MAX38888ATD+T

Click here to ask about the production status of specific part numbers. MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications General Description Benefits and Features The MAX38888 is a storage capacitor or capacitor bank backup regulator designed to efficiently transfer power between a storage element and a system supply rail in reversible buck and boost operations using the same inductor. ● ● ● ● ● ● ● ● When the main supply is present and above the minimum system supply voltage, the regulator operates in buck mode and charges the storage element at up to 500mA peak inductor current. Once the storage element is charged, the circuit draws only 2.5µA of current while it maintains the supercapacitor or other storage element in its ready state. When the main supply is removed, the regulator operates in boost mode and prevents the system from dropping below the minimum operating voltage, discharging the storage element at up to 2.5A peak inductor current. The MAX38888 is externally programmable for minimum and maximum voltage of the storage element, such as supercapacitor, minimum system voltage, and maximum charge and discharge currents. The internal DC-DC converter requires only a 1µH inductor. Applications ● Handheld Industrial Equipment ● Portable Computers ● Portable Devices with a Removable Battery 19-100369; Rev 5; 8/20 2.5V to 5V System Output Voltage 0.8V to 4.5V Cap Voltage Range Up to 2.5A Peak Inductor Discharge Current Programmable Voltage and Current Thresholds ±2% Threshold Accuracy Up to 95% Efficiency, Charge or Discharge 2.5μA Ready Quiescent Current Small Solution Size • 3mm x 3mm x 0.75mm TDFN Package Ordering Information appears at end of data sheet. MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Typical Application Circuit CHARGE 500mA (MAX) DISCHARGE 2.5A (MAX) L1 1µH VSC 2.7V (MAX) 1.5V (MIN) CAP 10F SUPERCAP C2 22µF R3 1.8MΩ LX SYS R7 1MΩ MAX38888 R8 1MΩ R6 2.49MΩ C1 22µF FBCL R2 402kΩ EN R1 499kΩ www.maximintegrated.com MAIN BATTERY (REMOVABLE) FBS BACKUP READY BKUPB RDY FBCH ENABLE INPUT VSYS SYSTEM LOAD 3V (MIN) GND ISET R4 20kΩ R5 499kΩ Maxim Integrated | 2 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Absolute Maximum Ratings CAP, EN, SYS, LX, BKUPB, RDY to GND............... -0.3V to +6V FBCH, FBCL to GND.................................... -0.3V to CAP + 0.3V FBS, ISET to GND........................................ -0.3V to SYS + 0.3V PGND to GND ....................................................... -0.3V to +0.3V Continuous Power Dissipation (TA = +70°C, TDFN, derate 24.4mW/°C above +70°C) ............................ 1951.2mW Operating Temperature Range ...........................-40°C to +125°C Storage Temperature Range ..............................-65°C to +150°C Maximum Junction Temperature ...................................... +150°C Lead Temperature (soldering, 10 seconds) ......................+300°C LX RMS Current........................................................... ±2.0ARMS Output Short-Circuit Duration......................................Continuous 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. Package Information TDFN Package Code T1433+2C Outline Number 21-0137 Land Pattern Number 90-0063 THERMAL RESISTANCE, FOUR-LAYER BOARD Junction-to-Ambient (θJA) 41°C/W Junction-to-Case Thermal Resistance (θJC) 8°C/W For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a four-layer board. For detailed information on package thermal considerations, refer to www.maximintegrated.com/ thermal-tutorial. Electrical Characteristics (VSYS = 3.7V, VCAP = 2.7V, TJ = -40°C to +125°C (typical values at TJ = +25°C), circuit of Figure 1, unless otherwise specified.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS SYS Voltage Range VVSYS 2.5 5 V CAP Voltage Range VVSC 0.8 4.5 V SYS Shutdown Current ISYS_SD EN = 0V, TA = +25°C 0.01 EN = 0V 0.1 SYS Charging Supply Current ISYS_CHG VFBS = 0.6V, VFBCH = VFBCL = 0.485V 1.5 SYS Backup Supply Current ISYS_BUP VFBS = VFBCH = VFBCL = 0.515V, TA = +25°C 35 VFBS = VFBCH = VFBCL = 0.515V 35 SYS Ready Supply Current ISYS_RDY VFBS = 0.6V, VFBCH = VFBCL = 0.515V, TA = +25°C 2.5 VFBS = 0.6V, VFBCH = VFBCL = 0.515V 2.5 CAP Shutdown Current ICAP_SD EN = 0V, TA = +25°C 0.01 EN = 0V 0.1 www.maximintegrated.com 1 μA mA 65 5 1 μA μA μA Maxim Integrated | 3 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Electrical Characteristics (continued) (VSYS = 3.7V, VCAP = 2.7V, TJ = -40°C to +125°C (typical values at TJ = +25°C), circuit of Figure 1, unless otherwise specified.) PARAMETER UVLO Threshold FBS Backup Voltage FBS Charging Threshold SYMBOL VUVLOF VFBS CONDITIONS MIN TYP MAX UNITS VVSYS falling, 100mV typical hysteresis 1.7 FBS rising, when discharging stops -2% 1.8 1.9 V 0.5 +2% V VTH_FBS_CHG Above FBS backup voltage, when charging begins, 30mV typical hysteresis 25 60 95 mV FBCH Threshold VTH_FBCH FBCH rising, when charging stops, 25mV typical hysteresis -2% 0.5 +2% V FBCL Threshold VTH_FBCL FBCL falling, when preserve mode starts, 25mV typical hysteresis -3.5% 0.475 +3.5% V 225 600 EN Threshold ISET Resistor Range LX Peak Backup Current Limit (Note 1) LX Peak Charge Current Limit (Note 1) FBS/FBCH/FBCL Input Bias Current VIL When LX stops switching, EN falling VIH EN rising RISET IDCHG ICHG IFBS/FBCH/ FBCL EN Input Leakage Current IEN LX Switching Frequency fSW LX Low-Side FET Resistance LX High-Side FET Resistance LX Leakage Current 660 Guaranteed by LX peak current limits 20 Circuit of Figure 1, VCAP = 2V, VSYS = 2.9V, RISET = 20kΩ 2.0 400 3.0 500 600 mA 100 -0.1 VFBS/FBCH/FBCL = 0.5V 0V < VEN < 5.5V, TA = +25°C 2.5 kΩ 0.50 Circuit of Figure 1, VSYS = 3.7V, VCAP = 2V, RISET = 100kΩ VFBS/FBCH/FBCL = 0.5V, TA = +25°C 100 mV A Circuit of Figure 1, VCAP = 2V, VSYS = 2.9V, RISET = 100kΩ Circuit of Figure 1, VSYS = 3.7V, VCAP = 2V, RISET = 20kΩ 925 0.001 0.1 0.01 -0.1 0V < VEN < 5.5V 0.001 0.1 0.01 μA μA Delivering maximum current from CAP 2 RLOW VSYS = 3V, LX switched to GND 50 100 mΩ RHIGH VSYS = 3V, LX switched to SYS 80 160 mΩ ILX_LKG VEN = 0V, VSYS = 5V, VLX = 0V/5V, TA = +25°C -1 VEN = 0V, VSYS = 5V, VLX = 0V/5V MHz 1 μA 0.1 Maximum On-Time tON Backup mode, VFBS = 0.485V 320 400 480 ns Minimum Off-Time tOFF Backup mode, VFBS = 0.485V 80 100 120 ns Overtemperature Lockout Threshold TOTLO TJ rising, 15°C typical hysteresis 165 °C High-Side FET ZeroCrossing (Note 1) IZXP Circuit of Figure 1, VCAP = 2V, VSYS = 2.9V 25 50 75 mA Low-Side FET ZeroCrossing (Note 1) IZXN Circuit of Figure 1, VSYS = 3.7V, VCAP = 2V 25 50 75 mA VEN = 0V, VBKUPB = 5V, TA = +25°C -1 BKUPB Leakage Current www.maximintegrated.com IBKUPB VEN = 0V, VBKUPB = 5V 1 0.1 μA Maxim Integrated | 4 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Electrical Characteristics (continued) (VSYS = 3.7V, VCAP = 2.7V, TJ = -40°C to +125°C (typical values at TJ = +25°C), circuit of Figure 1, unless otherwise specified.) PARAMETER SYMBOL CONDITIONS BKUPB Output Voltage Low VBKUPB_L VFBS = 0.48V, VFBCH = VFBCL = 0.515V, ISINK = 2mA RDY Leakage Current IRDY RDY Output Voltage Low VRDY_L VFBCH = 0.54V, VRDY = 5V, TA = 25°C VFBCH = 0.54V, VRDY = 5V VEN = 0V, ISINK = 2mA MIN TYP -1 MAX UNITS 0.4 V 1 0.1 0.4 μA V Note 1: DC measurement, actual zero-crossing, and peak current accuracy in the circuit will be affected by the propagation delay time. www.maximintegrated.com Maxim Integrated | 5 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Typical Operating Characteristics (VSYS = 3.6V, VCAP = 2.0V, C1 = 22μF, C2 = 22μF, TA = +25°C, unless otherwise noted.) www.maximintegrated.com Maxim Integrated | 6 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Typical Operating Characteristics (continued) (VSYS = 3.6V, VCAP = 2.0V, C1 = 22μF, C2 = 22μF, TA = +25°C, unless otherwise noted.) LX CAP EN FBCH FBCL 11 10 9 8 N.C 12 PGND 13 TOP VIEW 14 Pin Configuration MA X388 88 EXPOSED PAD . 1 2 3 4 5 6 7 SYS N.C BKUPB RDY ISET FBS GND + TD FN-EP 3m m x 3m m www.maximintegrated.com Maxim Integrated | 7 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Pin Description PIN NAME FUNCTION 1 SYS System Supply Rail. Connect to a system supply rail or removable battery between 2.5V and 5V and bypass with a 22μF capacitor to GND. 2 NC No Connect. 3 BKUPB 4 RDY Open-Drain Supercap Ready Indicator. RDY goes high when the supercapacitor is fully charged (i.e., FBCH > 0.5V). RDY is pulled low when FBCL < 0.475V. Connect to an external pullup resistor. 5 ISET Charge/Discharge Current Input. The peak discharge current is set by 50kV/RISET while the peak charging current is 1/5 the discharging current. 6 FBS SYS Feedback. Connect to the center point of a resistor divider from SYS to GND. SYS will boost to 0.5V x (1 + RSTop/RSBot) when VFBS < 0.5V. 7 GND Analog Ground. 8 FBCL CAP Feedback. Connect to the upper point of a resistor divider from CAP to GND. Part enters preserve mode when VFBCL < 0.475V. 9 FBCH CAP Feedback. Connect to the lower point of a resistor divider from CAP to GND. CAP will charge to 0.5V x (1 + RCTop/RCBot) when VFBS > 0.56V. 10 EN 11 CAP Open-Drain Backup Indicator. BKUPB is held low when the part is in backup mode (i.e., when FBS < 0.5V and FBCL > 0.5V). BKUPB is released high when FBCL < 0.475V or FBS > 0.56V. Connect to an external pullup resistor. Enable Input. Force this pin high to enable the regulator or force pin low to disable the part and enter shutdown. If not driven, tie it to the SYS rail. Super Cap. Connect to a supercapacitor rated between 0.8V to 5V with a maximum voltage less than VSYS. 12 LX Inductor Switching Node. Connect a 1.0μH to 4.7uH inductor from LX to CAP. 13 NC No Connect. 14, EP PGND www.maximintegrated.com Power Ground. Maxim Integrated | 8 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Functional Diagram CAP SYS BIAS EN LX DRIVERS CONTROL ISET PGND RDY BKUPB MAX38888 FBS MODE SELECT FBCH FBCL GND www.maximintegrated.com Maxim Integrated | 9 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Detailed Description The MAX38888 is a flexible storage capacitor or capacitor bank backup regulator efficiently transferring power between a storage element and a system supply rail. When the main supply is present and its voltage above the minimum system supply voltage, the regulator operates in the charging mode of operation and charges the storage element at up to 500mA peak inductor current. Once the storage element is charged, the RDY flag will assert and the circuit will draw only 2.5μA of current while maintaining the storage element in its ready state. When the main supply is removed, the regulator prevents the system from dropping below the minimum operating voltage, boosting VSYS by discharging the storage element at up to 2.5A peak inductor current. During this backup mode of operation, the MAX38888 utilizes a fixed on-time, current-limited, pulse-frequency-modulation (PFM) control scheme. Once MAX38888 is in the backup mode, the BKUPB flag is asserted. When VSYS is applied for the first time, ensure that the supercapacitor is charged to 2.7V to activate backup mode. The external pins allow a wide range of system and storage element, such as supercapacitor voltage settings, as well as charging and discharging peak inductor current settings. The MAX38888 implements a True Shutdown™ feature, disconnecting VSYS from VCAP as well as protecting against a SYS short or if VCAP > VSYS. Application Circuit The typical application of the MAX38888 is shown in Figure 1. CHARGE 500mA (MAX) DISCHARGE 2.5A (MAX) L1 1µH VSC 2.7V (MAX) 1.5V (MIN) CAP 10F SUPERCAP C2 22µF R3 1.8MΩ LX SYS R7 1MΩ MAX38888 R8 1MΩ R6 2.49MΩ C1 22µF FBCL R2 402kΩ MAIN BATTERY (REMOVABLE) FBS EN R1 499kΩ BACKUP READY BKUPB RDY FBCH ENABLE INPUT VSYS SYSTEM LOAD 3V (MIN) GND ISET R4 20kΩ R5 499kΩ Figure 1. Typical Application Supercapacitor Voltage Configuration The maximum supercapacitor voltage is set using a resistor-divider from CAP to FBCH to GND. The recommended value for R1 is 499kΩ. Because resistor tolerance will have direct effect on voltage accuracy, these resistors should have 1% accuracy or better. R2 + R3 = R1 × ((VCAPMAX / 0.5) − 1) www.maximintegrated.com Maxim Integrated | 10 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications VCAP halts charging when VFBCH reaches 0.5V. The maximum supercapacitor voltage is where the supercapacitor will remain after it is completely charged and ready for backup. The minimum supercapacitor discharge voltage is set using a resistor-divider from CAP to FBCL to GND. R3 = (R1 + R2) × ((VCAPMIN / 0.5) − 1) FBCL prevents the supercapacitor from further discharge when VFBCL reaches 0.475V during a backup event in order to preserve the remaining capacity for keeping alive a real-time clock, memory, or other low-level function. In this preserve mode, the IC disconnects all circuitry from the supercapacitor and draws 2.5μA current from it. In applications where SYS voltage needs to be boosted to higher levels, selecting VCAP min has to take into account duty cycle limitation of the boosting phase, which is 80%. The MAX38888 detects when VSYS falls below VCAP. The device will not enable if VSYS is below VCAP. Raising VSYS above the backup threshold re-initiates charging and backup. System Voltage Configuration The minimum system voltage is set using a resistor-divider from SYS to FBS to GND. The recommended value for R5 is 499kΩ. Because resistor tolerance will have direct effect on voltage accuracy, these resistors should have 1% accuracy or better. R6 = R5 × ((VSYSMIN / 0.5) − 1) When VFBS is above 0.56V, the DC-DC regulator will draw power from the SYS pin to charge the supercapacitor to the maximum voltage set by FBCH and be ready for backup. When the main battery is removed, VFBS drops to 0.5V and the SYS pin is regulated to the programmed minimum voltage with up to 2A of CAP current. Charge/Discharge Current Configuration The peak inductor discharge current is set by placing a resistor from ISET to GND. The values of RISET resistor is calculated by following formula: IDISCHARGE = 2.5A × (20kΩ / RISET) The supercapacitor charging current is internally set to 1/5 of the discharge current. ICHARGE = 0.5A × (20kΩ / RISET) the value of RISET between 20kΩ and 100kΩ is recommended to ensure accurate current compliance. System Waveforms The waveforms in Figure 2 represent system behavior of the MAX38888 in the Typical Application Circuit. www.maximintegrated.com Maxim Integrated | 11 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications 4V 3.36V VSYS 3.18V 3V 0V 2.7V VCAP 1.42V 0V BKUPB FBS ≤ 0.5V 0V RDY FBCH ≥ 0.5V CHARGE FBCL < 0.475V LOW CURRENT BACKUP PRESERVE Figure 2. System Waveforms www.maximintegrated.com Maxim Integrated | 12 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Applications Information Capacitor Selection Capacitors at the SYS and CAP pins reduce current peaks and increase efficiency. Ceramic capacitors are recommended because they have the lowest equivalent series resistance (ESR), smallest size, and lowest cost. Choose an acceptable dielectric such as X5R or X7R. Due to the ceramic capacitors' capacitance derating with DC bias, standard 22μF ceramic capacitors are recommended at both pins for most applications. Supercapacitor Selection When the power source supplying the VSYS voltage is removed, power to the output is provided by the MAX38888 operating in the back-up or boost mode of operation using the supercapacitor as its source. In order to ensure the supply voltage stays in regulation, the amount of power the supercapacitor can deliver at its minimal voltage should be greater than that required by the system. The MAX38888 will present a constant power load to the supercapacitor where smaller current will be pulled out of the supercapacitor near its maximum VCAP voltage. However, current drawn from the supercapacitor will increase as it discharges to maintain constant power at the load. The amount of energy required in the backup mode will be the product of the constant backup power and time defined as backup time, tBACKUP. The amount of energy available in the supercapacitor is calculated using the following formula: / E = 1 2 × CSCAP × (VCAPMAX2 − VCAPMIN2)(J) The amount of energy required to complete the backup equals: E = VSYS × ISYS × tBACKUP)(J) where, ISYS will be the system load during backup. Since the energy required at the system side during the backup event comes from the available energy in the supercapacitor, assuming conversion efficiency η and given tBACKUP, the required CSCAP will be determined by the following equation: / CSCAP = (2xVSYS × ISYS × tBACKUP) [(VCAPMAX2 – VCAPMIN2) × η](F) www.maximintegrated.com Maxim Integrated | 13 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications VOLTAGE (V) 4 VSYS 3.36 3 2.7 VCAP LOW IQ 1.5 0 CHARGING CAP (BUCK) IDLE (NO SWITCHING) BACKUP (BOOST) PRESERVE (LOW CURRENT) Figure 3. Charging/Discharging Waveforms For example, in Figure 1 (Application Circuit), the minimum value of the supercapacitor required for 1s backup time, assuming a 200mA system load and average efficiency of 93%, will be: / CSCAP ≥ (2 × 3.0V × 0.2A × 1s) [((2.7V)2 – (1.5V)2) × 0.93] = 256mF Inductor Selection The MAX38888 works with a 1μH inductor in most applications. In applications where lower peak currents are desired, larger inductance may be used in order to reduce the ripple. The recommended inductance range is from 1μH to 4.7μH. Select 4.7μH for higher RISET value (100kΩ). 1μH is not supported for a 100kΩ RISET value. Status Flags The MAX38888 has two dedicated pins to report the device status to the host processor. The ready output (RDY) will be high when the supercapacitor is fully charged (i.e., FBCH > 0.5V). RDY is pulled low when FBCL < 0.475V. The other status flag is the Backup Output (BKUPB), which will be held low when the part is in the backup mode (i.e., when FBS < 0.5V and FBCL > 0.5V). BKUPB is released high when FBCL < 0.475V or FBS > 0.56V. Both output pins are open-drain type and require external pullup resistors. Recommended values for the pullup resistors are 1MΩ. The pins should be pulled up to the SYS rail. Enabling Device The MAX38888 has a dedicated enable pin. The pin can either be driven by a digital signal, pulled up, or strapped to the SYS rail. PCB Layout Guidelines Minimize trace lengths to reduce parasitic capacitance, inductance and resistance, and radiated noise. Keep the main power path from SYS, LX, CAP, and PGND as tight and short as possible. Minimize the surface area used for LX since this is the noisiest node. The trace between the feedback resistor-dividers should be as short as possible and should be isolated from the noisy power path. Refer to the EV kit layout for best practices. www.maximintegrated.com Maxim Integrated | 14 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications The PCB layout is important for robust thermal design. The junction-to-ambient thermal resistance of the package greatly depends on the PCB type, layout, and pad connections. Using thick PCB copper and having the SYS, LX, CAP, and PGND copper pours will enhance the thermal performance. The TDFN package has a large thermal pad under the package, which creates excellent thermal path to PCB. This pad is electrically connected to PGND. Its PCB pad should have multiple thermal vias connecting the pad to the internal PGND plane. Thermal vias should either be capped or have small diameter to minimize solder wicking and voids. Ordering Information PART NUMBER TEMP RANGE PIN-PACKAGE MAX38888ATD+ -40°C to +125°C 14 TDFN FEATURES Enable Input, Selectable Voltages and Currents + Denotes a lead(Pb)-free/RoHS-compliant package. T Denotes tape-and-reel. www.maximintegrated.com Maxim Integrated | 15 MAX38888 2.5V to 5.0V, 0.5A/2.5A Reversible Buck/Boost Regulator for Backup Power Applications Revision History REVISION NUMBER REVISION DATE PAGES CHANGED 0 6/18 Initial release — 1 7/18 Updated General Description and Benefits and Features 1 2 10/18 Updated General Description, Benefits and Features, Electrical Characteristics table, Typical Operating Characteristics, Detailed Description 3 7/19 Updated Supercapacitor Voltage Configuration section 9 4 12/19 Updated Enabling Device section 12 5 8/20 Updated Detailed Description 10 DESCRIPTION 1, 3–6, 9–12 For pricing, delivery, and ordering information, please visit Maxim Integrated’s online storefront at https://www.maximintegrated.com/en/storefront/storefront.html. Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. © 2020 Maxim Integrated Products, Inc.