Power Approaches for Implantable Medical Devices

Amar, Achraf Ben; Kouki, Ammar B.; Cao, Hung

doi:10.3390/s151128889

Cited by 327 publications

(216 citation statements)

References 145 publications

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“…[181] In a common vehicle, more than two-thirds of the energy produced from gasoline is expended as waste heat and is discharged by the exhaust gas and cooling system, which is approximately tens of kilowatts of heat losses. [189] One challenge for the development of IMDs is that its batteries, the energy source of the device, may exceed their lifespan after long-term usage. [171] A challenge for the utilization of FTEGs on exhaust pipes is the polymer stability, because the temperature of exhaust gas in a vehicle can reach as high as 500 °C.…”

Section: Potential Applications and Benchmarksmentioning

confidence: 99%

Fiber‐Based Thermoelectric Generators: Materials, Device Structures, Fabrication, Characterization, and Applications

Zhang

Lin

Tao

et al. 2017

Advanced Energy Materials

117

100

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Fiber‐based flexible thermoelectric energy generators are 3D deformable, lightweight, and desirable for applications in large‐area waste heat recovery, and as energy suppliers for wearable or mobile electronic systems in which large mechanical deformations, high energy conversion efficiency, and electrical stability are greatly demanded. These devices can be manufactured at low or room temperature under ambient conditions by established industrial processes, offering cost‐effective and reliable products in mass quantity. This article presents a critical overview and review of state‐of‐the‐art fiber‐based thermoelectric generators, covering their operational principle, materials, device structures, fabrication methods, characterization, and potential applications. Scientific and practical challenges along with critical issues and opportunities are also discussed.

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Section: Potential Applications and Benchmarksmentioning

confidence: 99%

Fiber‐Based Thermoelectric Generators: Materials, Device Structures, Fabrication, Characterization, and Applications

Zhang

Lin

Tao

et al. 2017

Advanced Energy Materials

117

100

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“…It has been over 180 years since Michael Faraday figured out that power can be exchanged by magnetic induction through the air [5]. In 1914, Tesla first reported about the wireless power and transferring of data based on the magnetic coupling of two loops.…”

Section: Magnetic Inductionmentioning

confidence: 99%

A Computational Study on the Magnetic Resonance Coupling Technique for Wireless Power Transfer

et al. 2017

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Abstract. Non-radiative wireless power transfer (WPT) system using magnetic resonance coupling (MRC) technique has recently been a topic of discussion among researchers. This technique discussed more scenarios in mid-range field of wireless power transmission reflected to the distance and efficiency. The WPT system efficiency varies when the coupling distance between two coils involved changes. This could lead to a decisive issue of high efficient power transfer. This paper presents case studies on the relationship of operating range with the efficiency of the MRC technique. Demonstrative WPT system operates at two different frequencies are projected in order to verify performance. The resonance frequencies used are less than 100MHz within range of 10cm to 20cm.

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“…With an advanced concept of strongly coupled magnetic resonances, which was proposed in 2007[1, 2], the WPT has become a promising method to address the problem of power delivery in highly constrained environment. One of the most popular application areas of WPT is wirelessly powering biosensors or implants within the bodies of humans or animals [3–5]. The non-invasive solution has attracted a great deal of attention in diverse applications, such as electric stimulators for muscles and neural tissues, endoscopic capsules, cardiac pacemakers, and cochlear implants [6–14].…”

Section: Introductionmentioning

confidence: 99%

“…One additional challenge associated with medical implants is the transmission of data acquired by these devices to the outside of the biological body[4, 5]. The methods of data transmission usually involve an independent wireless data link.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous wireless power transfer and data communication using synchronous pulse-controlled load modulation

et al. 2017

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Wireless Power Transfer (WPT) and wireless data communication are both important problems of research with various applications, especially in medicine. However, these two problems are usually studied separately. In this work, we present a joint study of both problems. Most medical electronic devices, such as smart implants, must have both a power supply to allow continuous operation and a communication link to pass information. Traditionally, separate wireless channels for power transfer and communication are utilized, which complicate the system structure, increase power consumption and make device miniaturization difficult. A more effective approach is to use a single wireless link with both functions of delivering power and passing information. We present a design of such a wireless link in which power and data travel in opposite directions. In order to aggressively miniaturize the implant and reduce power consumption, we eliminate the traditional multi-bit Analog-to-Digital Converter (ADC), digital memory and data transmission circuits all together. Instead, we use a pulse stream, which is obtained from the original biological signal, by a sigma-delta converter and an edge detector, to alter the load properties of the WPT channel. The resulting WPT signal is synchronized with the load changes therefore requiring no memory elements to record inter-pulse intervals. We take advantage of the high sensitivity of the resonant WPT to the load change, and the system dynamic response is used to transfer each pulse. The transient time of the WPT system is analyzed using the coupling mode theory (CMT). Our experimental results show that the memoryless approach works well for both power delivery and data transmission, providing a new wireless platform for the design of future miniaturized medical implants.

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Power Approaches for Implantable Medical Devices

Cited by 327 publications

References 145 publications

Fiber‐Based Thermoelectric Generators: Materials, Device Structures, Fabrication, Characterization, and Applications

Fiber‐Based Thermoelectric Generators: Materials, Device Structures, Fabrication, Characterization, and Applications

A Computational Study on the Magnetic Resonance Coupling Technique for Wireless Power Transfer

Simultaneous wireless power transfer and data communication using synchronous pulse-controlled load modulation

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