Abstract
A gastric acid battery and its charge storage in a capacitor are a simple and safe method to provide a power source to an ingestible device. For that method, the electromotive force of the battery should be boosted for storing a large amount of energy. In this study, we have proposed an all-p-channel metal-oxide semiconductor (pMOS)-based cross-coupled voltage multiplier (CCVM) utilizing single-well CMOS technology to achieve a voltage boosting higher than from a conventional complementary MOS (CMOS) CCVM. We prototyped a custom integrated circuit (IC) implemented with the above CCVMs and a ring oscillator as a clock source. The characterization experiment demonstrated that our proposed pMOS-based CCVM can boost the input voltage higher because it avoids the body effect problem resulting from an n-channel MOS transistor. This circuit was also demonstrated to significantly reduce the circuit area on the IC, which is advantageous as it reduces the chip size or provides an area for other functional circuits. This simple circuit structure based on mature and low-cost technologies matches well with disposal applications such as an ingestible device. We believe that this pMOS-based CCVM has the potential to become a useful energy harvesting circuit for ingestible devices.
Highlights
An ingestible device has been developed as an ideal device for diagnosis and healthcare for use in the near future [1,2,3]
We successfully demonstrated voltage boosting with a on a gastric acid battery
We prototyped an all-p-channel MOS (pMOS)-based cross-coupled voltage multiplier (CCVM) operated by two-phase clocks with single-well complementary metal-oxide semiconductor (CMOS) technology for an energy harvesting application based on a gastric acid battery used single-well CMOS technology for an energy harvesting application based on a gastric acid battery in an ingestible device
Summary
An ingestible device has been developed as an ideal device for diagnosis and healthcare for use in the near future [1,2,3]. In the energy harvesting domain, the power generated by the gastric acid battery battery operates an oscillator and a voltage-boosting. A charge pump with four-phase clocks is p-channel MOS (pMOS)-based charge pumps were proposed for eliminating this reported to exhibit a highly efficient voltage boosting [16,17,18]. Such a multiple-clock-based body effect problem of an nMOS transistor. Charge pumps utilizing twin- or reported to exhibit a highly efficient voltage boosting [16,17,18] Such a multiple-clock-based triple-well CMOS technologies have been reported [19,20,21].
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