65V, 500mA Step-Down Converter Fits Easily into Automotive and Industrial Applications Design Note 512 Charlie Zhao VIN 48V 100µH VIN + OPT. 2M 47µF RUN FBO 68.1k ISET 200pF 100k 806k VFB VPRG1 VIN = 30V EFFICIENCY (%) 96 92 VIN = 48V 88 84 80 76 1 10 100 LOAD CURRENT (mA) 1000 F02 Figure 2. Efficiency of Circuit in Figure 1 VIN 35 30 27V 25 20 24V 30 VOUT 20 VOUT 24V, 300mA 2× 22µF SW LTC3630 100 10 0 221k SS 47nF VPRG2 GND TIME (5s/DIV) OUTPUT VOLTAGE (V) 65V Input, 500mA DC/DC Converter with an Adjustable Output Down to 800mV The LTC ®3630 is a versatile Burst Mode ® synchronous step-down DC/DC converter that includes three pinselectable preset output voltages. Alternatively, the output can be set via feedback resistors down to 800mV. An adjustable output or input current limit from 50mA to 500mA can be set via a single resistor. The hysteretic nature of this topology provides inherent short-circuit protection. Higher output currents are possible by paralleling multiple LTC3630s together and connecting the FBO of the master device to the VFB pin of a slave device. An adjustable soft-start is included. A precision RUN pin threshold voltage can be used for an undervoltage lockout function. 24V Regulator with 300mA Output Current Limit and Input Undervoltage Lockout Figure 1 shows a 48V to 24V application that showcases several of the LTC3630’s features, including the undervoltage lockout and output current limit. Operational efficiencies are shown in Figure 2. INPUT VOLTAGE (V) Introduction The trend in automobiles and industrial systems is to replace mechanical functions with electronics, thus multiplying the number of microcontrollers, signal processors, sensors and other electronic devices throughout. The issue is that 24V truck electrical systems and industrial equipment use relatively high voltages for motors and solenoids while the microcontrollers and other electronics require much lower voltages. As a result, there is a clear need for compact, high efficiency step-down converters that can produce very low voltages from the high input voltages. F03 Figure 3. Input Voltage Sweep vs Output Voltage Showing Undervoltage Lockout Threshold Levels F01 Figure 1. High Efficiency 24V Regulator with Undervoltage Lockout and 300mA Current Limit 03/13/512 L, LT, LTC, LTM, Linear Technology, the Linear logo and Burst Mode are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. VIN = 48V 25 80Ω OUTPUT VOLTAGE OUTPUT CURRENT 300 15 42Ω 10 200 25Ω 5 RESISTIVE LOAD 0 18Ω 14Ω 11Ω 100 8Ω 0 OUTPUT CURRENT (mA) VOUT (V) 20 VIN 10V TO 60V 100µH + VIN 47µF OPT. 665k LTC3630 RUN FBO ISET 100nF VOUT 5V 2× 22µF SW VFB VPRG1 SS 47nF 10k VPRG2 GND F05 F04 Figure 4. Resistive Load Sweep vs Output Current vs Output Voltage with Output Current Limit Set to 300mA Figure 5. 5V Regulator with 55mA Input Current Limit The RUN pin is programmed for VIN undervoltage lockout threshold levels of 27V rising and 24V falling. Figure 3 shows VOUT vs VIN. This feature assures that VOUT is in regulation only when sufficient input voltage is available. An increased voltage on ISET increases the converter’s current limit. Figure 6 shows the steady-state input current vs input voltage and the available output current before the output voltage begins to drop out of regulation. For the values shown in Figure 5, the input current is limited to approximately 55mA over a 10V to 60V input voltage range. Although the LTC3630 can supply up to 500mA of output current, the circuit in Figure 1 is programmed for a maximum of 300mA. An internally generated 5µA bias out of the ISET pin produces a voltage across an ISET resistor, which determines the maximum output current. Figure 4 shows the output voltage as a resistive load is varied from approximately 100Ω down to 8Ω while maintaining the output current near the programmed value of 300mA. In addition, the hysteretic topology used in this DC/DC converter provides inherent short-circuit protection. Input Current Limit Another useful feature of the LTC3630 is shown in Figure 5. In this 5V circuit, the current limit is set by a resistive divider from VIN to ISET, which produces a voltage on the ISET pin that tracks VIN. This allows VIN to control output current which determines input current. Data Sheet Download www.linear.com/3630 Linear Technology Corporation 500 VOUT = 5V 400 CURRENT (mA) The 24V output voltage can be programmed using the 800mV 1% reference or one of the preset voltages. This circuit uses the 5V preset option along with feedback resistors to program the output voltage. This increases circuit noise immunity and allows lower value feedback resistors to be used. MAX LOAD CURRENT BEFORE VOUT DROPS 300 200 100 0 INPUT CURRENT 0 10 20 30 40 INPUT VOLTAGE (V) 50 60 F06 Figure 6. Input Voltage vs Load Current and Input Current with Input Current Limit Circuit Shown in Figure 5 Conclusion The LTC3630 offers a mixture of features useful in high efficiency, high voltage applications. Its wide output voltage range, adjustable current capabilities and inherent short-circuit tolerant operation makes this DC/DC converter an easy fit in demanding applications. For applications help, call (408) 432-1900, Ext. 3258 dn512 LT/AP 0313 196K • PRINTED IN THE USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com © LINEAR TECHNOLOGY CORPORATION 2013