Ultra-Compact Pulse Charger for Lithium Polymer Battery with Simple Built-in Resistance Compensation in Biomedical Applications.

Yemin Kim, Junhyuck Lee, Byunghun Lee
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Abstract

Active implantable medical devices (AIMDs) rely on batteries for uninterrupted operation and patient safety. Therefore, it is critical to ensure battery safety and longevity. To achieve this, constant current/constant voltage (CC/CV) methods have been commonly used and research has been conducted to compensate for the effects of built-in resistance (BIR) of batteries. However, conventional CC/CV methods may pose the risk of lithium plating. Furthermore, conventional compensation methods for BIR require external components, complex algorithms, or large chip sizes, which inhibit the miniaturization and integration of AIMDs. To address this issue, we have developed a pulse charger that utilizes pulse current to ensure battery safety and facilitate easy compensation for BIR. A comparison with previous research on BIR compensation shows that our approach achieves the smallest chip size of 0.0062 mm2 and the lowest system complexity using 1-bit ADC. In addition, we have demonstrated a reduction in charging time by at least 44.4% compared to conventional CC/CV methods, validating the effectiveness of our system's BIR compensation. The compact size and safety features of the proposed charging system make it promising for AIMDs, which have space-constrained environments.
用于锂聚合物电池的超紧凑型脉冲充电器,内置生物医学应用中的简单电阻补偿。
有源植入式医疗设备 (AIMD) 依靠电池实现不间断运行和患者安全。因此,确保电池的安全性和使用寿命至关重要。为此,人们普遍采用恒流/恒压(CC/CV)方法,并开展了补偿电池内置电阻(BIR)影响的研究。然而,传统的 CC/CV 方法可能会带来镀锂的风险。此外,传统的 BIR 补偿方法需要外部元件、复杂的算法或较大的芯片尺寸,这阻碍了 AIMD 的微型化和集成化。为了解决这个问题,我们开发了一种脉冲充电器,利用脉冲电流确保电池安全,并方便对 BIR 进行补偿。与以往的 BIR 补偿研究相比,我们的方法实现了 0.0062 mm2 的最小芯片尺寸,并使用 1 位 ADC 实现了最低的系统复杂性。此外,与传统的 CC/CV 方法相比,我们已证明充电时间至少缩短了 44.4%,这也验证了我们系统的 BIR 补偿的有效性。建议的充电系统体积小巧、安全可靠,因此很有希望应用于空间有限的 AIMD。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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