Paul Roche , Kevin Nadaud , Dimitri Galayko , Samuel Calle , Flavien Barcella , Jean-Charles Le Bunetel , Dominique Certon , Guylaine Poulin-Vittrant
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引用次数: 0
摘要
无线电力传输是生物医学工程的一个基本特征。它减少了医疗植入物对储能装置的需求。要给体内植入的电池充电,一种便捷的方法是通过皮肤向连接的超声波换能器传输超声波。无引线、片上系统兼容(SoC)、宽带、电容式微机械超声换能器(CMUT)与基于压电的技术相比具有竞争力。然而,它们对高偏置电压的需求阻碍了它们在植入式医疗设备 (IMD) 中的应用。所需的电压源必须满足精确的规格要求,如可靠性和体积,这也是研究界希望遵守的。为了应对这一挑战,这项研究提出了一种电子电路,允许 CMUT 器件从极低的初始能量输入开始自偏压。在介绍了电子结构及其主要特点后,模拟和实验结果验证了该解决方案的工作原理和操作要点。通过一个由分立元件组成的电子电路,可从 2.2 V 的植入电池电压和 120 kPa 的水中入射压强建立起 60 V 的偏置电压。
A discrete CMUT self-biasing circuit towards implanted devices application
Wireless power transfer is an essential feature of biomedical engineering. It reduces the need for energy storage devices in medical implants. To recharge a body implanted battery, a convenient way is to transmit ultrasounds through the skin to a connected ultrasonic transducer. Lead-less, System-on-Chip compatible (SoC) and wideband, Capacitive Micromachined Ultrasonic Transducers (CMUT) are competitive with piezoelectric based technologies. However, their need for a high bias voltage is an obstacle to their use in implanted medical devices (IMDs). The voltage source required must meet precise specifications, such as reliability and volume, which the research community intends to respect. To meet this challenge, this work proposes an electronic circuit that allows a CMUT device to self-bias from a very low initial energy input. After presenting the electronic architecture and its main features, simulation and experimental results validate the solution’s working principle and operating points. With an electronic circuit made up of discrete components, a bias voltage of 60 V is built up from an implanted battery voltage of 2.2 V and an incident pressure of 120 kPa in water.
期刊介绍:
Sensors and Actuators A: Physical brings together multidisciplinary interests in one journal entirely devoted to disseminating information on all aspects of research and development of solid-state devices for transducing physical signals. Sensors and Actuators A: Physical regularly publishes original papers, letters to the Editors and from time to time invited review articles within the following device areas:
• Fundamentals and Physics, such as: classification of effects, physical effects, measurement theory, modelling of sensors, measurement standards, measurement errors, units and constants, time and frequency measurement. Modeling papers should bring new modeling techniques to the field and be supported by experimental results.
• Materials and their Processing, such as: piezoelectric materials, polymers, metal oxides, III-V and II-VI semiconductors, thick and thin films, optical glass fibres, amorphous, polycrystalline and monocrystalline silicon.
• Optoelectronic sensors, such as: photovoltaic diodes, photoconductors, photodiodes, phototransistors, positron-sensitive photodetectors, optoisolators, photodiode arrays, charge-coupled devices, light-emitting diodes, injection lasers and liquid-crystal displays.
• Mechanical sensors, such as: metallic, thin-film and semiconductor strain gauges, diffused silicon pressure sensors, silicon accelerometers, solid-state displacement transducers, piezo junction devices, piezoelectric field-effect transducers (PiFETs), tunnel-diode strain sensors, surface acoustic wave devices, silicon micromechanical switches, solid-state flow meters and electronic flow controllers.
Etc...
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