Abstract: A resistive network that includes a thermistor is used to temperature-compensate the current-limit input (ILIM) of a DC-DC converter. Recent advances in the design of step-down DC-DC converters have eliminated the current-sense resistor by substituting the drop across the low-side MOSFET (synchronous rectifier) instead. This topology saves the cost and space of a sense resistor, and also provides a modest boost in efficiency. One compromise imposed by the new approach, however, is a current-limit value dominated by the MOSFET's on-resistance, which is highly temperature dependent. Fortunately, the new DC-DC converters provide a pin that allows adjustment of the current-limit threshold. By changing this threshold according to temperature, you can temperature-compensate the circuit's output-current limit. That task is readily accomplished with a thermistor as shown in Figure 1. Figure 1. This resistive network temperature-compensates the current-limit input (ILIM) of a DC-DC converter. The linear input range for the ILIM input of U1 is 0.5V to 2.0V, which corresponds to current-limit thresholds of 50mV to 200mV, respectively. For the default current-limit setting (100mV), the circuit has a 7.5A current limit at +25°C. As shown in Figure 2, however, the limit ranges from 9A at -40°C to 6A at +85°C. Figure 2. Output current limit vs. temperature for the Figure 1 circuit, with and without thermistor compensation at the ILIM input. The intent of this design is to cancel U1's temperature variation using a thermistor-based compensation circuit. Figure 1 depicts one of several possible resistor/thermistor topologies. First, choose and characterize the thermistor. R1 serves to linearize the thermistor, while R2 and R3 are chosen so that the slope and intercept of VILIM versus temperature directly compensate for temperature variations in the current limit. The curves shown in the corrected output characteristic (Figure 2) are intrinsic to the thermistor. Though not perfectly flat, the corrected slope is a great improvement over the original and sufficient for our purpose. (You can achieve a more precise compensation using a different thermistor or multiple thermistors.) This circuit provides higher current limits at room temperature or colder, while meeting its specification at higher temperatures. This article appeared as a Design Idea in the October 13, 2005 edition of EDN magazine. 相关型号   APP 3753: Mar 17, 2006 MAX1714 高速、降压型控制器，用于笔记本电脑 完整的数据资料 (PDF, 896kB) 免费样品 自动更新 需要自动接收最新发布的应用笔记吗？请订阅EE-Mail™ (English only)。 我们期待您的反馈！ 喜欢？不喜欢？有待改善？或为我们提供建议？请与我们联系 — 我们将根据您的意见或建议改善我们的工作。 网页评价或提供建议   下载，PDF格式 (27kB)  AN3753, AN 3753, APP3753, Appnote3753, Appnote 3753