DESIGN FEATURES LTC1622: Low Input Voltage, Current Mode PWM Buck Converter by San-Hwa Chee Introduction 750kHz. High frequency operation allows the use of small inductors, making this part ideal for communications products. The LTC1622 comes in a tiny 8-lead MSOP package, providing a complete power solution while occupying only a small area. The LTC1622 uses a pulse-width, current mode architecture, which provides excellent AC and DC load and line regulation. Peak inductor current is set by an external sense resistor. This allows the design to be optimized for each application. A softstart pin allows the LTC1622 to power up gently. A Detailed Look at the LTC1622 The LTC1622 is a constant-frequency, pulse-width-modulated, current mode switching regulator. In normal operation, the external P-channel power MOSFET is turned on during each cycle when the oscillator sets a latch and turned off when the current comparator resets the latch. The peak inductor current at which the current comparator resets the latch is controlled by the voltage on the ITH pin, which is the output of the error amplifier, gm. An external resistive divider connected between VOUT and ground allows gm to receive an output feedback voltage, VFB. When the load current increases, it causes a slight decrease in VFB relative to the 0.8V reference, which, in turn, causes the ITH voltage to increase until the average inductor current matches the new load current. (For a more detailed description, please refer to the LTC1622 data sheet.) The value of the RSENSE is chosen based on the required output current. The LTC1622 current comparator has a maximum threshold of 100mV/ R SENSE . The current-comparator threshold sets the peak of the inductor current, yielding a maximum average output current equal to the peak value minus one-half the peakto-peak inductor ripple current. For applications where the duty cycle is 100 90 EFFICIENCY (%) The push for 2.5V system supplies continues unabated as manufacturers introduce more parts that operate at this low voltage. The rewards are great, especially for battery-powered equipment, since the lower voltage reduces power consumption and thereby extends the time between battery replacements or recharges. With a 2.5V system supply, operation from a single lithium-ion battery becomes highly attractive, because its end-of-charge voltage is 2.7V and it has the most energy per volume compared to NiCd and NiMH. The 8-pin LTC1622 step-down DC/ DC controller is designed to help system designers harness all of the available energy from lithium-ion batteries in several ways. Its wide operating input-voltage range (2.0V to an absolute maximum of 10V) and 100% duty cycle allows low dropout for maximum energy extraction from the battery. The part’s low quiescent current, 400µ A, with a shutdown current of 15µ A, extends battery life. Its user-selectable Burst Mode operation enhances efficiency at low load current. For portable applications where board space is a premium, the LTC1622 operates at a constant frequency of 550kHz and can be synchronized to frequencies of up to VIN = 4.2V VIN = 3.3V 80 VIN = 8.4V 70 VIN = 6V 60 VOUT = 2.5V RSENSE = 0.03Ω 50 40 0.001 0.100 0.010 LOAD CURRENT (A) 1.000 Figure 2. Efficiency vs load current for Figure 1’s circuit (Burst Mode enabled) 100 VIN = 4.2V R2 0.03Ω VIN = 3.3V VIN 2.5V–8.5V LTC1622 1 SENSE– 7 2 ITH PDRV 6 5 SYNC/MODE GND 3 4 RUN/SS VFB 8 C1 + 10µF 16V R1 10k C3 220pF VIN Si3443DV L1 4.7µH D1 470pF C1: MURATA CERAMIC GRM235Y5V106Z (814) 236-1431 C2: SANYO POSCAP 6TPA47M (619) 661-6835 L1: MURATA LQN6C-4R7M04 R3 159k + R4 75k D1: IR10BQ015 (310) 322-3331 R2: DALE, 0.25W (605) 665-9301 Figure 1. LTC1622 typical application: 2.5V/1.5A converter Linear Technology Magazine • November 1998 VOUT C2 2.5V/1.5A 47µF 6V EFFICIENCY (%) 90 80 70 60 VIN = 8.4V VIN = 6V VOUT = 2.5V RSENSE = 0.03Ω 50 40 0.001 0.010 0.100 1.000 LOAD CURRENT (A) Figure 3. Efficiency vs load current for Figure 1’s circuit (Burst Mode disabled) 21 DESIGN FEATURES high (> 80%), the value of the sense resistor is set to approximately 50mV/ IOUTMAX to account for the effect of slope compensation. Under short-circuit conditions, the frequency of the oscillator will be reduced to about 120kHz. This low frequency allows the inductor current to safely discharge, thereby preventing current runaway. The LTC1622 includes protection against output overvoltage conditions or transients. An overvoltage comparator monitors the output voltage and forces the external MOSFET off when the feedback voltage has risen to 8% above the reference voltage (0.8V). necting the SYNC/MODE pin to ground. In this case, constant-frequency operation will be maintained at a lower load current together with lower output ripple. If the load current is low enough, cycle skipping will occur to maintain regulation. Frequency Synchronization The LTC1622 can be externally driven by a clock signal of up to 750kHz. Synchronization is inhibited when the feedback voltage is below 0.3V. This is done to prevent inductor current build-up under short-circuit conditions. Burst Mode operation is inhibited when the LTC1622 is driven by an external clock. Undervoltage Lockout and The LTC1622’s Burst Mode operation Dropout Operation Burst Mode Operation is enabled at low load currents simply by connecting the SYNC/MODE pin to VIN or letting it float. In this mode, the minimum peak current of the inductor is set to 0.36V/RSENSE even though the voltage at the ITH pin would indicate a lower value. If the inductor’s average current is greater than the load requirement, the voltage at the ITH pin will drop as VOUT rises slightly. When the ITH voltage goes below 0.12V, a sleep signal is generated, turning off the external MOSFET. The load current is now supported by the output capacitor. The LTC1622 will resume normal operation when the ITH voltage goes above 0.22V. For frequency-sensitive applications, Burst Mode operation is inhibited by con- An undervoltage lockout circuit is incorporated into the LTC1622. When the input voltage drops below 2.0V, most of the LTC1622 circuitry will be turned off, reducing the quiescent current from 400µ A to several microamperes and forcing the external MOSFET off. The LTC1622 is capable of turning the external P-channel MOSFET on continuously (100% duty cycle) when the input voltage falls to near the output voltage. In dropout, the output voltage is determined by the input voltage minus the voltage drop across the MOSFET, the sense resistor and the inductor resistance. The RUN/SS pin is a dual-function pin that provides the soft-start function and a means to shut down the LTC1622. An internal current source charges an external capacitor. When the voltage on the Run/SS pin reaches 0.65V, the LTC1622 begins operating. As the voltage on the RUN/SS continues to increase linearly from 0.65V to 1.8V, the internal current limit also increases proportionally. The current limit begins at 0A (at VRUN/SS = 0.65V) and ends at 0.10V/ RSENSE (VRUN/SS > 1.8V); therefore, this pin can be used for power supply sequencing. 2.5V/1.5A Step-Down Regulator A typical application circuit using the LTC1622 is shown in Figure 1. This circuit supplies a 1.5A load at 2.5V with an input supply between 2.7V up to 8.5V. The 0.03Ω sense resistor is selected to ensure that the circuit is capable of supplying 1.5A at a low input voltage. In addition, a sublogic threshold MOSFET is used, since the circuit operates at input voltages as low as 2.7V. The circuit operates at the internally set frequency of 550kHz. A 4.7µ H inductor is chosen so that the inductor’s current remains continuous during burst periods at low load current. For low output voltage ripple, a low ESR capacitor (100mΩ) is used. OUTPUT VOLTAGE (AC COUPLED) 0.1V/DIV OUTPUT VOLTAGE (AC COUPLED) 0.1V/DIV 0.1ms/DIV Figure 4. Transient response with Burst Mode enabled; load step = 50mA to 1.2A 22 RUN/Soft-Start Pin 0.1ms/DIV Figure 5. Transient response with Burst Mode inhibited; load step = 50mA to 1.2A Linear Technology Magazine • November 1998 DESIGN FEATURES 100 R2 0.03Ω LTC1622 1 SENSE– 7 2 ITH PDRV 6 5 SYNC/MODE GND 3 4 RUN/SS VFB 8 C1 + 47µF 16V R1 22k C3 100pF VIN Si3443DV L1 1.3µH D1 470pF R3 159k + EFFICIENCY (%) VIN 2.5V–8.5V VOUT C2 2.5V/1.5A 100µF 6V R4 75k C1: AVX TPSD476M016R0150 (803) 946-0362 C2: AVX TPSD476M016R0065 L1: MURATA LQN6C-1R5M04 (814) 237-1431 VIN = 8.4V 70 VIN = 6V 60 40 0.001 Figure 6. 2.5V/1.5A converter with improved transient response for Burst Mode operation than with Burst Mode disabled at 50mA load current. Applications that require better transient response can use the circuit in Figure 6, whose components are selected specifically for this requirement. Figures 7 and 8 show the response with and without Burst Mode operation, respectively. Note that the transient response has been enhanced significantly. However, this comes at the expense of slightly reduced efficiency at low load currents, as indicated by the efficiency curves of Figures 9 and 10. VOUT = 2.5V RSENSE = 0.03Ω 0.010 0.100 LOAD CURRENT (A) 1.000 Figure 9. Efficiency vs load current for Figure 6’s circuit (Burst Mode enabled) 100 VIN = 3.3V 90 EFFICIENCY (%) The efficiency curves for Figure 1’s circuit are shown in Figures 2 and 3. Figure 2 shows the efficiency with Burst Mode enabled, whereas Figure 3 has Burst Mode defeated. Note that, at low load currents, the efficiency is higher with Burst Mode operation. However, constant frequency operation is still achievable at a lower load currents with Burst Mode operation defeated. The kinks in the efficiency curves indicate the transition out of Burst Mode operation. The components of Figure 1 have been carefully chosen to provide the amount of output power using a minimum of board space. Efficiency is also a prime consideration in selecting the components, as illustrated in Figures 2 and 3. Figures 4 and 5 show the transient response of VOUT with a load step from 50mA to 1.2A. Figure 4 has Burst Mode enabled, while Figure 5 has it defeated. Note that the output voltage ripple (in the middle portion of the photographs) is higher VIN = 3.3V 80 50 D1: IR10BQ015 (310) 322-3331 R2: DALE, 0.25W (605) 665-9301 Efficiency Considerations VIN = 4.2V 90 VIN = 4.2V 80 VIN = 8.4V 70 VIN = 6V 60 VOUT = 2.5V RSENSE = 0.03Ω 50 40 0.001 0.010 0.100 LOAD CURRENT (A) 1.000 Figure 10. Efficiency vs load current for Figure 6’s circuit (Burst Mode disabled) Conclusion Although the LTC1622 comes in a tiny 8-pin MSOP, it is packed with features that are not normally found in other DC/DC converters. Its ability to operate from input voltages as low as 2.0V makes it attractive for single lithium-ion battery-powered applications. Features like Burst Mode and 100% duty cycle ensure that energy from the battery is used efficiently and charge is extracted down to the last coulomb. For telecommunications products, where noise generated by a switching regulator may spell trouble, the synchronizable LTC1622 can operate at a constant frequency, making noise a nonissue for system designers. OUTPUT VOLTAGE (AC COUPLED) 0.1V/DIV OUTPUT VOLTAGE (AC COUPLED) 0.1V/DIV 0.1ms/DIV Figure 7. Transient response with Burst Mode enabled; load step = 50mA to 1.2A Linear Technology Magazine • November 1998 0.1ms/DIV Figure 8. Transient response with Burst Mode inhibited; load step = 50mA to 1.2A 23