FEATURES TYPICAL APPLICATION CIRCUIT VIN = 3.3V L1 4.7µH C3 1µF 10V C4 0.1µF 10V IN R1 35.7kΩ 1% RS 80Ω ADP1621 SDSN GATE COMP C2 120pF RCOMP 9.09kΩ CCOMP 1.8nF M1 COUT1 1µF 10V COUT2 10µF 10V R2 11.5kΩ 1% COUT3 150µF 6.3V ×2 PGND FREQ FB GND C1 47µF 6.3V RFREQ 31.6kΩ 1% AGND fOSC = 600kHz C1 = MURATA GRM31CR60J476M COUT3 = SANYO POSCAP 6TPE150M L1 = TOKO FDV0630-4R7M M1 = VISHAY Si7882DP D1 = VISHAY SSA33L Figure 1. High Efficiency Output Boost Converter in Lossless Mode, 3.3 V Input, 5 V Output (Bootstrapped) 100 90 EFFICIENCY (%) 80 70 60 GENERAL DESCRIPTION 50 The ADP1621 is a fixed-frequency, pulse-width modulation (PWM), current-mode, step-up converter controller. It drives an external n-channel MOSFET to convert the input voltage to a higher output voltage. The ADP1621 can also be used to drive flyback, SEPIC, and forward converter topologies, either isolated or nonisolated. 40 The ADP1621 eliminates the use of a current-sense power resistor by measuring the voltage drop across the on resistance of the n-channel MOSFET. This technique, allowed up to a maximum voltage of 30 V at the switch node, maximizes efficiency and reduces cost. For switch-node voltages higher than 30 V or for more accurate current limiting, the CS pin can be connected to a current-sense resistor in the source of the MOSFET. The slope compensation is implemented by an external resistor, allowing a wide range of external components (inductors and MOSFETs), and can be chosen for various switching frequencies and input and output voltages. PIN CS APPLICATIONS APD bias Portable electronic equipment Isolated dc/dc converter Step-up/step-down dc/dc converter LED driver for laptop computer and navigation system LCD backlighting VOUT = 5V 1A D1 06090-001 92% efficiency (no sense resistor required) ±1.0% initial accuracy IC supply voltage range: 2.9 V to 5.5 V Power-input voltage as low as 1.0 V Capable of high supply input voltage (>5.5 V) with an external NPN or a resistor VIN UVLO and 35 mA shunt regulator External slope compensation with 1 resistor Programmable operating frequency (100 kHz to 1.5 MHz) with 1 resistor Lossless current sensing for switch-node voltage <30 V Resistor current sensing for switch-node voltage >30 V Synchronizable to external clock Current-mode operation for excellent line and load transient responses 10 µA shutdown current Current limit and thermal overload protection Soft start in 2048 clock cycles Supported by ADIsimPower™ design tool 30 0.01 0.1 1 LOAD CURRENT (A) 10 06090-042 Data Sheet Constant-Frequency, Current-Mode Step-Up DC/DC Controller ADP1621 Figure 2. Efficiency of Circuit Shown in Figure 1 The ADP1621 supply input voltage range is 2.9 V to 5.5 V, although higher input voltages are possible with the use of a small-signal NPN pass transistor or a single resistor. The voltage of the power input can be as low as 1 V for fuel cell applications. The switching frequency is set by an external resistor over a range of 100 kHz to 1.5 MHz and can be synchronized to an external clock by using the SDSN pin. The shutdown quiescent current is less than 10 µA. The ADP1621 has a thermal shutdown feature that shuts down the gate driver when the junction temperature reaches approximately 150°C. The internal soft start circuit limits inrush current at startup. The ADP1621 is available in the 10-lead MSOP lead-free package and is specified over the −40°C to +125°C junction temperature range. Rev. B Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.461.3113 ©2006–2012 Analog Devices, Inc. All rights reserved. ADP1621 Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 Duty Cycle ................................................................................... 14 Applications ....................................................................................... 1 Setting the Output Voltage ........................................................ 14 General Description ......................................................................... 1 Inductor Current Ripple ............................................................ 14 Typical Application Circuit ............................................................. 1 Inductor Selection ...................................................................... 14 Revision History ............................................................................... 2 Input Capacitor Selection .......................................................... 15 Specifications..................................................................................... 3 Output Capacitor Selection....................................................... 15 Absolute Maximum Ratings............................................................ 5 Diode Selection........................................................................... 15 Thermal Resistance ...................................................................... 5 MOSFET Selection ..................................................................... 16 ESD Caution .................................................................................. 5 Loop Compensation .................................................................. 16 Simplified Block Diagram ............................................................... 6 Slope Compensation .................................................................. 17 Pin Configuration and Function Descriptions ............................. 7 Current Limit .............................................................................. 18 Typical Performance Characteristics ............................................. 8 Light Load Operation ................................................................ 18 Theory of Operation ...................................................................... 12 Recommended Component Manufacturers ........................... 19 Control Loop ............................................................................... 12 Layout Considerations ................................................................... 20 Current-Sense Configurations.................................................. 12 Efficiency Considerations ............................................................. 21 Current Limit .............................................................................. 13 Examples of Application Circuits ................................................. 22 Undervoltage Lockout ............................................................... 13 Standard Boost Converter—Design Example ........................ 22 Shutdown ..................................................................................... 13 Bootstrapped Boost Converter ................................................. 23 Soft Start ...................................................................................... 13 SEPIC Converter Circuit ........................................................... 27 Internal Shunt Regulators.......................................................... 13 Low Voltage Power-Input Circuit ............................................ 27 Setting the Oscillator Frequency and Synchronization Frequency .................................................................................... 13 LED Driver Application Circuits ............................................. 28 Related Parts .................................................................................... 30 Application Information: Boost Converter ................................. 14 Outline Dimensions ....................................................................... 31 ADIsimPower Design Tool ....................................................... 14 Ordering Guide .......................................................................... 31 REVISION HISTORY 6/12—Rev. A to Rev. B Change to Features Section ............................................................. 1 Added ADIsimPower Design Tool Section ................................. 14 Change to Table 6 ........................................................................... 30 Updated Outline Dimensions ....................................................... 31 Changes to Ordering Guide .......................................................... 31 12/06—Rev. 0 to Rev. A Changes to Table 1 ............................................................................ 3 Changes to Table 2 ............................................................................ 5 Added Table 3.................................................................................... 5 Changes to Table 5 .......................................................................... 19 Changes to Ordering Guide .......................................................... 31 7/06—Revision 0: Initial Version Rev. B | Page 2 of 32 Data Sheet ADP1621 SPECIFICATIONS VIN = 5 V, RFREQ = 100 kΩ, fOSC = 200 kHz, TJ = −40°C to 125°C, unless otherwise noted. Table 1. Parameter MAIN CONTROL LOOP Internal Soft Start Time PIN Supply Voltage 1 IN Supply Voltage1 Shunt Regulation Voltage Symbol tSS VPIN VIN VSHUNT Shunt Resistance RSHUNT IN Quiescent Current IN Shutdown Current PIN Supply Current Static Mode, No Switching Shutdown Mode Undervoltage Lockout Threshold at IN Pin IIN Min Typ Max 2048 IIN = 3 mA, IPIN = 3 mA, TA = 25°C IIN = 3 mA, IPIN = 3 mA Current into IN = 8 mA to 12 mA Current into PIN = 8 mA to 12 mA VIN = 2.9 V to 5.5 V, VFB = 1.215 V VIN = 2.9 V to 5.5 V, SDSN = GND 2.9 2.9 5.4 5.2 5.6 5.6 13 7 1.8 1 VSHUNT VSHUNT 5.7 6.0 3 10 Unit Cycles V V V V Ω Ω mA µA IPIN VUVLO FB Regulation Voltage VFB FB Input Current Line Regulation 2 IFB ∆VFB/∆VIN Load Regulation 3 Error Amplifier Transconductance COMP Zero-Current Threshold COMP Clamp High Voltage ∆VFB/∆VCOMP gm VCOMP,ZCT VCOMP,CLAMP Current-Sense Amplifier Gain Peak Slope-Compensation Current at CS Pin 4 CS Pin Leakage Current Shutdown Time Thermal Shutdown Threshold 5 Thermal Shutdown Hysteresis5 OSCILLATOR Oscillator Frequency Range 6 Oscillator Frequency Oscillator Frequency Tempco SDSN Input Level Threshold SDSN Threshold Hysteresis SDSN Internal Pull-Down Resistor Synchronization Minimum Pulse Width Synchronization Maximum Pulse Width Synchronization Frequency GATE Minimum On Time GATE Minimum Off Time Maximum Duty Cycle6, 7 Recommended Maximum Synchronized Frequency Ratio6, 8 Conditions n ISC,PK ICS,LEAK tSD TTMSD fOSC fOSC fOSC,TC VSDSN,THRESH RSDSN tSYNC,MIN tSYNC,MAX fSYNC tON,MIN tOFF,MIN DMAX fSYNC/fOSC VFB = 1.3 V, VCOMP < VCOMP,ZCT, GATE = 0 V SDSN = GND VUVLO rising VUVLO hysteresis TA = 25°C VFB = 1.215 V, TA = 25°C 2.9 V ≤ VIN ≤ 5 V, TJ = −40°C to +85°C 2.9 V ≤ VIN ≤ 5 V, TJ = −40°C to +125°C VCOMP = 1.4 V to 1.5 V TJ = −40°C to +85°C TJ = −40°C to +125°C VCS = 0 V to 100 mV maximum across RS (GATE high) VCS = 30 V (GATE low) SDSN pin from high to low or left floating 2.2 1.203 1.197 −75 −1 0.85 1.9 1.9 7.5 55 1 1 2.5 −80 1.215 1.215 +25 0.02 0.02 −0.1 300 1.0 2.0 2.0 9.5 70 100 255 VIN = VPIN = 5 V 1.5 VSDSN = 0 V to VIN VSDSN = 0 V to VIN 325 ±0.06 1.7 −0.19 100 45 0.8/fSYNC 110 Rev. B | Page 3 of 32 1.227 1.233 +75 0.06 0.072 1.15 2.1 2.2 11.5 85 180 190 93 1.1 1.2 µA µA V mV V V nA %/V %/V % µS V V V V/V µA 5 µA µs °C °C 1500 395 kHz kHz %/°C V V kΩ ns ns kHz ns ns % 50 150 −10 RFREQ = 65 kΩ, TA = 25°C VFB = 1.215 V, VCOMP = 1.0 V VFB = 1.215 V, VCOMP = 2.0 V fSW = 200 kHz, RFREQ = 100 kΩ fOSC = 200 kHz, RFREQ = 100 kΩ, fSYNC = fSW 10 10 2.8 1.9 100 1800 215 230 97 1.4 ADP1621 Parameter GATE DRIVER GATE Rise Time 9 GATE Fall Time9 Data Sheet Symbol Conditions tR tF CGATE = 3.3 nF CGATE = 3.3 nF Min Typ 17 13 Max Unit ns ns The maximum input voltage is the shunt regulation voltage, which is typically 5.5 V and can range from 5.3 V to 6.0 V over the specified temperature range. The ADP1621 is tested in a feedback servo loop, which servos VFB to the internal reference voltage. The voltage change in FB is measured while VIN is changed from 2.9 V to 5 V. The line regulation is calculated by (∆VFB/VFB) × 100%/∆VIN. 3 The ADP1621 is tested in a feedback servo loop, which servos VFB to the internal reference voltage, and VCOMP is forced from 1.4 V to 1.5 V. The VCOMP range is (1.0 V ≤ VCOMP ≤ 2.0 V). 4 The peak slope-compensation current at the CS pin is typically 70 µA, and effectively clamped at 116 mV. Thus, RS should not exceed 1.6 kΩ (116 mV/70 µA). 5 Guaranteed by design for thermal shutdown. When the thermal junction temperature of the ADP1621 reaches approximately 150°C, the ADP1621 goes into thermal shutdown and the GATE voltage is pulled low. When the junction temperature drops below about 140°C, the soft start sequence is initiated and the ADP1621 resumes normal operation. 6 fOSC is the natural oscillation frequency, fSYNC is the synchronization frequency, and fSW is the switching frequency. If synchronization is used, then fSW = fSYNC; otherwise, fSW = fOSC. 7 Guaranteed by design and bench characterization. 8 To ensure proper synchronization operation, set the synchronization frequency, fSYNC, to 1.2× of the free-running frequency, fOSC. Although the switching frequency can be synchronized to as high as 1.8 MHz, the peak slope-compensation current decreases at higher synchronization frequencies. It is recommended that the maximum fSYNC be less than 1.4× of fOSC and should not exceed 1.8 MHz. The slope-compensation resistor, RS, should be chosen for the synchronization frequency (see the Slope Compensation section in the Application Information: Boost Converter section). 9 GATE rise and fall times are measured from 10% to 90% levels. 1 2 Rev. B | Page 4 of 32 Data Sheet ADP1621 ABSOLUTE MAXIMUM RATINGS Table 2. Parameter IN to GND FB, COMP, SDSN, FREQ, GATE to GND CS to GND PIN to PGND Supply Current into IN Supply Current into PIN Storage Temperature Range Junction Operating Temperature Range1 Junction Storage Temperature Range Lead Temperature (Soldering, 10 sec) Package Power Dissipation1 Rating −0.3 V to VSHUNT −0.3 V to (VIN + 0.3 V) −5 V to +33 V −0.3 V to VSHUNT 25 mA 35 mA −55°C to +150°C −55°C to +150°C −55°C to +150°C 300°C (TJ,MAX − TA)/θJA In applications where high power dissipation and poor package thermal resistance are present, the maximum ambient temperature may need to be derated. Maximum ambient temperature (TA,MAX) is dependent on the maximum operating junction temperature (TJ,MAX = 150oC), the maximum power dissipation of the device in the application (PD,MAX), and the junctionto-ambient thermal resistance of the package in the application (θJA), is given by the following equation: TA,MAX = TJ,MAX --- (θJA x PD,MAX). 1 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 these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Absolute maximum ratings apply individually only, not in combination. Unless otherwise specified, all other voltages are referenced to GND. THERMAL RESISTANCE θJA is specified for the worst-case conditions, that is, a device soldered in a circuit board for surface-mount packages. Table 3. Thermal Resistance Package Type 10-lead MSOP on a 2-layer PCB 10-lead MSOP on a 4-layer PCB θJA 200 172 Unit °C/W °C/W Junction-to-ambient thermal resistance of the package is based on modeling and calculation using 2-layer and 4-layer boards, and natural convection. The junction-to-ambient thermal resistance is application- and board-layout dependent. In applications where high maximum power dissipation exists, attention to thermal dissipation issues in board design is required. ESD CAUTION Rev. B | Page 5 of 32 ADP1621 Data Sheet SIMPLIFIED BLOCK DIAGRAM VREF 1.215V ERROR AMPLIFIER SOFT START (2048 CYCLES) gm PIN FB 5.5V COMP VOSC 1.4V SET OSC S GATE R SLOPE COMP GATE DRIVER PWM COMPARATOR CS + + IN UVLO SDSN n 100kΩ PGND 5.5V GND ADP1621 Figure 3. ADP1621 Simplified Block Diagram Rev. B | Page 6 of 32 06090-002 FREQ Data Sheet ADP1621 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS SDSN 1 COMP 3 FB 4 FREQ 5 10 IN CS ADP1621 9 TOP VIEW (Not to Scale) 8 PIN 7 GATE 6 PGND 06090-003 GND 2 Figure 4. Pin Configuration Table 4. Pin Function Descriptions Pin No. 1 Mnemonic SDSN 2 3 GND COMP 4 FB 5 FREQ 6 PGND 7 GATE 8 PIN 9 CS 10 IN Description Shutdown and Synchronization Input. Turn the ADP1621 on by driving SDSN high; turn it off by driving SDSN low. If SDSN is left floating or when the SDSN is pulled low, the ADP1621 goes into shutdown after 50 µs. If synchronization is needed, synchronize the switching frequency to an external clock by connecting the external clock to the SDSN pin. An internal 100 kΩ pull-down resistor is connected from SDSN to GND. Ground. Regulation Control Compensation Node. COMP is the output of the internal transconductance error amplifier. Connect a series RC from COMP to GND to compensate the regulator. The nominal voltage range for this pin is 1.0 V to 2.0 V. Feedback Input. FB is the input to the internal transconductance error amplifier. Drive FB from the output voltage through a resistive voltage divider. The ratio of the voltage divider sets the output voltage. The regulation voltage at FB is nominally 1.215 V. Frequency Control Input. Connect a resistor from FREQ to GND to set the free-running switching frequency between 100 kHz and 1.5 MHz. The nominal voltage of this pin is 1.4 V. Power Ground Input. PGND is the ground return for the internal gate driver and the negative input of the internal current-sense amplifier. Connect PGND to GND as close to the ADP1621 as possible. Gate Driver Output. The maximum gate driver output is equal to the PIN voltage. GATE drives the gate of the external n-channel power MOSFET. Connect GATE to the gate of the MOSFET. Power Input. PIN powers the gate driver output. An internal 5.5 V shunt regulator is connected to this pin. Bypass PIN to PGND with a 0.1 µF or greater capacitor. Current-Sense Input. CS is the positive input of the current-sense amplifier. When GATE is turned on, the voltage at the CS pin increases linearly from 0 V to a maximum of 116 mV, and the nominal peak slope-compensation output current is 70 µA. When GATE is off, the CS function is disabled. For current sensing in lossless mode, connect CS to the drain of the power MOSFET. The absolute maximum voltage at CS is 33 V. For higher accuracy current sensing or higher switch-node voltages, connect CS to a current-sense power resistor in the source of the power MOSFET. In both sensing methods, it is required to add a slope-compensation resistor, RS, to the CS pin to achieve stability in the inductor current for duty cycles greater than 50%. However, it is recommended to add RS for all duty cycles because load transients can momentarily cause the duty cycle to be greater than 50%, even when the steadystate duty cycle is less than 50%. Input Voltage. IN powers the ADP1621 internal circuitry. An internal 5.5 V shunt regulator is connected to this pin. Bypass IN to GND with a 0.1 µF or greater capacitor. Rev. B | Page 7 of 32 ADP1621 Data Sheet TYPICAL PERFORMANCE CHARACTERISTICS 100 92 90 91 LOAD = 0.5A 90 EFFICIENCY (%) 70 60 50 0.1 10 1 88 87 TA = 25°C VIN = 3.3V VOUT = 5V 85 LOAD CURRENT (A) 84 100 06090-004 30 0.01 LOAD = 1A 86 TA = 25°C fSW = 220kHz VIN = 3.3V VOUT = 5V 40 89 300 700 500 900 1100 1300 06090-007 EFFICIENCY (%) 80 1500 SWITCHING FREQUENCY (kHz) Figure 5. Efficiency vs. Load Current Figure 8. Efficiency vs. Switching Frequency 100 10 VOUT RIPPLES @ 5V AC-COUPLED SUPPLY CURRENT (mA) IIN 1 1 0.1 IPIN 0.01 0.001 0.0001 TA = 25°C NO SWITCHING 2 CH1 20mV CH2 2V M2µs A CH2 2.6V 0.00001 06090-005 CH2 = GATE 0 1 2 3 4 5 6 7 SUPPLY VOLTAGE (V) Figure 6. Output Voltage Ripple of the Circuit Shown in Figure 1 06090-008 TA = 25°C VIN = 3.3V VOUT = 5V LOAD = 1A Figure 9. Supply Current vs. Supply Voltage 1.21605 2.5 TA = 25°C VIN = 5V TA = 25°C 1.21600 2.0 VCOMP (V) 1.21590 1.5 1.0 1.21585 1.21575 2.5 3.0 3.5 4.0 4.5 VIN (V) 5.0 5.5 6.0 Figure 7. VFB vs. VIN 0 1.17 1.19 1.21 1.23 1.25 VFB (V) Figure 10. VCOMP vs. VFB Rev. B | Page 8 of 32 1.27 1.29 06090-009 0.5 1.21580 06090-006 VFB (V) 1.21595 Data Sheet ADP1621 45 35 MOSFET QG = 25nC GATE RISE AND FALL TIMES (ns) 35 30 25 20 MOSFET QG = 15nC 10 25 tF 20 15 10 5 MOSFET QG = 7nC 5 0 200 400 600 800 1000 1200 1400 1600 1800 SWITCHING FREQUENCY (kHz) 0 0 15 20 25 30 35 45 50 180 200 40 Figure 14. GATE Rise and Fall Times vs. CGATE 2.60 SDSN = 5V 1600 1500 1400 1300 1200 1100 1000 900 800 700 600 500 400 300 200 100 0 fOSC (kHz) 2.55 2.50 2.40 –50 0 50 100 150 TEMPERATURE (°C) 06090-011 2.45 0 20 40 60 80 100 120 140 160 RFREQ (kΩ) Figure 12. VUVLO Threshold vs. Temperature Figure 15. Oscillator Frequency vs. Resistance 1.03 198 VIN = 5V TA = 25°C RFREQ = 100kΩ 197 1.02 196 fOSC (kHz) 1.01 1.00 195 194 0.99 193 0.98 0 50 100 TEMPERATURE (°C) 150 06090-012 0.97 –50 192 Figure 13. Frequency vs. Temperature 191 2 3 4 VIN (V) Figure 16. Oscillator Frequency vs. VIN Rev. B | Page 9 of 32 5 06090-015 VUVLO (V) 10 GATE CAPACITANCE (nF) Figure 11. PIN Supply Current vs. Switching Frequency NORMALIZED FREQUENCY (fOSC/fOSC,25°C) 5 06090-014 0 tR 06090-013 15 TA = 25°C VIN = VPIN = 5V tR OR tF IS FROM 10% TO 90% OF THE GATE VOLTAGE 30 06090-010 PIN SUPPLY CURRENT (mA) 40 ADP1621 Data Sheet 250 1.6 VIN = 5V CS = 30V 1.4 SHUTDOWN IN CURRENT (µA) TEMPERATURE (°C) 200 150 100 50 VIN = 5V SDSN = 0V 1.2 1.0 0.8 0.6 0.4 10 60 160 110 CS LEAKAGE (nA) 0 –50 06090-016 0 –40 0 50 150 100 TEMPERATURE (°C) Figure 17. Temperature vs. CS Leakage 06090-019 0.2 Figure 20. Shutdown IN Current vs. Temperature 1.2165 VFB = 1.2113V AT 25°C FB BIAS CURRENT IS MEASURED BY FORCING A CONSTANT 1.2113V OVER THE TEMPERATURE RANGE. 8 VIN = 5V SDSN = 0V 1.2155 1.2150 0 VFB (V) FB BIAS CURRENT (nA) 4 1.2160 –4 1.2145 1.2140 1.2135 –8 1.2130 –12 0 50 150 100 TEMPERATURE (°C) 1.2120 –50 0 50 150 100 TEMPERATURE (°C) Figure 18. FB Bias Current vs. Temperature Figure 21. FB Voltage vs. Temperature TA = 25°C VIN = 3.3V VOUT = 5V LOAD = 0.1A DCM OPERATION 80 70 60 4 50 CH4 = INDUCTOR CURRENT fOSC = 200kHz 40 fOSC = 550kHz 30 2 CH2 = DRAIN VOLTAGE 20 10 1 CH1 = GATE 1.2 1.4 1.6 1.8 2.0 fSYNC /fOSC 2.2 Figure 19. Slope-Compensation Current vs. fSYNC/fOSC CH1 5V CH2 5V CH4 500mAΩ M2µs A CH1 Figure 22. DCM Switching Waveform Rev. B | Page 10 of 32 2.9V 06090-021 0 1.0 06090-018 PEAK SLOPE COMPENSATION CURRENT (µA) 90 06090-020 –16 –50 06090-017 1.2125 Data Sheet ADP1621 TA = 25°C VIN = 3.3V VOUT = 5V LOAD = 0.3A CCM OPERATION LOAD CURRENT FROM 0.2A TO 1.2A 4 4 CH4 = INDUCTOR CURRENT 1 2 CH2 = DRAIN VOLTAGE OUTPUT, AC-COUPLED CH1 5V CH2 5V CH4 500mAΩ M2µs A CH1 2.9V 06090-022 CH1 = GATE CH1 50mV Figure 23. CCM Switching Waveform TA = 25°C VIN = 3.3V VOUT = 5V fSW = 220kHz SOFT-START = 9.3ms CH4 1AΩ M200µs A CH4 700V 06090-025 TA = 25°C VIN = 3.3V VOUT = 5V 1 Figure 26. Load Transient Response of the Circuit Shown in Figure 1 TA = 25°C VOUT = 5V NO LOAD AT VOUT CH1 = VOUT CH1 = VOUT, AC-COUPLED 1 CH2 = SDSN 2 1 CH2 = VIN FROM 3V TO 4V 3 CH2 5V M2ms A CH1 4.5V 06090-023 CH1 1V CH3 5V CH1 50mV Figure 24. Soft Start Waveform CH1 = VOUT, AC-COUPLED 1 CH2 = VIN FROM 3V TO 4V M400µs A CH2 3.8V 06090-024 2 CH2 2V M400µs A CH2 3.8V Figure 27. Line Transient Response of the Configuration Shown in Figure 1 with No Load TA = 25°C VOUT = 5V LOAD AT VOUT = 1A CH1 50mV CH2 2V 06090-026 2 CH3 = GATE Figure 25. Line Transient Response of the Configuration Shown in Figure 1 with a 1 A Load Rev. B | Page 11 of 32 ADP1621 Data Sheet THEORY OF OPERATION CONTROL LOOP The ADP1621 uses a current-mode architecture to regulate the output voltage. The output voltage is monitored at FB through a resistive voltage divider. The voltage at FB is compared to the internal 1.215 V reference voltage by the internal transconductance error amplifier to create an error current at COMP. A resistorcapacitor compensation impedance connected from COMP to GND converts the error current to an error voltage. The ADP1621 can sense the current across the on resistance of the MOSFET to minimize external component count and improve efficiency by eliminating the power that would be lost in a currentsense resistor. This lossless technique eliminates the need for an expensive current-sense resistor. In the lossless mode configuration, the voltage at the CS pin (or the switch-node voltage at the drain of the MOSFET) must not exceed 30 V (see Figure 28). This technique maximizes efficiency and reduces cost. In practice, when the calculated VSW approaches 30 V, one should build the board and measure the actual VSW before committing to the lossless mode design. Because of the parasitic inductance in the diode, output capacitor, and PCB traces, VSW typically has narrow peaks that exceed the theoretical maximum voltage at VSW—the sum of VOUT and the forward-voltage drop of Diode D1. If the measured peak voltage exceeds 30 V, or if a more accurate current limit is desired, then the CS pin can be connected to an external currentsense resistor in the source of the MOSFET (Figure 29). The maximum power output is limited by the selection of the external components. At the beginning of the switching cycle, the MOSFET is turned on and the inductor current ramps up. The MOSFET current is measured and converted to a voltage using RCS or RDSON and is added to the stabilizing slope-compensation ramp. The resulting voltage sum passes through the current-sense amplifier to generate the current-sense voltage. When the current-sense voltage is greater than the COMP error voltage, the MOSFET is turned off and the inductor current ramps down until the internal clock initiates the next switching cycle. The duty-cycle of the PWM modulator is thus adjusted to provide the necessary load current at the desired output voltage. Because the output voltage ultimately controls the peak inductor current through the COMP error voltage, this scheme is referred to as peak current-mode control. With light loads, the converter can also operate under discontinuous conduction mode and pulse-skipping modulation to maintain output-voltage regulation. These two forms of operation are discussed in detail in the Light Load Operation section. Note that the converter can also be designed to operate in discontinuous conduction mode at full load if desired. Overall, the current-mode regulation system of the ADP1621 allows fast transient responses while maintaining a stable output voltage. By selecting the proper resistor-capacitor network from COMP to GND, the regulator response can be optimized for a wide range of input voltages, output voltages, and load currents. Rev. B | Page 12 of 32 L VIN PIN IN VOUT VSW CS ADP1621 D1 RS CO SDSN GATE PGND GND 06090-027 The input supply current to the ADP1621 is less than 3 mA during normal operation and less than 10 µA during shutdown. The ADP1621 can drive large external MOSFETs, allowing it to support load currents in excess of 10 A. CURRENT-SENSE CONFIGURATIONS Figure 28. CS Pin Connection for VSW < 30 V, Lossless Mode (No Current-Sense Resistor Needed) L VSW D1 VIN PIN VOUT IN GATE ADP1621 CO SDSN CS RS PGND GND RCS 06090-028 The ADP1621 is a fixed-frequency, current-mode, step-up dc/dc converter controller. It drives an external n-channel MOSFET to step the input voltage up to a higher output voltage. It can be used for SEPIC, flyback, boost, buck-boost, forward, and other converter topologies. It operates at a fixed switching frequency that is set by an external resistor over a range of 100 kHz to 1.5 MHz, and it can be synchronized to an external clock by connecting the SDSN pin to the clock. Figure 29. CS Pin Connection for VSW > 30 V, Resistor Sense Mode with a Current-Sense Resistor, RCS Data Sheet ADP1621 CURRENT LIMIT The current limit is achieved by the COMP voltage clamp, owing to the current-mode operation of the ADP1621. A detailed explanation of how the current limit is determined can be found in the Current Limit section of the Application Information: Boost Converter section. UNDERVOLTAGE LOCKOUT SETTING THE OSCILLATOR FREQUENCY AND SYNCHRONIZATION FREQUENCY The free-running oscillator frequency, fOSC, is set by a resistor from FREQ to GND. A 100 kΩ resistor sets the typical oscillator frequency to 200 kHz, a 65 kΩ resistor sets it to 325 kHz, a 32 kΩ resistor sets it to 600 kHz, and a 10 kΩ resistor sets it to 1.5 MHz. Figure 30 shows a typical relationship between fOSC and RFREQ. 1600 1500 An internal undervoltage lockout (UVLO) circuit at the IN pin holds the GATE voltage low when the IN voltage is below the UVLO voltage, which is typically 2.5 V. 1400 1300 1200 1100 SHUTDOWN When the junction temperature of the ADP1621 reaches about 150°C, the ADP1621 goes into thermal shutdown and the GATE voltage is pulled low. When the junction temperature drops below about 140°C, the ADP1621 resumes normal operation after the soft start sequence. 900 800 700 600 500 400 300 200 100 0 0 20 40 60 80 100 120 RFREQ (kΩ) SOFT START 140 160 180 200 06090-029 fOSC (kHz) 1000 The ADP1621 goes into shutdown approximately 50 µs after the SDSN pin is pulled low or left floating. There is an internal 100 kΩ resistor connected between SDSN and GND. Figure 30. fOSC vs. RFREQ The ADP1621 has an internal soft start circuit that ramps the FB regulation voltage from 0 V to 1.215 V in 64 steps over 2048 clock oscillator cycles. This soft start ramp allows the output voltage to slowly rise to the steady-state output voltage, preventing input inrush current at startup. INTERNAL SHUNT REGULATORS The IN and PIN pins each have an internal shunt regulator that allows the ADP1621 to operate over a wide input voltage range. The shunt regulators limit the voltages at IN and PIN to about 5.5 V, allowing the use of logic-level MOSFETs independent of the input and/or output voltage. The shunt regulator voltage can reach 5.7 V at 10 mA. See Figure 9 for the I-V characteristics of these shunt regulators. The internal power is derived from the IN pin, whereas the MOSFET gate driver (GATE) current comes from the power input, PIN. By separating the two inputs, PIN can be driven with an external small-signal NPN transistor to limit the power loss in the PIN shunt regulator when the input voltage is higher than 5.5 V. See Figure 37 for an example. The maximum currents going into PIN and IN should not exceed 35 mA and 25 mA, respectively. The switching frequency can be synchronized to an external clock by driving the SDSN pin with that clock signal. The SDSN pin serves the two functions of shutdown control and frequency synchronization input. If the SDSN input detects a low-to-high transition within 10 µs of a high-to-low transition, it resets the oscillator to synchronize to the frequency of the signal at SDSN. The ADP1621 only synchronizes to frequencies greater than the free-running switching frequency. To ensure proper synchronization operation, set the synchronization frequency, fSYNC, to 1.2× the freerunning frequency, fOSC. The switching frequency, fSW, is equal to fSYNC. Although the switching frequency can be synchronized to as high as 1.8 MHz, the peak slope-compensation current decreases at higher fSYNC. It is recommended that the maximum fSYNC be less than 1.4× of fOSC. The slope-compensation resistor, RS, should be chosen for the synchronization frequency (see the Slope Compensation section). For SDSN to detect a high input, the high state must remain high for at least 100 ns. Rev. B | Page 13 of 32 ADP1621 Data Sheet APPLICATION INFORMATION: BOOST CONVERTER In this section, an analysis of a boost converter is presented, along with guidelines for component selection. A typical boostconverter application circuit is shown in Figure 1. ADIsimPower DESIGN TOOL SETTING THE OUTPUT VOLTAGE The output voltage is set through a voltage divider from the output voltage to the FB input. The feedback resistor ratio sets the output voltage of the system. The regulation voltage at FB is 1.215 V. The output voltage is given by (see Figure 1) The ADP1621 is supported by ADIsimPower design tool set. ADIsimPower is a collection of tools that produce complete power designs optimized for a specific design goal. The tools enable the user to generate a full schematic, bill of materials, and calculate performance in minutes. ADIsimPower can optimize designs for cost, area, efficiency, and parts count while taking into consideration the operating conditions and limitations of the IC and all real external components. For more information about ADIsimPower design tools, refer to www.analog.com/ADIsimPower. The tool set is available from this website, and users can also request an unpopulated board through the tool. The input bias current into FB is 25 nA typical, 70 nA maximum. For a 0.1% degradation in regulation voltage and with 70 nA bias current, R2 must be less than 18 kΩ, which results in 68 µA of divider current. Choose the value of R1 to set the output voltage. Using higher values for R2 results in reduced output voltage accuracy due to the input bias current at the FB pin, whereas lower values cause increased quiescent current consumption. DUTY CYCLE INDUCTOR CURRENT RIPPLE To determine the worst-case inductor current ripple, output voltage ripple, and slope-compensation factor, it is first necessary to determine the system duty cycle. The duty cycle in continuous conduction mode (CCM) is calculated by the equation Choose a peak-to-peak inductor ripple current between 20% and 40% of the average inductor current. A good starting point for a design is to choose the peak-to-peak ripple current to be 30% of 1/(1 − D) times the maximum load current: D= VOUT + VD − VIN VOUT + VD R1 VOUT = 1.215 V × 1 + R2 ∆I L = 0.3 × (1) I LOAD , MAX 1− D (4) (5) where VOUT is the desired output voltage, VIN is the input voltage, and VD is the forward-voltage drop of the diode. A typical Schottky diode has a forward-voltage drop of 0.5 V. where ΔIL is the peak-to-peak inductor ripple current, and ILOAD,MAX is the maximum load current required by the application. The GATE minimum on and off times determine the minimum and maximum duty cycles, respectively. The minimum on and off times are typically 180 ns and 190 ns, respectively. The minimum and maximum duty cycles are given by The inductor value choice is important because it dictates the inductor current ripple and therefore the voltage ripple at the output. D MIN = t ON , MIN t SW D MAX = 1 − = t ON , MIN × f SW t OFF , MIN t SW = 1 − (t OFF , MIN × f SW ) INDUCTOR SELECTION The average inductor current, IL,AVE, is given by (2) (3) where DMIN is the minimum duty cycle, DMAX is the maximum duty cycle, tON,MIN is the minimum on time, tOFF,MIN is the minimum off time, tSW is the switching period, and fSW is the switching frequency. Note that when the converter tries to operate at a duty cycle lower than DMIN, pulse-skipping modulation occurs to maintain the output voltage regulation (see the Light Load Operation section). I L , AVE = I LOAD 1− D (6) and the peak-to-peak inductor ripple current is inversely proportional to the inductor value: ∆I L = VIN × D f SW × L (7) where fSW is the switching frequency, and L is the inductor value. Assuming continuous conduction mode (CCM) operation, the peak inductor current is given by I L ,PK = I LOAD ∆I L I LOAD V ×D + = + IN 1− D 2 1 − D 2 × f SW × L (8) Smaller inductor values are typically smaller in size and usually less expensive, but increase the ripple current. Larger ripple current also increases the power loss in the inductor core. Too large an inductor value results in added expense and may impede load transient responses because it reduces the effect of slope compensation. Rev. B | Page 14 of 32 Data Sheet ADP1621 Assuming the ripple current is 30% of 1/(1 − D) times the maximum load current, a reasonable choice for the inductor value is VIN × D × (1 − D ) L= 0.3 × f SW × I LOAD , MAX (9) From this starting point, modify the inductance to obtain the right balance of size, cost, and output voltage ripple while maintaining the inductor ripple current between 20% and 40% of 1/(1 − D) times the maximum load current. Keep in mind that the inductor saturation current must be greater than the peak inductor current. Magnetically shielded inductors are generally recommended, although they cost slightly more than unshielded inductors. Also, losses due to the inductor winding resistance reduce the efficiency of the boost converter. This power loss is given by 2 I PL ,W = LOAD × RW 1− D (10) where PL,W is the power dissipation in the winding of the inductor, and RW is the winding resistance. INPUT CAPACITOR SELECTION The bulk input capacitor provides a low impedance path for the inductor ripple current. Capacitor C1 in Figure 1 represents a bulk input capacitor. Choose a bulk input capacitor whose impedance at the switching frequency is lower than the impedance of the voltage source VIN. The preferred bulk input capacitor is a 10 µF to 100 µF ceramic capacitor because it has low equivalent series resistance (ESR) and low impedance. Aluminum electrolytic and aluminum polymer capacitors can also be used as the bulk input capacitors. The bulk input capacitor does not need to be placed very close to the IN and PIN pins. Aluminum electrolytic capacitors are the cheapest and generally have high ESR values, which increase dramatically at temperatures less than 0°C. Some aluminum electrolytic capacitors have ESR less than 20 mΩ, but their capacitances are generally greater than 800 µF. Aluminum polymer capacitors are more expensive than the aluminum electrolytic ones, but are generally cheaper than the ceramic capacitors for the same amount of capacitance. Polymer capacitors have relatively low ESR, with some models having less than 10 mΩ. Regardless of the type of capacitor used, make sure the ripple current rating of the bulk input capacitor, ICIN,RMS, is greater than I CIN ,RMS 1 ∆I L = × 2 3 OUTPUT CAPACITOR SELECTION The output capacitor maintains the output voltage and supplies current to the load while the external MOSFET is on. The value and characteristics of the output capacitor greatly affect the output voltage ripple and stability of the converter. The amount of peak-to-peak output voltage ripple, ΔVOUT, can be approximated by ∆I I ∆VOUT ≈ LOAD + L × D 1 − 2 1 2π × f × C SW OUT 2 + ESR 2 + (2π × f SW × ESL )2 (12) where ΔIL is the peak-to-peak inductor ripple current, fSW is the switching frequency, COUT is the output capacitance, ESR is the effective ESR of COUT, and ESL is the effective equivalent series inductance of COUT. Because the output capacitor is typically greater than 40 µF, the ESR dominates the output capacitance impedance and thus the output voltage ripple. The use of low ESR, ceramic dielectric capacitors is preferred, although aluminum electrolytic, tantalum, OS-CON™ (from Sanyo), and aluminum polymer capacitors can be used. At higher switching frequencies, the ESL of the output capacitor may also be a factor in determining the output voltage ripple. Multiple capacitors can be connected in parallel to reduce the effective ESR and ESL. Keep in mind that the capacitance of a given capacitor typically degrades with increased temperature and bias voltage. Consult the capacitor manufacturer’s data sheet when determining the actual capacitance of a capacitor under certain conditions. Ensure that the output capacitor ripple current rating, ICOUT,RMS, is greater than I COUT ,RMS = I LOAD × D 1− D (13) DIODE SELECTION The diode conducts the inductor current to the output capacitor and load while the MOSFET is off. The average diode current is the load current: I DIODE , AVE = I LOAD (14) The rms diode current in continuous conduction mode is given by (11) I DIODE ,RMS = I LOAD × 1− D 1− D where ΔIL is the peak-to-peak inductor ripple current. where D is the duty cycle. In addition to the bulk input capacitor, a bypass input capacitor is required. The function of the bypass capacitor is to locally filter the input voltage to the ADP1621 and maintain the input voltage at a steady value during switching transitions. The bypass capacitor is typically a 0.1 µF or greater ceramic capacitor and should be placed as close as possible to the IN and PIN pins of the ADP1621. Capacitors C3 and C4 in Figure 1 represent the bypass capacitors. The power dissipated in the diode is PDIODE = VD × I LOAD where VD is the forward-voltage drop of the diode. Rev. B | Page 15 of 32 (15) (16) ADP1621 Data Sheet The MOSFET power dissipation due to conduction is thus The total power dissipation determines the diode junction temperature, which is given by TJ , DIODE = TA + PDIODE × θ JA 2 (17) where TJ,DIODE is the junction temperature, TA is the ambient temperature, and θJA is the junction-to-ambient thermal resistance of the diode package. The diode junction temperature must not exceed its maximum rating at the given power dissipation level. For high efficiency, Schottky diodes are recommended. The low forward-voltage drop of a Schottky diode reduces the power losses during the MOSFET off time, and the fast switching speed reduces the switching losses during the MOSFET transitions. However, for high voltage, high temperature applications where the reverse leakage current of the Schottky diode can become significant and degrade efficiency, use an ultrafast-recovery junction diode. Make sure that the diode is rated to handle the average output load current. Many diode manufacturers derate the current capability of the diode as a function of the duty cycle. Verify that the diode is rated to handle the average output load current with the minimum duty cycle. Also, ensure that the peak inductor current is less than the maximum rated current of the diode. MOSFET SELECTION When turned on, the external n-channel MOSFET allows energy to be stored in the magnetic field of the inductor. When the MOSFET is turned off, this energy is delivered to the load to boost the output voltage. The choice of the external power MOSFET directly affects the boost converter performance. Choose the MOSFET based on the following: threshold voltage (VT), on resistance (RDSON), maximum voltage and current ratings, and gate charge. The minimum operating voltage of the ADP1621 is 2.9 V. Choose a MOSFET with a VT that is at least 0.3 V less than the minimum input supply voltage at PIN used in the application. Ensure that the maximum VGS rating of the MOSFET is at least a few volts greater than the maximum voltage that is applied to PIN. Ensure that the maximum VDS rating of the MOSFET exceeds the maximum VOUT by at least 5 V to 10 V. Depending on parasitics, the MOSFET may be exposed to voltage spikes that exceed the sum of VOUT and the forward-voltage drop of the diode. Estimate the rms current in the MOSFET under continuous conduction mode by I MOSFET , RMS I = LOAD × D 1− D I PC = LOAD × D × RDSON × (1 + K ) 1− D (19) where PC is the conduction power loss, and RDSON is the MOSFET on resistance. The variable K is a factor that models the increase of RDSON with temperature: ( K = 0.005 / C × TJ,MOSFET − 25 C ) (20) where TJ,MOSFET is the MOSFET junction temperature. Note that multiple n-channel MOSFETs can be placed in parallel to reduce the effective RDSON. The power dissipation due to switching transition loss is approximated by PSW = (VOUT + VD )× I LOAD × (t R + t F )× f SW 1− D 2 (21) where PSW is the switching power loss, tR is the MOSFET rise time, and tF is the MOSFET fall time. The MOSFET rise and fall times are functions of both the gate drive circuitry and the MOSFET used in the application. The total power dissipation of the MOSFET is the sum of the conduction and transition losses: PMOSFET = PC + PSW (22) where PMOSFET is the total MOSFET power dissipation. Ensure that the maximum power dissipation is significantly less than the maximum power rating of the MOSFET. The total power dissipation also determines the MOSFET junction temperature, which is given by TJ , MOSFET = TA + PMOSFET × θ JA (23) where TJ,MOSFET is the junction temperature, TA is the ambient temperature, and θJA is the junction-to-ambient thermal resistance of the MOSFET package. The MOSFET junction temperature must not exceed its maximum rating at the given power dissipation level. If lossless current sensing is not used, there will also be power dissipation in the external current-sense resistor, RCS. The power dissipation, PCS, in the external resistor due to conduction losses is given by 2 I PCS = LOAD × D × RCS 1− D (18) where D is the duty cycle. Derate the MOSFET current at least 20% to account for inductor ripple and changes in the forwardvoltage drop of the diode. (24) LOOP COMPENSATION The ADP1621 uses external components to compensate the regulator loop, allowing optimization of the loop dynamics for a given application. The step-up converter produces an undesirable right-half plane (RHP) zero in the regulation feedback loop. This RHP zero requires compensating the regulator such that the crossover Rev. B | Page 16 of 32 Data Sheet ADP1621 f Z ,RHP = (1 − D )2 × RLOAD 2π × L (25) where fZ,RHP is the RHP zero frequency, and RLOAD is the equivalent load resistance or the output voltage divided by the load current. To stabilize the regulator, ensure that the regulator crossover frequency is less than or equal to one-fifth of the RHP zero frequency and less than or equal to one-fifteenth of the switching frequency. For an initial practical design, choose the crossover frequency fC to be the lower of fC = f SW (26) 15 and fC = f Z ,RHP (27) 5 where fC is the crossover frequency, and fSW is the switching frequency. Once the compensation resistor, RCOMP, is known, set the zero formed by the resistor and compensation capacitor, CCOMP, to one-fourth of the crossover frequency, or CCOMP = AVL C2 = ESR × COUT RCOMP where ESR represents the ESR of COUT. For low ESR output capacitors, such as ceramic capacitors, C2 is small, generally in the range of 10 pF to 400 pF. Because of the parasitic inductance, resistance, and capacitance of the PCB layout, the RCOMP, CCOMP, and C2 values might need to be adjusted by observing the load transient response of the ADP1621 to establish a stable operating system and achieve optimal transient performance. For most applications, RCOMP is in the range of 5 kΩ to 100 kΩ, and CCOMP is in the range of 100 pF to 30 nF. 2 (28) | AVL | = VFB 1 1 × (1 − D ) × g m × RCOMP × × =1 VOUT n × RCS 2π × f C × C OUT Solving for RCOMP gives (30) RCOMP C2 Figure 31. Compensation Components SLOPE COMPENSATION The ADP1621 includes a circuit that allows adjustable slope compensation. Slope compensation is required by currentmode regulators to stabilize the current-control loop when operating in continuous conduction and the switching duty cycle is greater than 50%. Slope compensation is achieved by internally forcing a ramping current source out of the CS current-sense pin. By placing a resistor between the CS pin and the current sensing device (the drain of the external MOSFET in the case of lossless current sensing or the source of the MOSFET if a current-sense resistor is used), a voltage is developed across the resistor that is proportional to the slope-compensation current. To ensure stability of the current-mode control loop, use a compensation voltage slope that is equal to or greater than onehalf of the current-sense representation of the inductor current downslope. Therefore, it follows that 2 × RS × where fC is the crossover frequency, RCOMP is the compensation resistor, and COUT is the output capacitance. 3 CCOMP (29) V FB × (1 − D ) × g m COMP gm To determine the crossover frequency, it is important to note that at that frequency the compensation impedance, ZCOMP, is dominated by Resistor RCOMP, and the output impedance, ZOUT, is dominated by the impedance of the output capacitor, COUT. When solving for the crossover frequency, the equation is simplified to 2π × f C × C OUT × n × R CS × VOUT (32) REF where AVL is the loop gain, VFB is the feedback regulation voltage (typically 1.215 V), VOUT is the regulated output voltage, D is the duty cycle, gm is the error amplifier transconductance gain (typically 300 µS), ZCOMP is the impedance of the RC network from COMP to GND, n is the current-sense amplifier gain (typically 9.5), RCS is the current-sense resistance, and ZOUT is the impedance of the load and output capacitor. In the case of lossless current sensing, as shown in Figure 28, RCS is equal to the on resistance, RDSON, of the external power MOSFET. Otherwise, RCS represents the external current-sense resistor, as shown in Figure 29. R COMP = (31) Capacitor C2 is chosen to cancel the zero introduced by the output capacitance ESR. Thus, C2 should be set to (see Figure 31) The regulator loop gain is V 1 = FB × (1 − D ) × g m × | Z COMP | × × | Z OUT | VOUT n × R CS 2 π × f C × RCOMP 06090-030 frequency occurs well below the frequency of the RHP zero. The location of the RHP zero is determined by the following equation: I SC,PK × f SW V + VD − VIN > RCS × OUT 1 − tOFF,MIN × f SW L (33) where RS is the slope-compensation resistor, ISC,PK is the peak slopecompensation current, fSW is the switching frequency, RCS is the current-sense resistor, VOUT is the regulated output voltage, VD is the forward-voltage drop of the diode, VIN is the input voltage, tOFF,MIN is the minimum off time, and L is the power-stage inductor. In the case of lossless current sensing, RCS is equal to the on resistance, Rev. B | Page 17 of 32 ADP1621 Data Sheet which vary from part to part and with temperature. If lossless current sensing is used, consider that the on resistance of a MOSFET typically increases with increasing junction temperature. RDSON, of the external power MOSFET. Otherwise, RCS represents the external current-sense resistor. Solving for RS gives the slope-compensation criterion: RS > RCS × (VOUT + VD − VIN ) × (1 − t OFF , MIN × f SW ) 2 × I SC , PK × f SW × L (34) Keep in mind that the above inequality is a function of both ADP1621 parameters and off-chip components, the values of which vary from part to part and with temperature. Select RS to ensure current-loop stability for all possible variations. After accounting for parameter variations, use values of RS that are as close to the calculated limit as possible because excessive slope compensation reduces the benefits of current-mode control and increases the “softness” of the current limit, as discussed in the Current Limit section. Given a typical peak slope-compensation current of 70 µA, RS should not exceed 1.6 kΩ because the voltage at the CS pin is typically clamped at 116 mV. It is also recommended that RS be greater than 20 Ω. If the calculated RS is greater than 1.6 kΩ, the parameters in Equation 34, such as RCS, fSW, and L, can be adjusted such that RS is less than 1.6 kΩ. In conclusion, the value of RS should be 20 Ω ≤ RS ≤ 1.6 kΩ. CURRENT LIMIT The current limit in the ADP1621 limits the peak inductor current and is achieved by the COMP voltage clamp. The peak inductor current, IL,PK, is given by VCOMP ,CLAMP − VCOMP , ZCT I L , PK = n − I SC , PK × R S × D 1 − t OFF , MIN × f SW (35) RCS where VCOMP,CLAMP is the COMP clamp voltage (typically 2.0 V), VCOMP,ZCT is the COMP zero-current threshold (typically 1.0 V), n is the current-sense amplifier gain (typically 9.5), ISC,PK is the peak slope-compensation current (typically 70 µA), RS is the slope-compensation resistor, D is the duty cycle, fSW is the switching frequency, tOFF,MIN is the minimum off time (typically 190 ns), and RCS is the current-sense resistor. In the case of lossless current sensing, RCS is equal to the on resistance, RDSON, of the external power MOSFET. Otherwise, RCS represents the external current-sense resistor. The current limit in the ADP1621 is a “soft” current limit. When the inductor current reaches the IL,PK limit given in Equation 35, the duty cycle decreases, and the output voltage drops below the desired voltage. The IL,PK limit in Equation 35 then increases in response to the smaller duty cycle, D. The larger the slope-compensation resistor, RS, the larger the effect on IL,PK for an incremental decrease in D. This behavior results in a “soft” current limit for the ADP1621. Use values of RS that are as close as possible to the calculated limit derived from Equation 34. If high-precision current limiting is required, consider inserting a fuse in series with the inductor. Also, keep in mind that the current limit is a function of both ADP1621 parameters and off-chip components, the values of The peak inductor current limit also limits the maximum load current at a given output voltage. The maximum load current, assuming CCM operation, is given by I LOAD , MAX = (1 − D ) × × RS × D I VCOMP ,CLAMP − VCOMP , ZCT − SC , PK 1 − tOFF , MIN × f SW n VIN × D − 2 × f SW × L RCS (36) If the load current exceeds ILOAD,MAX, the output voltage drops below the desired voltage. LIGHT LOAD OPERATION Discontinuous Conduction Mode With light loads, the average inductor current is small, and, depending on the converter design, the instantaneous inductor current may reach 0 during the time when the MOSFET is off. This mode of operation is termed discontinuous conduction mode. The condition for entering discontinuous conduction mode in a boost converter is I LOAD < VIN × D × (1 − D ) 2 × L × f SW (37) When the instantaneous inductor current reaches 0 during the cycle, the inductor ceases to be a current source, and ringing can be observed in the waveforms of the MOSFET drain voltage and the inductor current. The frequency of the ringing is the resonant frequency of the inductor and the total capacitance from the SW node to GND, which includes the capacitances of the MOSFET and diode, and any parasitic capacitances from the PCB. While adding a resistive element, such as a snubber, to the system further dampens the resonance, it also decreases the efficiency of the regulator. Pulse-Skipping Modulation The ADP1621 features circuitry that improves the converter efficiency and minimizes power consumption with no load or very light loads. When the COMP voltage drops below VCOMP,ZCT (typically 1.0 V), which can occur at sufficiently light loads, the MOSFET is powered off until the FB voltage drops below 1.215 V. Then, the error amplifier drives the COMP voltage higher, and the converter resumes switching when the COMP voltage rises above the VCOMP,ZCT voltage. While the MOSFET is powered off, the output capacitor supplies current to the load. With light loads, the COMP voltage hovers around 1.0 V, and short periods of switching are followed by long periods of the MOSFET being powered off. This pulse-skipping modulation operation improves converter efficiency by reducing the number of switching cycles and therefore reducing the gate drive current and the switching transition power loss. Rev. B | Page 18 of 32 Data Sheet ADP1621 Given the minimum on time of the ADP1621, pulse-skipping modulation is also a requirement to maintain output voltage regulation with light loads. During the short switching periods of pulse-skipping modulation, the MOSFET is turned on for the minimum on time each cycle, storing just enough energy in the inductor to charge the output capacitor. During the long period when the MOSFET is off, no current flows through the inductor, and the light load current is supplied by the output capacitor. RECOMMENDED COMPONENT MANUFACTURERS Table 5. Vendor AVX Corporation Central Semiconductor Corp. Coilcraft, Inc. Diodes, Inc. International Rectifier Murata Manufacturing Co., Ltd. ON Semiconductor Rubycon Corporation Sanyo Sumida Taiyo Yuden, Inc. Toko America, Inc. United Chemi-Con, Inc. Vishay Siliconix Components Capacitors Diodes Inductors Diodes Diodes, MOSFETs Capacitors, inductors Diodes, MOSFETs Capacitors Capacitors Inductors Capacitors, inductors Inductors Capacitors Diodes, MOSFETs, resistors, capacitors Rev. B | Page 19 of 32 ADP1621 Data Sheet LAYOUT CONSIDERATIONS Layout is important for all switching regulators, but is particularly important for regulators with high switching frequencies. To achieve high efficiency, good regulation, and stability, a welldesigned printed circuit board layout is required. A sample PCB layout for the standard boost converter circuit shown in Figure 33 is given in Figure 32. Follow these guidelines when designing printed circuit boards: • Keep the low ESR bypass input capacitor of 0.1 µF or higher close to IN/PIN and GND. • Keep the high current path from Bulk Input Capacitor C1 through Inductor L1 and MOSFET M1 to PGND as short as possible. • Keep the high current path from Bulk Input Capacitor C1 through Inductor L1, Diode D1, and Output Capacitor COUT to PGND as short as possible. Place COUT as close to PGND as possible to reduce ground bouncing. • Keep high current traces as short and wide as possible to minimize parasitic series inductance, which causes spiking and electromagnetic interference (EMI). • To minimize switching noise, the drain of the power MOSFET should be placed very close to the inductor, and the source of the MOSFET (or the bottom side of the sense resistor) should be connected directly to the power GND plane. Use wide copper traces on the drain and on the source of the MOSFET to minimize parasitic inductance and resistance. Parasitic inductance can lead to excessive ringing during switching transitions, and parasitic resistance reduces the converter efficiency. Make sure that the MOSFET selected is capable of handling the total power loss (conduction plus transition losses) in the application circuit. • Avoid routing high impedance traces near any node connected to the switch node (the MOSFET drain) or near Inductor L1 to prevent radiated switching-noise injection. • Add an extra copper plane at the connection of the MOSFET drain and the anode of the diode to help dissipate the heat generated by losses in those components. • Avoid ground loops by having one central ground node on the PCB. If this is impractical, place the power ground with high current levels physically closer to the PCB ground terminal. The analog, low current-level ground should be placed farther from the PCB ground terminal. • Minimize the length of the PCB trace between the GATE pin and the MOSFET gate. The parasitic inductance in this PCB trace can give rise to excessive voltage ringing at the MOSFET gate and drain, as well as the regulator output. It is recommended to add 5 Ω of resistance for every inch of PCB trace. This helps to reduce the overshoot and ringing at the drain and the output. However, this added resistance increases the rise and fall times of the MOSFET; thus, the switching loss in the MOSFET is increased. • Place the feedback resistors as close to FB as possible to prevent high frequency switching-noise injection. • Place the top of the upper feedback resistor, R1, as close as possible to the top of COUT for optimum output voltage sensing. • If a current-sense resistor is connected between the source of the MOSFET and PGND, ensure that the capacitance from CS to PGND is minimized. • Place the compensation components as close as possible to COMP. VIN C1 L1 GND D1 COUT1 M1 COUT2 VOUT RS GATE COUT3 ADP1621 R1 R2 CCOMP C2 VIAS TO GND PLANE VIAS TO 2ND LAYER RCOMP RFREQ REMOTE OUTPUT SENSING 06090-031 SDSN C4 C3 GND Figure 32. PCB Layout of the Circuit Shown in Figure 33 (2-layer PCB) Rev. B | Page 20 of 32 Data Sheet ADP1621 EFFICIENCY CONSIDERATIONS The efficiency, η, of a dc/dc converter is given by η= POUT PIN • × 100% (38) where POUT is the output power, and PIN is the input power to the converter. While switching regulators are ideally lossless converters of power, the nonideal characteristics of regulator components degrade the efficiency of the regulator. 2 I PL , W = LOAD × RW 1− D • The primary sources of power dissipation in the regulator include • • PIC = PG + (VIN × I Q ) ( ) The secondary sources of power dissipation in the regulator include (40) • The power dissipation in the ESR of the input and output capacitors. • Inductor core losses due to hysteresis and eddy currents. The power dissipation in the external diode. PDIODE = VD × I LOAD (44) where PIC is the total power dissipated in the IC, IQ is the quiescent current, and VIN is the voltage at the IN pin. 2 • (43) = (VPIN × QG × f SW ) + VIN × I Q The power dissipation in the external current-sense resistor if lossless current sensing is not used. I PCS = LOAD × D × RCS 1− D The supply current to the ADP1621 IC, which includes the quiescent current and the gate driver charging current. The power dissipation due to gate charging loss is approximated by where PG is the gate charging power loss, VPIN is the voltage at the PIN pin, QG is the MOSFET total gate charge, and fSW is the converter switching frequency. Therefore, the total power dissipation in the IC itself is given by (39) I = LOAD × D × R DSON × (1 + K ) + 1 − D I LOAD (VOUT + V D ) × 1 − D × (t R + t F ) × f SW 2 (42) PG = VPIN × QG × f SW The power dissipation in the external power MOSFET due to conduction and switching losses. PMOSFET = PC + PSW The power dissipation in the winding resistance of the power stage inductor. (41) Rev. B | Page 21 of 32 ADP1621 Data Sheet EXAMPLES OF APPLICATION CIRCUITS The next step is to choose a Schottky diode. The average and rms diode currents are calculated to be 1.0 A and 1.3 A, respectively, using Equations 14 and 15. A Vishay SSA33L Schottky diode meets the current and thermal requirements and is an excellent choice. STANDARD BOOST CONVERTER— DESIGN EXAMPLE The example covered here is for the ADP1621 configured as a standard boost converter, as shown in Figure 33, where lossless current sensing is employed. The design parameters are VIN = 3.3 V, VOUT = 5 V, and a maximum load current of 1 A. The power MOSFET must be chosen based on threshold voltage (VT), on resistance (RDSON), maximum voltage and current ratings, and gate charge. The rms current through the MOSFET is given by Equation 18 as 1.1 A. The Vishay Si7882DP is a 20 V n-channel power MOSFET that meets the current and thermal requirements. It comes in a PowerPAK® package and offers low RDSON and gate charge. At VGS = 2.5 V, the on resistance, RDSON, is 8 mΩ. To begin this design, a switching frequency of 600 kHz is chosen (by setting RFREQ to 32 kΩ, see Figure 30) so that a small inductor and small output capacitors can be used. The duty cycle is calculated from Equation 1 to be 0.4, given a forward-voltage drop of 0.5 V for the Schottky diode. The feedback resistors are calculated to be R1 = 35.7 kΩ and R2 = 11.5 kΩ from Equation 4. The loop-compensation components are chosen to be RCOMP = 9.1 kΩ and CCOMP = 1.7 nF from Equations 30 and 31, respectively. A roll-off capacitor of C2 = 120 pF is also added. The slopecompensation resistor is set to be RS = 80 Ω from Equation 34. Assuming that the inductor ripple is 30% of 1/(1 − D) times the maximum load current, the inductor size is calculated to be about 4.4 µH, according to Equation 9. The small, magnetically shielded 4.7 µH Toko FDV0630-4R7M inductor is selected. Because ceramic capacitors have very low ESR (a few milliohms), a 47 µF/6.3 V Murata GRM31CR60J476M ceramic capacitor is chosen for the input capacitor. The output voltage ripple for a given COUT, ESR, and ESL can be found by solving Equation 12. By choosing an output voltage ripple equal to 1% of the output voltage, Equation 12 yields that the minimum COUT required is 100 µF and the maximum ESR required is 25 mΩ. Other combinations of capacitance and ESR are possible by choosing a much larger COUT and a larger ESR. In this case, a small 1 µF ceramic capacitor and two 150 µF Sanyo POSCAP™ capacitors are selected. The low ESR ceramic capacitor helps to suppress the high frequency overshoot at the output. POSCAP has low ESR and high capacitance in a relatively small package. Ceramic capacitors can also be used. Generally, bigger ceramic capacitors are more expensive. Lastly, given the chosen components, the peak inductor current as set by the current limit circuitry is given by Equation 35 as IL,PK = 12 A. Thus, the maximum load current, assuming CCM operation, is given by Equation 36 as ILOAD,MAX = 8 A, which is safely above the 1.0 A load current requirement for this design example. Note that the current limit is a strong function of RCS, which can vary part to part and with temperature. In addition, note that RCS can be implemented with an external currentsense resistor or with the RDSON of a MOSFET. Variations in RCS and the other parameters in Equations 35 and 36 must be taken into account if precise current limiting is necessary. Due to the parasitic resistance of PCB traces, RS might need to be adjusted on the actual circuit board to achieve the desired current limit. Keep in mind that RS must be less than 1.6 kΩ. Using a MOSFET with a different RDSON or adjusting RCS can also set the current limit to the desired level. VIN = 3.3V L1 4.7µH C3 1µF 10V IN PIN CS R1 35.7kΩ 1% RS 80Ω ADP1621 SDSN GATE COMP RCOMP 9.09kΩ C2 120pF CCOMP 1.8nF VOUT = 5V 1A D1 C4 0.1µF 10V M1 COUT1 1µF 10V COUT2 10µF 10V COUT3 150µF 6.3V ×2 R2 11.5kΩ 1% PGND FREQ FB GND C1 47µF 6.3V RFREQ 31.6kΩ 1% AGND C1 = MURATA GRM31CR60J476M COUT3 = SANYO POSCAP 6TPE150M L1 = TOKO FDV0630-4R7M M1 = VISHAY Si7882DP D1 = VISHAY SSA33L Figure 33. Typical Boost Converter Application Circuit Rev. B | Page 22 of 32 06090-032 fOSC = 600kHz Data Sheet ADP1621 BOOTSTRAPPED BOOST CONVERTER The inputs of the ADP1621 can be driven from the step-up converter output voltage to improve efficiency for low input voltages. For low input voltages, bootstrapped operation improves efficiency with heavy loads by increasing the available gate drive voltage, thus reducing the on resistance of the MOSFET. However, because the internal circuitry is driven from IN, the ADP1621 quiescent current and gate drive current supplied from the input increases due to the step-up ratio and the conversion efficiency loss. The circuit shown in Figure 1 shows a bootstrapped boost converter, where VIN = 3.3 V and VOUT = 5 V. To ensure that the circuit starts, make sure that the input voltage minus the forward-voltage drop of the diode is greater than the UVLO voltage and the gate threshold voltage of the MOFSET. In this example, the MOSFET has a gate threshold voltage of 2.5 V. The regulator shown in Figure 1 is very similar to that shown in Figure 33, which is a standard boost without bootstrapping. Because the same MOSFET and inductor are used in both circuits and the input and output conditions are the same, the compensation components remain unchanged. Figure 34 shows a bootstrapped application circuit for output voltages greater than 5.5 V. In this case, the output is 12 V. Notice that a resistor, R3, of 700 Ω is placed between VOUT and the IN and PIN pins to limit the input currents because the IN and PIN pins are regulated to 5.5 V. A diode, D2, is placed between VIN and the IN/PIN pins to supply the necessary quiescent current to start the ADP1621. Once the ADP1621 starts and the output voltage reaches 12 V, the quiescent current stops flowing through D2 and is supplied by the output. Keep in mind that the dynamic supply current to PIN increases as the switching frequency increases because more gate drive is needed for a higher switching frequency. Therefore, R3 needs to be set appropriately. The PIN supply current can be approximated by I PIN = f SW × QG (45) where IPIN is the PIN supply current, fSW is the switching frequency, and QG is the gate charge of a particular MOSFET. An alternative implementation to Figure 34 is shown in Figure 35, where an NPN transistor is used to supply the necessary current to the input PIN at various loads, but the gate drive voltage is limited to approximately 4.8 V (one diode drop below the voltage at IN). Signal Diodes D2 and D3 help to provide the necessary quiescent current to start the ADP1621. Once the ADP1621 starts, the current stops flowing through these two diodes because the voltages at PIN and IN are approximately 4.8 V and 5.5 V, respectively. One advantage of this technique is that Q1 provides enough current to the gate driver at any switching frequency with a wide range of MOSFETs that have different gate charge specifications. Notice that the output capacitor, COUT2 in Figure 34 and Figure 35, is a large aluminum electrolytic capacitor, both in physical size and capacitance. Such capacitors are very cheap relative to ceramic capacitors (such as Sanyo POSCAP) or aluminum polymer capacitors. The ADP1621 can work with a wide range of capacitor types. Rev. B | Page 23 of 32 ADP1621 Data Sheet VIN = 3.3V D2 C3 1µF 10V R3 700Ω L1 10µH IN PIN CS R1 88.7kΩ 1% RS 200Ω ADP1621 SDSN C2 220pF CCOMP 330pF COUT1 10µF 16V ×2 COUT2 330µF 25V ×2 R2 10kΩ 1% M1 GATE COMP RCOMP 51.5kΩ VOUT = 12V 1A D1 C4 0.1µF 10V PGND FREQ FB GND C1 47µF 6.3V RFREQ 31.6kΩ 1% AGND fOSC = 600kHz C1 = MURATA GRM31CR60J476M COUT2 = RUBYCON 25ZL330M8x16 L1 = COILCRAFT MSS1260-103ML 06090-033 M1 = IRF7470 D1 = VISHAY SSC53L D2 = SIGNAL DIODE Figure 34. Bootstrapped Application Circuit for VOUT > 5.5 V VIN = 3.3V L1 10µH D2 D3 Q1 R3 1.5kΩ C3 1µF 10V IN PIN CS R1 88.7kΩ 1% RS 200Ω ADP1621 SDSN GATE COMP RCOMP 51.5kΩ C2 220pF CCOMP 330pF VOUT = 12V 1A D1 C4 0.1µF 10V M1 COUT1 10µF 16V ×2 COUT2 330µF 25V ×2 R2 10kΩ 1% PGND FREQ FB GND C1 47µF 6.3V RFREQ 31.6kΩ 1% AGND C1 = MURATA GRM31CR60J476M COUT2 = RUBYCON 25ZL330M8x16 L1 = COILCRAFT MSS1260-103ML Q1 = SIGNAL NPN TRANSISTOR M1 = IRF7470 D1 = VISHAY SSC53L D2, D3 = SIGNAL DIODE Figure 35. Bootstrapped Application Circuit for VOUT > 5.5 V Rev. B | Page 24 of 32 06090-034 fOSC = 600kHz Data Sheet ADP1621 Low Input and High Output Boost Converter with a single resistor, as shown in Figure 38. When there is a wide input voltage range, it is sometimes desirable to use the pass NPN transistor, as shown in Figure 37. If the input voltage range is narrow, a single resistor connecting to the IN and PIN pins is sufficient, as shown in Figure 38. In Figure 37, Resistor R3 limits the current going into IN, and there is power loss in this resistor. The voltages at IN and PIN are both clamped to about 5.5 V, which can rise to as high as 5.9 V when the shunt current is 30 mA. Refer to Figure 9 for the I-V characteristics of the shunt regulators. Ensure that Resistor R3 is physically large enough to handle the power dissipation. For switch-node voltages higher than 30 V, a current-sense resistor is needed and the CS pin senses the voltage across the sense resistor. Figure 36 shows a typical application boost converter circuit that operates at a switching frequency of 200 kHz with VIN = 5 V and VOUT = 30 V with a 1 A load. The duty cycle for this circuit is about 83%. A higher switching frequency can be selected, but the switching power loss in the MOSFET increases and a bigger MOSFET is needed. For switch-node voltages greater than 30 V, a sense resistor, RCS, is needed because the absolute maximum voltage at CS is 33 V. High Input Voltage Boost Converter Circuit Input voltages higher than 5.5 V are possible with the addition of a resistor and an NPN transistor, as shown in Figure 37, or just VIN = 5V L1 7.8µH C3 1µF 10V R1 115kΩ 1% PIN IN FB ADP1621 SDSN C2 120pF CCOMP 20pF FREQ M1 GATE COMP RCOMP 1.6MΩ VOUT = 30V 1A D1 C4 0.1µF 10V CS PGND GND RS 909Ω COUT1 1µF 100V COUT2 4.7µF 50V COUT3 330µF 50V ×2 R2 4.87kΩ 1% RCS 3mΩ C1 47µF 6.3V ×2 RFREQ 100kΩ 1% AGND fOSC = 200kHz 06090-035 M1 = VISHAY SUD50N06-07L C1 = MURATA GRM31CR60J476M COUT1 = MURATA GRM31CR72A10 COUT2 = MURATA GRM55ER71H475K COUT3 = RUBYCON 50ZL330M10x23 D1 = IRF 15TQ060 L1 = COILCRAFT DO501DH-782ML Figure 36. Low Input, High Output Boost Converter VIN = 8V TO 15V R3 700Ω Q1 C4 0.1µF 10V C3 1µF 10V L1 8.2µH R1 115kΩ 1% PIN IN FB RCOMP 2MΩ C2 120pF CCOMP 220pF FREQ CS PGND GND COUT2 4.7µF 50V COUT3 330µF 50V ×2 M1 GATE COMP COUT1 1µF 100V R2 4.87kΩ 1% ADP1621 SDSN VOUT = 30V 1A D1 RS 402Ω RCS 3mΩ C1 22µF 16V ×2 RFREQ 34.8kΩ AGND C1 = MURATA GRM32ER61C226K COUT1 = MURATA GRM31CR72A105K COUT2 = MURATA GRM55ER71H475K COUT3 = RUBYCON 50ZL220M10x23 M1 = IRF7470 Q1 = SIGNAL NPN TRANSISTOR D1 = MBRB7H50 L1 = COILCRAFT MSS1260-822ML Figure 37. High Input Voltage and High Output Voltage Converter Rev. B | Page 25 of 32 06090-036 fOSC = 560kHz ADP1621 Data Sheet VIN = 12V R3 649Ω C3 1µF 10V L1 15µH R1 324kΩ 1% PIN IN FB ADP1621 SDSN C2 120pF CCOMP 18pF FREQ M1 GATE COMP RCOMP 2MΩ VOUT = 40V 1A D1 C4 0.1µF 10V CS PGND GND RS 442Ω COUT1 1µF 100V COUT2 4.7µF 50V COUT3 220µF 63V ×2 R2 10.2kΩ 1% RCS 0.01Ω C1 22µF 16V ×2 RFREQ 34.8Ω AGND fOSC = 560kHz M1 = VISHAY Si7478DP D1 = MBRB7H50 L1 = COILCRAFT MSS1278-153ML Figure 38. High Input Voltage and High Output Voltage Converter Rev. B | Page 26 of 32 06090-037 C1 = MURATA GRM32ER61C226K COUT1 = MURATA GRM31CR72A105K COUT2 = MURATA GRM55ER71H475K COUT3 = RUBYCON 63ZL220M10x23 Data Sheet ADP1621 SEPIC CONVERTER CIRCUIT load current during this time. When the MOSFET turns off and the diode turns on, the energy in L1 and L2 is released to charge the output capacitor, COUT, and the coupling capacitor, C5, as well as to supply current to the load. A single-ended primary inductance converter (SEPIC) topology is shown in Figure 39. This topology is useful for an unregulated input voltage, where the regulated output voltage falls within the input voltage range. LOW VOLTAGE POWER-INPUT CIRCUIT The input and output are dc-isolated by a coupling capacitor, C5. L1 and L2 are coupled inductors with a 1:1 turn ratio, which saves space on the PCB. In steady state, the average voltage across C5 is the input voltage. When the MOSFET turns on and the diode turns off, the input voltage provides energy to L1, and C5 provides energy to L2. The output capacitor, COUT, supplies the The ADP1621 can be configured to run from a low voltage (as low as 1 V) power input. The power source generally needs to have a high current capability, such as a fuel cell. Figure 40 illustrates such an application, where the voltage of the power input is 1 V and the voltage of the chip supply to the IN and PIN pins is provided by an auxiliary low power source. VIN = 3V TO 5.5V L2 2.4µH C3 1µF 10V L1 2.4µH C4 0.1µF 10V IN PIN CS COUT1 1µF 10V RS 80Ω ADP1621 SDSN RCOMP 26kΩ CCOMP 1.2nF M1 GATE COMP C2 33pF VOUT = 3.3V 2A D1 C5 10µF 10V X5R R1 17.4kΩ 1% PGND FREQ COUT2 150µF 6.3V ×3 FB GND R2 10kΩ 1% RFREQ 65kΩ C1 22µF 10V ×2 AGND fOSC = 325kHz 06090-038 C1 = MURATA GRM332ER61A226K M1 = VISHAY Si7882DP COUT2 = SANYO POSCAP 6TPE150MI D1 = VISHAY SSC53L C5 = MURATA GRM21BR61A106K L1, L2 = COUPLED INDUCTORS, 1:1 RATIO, BH ELECTRONICS BH510-1006 Figure 39. A SEPIC DC/DC Converter VIN = 1V L1 2.2µH VCC = 2.9V TO 5.5V C3 1µF 10V IN PIN CS R1 35.7kΩ 1% RS 249Ω ADP1621 SDSN GATE COMP RCOMP 9.4kΩ C2 260pF CCOMP 56nF VOUT = 5V 1A D1 C4 0.1µF 10V M1 COUT1 1µF 10V COUT2 10µF 6.3V COUT3 150µF 6.3V ×2 R2 11.5kΩ 1% PGND FREQ FB GND C1 100µF X5R 6.3V RFREQ 31.6kΩ 1% AGND C1 = MURATA GRM32ER60J107ME20 M1 = VISHAY Si7882DP COUT2 = MURATA GRM21BR60J106K D1 = MBRD835L COUT3 = SANYO POSCAP 6TPE150MI L1 = TOKO FDV0630-2R2M Figure 40. Low Voltage Power-Input Application Circuit Rev. B | Page 27 of 32 06090-039 fOSC = 600kHz ADP1621 Data Sheet LED DRIVER APPLICATION CIRCUITS The ADP1621 can be used as an LED driver. Two LED application circuits are shown in Figure 41 and Figure 42, where each circuit is driving 20 white LEDs in series. Each white LED has a typical current of 150 mA at a typical forward voltage of 4.0 V, with a maximum voltage of 4.5 V over the temperature range of −40°C to +125°C. Two methods for dimming the brightness of the LEDs are shown in Figure 41 and Figure 42. In Figure 41, a PWM signal is fed to the SDSN pin to turn the ADP1621 controller on and off. As a result, the LED current is turned on and off, and the average LED current is dependent on the PWM duty cycle. The advantage of this method is that no current flows through the LEDs during the PWM off cycle. In addition, when the ADP1621 is on, the forward current through the LEDs is constant, which guarantees constant color emission across the entire dimming range. Because the soft start period is fixed at 2048 oscillator cycles, the PWM frequency range is limited. As shown in Figure 41, because the natural switching frequency chosen is 400 kHz, the useful PWM frequency range is 90 Hz to 195 Hz. However, when driving fewer LEDs, the ADP1621 can be set to run at a faster frequency, increasing the maximum PWM frequency. The PWM duty cycle can be between 5% and 95%. A higher PWM duty cycle produces a higher average LED current. Another method for driving the LEDs is shown in Figure 42, where the PWM signal is filtered by an RC low-pass filter and is fed to the FB node. The effective FB voltage at the bottom of the LED string is modulated in an analog manner by the PWM duty cycle. Thus, the average current through the LEDs is modulated accordingly. Unlike the case depicted in Figure 41, a higher duty cycle produces a lower average LED current using the filtered PWM scheme in Figure 42. The advantage of this circuit is that the PWM frequency can be in the range between 90 Hz and 100 kHz, and the duty cycle can be between 5% and 95%. The disadvantage of this method is that the forward current through the LEDs is directly modified to control the brightness of the LEDs. Because the wavelength of the light emitted from an LED is a weak function of its forward current, perfect color purity across the entire dimming range cannot be guaranteed. If PCB space is a constraint, smaller inductors can be selected for the circuits shown in Figure 41 and Figure 42. For example, a 4.7 µH inductor can be used, and a 200 kHz switching frequency can be selected. However, with this small inductor, the system operates in DCM, which is slightly less efficient than operating in CCM. Rev. B | Page 28 of 32 Data Sheet ADP1621 VIN = 10V TO 16V RB 800Ω L1 33µH D1 100V C4 0.1µF C3 0.1µF IN PIN M1 100V GATE SDSN CS COMP RCOMP 101kΩ C2 18pF CCOMP 390nF FREQ COUT 1µF 100V ×3 150mA ADP1621 PWM VOUT RS 800Ω 20 LEDS FB PGND GND RCS 3mΩ RFREQ 50kΩ 1% R1 8Ω 1/4W C1 2.2µF 25V AGND C1 = MURATA GRM31MR71E225K COUT = MURATA GRM31CR72A105K L1 = COILCRAFT MSS1038-333NL M1 = VISHAY Si4482DY D1 = IRF 10MQ100 06090-040 fOSC = 400kHz Figure 41. 20-Series LED Driver with PWM at SDSN VIN = 10V TO 16V RB 800Ω C4 0.1µF C3 0.1µF IN PIN ADP1621 SDSN CS COMP RCOMP 101kΩ C2 10pF CCOMP 390nF FREQ RS 800Ω RFREQ 50kΩ 1% 20 LEDS R2 10kΩ FB PGND GND VOUT COUT 1µF 100V ×3 150mA M1 100V GATE R5 18kΩ L1 33µH D1 100V RCS 3m R1 8Ω 1/4W R3 R4 22.9kΩ 10kΩ C5 0.1µF 6.3V PWM = 0V TO 4V C1 2.2µF 25V C1 = MURATA GRM31MR71E225K COUT = MURATA GRM31CR72A105K L1 = COILCRAFT MSS1038-333NL M1 = VISHAY Si4482DY D1 = IRF 10MQ100 Figure 42. 20-Series LED Driver with Filtered PWM Rev. B | Page 29 of 32 06090-041 AGND fOSC = 400kHz ADP1621 Data Sheet RELATED PARTS Table 6. Part Number ADP1612 ADP1613 ADP1614 Description Current-mode PWM step-up controller Current-mode PWM step-up controller Current-mode PWM step-up controller Comments 1.4 A, internal FET RDSON is 130 m Ω nominal, VIN = 1.8 V to 5.5 V, VOUTMAX is 20 V 2.0 A, internal FET RDSON is 130 m Ω nominal, VIN = 2.5 V to 5.5 V, VOUTMAX is 20 V 4.0 A, internal FET RDSON is 50 m Ω nominal, VIN = 2.5 V to 5.5 V, VOUTMAX is 20 V Rev. B | Page 30 of 32 Data Sheet ADP1621 OUTLINE DIMENSIONS 3.10 3.00 2.90 10 3.10 3.00 2.90 1 5.15 4.90 4.65 6 5 PIN 1 IDENTIFIER 0.50 BSC 0.95 0.85 0.75 15° MAX 1.10 MAX 0.30 0.15 6° 0° 0.23 0.13 0.70 0.55 0.40 COMPLIANT TO JEDEC STANDARDS MO-187-BA 091709-A 0.15 0.05 COPLANARITY 0.10 Figure 43. 10-Lead Mini Small Outline Package [MSOP] (RM-10) Dimensions shown in millimeters ORDERING GUIDE Model 1 ADP1621ARMZ-R7 ADP1621-EVAL 1 Temperature Range −40°C to +125°C Package Description 10-Lead Mini Small Outline Package [MSOP] Evaluation Board Z = RoHS Compliant Part. Rev. B | Page 31 of 32 Package Option RM-10 Ordering Quantity 1,000 1 Branding L3M ADP1621 Data Sheet NOTES ©2006–2012 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D06090-0-6/12(B) Rev. B | Page 32 of 32