge rate. The battery is drained to 1 volt/cell as read at the VIN pin under load. The ICS1722 shuts down after the discharge sequence is finished and a master reset must be performed to reactivate the device. The discharge load is activated by the DCHG pin which goes low for about 400ms every second. A resistor value selected for a 2.5C discharge based on 1.4V/cell results in about a 1C discharge rate. The discharge-only mode can be entered by placing the AUX0 pin open (Z) and the AUX1 pin low (L). The ICS1722 enters this mode at initial power-up or with a master reset. During the discharge portion, the MMN indicator flashes at a one second rate. Auxiliary Modes of Operation The ICS1722 allows six alternate modes of operation to help customize the charging system for certain applications. The trilevel AUX0 and AUX1 pins are used to select the operating mode. The AUX0 and AUX1 pins default the ICS1722 into fast charge operation. Except for the discharge-to-charge mode, another mode can only be selected by re-programming and resetting the controller. 7 ICS1722 Direct Maintenance Mode Ten Hour Timer Mode The ICS1722 can enter directly into the C/40 maintenance mode for cells that require a maintenance charge only. The direct maintenance mode is activated by setting the AUX0 pin low (L) and the AUX1 pin high (H), and resetting the device. The SEL0 and SEL1 pins must be set based on the charging current and the battery capacity. The formula Placing the AUX0 and AUX1 pins both high (H) enables a ten hour timer. This timer limits the total charge, including the maintenance charge, to approximately ten hours for a battery that is completely discharged before fast charge is initiated. The ten hour limit is based on the assumption that the charge terminates due to the fast charge timer as shown in Table 1. Charging System Test Charging Current (Amps) Battery Capacity (Amp • hr) The system test mode is intended for use in applications where the charging system functionality needs to be tested. The system test sequence consists of a one second activation of the CMN, MMN and PFN indicator pins as well as the CHG and DCHG lines. The system test mode is entered by placing both the AUX0 and AUX1 pins low (L). The ICS1722 shuts down after the test sequence is finished and a master reset must be performed to reactivate the device. gives the charge rate. Use Table 4 to find the correct SEL0 and SEL1 settings. The maintenance charge is applied until the battery is removed, upon which the ICS1722 will enter the polling detect mode. The ICS1722 will enter the direct maintenance mode upon initial power-up or after a master reset. The MMN indicator will be active during this mode. Conditioning Mode The ICS1722 can enter a conditioning mode which applies a C/10 charge for a timed 10 hour period, followed by an indefinite C/40 maintenance charge until the batteries are removed. The conditioning mode can be entered by setting the AUX0 pin high (H) and the AUX1 pin open (Z). The SEL0 and SEL1 pins must be set based on the charging current and the battery capacity. The formula Charging Current (Amps) Battery Capacity (Amp • hr) gives the charge rate. Use Table 3 to find the correct SEL0 and SEL1 settings. The MMN indicator will be active during the 10 hour conditioning charge and the maintenance charge that follows. The ICS1722 enters the polling detect mode if the battery is removed. Table 1: Ten Hour Timer Information Charge Rate 4C 2C 1.3 C 1C C/1.5 C/2 C/2.5 C/3 C/4 Maintenance Timer Cutoff (after fast charge termination) 9.7 hrs 9.4 hrs 9.1 hrs 8.8 hrs 8.2 hrs 7.6 hrs 6.5 hrs 6.0 hrs 5.4 hrs Fast Charge Timer Cutoff 0.3 0.6 0.9 1.2 1.8 2.4 3.5 4.0 4.6 hrs hrs hrs hrs hrs hrs hrs hrs hrs 8 Charge Time Limit (from reset) 10 hrs 10 hrs 10 hrs 10 hrs 10 hrs 10 hrs 10 hrs 10 hrs 10 hrs ICS1722 Pin Descriptions The maintenance mode (MMN) indicator is on when the ICS1722 is either in the topping charge, maintenance charge, direct maintenance mode, or the condition mode. The maintenance mode indicator flashes at a one second rate when the ICS1702 is controlling the discharge portion of the discharge-to-charge or the discharge-only mode. The polling detect (PFN) indicator is on when the ICS1722 polls for a battery. The controller applies periodic charge pulses to detect the presence of a battery. The indicator is a warning that these charge pulses are appearing at the charging system terminals at regular intervals. When a battery is detected, the indicator is turned off. The ICS1722 requires some external components to control the clock rate and provide an indicator display. The controller must be interfaced to an external power source that will provide the current required to charge a battery pack and, if desired, a circuit that will sink discharge current. Output Logic Signals: CHG, DCHG Pins The CHG and DCHG pins are active high, TTL compatible outputs. In addition to being TTL compatible, the CMOS outputs are capable of sourcing current which adds flexibility when interfacing to other circuitry. A logic high on the CHG pin indicates that the charging current supply should be activated. If applicable, a logic high on the DCHG pin indicates that the discharge circuit should be activated. Charge Rate Selection: SEL0, SEL1 Pins The SEL0 and SEL1 inputs must be programmed by the user to inform the ICS1722 of the desired charge rate. When left unconnected (open), these tri-level pins will float to about 2.3V. When a low level is required, the pin must be grounded. When a high level is required, the pin must be tied to VDD . The voltage ranges for low (L), open (Z) and high (H) are listed in Table 6, DC Characteristics. To program the SEL0 and SEL1 inputs, refer to the Charge Rate List in Table 3. Care must be taken to control wiring resistance and inductance. The load resistor must be capable of handling this short duration high-amplitude pulse. If the auxiliary discharge-to-charge mode is selected, the power dissipation of the load resistor must be properly selected to accept the extended length of the discharge pulse. Indicators: CMN, MMN, PFN Pins The ICS1722 does not control the current flowing into the battery in any way other than turning it on and off. The required current for the selected charge rate must be provided by the user’s power source. The external charging circuitry should provide current at the selected charge rate. For example, to charge a 1.2 ampere hour battery in 30 minutes (2C), approximately 2.4 amperes of current is required. The controller has three outputs for driving external indicators. These pins are active low. The three indicator outputs have open drains and are designed to be used with LEDs. Each output can sink over 20mA which requires the use of an external current limiting resistor. The three indicator signals denote fast charge stage, topping and maintenance stages, and the polling detect mode as shown in Table 2. The charge mode (CMN) indicator is activated continuously during the soft start and fast charge stages. When the controller enters the topping charge stage, the output goes high and the indicator turns off. Table 2: Indicator Description List PFN On MMN CMN On On Flash Flash On Flash Flash Description Polling mode or battery fault Maintenance or topping charge, direct maintenance or condition mode Fast charge Discharge portion of the discharge-to-charge or discharge-only mode See Applications Information See Applications Information Fast Charge (See Applications Information) 9 ICS1722 Table 3: Charge Rate List SEL0 SEL1 Charge Rate Topping Charge pulse Rate Maintenance Charge Pulse Rate L L L H H H Z Z Z L H Z L Z H L Z H 4C (15 min) 2C (30 min) 1.3C (45 min) 1C (60 min) C/1.5 (90 min) C/2 (120 min) C/2.5 (150 min) C/3 (180 min) C/4 (240 min) one every 40 sec one every 20 sec one every 13 sec one every 10 sec one every 7 sec one every 5 sec one every 4 sec one every 3 sec one every 2 sec one every 160 sec one every 80 sec one every 53 sec one every 40 sec one every 27 sec one every 20 sec one every 16 sec one every 13 sec one every 10 sec Fast Charge Timer Duration (after reset) 21 min 39 min 57 min 75 min 110 min 144 min 212 min 244 min 275 min See the section on Controller Operation for additional information on the topping charge and maintenance charge. See the section on Charge Termination Methods for additional information on the charge timer. Mode Selection: AUX0, AUX1 Pins When a high level is required, the pin must be tied to VDD . The voltage ranges for low (L), open (Z) and high (H) are listed in Table 6, DC Characteristics. To program the AUX0 and AUX1 inputs, refer to the Mode Select List in Table 4. See the section on Auxiliary Modes of Operation for additional information. The AUX0 and AUX1 inputs must be programmed by the user to inform the ICS1722 of the desired auxiliary mode. When left unconnected (open) these tri-level pins will float to about 2.3V. When a low level is required, the pin must be grounded. Table 4: Mode Select List AUX0 L L Z Z H H H AUX1 L H Z L L Z H Mode Selected Charging System Test Direct Maintenance Fast Charge Discharge-Only Discharge-to-Charge Condition Ten Hour Timer Mode Operation Charging system test for embedded applications Indefinite C/40 maintenance charge Default Battery discharge to 1V/cell Battery discharge to 1V/cell followed by the selected charge mode Timed C/10 topping charge followed by a C/40 maintenance charge Limits total charge including the maintenance charge to 10 hours 10 ICS1722 Master Reset: MRN Pin VIN pin The MRN pin is provided to re-program the controller for a new mode or charging sequence. This pin has an internal pull-up of about 75kΩ . A logic low on the MRN pin must be present for more than 700ms for a reset to occur. As long as the pin is low, the controller is held in a reset condition. A master reset is required to clear the charging system test, reset the ten hour timer, change charge rates or auxiliary modes. Upon power-up, the controller automatically resets itself. R1 # of cells R2 Clock Input: RC Pin The RC pin is used to set the frequency of the internal clock when an external 1 MHz clock is not available. An external resistor must be connected between this pin and VDD . An external capacitor must be connected between this pin and ground. The frequency of the internal clock will be about 1 MHz with a 16kΩ resistor and a 100pF capacitor. All time durations noted in this document are based on a 1 MHz clock. Operating the clock at a lower frequency will proportionally change all time durations. Operating the clock at a frequency significantly lower than 1 MHz, without adjusting the charge current accordingly, will lessen the effectiveness of the fast charge timer and lower the accuracy of the controller. Operating the clock at a frequency greater than 1 MHz will also change all time durations and, without adjusting the charge current accordingly, may cause termination to occur due to the fast charge timer expiring rather than by the battery reaching full charge. Figure 7: Resistor divider network at the VIN pin Open Circuit Voltage Reference: OPREF Pin The OPREF pin has an internal 75kΩ pull-up resistor to VDD . OPREF requires an external pull-down resistor to establish the open circuit (no battery) voltage reference. The purpose of this voltage reference is to detect the removal of the battery from the charging system. The voltage at this pin is compared to the voltage at the VIN pin when the current source is turned on. If the voltage at VIN is greater than the voltage at OPREF, the ICS1722 assumes the battery has been removed and the ICS1722 enters the polling detect mode. The clock may be driven by a 1 MHz external 0 to 5V pulse provided the duty cycle is between 10% and 60%. The clock input impedance is about 1kΩ . For proper operation, the voltage at OPREF must be set below the (divided down) open circuit voltage produced by the current source and above the maximum normalized battery voltage. The OPREF pin voltage must not exceed 2.3V or it will prevent the start of fast charge. If the voltage on OPREF exceeds 4V, the controller will shutdown and must be reset. Voltage Input: VIN Pin The battery voltage must be normalized by an external resistor divider network to one cell. The electrochemical potential of one cell is about 1.2V. For example, if the battery consists of six cells in series, the voltage at the VIN pin must be equal to the total battery voltage divided by six. This can be accomplished with two resistors, as shown in Figure 7. To determine the correct resistor values, count the number of cells to be charged in series. Then choose either R1 or R2 and solve for the other resistor using: R1 = R2 * (# of cells -1) or R2 = As an example, suppose that a current source has an open circuit voltage of 12V as shown in Figure 8. The maximum expected battery voltage of a six-cell pack is determined to be 9.6V. The voltage at OPREF should be set at a point between 1.6V (9.6V/6 cells=1.6V) and 2V (12V/6=2V). This is accomplished with a pulldown resistor. Refer to the VIN and OPREF resistor tables in the Applications Information section. From the VIN table, the divider resistors are 10kΩ and 2kΩ for R1 and R2. From the OPREF table, the pull-down resistor is 43kΩ for R3. If R3 is 43kΩ , the voltage at OPREF is 1.82V since the internal pull-up at the OPREF pin is 75kΩ . R1 (# of cells -1) 11 ICS1722 current source (open circuit voltage = 12V) +5V + R1 = 10k R3 = 2.2k OPREF = 1.86V 6 cells (9.6 V) VIN = 1.60V (battery present) (no battery) { 2.00V R2 = 2k R4 = 1.3k - Resistor divider at the OPREF pin Resistor divider at the VIN pin Figure 8: Open Circuit Reference Example Power: VDD Pin Grounding: VSS Pin The power supply for the device must be connected to the VDD pin. The voltage should be +5 VDC and should be supplied to the part through a regulator that has good noise rejection and an adequate current rating. The controller requires up to a maximum of 11mA with VDD =5.00V. This pin must have a direct connection to a solid ground plane. Data Tables Table 5: Absolute Maximum Ratings Supply Voltage Logic Input Levels Ambient Operating Temperature Storage Temperature 6.5 -0.5 to VDD + 0.5 0 to 70 -55 to 150 V V °C °C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only. Functional operation of the device at the Absolute Maximum Ratings or other conditions not consistent with the characteristics shown in this document is not recommended. Exposure to absolute maximum rating conditions for extended periods may affect product reliability. 12 ICS1722 Table 6: DC Characteristics T amb=25°C. All values given are typical at specified VDD. Parameter Supply Voltage Supply Current High Level Input Voltage SEL0, SEL1, AUX0, AUX1 Low Level Input Voltage SEL0, SEL1, AUX0, AUX1 Open Input Voltage SEL0, SEL1, AUX0, AUX1 Low Level Input Current, pull-up MRN, OPREF High Level Source Current CHG, DCHG Low Level Sink Current CHG, DCHG Low Level Sink Current, indicator PFN, CMN, MMN Symbol Test Conditions VDD IDD VIH VIL MIN 4.5 MAX 5.5 3.6 TYP 5.0 7.3 4.1 4.5 UNITS V mA V 0.73 0.75 0.8 V open 2.3 V IIL V=0.4V 74 µA IOH V= VDD - 0.4V 28 mA IOL V=0.4V 25 mA IOL V=0.4V 40 mA Input Impedance Analog/Digital Converter Range Minimum Battery Threshold 0-2.2 13 1.0 0-2.7 0.5 0-2.7 MΩ V V ICS1722 Table 8: Timing Characteristics R≈16kΩ , C≈100pF PARAMETER Clock Frequency Reset Pulse Duration Charge Pulse Width Discharge Pulse Width Rest Time Data Acquisition Time Cycle Time Capacitor Discharge Pulse Width Capacitor Discharge Pulse Period Polling Detect Pulse Width Polling Detect Pulse Period Soft Start Initial Pulse Width Soft Start Incremental Pulse Width Discharge Mode Pulse Width Discharge Mode Pulse Period RESET to SEL Dynamic Reprogram Period SYMBOL REFERENCE t RESET t CHG t DCHG tR t DA t CYCLE see Figure B see Figure A see Figure A see Figure A see Figure A see Figure A t RSA see Figure B TYP 1.0 700 1048 5.0 4.0 16.4 1077 5.0 100 100 624 200 7.0 400 1050 1160 Timing Diagrams Figure A: tCHG tR CHG DCHG voltage t DCHG tCYCLE Figure B: t RE S E T R ES E T SEL0 SEL1 AU X 0 AU X 1 t RS A 14 tR tDA UNITS MHz ms ms ms ms ms ms ms ms ms ms ms ms ms ms ms ICS1722 Applications Information With the batteries removed, the current source must be capable of raising the voltage at the VIN pin above the voltage at the OPREF pin to ensure proper polling. With the batteries in-stalled, the current source overshoot characteristics when turned on and off must not cause the voltage at the VIN pin to exceed the voltage at the OPREF pin. If the voltage at OPREF exceeds the voltage at VIN when a charge pulse is applied or removed, the polling feature will be activated. To ensure proper operation of the ICS1722, external components must be properly selected. The external current source used must meet several important criteria to ensure optimal performance of the charging system. The charging current should be constant when using voltage slope termination. VIN and OPREF Divider Resistors Figure 9 shows a typical application using the ICS1722. R1 through R3 must be carefully selected to ensure that battery detection and voltage termination methods operate properly. R1 and R2 are selected to scale the battery voltage down to the voltage of one cell. The following table shows some typical values. Additional information is available in the Voltage Input section. Cells 1 2 3 4 5 6 7 8 R1 Short 2.0k 2.0k 3.0k 12k 10k 12k 9.1k PC Board Design Considerations It is very important that care be taken to minimize noise coupling and ground bounce. In addition, wires and connectors can add significant resistance and inductance to the charge and discharge circuits. When designing the printed circuit board, make sure ground and power traces are wide and bypass capacitors are used right at the controller. Use separate grounds for the signal, charge and discharge circuits. Separate ground planes on the component side of the PC board are recommended. Be sure to connect these grounds together at the negative lead of the battery only. For the discharge circuit, keep the physical separation between power and return (ground) to a minimum to minimize field radiation effects. This precaution is also applicable to the constant current source, particularly if it is a switch mode type. Keep the ICS1722 and the constant current source control circuits outside the power and return loop described above. These precautions will prevent high circulating currents and coupled noise from disturbing normal operation. R2 Open 2.0k 1.0k 1.0k 3.0k 2.0k 2.0k 1.3k The current source should prevent ripple voltage from appearing on the battery. The effects of ripple on the battery voltage may interfere with proper operation. Using the Voltage Slope Termination Method In general, the voltage slope termination method works best for equipment where the battery is fast charged with the equipment off or the battery is removed from the equipment for fast charge. R3 is used to set the open circuit (no battery) reference voltage on the OPREF pin. The function of this pin is discussed in the Open Circuit Reference section. VOPREF 1.82 V 1.93 V 2.02 V 2.14 V R3 43k 47k 51k 56k 15 ICS1722 Charging System Status by Indicator The voltage slope termination method used by the ICS1722 requires a nearly constant current flow into the battery during fast charge. Charging the battery in equipment that draws a known constant current while the battery is charging should have this current draw added to the fast charge current. Using the ICS1722 for charging the batteries in equipment that randomly or periodically requires moderate current from the battery during fast charge needs evaluation. Equipment that randomly or periodically requires high current from the battery during fast charge may cause a voltage inflection that results in termination before full charge. A voltage inflection can occur due to the charge current decreasing or fluctuating as the load changes rather than by the battery reaching full charge. The voltage slope method will terminate charge based on voltage inflections that are characteristic of a fully charged battery. The ICS1702 and ICS1712 charge controllers have temperature termination methods for equipment that randomly or periodically draws significant current from the battery during fast charge. The Indicator Description List in Table 2 contains displays that are caused by charging system abnormalities. When the CMN indicator is flashing with no other indicator active, there is voltage present at the battery terminals with the current source off and no battery. Check the current source and ensure that it produces no more than the equivalent of 350mV/cell when turned off with no battery. If the VIN divider resistors were not properly selected, an open circuit voltage that is actually less than the equivalent of 350mV/cell with the charger off and no battery will not divide down this open circuit voltage properly and produce the CMN flash indication. Check the VIN divider and ensure that it properly normalizes the battery voltage to the electrochemical potential of about 1.2V cell. If the CMN flash indication occurs with the battery installed, then the constant current source is producing more than the equivalent of 350mV/cell when off and there is an open connection between the charger terminals and the battery. Check wires, connections, battery terminals, and the battery itself for an open circuit condition. Charging sources that produce decreasing current as fast charge progresses may also cause a voltage inflection that may result in termination before full charge. For example, if the charge current is supplied through a resistor or if the charging source is a constant current type that has insufficient input voltage, the current will decrease and may cause a termination before full charge. Other current source abnormalities that may cause a voltage inflection that is characteristic of a fully charged battery are inadequate ripple and noise attenuation capability or charge current decreasing due to thermal drift. Charging sources that have any of the above characteristics need evaluation to access their suitability for the application if the use of the voltage slope termination is desired. If the MMN and CMN indicators are alternately flashing, the likely cause is no battery with the ICS1722 programmed in the discharge-to-charge auxiliary mode. If the battery is present, check wires, connectors, battery terminals, and the battery itself for an open circuit condition. If the MMN indicator is active at the initiation of fast charge, check the external pull-down resistor from OPREF to ground. A voltage at OPREF that exceeds 2.3V will prevent the start of fast charge. The controller soft start stage, built-in noise filtering, and fast charge timer operate optimally when the constant current source charges the battery at the rate selected. If the actual charge current is significantly less than the rate selected, the conditioning effect of the soft start stage and the controller noise immunity are lessened. Also, the fast charge timer may cause termination based on time duration rather than by the battery reaching full charge due to inadequate charge current. 16 ICS1722 V CONSTANT CURRENT SOURCE in R4 (note 1) +5V +5V Q1 (note 2) + 5 V (note 5) ICS1722 390 390 1k (note 3) +5V 1 2 FAULT 3 MAINT 4 CHG 5 6 7 8 CHG VDD unused DCHG PFN VIN MMN OPREF CMN AUX1 AUX0 SEL0 VSS RC SEL1 MRN 16 15 14 13 12 11 10 9 4.7µF .047µF R1 .047µF +5V R3 open @ 45°C R2 16k (note 6) 100pF Notes: 1) Value of R4 determined by discharge current and capacity of battery pack. 2) Discharge FET is logic-level compatible in this application. 3) DC return of discharge FET must be connected close to negative battery terminal. 4) Regulated supply 5) Power ground; others are signal ground. Connect signal ground to power ground at negative battery terminal only. Figure 9: Functional Diagram 17 ICS1722 Package Information 0.018 0.060 0.016 QuickSaver 0.250 QuickSaver GPI ICS1722N 0.296 GPI ICS1722M 0.310 0.750 0.404 0.041 0.250 0.405 0.130 0.094 0.130 0.041 0.010 0.015 0.296 0.008 0.008 0.016 0.350 0.050 0.018 0.033 All package dimensions are in inches. 0.100 0.060 All package dimensions are in inches. 16-Pin SOIC Package (300 mil) 16-Pin DIP package (300 mil) 0.016 0.039 QuickSaver GPI ICS1722S R 0.155 0.236 0.390 0.031 0.058 0.024 0.154 0.008 0.006 0.016 0.050 All package dimensions are in inches. 16-Pin SOIC Package (150 mil) Ordering Information: ICS1722M, ICS1722MT, ICS1722S, ICS1722ST, ICS1722N Example: ICS 1712 ST Package type: N= DIP (Plastic) M= 300 mil SOIC S= 150 mil SOIC MT= 300 mil SOIC Tape and Reel ST= 150 mil SOIC Tape and Reel Device type: Consists of 3 to 5 digits or numbers Prefix: ICS = Intelligent Charging Solution standard device 18 0.008 0.025 ICS1722 IMPORTANT NOTICE Galaxy Power Incorporated makes no claim about the capability of any particular battery (NiCd or NiMH) to accept a fast charge. GPI strongly recommends that the battery manufacturer be consulted before fast charging. GPI shall be held harmless for any misapplication of this device such as: exceeding the rated specifications of the battery manufacturer; charging batteries other than nickel-cadmium or nickelmetal hydride type; personal or product damage caused by the charging device, circuit, or system itself; unsafe use, application, and/or manufacture of a charging system using this device. GPI reserves the right to make changes in the device data identified in this publication without further notice. GPI advises its customers to obtain the latest version of all device data to verify that any information being relied upon by the customer is current and accurate. GPI does not assume any liability arising out of or associated with the application or use of any product or integrated circuit or component described herein. GPI does not convey any license under its patent rights or the patent rights of others described herein. In the absence of a written or prior stated agreement to the contrary, the terms and conditions stated on the back of the GPI order acknowledgment obtain. GPI makes no warranty of any kind with regard to this material, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. GPI products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any nuclear facility application, or for any other application in which the failure of the GPI product(s) could create a situation where personal injury or death may occur. GPI will not knowingly sell its products for use in such applications, and the buyer shall indemnify and hold harmless GPI and its officers, employees, subsidiaries, affiliates, representatives and distributors against all claims, costs, damages, expenses, tort and attorney fees arising out of directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that GPI was negligent regarding the design or manufacture of the part. COPYRIGHT © 1998 Galaxy Power Incorporated 19 ICS1722 NOTES 20 NOTES 21 ICS1722 ICS1722 NOTES 22 NOTES 23 ICS1722 ICS1722 GPI Sales Offices Headquarters Galaxy Power, Inc. PO Box 890 2500 Eisenhower Avenue Valley Forge, PA 19482-0890 Phone: 1-610-676-0188 FAX: 1-610-676-0189 Internet: www.galaxypower.com January 20, 1999 GPI Sales Representative 24