Abstract: To implement a step-up converter with current output, the approach often taken is simply to connect the load in place of the top resistor in a resistive-divider feedback network. The bottom resistor then serves as a current-sense resistor. Though simple, this solution is not efficient. A simple circuit can reduce sense resistor losses and improve efficiency. To implement a step-up converter with current output, the approach often taken is simply to connect the load in place of the top resistor in a resistive-divider feedback network. The bottom resistor then serves as a current-sense resistor. Though simple, this solution is not efficient. Figure 1. A low-cost feedback network (Q1, Q2, and associated resistors) improves the efficiency of this switchmode current source by a factor of six. Low efficiency is caused by a relatively high-sense voltage. This is usually 1.25V but for some ICs, can be as high as 2.5V. In Figure 1, a switchmode DC-DC converter configured as a 20mA current source minimizes the efficiency loss by lowering the sense voltage to 200mV. Advantages of this circuit include the factor-of-6 gain in efficiency, minimal board area, and readily available low-cost components. Applications include battery charging, LED driving, and general-purpose current sources. Certain ICs such as the MAX1698 and the MAX1848 are designed to efficiently drive LEDs in a manner similar to the one described here. As an extra benefit, the circuit allows deep discharge of single-cell alkaline batteries. Resistors R1 and R2 form a voltage divider that derives 200mV from the IC's reference output. This sense voltage connects to one emitter of the current mirror formed by Q1 and Q2. Both collectors connect to the output voltage via 200kΩ resistors. The collector of Q2 also connects to the IC's feedback pin, and Q2's emitter connects to the low-side current-sense resistor (R5). This feedback network appears to the IC's control loop as a common-base amplifier. Choosing a 2N3904 for Q2 yields sufficient emitter-to-collector gain, approximately 80V/V. Moreover, the network's wide bandwidth (characteristic of common-base configurations) prevents instability in the IC's control loop. A similar version of this article appeared in the Jan 21, 1999 issue of EDN magazine. 의견을 보내주세요! 위 내용이 도움이 되셨나요? 여러분의 의견을 기다립니다 — Maxim은 보내주신 정정이나 제안사항을 반영하고 있습니다. 이 페이지를 평가하고 의견을 보내주십시오. 자동 업데이트 관심있는 분야의 애플리케이션 노트가 나올 때 자동으로 업데이트 받고 싶으세요? 그렇다면 EE-Mail™을 신청하십시오. 추가 정보   APP 940: Jan 18, 2002 MAX1698 LED용 고효율 스텝 업 전류 레귤레이터 전체 데이터 시트 (PDF, 172kB) 무료 샘플 MAX1848 SOT23 패키지로 제공되는 백색 LED 스텝 업 컨버터 전체 데이터 시트 (PDF, 284kB) 무료 샘플   다운로드, PDF 형식 (31kB)  AN940, AN 940, APP940, Appnote940, Appnote 940