Conferences related to Inductive power transmission

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2020 22nd European Conference on Power Electronics and Applications (EPE'20 ECCE Europe)

Energy conversion and conditioning technologies, power electronics, adjustable speed drives and their applications, power electronics for smarter grid, energy efficiency,technologies for sustainable energy systems, converters and power supplies


2020 42nd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)

The conference program will consist of plenary lectures, symposia, workshops and invitedsessions of the latest significant findings and developments in all the major fields of biomedical engineering.Submitted papers will be peer reviewed. Accepted high quality papers will be presented in oral and postersessions, will appear in the Conference Proceedings and will be indexed in PubMed/MEDLINE


2020 IEEE Energy Conversion Congress and Exposition (ECCE)

IEEE-ECCE 2020 brings together practicing engineers, researchers, entrepreneurs and other professionals for interactive and multi-disciplinary discussions on the latest advances in energy conversion technologies. The Conference provides a unique platform for promoting your organization.

  • 2019 IEEE Energy Conversion Congress and Exposition (ECCE)

    IEEE-ECCE 2019 brings together practicing engineers, researchers, entrepreneurs and other professionals for interactive and multi-disciplinary discussions on the latest advances in energy conversion technologies. The Conference provides a unique platform for promoting your organization.

  • 2018 IEEE Energy Conversion Congress and Exposition (ECCE)

    The scope of ECCE 2018 includes all technical aspects of research, design, manufacture, application and marketing of devices, components, circuits and systems related to energyconversion, industrial power and power electronics.

  • 2017 IEEE Energy Conversion Congress and Exposition (ECCE)

    ECCE is the premier global conference covering topics in energy conversion from electric machines, power electronics, drives, devices and applications both existing and emergent

  • 2016 IEEE Energy Conversion Congress and Exposition (ECCE)

    The Energy Conversion Congress and Exposition (ECCE) is focused on research and industrial advancements related to our sustainable energy future. ECCE began as a collaborative effort between two societies within the IEEE: The Power Electronics Society (PELS) and the Industrial Power Conversion Systems Department (IPCSD) of the Industry Application Society (IAS) and has grown to the premier conference to discuss next generation technologies.

  • 2015 IEEE Energy Conversion Congress and Exposition

    The scope of ECCE 2015 includes all technical aspects of research, design, manufacture, application and marketing of devices, components, circuits and systems related to energy conversion, industrial power and power electronics.

  • 2014 IEEE Energy Conversion Congress and Exposition (ECCE)

    Those companies who have an interest in selling to: research engineers, application engineers, strategists, policy makers, and innovators, anyone with an interest in energy conversion systems and components.

  • 2013 IEEE Energy Conversion Congress and Exposition (ECCE)

    The scope of the congress interests include all technical aspects of the design, manufacture, application and marketing of devices, components, circuits and systems related to energy conversion, industrial power conversion and power electronics.

  • 2012 IEEE Energy Conversion Congress and Exposition (ECCE)

    The IEEE Energy Conversion Congress and Exposition (ECCE) will be held in Raleigh, the capital of North Carolina. This will provide a forum for the exchange of information among practicing professionals in the energy conversion business. This conference will bring together users and researchers and will provide technical insight as well.

  • 2011 IEEE Energy Conversion Congress and Exposition (ECCE)

    IEEE 3rd Energy Conversion Congress and Exposition follows the inagural event held in San Jose, CA in 2009 and 2nd meeting held in Atlanta, GA in 2010 as the premier conference dedicated to all aspects of energy processing in industrial, commercial, transportation and aerospace applications. ECCE2011 has a strong empahasis on renewable energy sources and power conditioning, grid interactions, power quality, storage and reliability.

  • 2010 IEEE Energy Conversion Congress and Exposition (ECCE)

    This conference covers all areas of electrical and electromechanical energy conversion. This includes power electrics, power semiconductors, electric machines and drives, components, subsystems, and applications of energy conversion systems.

  • 2009 IEEE Energy Conversion Congress and Exposition (ECCE)

    The scope of the conference include all technical aspects of the design, manufacture, application and marketing of devices, circuits, and systems related to electrical energy conversion technology


2020 IEEE International Conference on Industrial Technology (ICIT)

ICIT focuses on industrial and manufacturing applications of electronics, controls, communications, instrumentation, and computational intelligence.


2020 IEEE International Solid- State Circuits Conference - (ISSCC)

ISSCC is the foremost global forum for solid-state circuits and systems-on-a-chip. The Conference offers 5 days of technical papers and educational events related to integrated circuits, including analog, digital, data converters, memory, RF, communications, imagers, medical and MEMS ICs.


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Periodicals related to Inductive power transmission

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Advanced Packaging, IEEE Transactions on

The IEEE Transactions on Advanced Packaging has its focus on the modeling, design, and analysis of advanced electronic, photonic, sensors, and MEMS packaging.


Antennas and Propagation, IEEE Transactions on

Experimental and theoretical advances in antennas including design and development, and in the propagation of electromagnetic waves including scattering, diffraction and interaction with continuous media; and applications pertinent to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques.


Applied Superconductivity, IEEE Transactions on

Contains articles on the applications and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Power applications include magnet design as well asmotors, generators, and power transmission


Biomedical Circuits and Systems, IEEE Transactions on

The Transactions on Biomedical Circuits and Systems addresses areas at the crossroads of Circuits and Systems and Life Sciences. The main emphasis is on microelectronic issues in a wide range of applications found in life sciences, physical sciences and engineering. The primary goal of the journal is to bridge the unique scientific and technical activities of the Circuits and Systems ...


Broadcasting, IEEE Transactions on

Broadcast technology, including devices, equipment, techniques, and systems related to broadcast technology, including the production, distribution, transmission, and propagation aspects.


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Most published Xplore authors for Inductive power transmission

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Xplore Articles related to Inductive power transmission

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IEEE Draft Guide for Methods of Power-Factor Measurement for Low-Voltage (1000 V ac or lower) Inductive Test Circuits

IEEE PC37.26/D2, April 2014, 2014

This guide provides methods for determining the value of power factor for inductive low-voltage (1000 volts ac and below) test circuits. These methods are used in determining power factor during short-circuit current tests in high power laboratories. It is preferred that these methods be used during short-circuit current testing. Alternatively, other methods (including use of computerized or digital techniques) may ...


Design and Optimization of Printed Spiral Coils for Efficient Inductive Power Transmission

2007 14th IEEE International Conference on Electronics, Circuits and Systems, 2007

The next generation of high power neuroprosthetic devices such as retinal implants are going to be powered through transcutaneous inductive links formed between a pair of printed spiral coils (PSC) that are batch fabricated using micromachining technology (MEMS). Optimizing the power efficiency of the wireless link is imperative to minimize the size of the external energy source, electromagnetic heating of ...


Multicoil Telemetry System for Compensation of Coil Misalignment Effects in Implantable Systems

IEEE Antennas and Wireless Propagation Letters, 2012

Inductive coupling-based wireless power transfer (WPT) is commonly used for near-field power and data transfer to implanted electronics. Some implanted coils undergo relative motion during device operation causing variation in magnetic coupling from their normal position. To ensure stable power transfer efficiency and frequency bandwidth, these WPT systems should have high tolerance with coupling variation. In this letter, a multicoil-based ...


IEEE Draft Recommended Practice for Inductive Coordination of Electric Supply and Communication Lines

IEEE P776/D10, October 2018, 2018

The inductive environment that exists in the vicinity of electric power and wire-line telecommunications systems and the interfering effects that may be produced are addressed. An interface that permits either party, without need to involve the other, to verify the induction at the interface by use of a probe wire is presented. This recommended practice does not apply to railway ...


Experimental Research on an Inductive Power Transmission System for Blood Pumps

2010 International Conference on Electrical and Control Engineering, 2010

The invasive model of power supply for the commercial blood pumps has brought great discomfort to the patients. An inductive power transmission system based on transformer for blood pumps has been designed and developed. The system is mainly consist of power supply, control circuit of switch, transformer, rectifier circuit and energy storage element. Experiments on power transmission in the system ...


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Educational Resources on Inductive power transmission

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IEEE.tv Videos

Lionel O. Barthold - IEEE Medal in Power Engineering, 2019 IEEE Honors Ceremony
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IEEE-USA E-Books

  • IEEE Draft Guide for Methods of Power-Factor Measurement for Low-Voltage (1000 V ac or lower) Inductive Test Circuits

    This guide provides methods for determining the value of power factor for inductive low-voltage (1000 volts ac and below) test circuits. These methods are used in determining power factor during short-circuit current tests in high power laboratories. It is preferred that these methods be used during short-circuit current testing. Alternatively, other methods (including use of computerized or digital techniques) may be used, but the method used shall have been validated as producing results equivalent to those obtained using the methods in this guide. The methods described are intended for use in low- voltage test circuits (under 1000 volts ac), but may also be used for higher voltages.

  • Design and Optimization of Printed Spiral Coils for Efficient Inductive Power Transmission

    The next generation of high power neuroprosthetic devices such as retinal implants are going to be powered through transcutaneous inductive links formed between a pair of printed spiral coils (PSC) that are batch fabricated using micromachining technology (MEMS). Optimizing the power efficiency of the wireless link is imperative to minimize the size of the external energy source, electromagnetic heating of the tissue, and interference with other devices. In this paper, we outline the theoretical foundation of optimal power transmission in an inductive link and combine it with semi- empirical models to predict parasitic components in PSCs. Moreover, this foundation is utilized to devise an iterative PSC design methodology to find optimal PSC geometries. Finally, we have executed this procedure on two design examples at 1 and 5 MHz achieving power transmission efficiencies of 41.2% and 85.8%, respectively, at 10 mm spacing.

  • Multicoil Telemetry System for Compensation of Coil Misalignment Effects in Implantable Systems

    Inductive coupling-based wireless power transfer (WPT) is commonly used for near-field power and data transfer to implanted electronics. Some implanted coils undergo relative motion during device operation causing variation in magnetic coupling from their normal position. To ensure stable power transfer efficiency and frequency bandwidth, these WPT systems should have high tolerance with coupling variation. In this letter, a multicoil-based WPT system is utilized to achieve high tolerance for system power transfer efficiency and data bandwidth. It is demonstrated that a multicoil WPT system can reduce variation by half in power transfer efficiency (PTE) and by one third in frequency bandwidth compared to a two-coil WPT system with the same dimensions and operating conditions.

  • IEEE Draft Recommended Practice for Inductive Coordination of Electric Supply and Communication Lines

    The inductive environment that exists in the vicinity of electric power and wire-line telecommunications systems and the interfering effects that may be produced are addressed. An interface that permits either party, without need to involve the other, to verify the induction at the interface by use of a probe wire is presented. This recommended practice does not apply to railway signal circuits.

  • Experimental Research on an Inductive Power Transmission System for Blood Pumps

    The invasive model of power supply for the commercial blood pumps has brought great discomfort to the patients. An inductive power transmission system based on transformer for blood pumps has been designed and developed. The system is mainly consist of power supply, control circuit of switch, transformer, rectifier circuit and energy storage element. Experiments on power transmission in the system have been conducted for evaluation impact of frequency of switch, gas gap and windings number on the transmission efficiency of the system. The experimental results demonstrate that frequency of switch, gas gap and windings number influence the transmission efficiency in the inductive power supply system. The transmission efficiency decreases with the increase of the gap in the transformer and the system with the gap of 1 mm has the highest efficiency in the same performance conditions. The relation between the efficiency and the frequency of switch or the secondary windings number seem to be an approximate normal distribution: the system with the secondary windings number of 60 has the maximal efficiency; when the frequency of switch is 40 kHz, the efficiency reaches the peak.

  • A 13.56MHz time-interleaved resonant-voltage-mode wireless-power receiver with isolated resonator and quasi-resonant boost converter for implantable systems

    Wireless power transfer (WPT) has been widely adopted in various applications, such as biomedical implants and wireless sensors. A conventional voltage-mode receiver (VM-RX) uses a rectifier or a doubler for AC-DC conversion [1,2]. This requires a sufficiently large input power (P,<sub>N</sub>) inducing a large voltage (V<sub>AC</sub>) in the LC tank of the receiver (RX) due to the limited voltage conversion efficiency. A subordinate DC-DC converter is also required for voltage regulation or battery charging, which reduces the overall power-conversion efficiency (PCE) due to the 2-stage structure. To overcome these limitations, the resonant current-mode receiver (RCM-RX) has been proposed for direct battery charging [3] and voltage regulation [4,5]. The RCM-RX has two operation phases: a resonance phase (PH<sub>re</sub>) that accumulates energy in the LC tank during optimal resonant cycles (N<sub>OPT</sub>) to track the maximum efficiency [3], and a charging phase (PH<sub>ch</sub>) that delivers the energy of the LC tank to the output, when the resonant current (I<sub>AC</sub>) is at its peak. However, the RCM-RX typically operates at low resonant frequency f<sub>RESO</sub> (50kHz to 1MHz) because it is challenging to accurately detect the peak timing of I<sub>AC</sub> due to the intrinsic delay and offset of the comparator used in the peak timing detector. Operating at low f<sub>RESO</sub> causes the coil size to increase, making a burden on a size-constrained implant. In addition, the RCM-RX has a LC-tank resonance-loss interval PH<sub>ch</sub>, which hinders optimal power transfer from the transmitter (TX) to the RX because the reactive impedance is not cancelled out but appears on the TX side. Because the LC tank and the output are not isolated during PH<sub>ch</sub>, the power- transfer efficiency (PTE) can also be affected by load variation, such as the battery-voltage (V<sub>BAT</sub>) variation. These problems become worse as N<sub>OPT</sub> is reduced to lower number.

  • Performance Prediction of Single-Sided Induction Heating System

    Surface induction heating is nowadays widely used with coil arrangement varied according to the work piece topology. For a flat work piece arrangement, the coil may be of the single-conductor type or single-coil type, and finally, it may be of multicoil type. It is thought that the development of a generalized approach to analyze all three possible excitation systems mentioned earlier is an important task. In this paper, a generalized approach using a multilayer electromagnetic model is presented to analyze all three possible excitation arrangements. The theoretical results are compared with the experimental findings and with theoretical results obtained using other approaches.

  • IEEE Approved Draft Recommended Practice for the Implementation of Inductive Coordination Mitigation Techniques and Application

    Guidance for controlling or modifying the inductive environment and the susceptibility of affected wire line telecommunications facilities in order to operate within the acceptable levels of steady-state or surge induced voltages of the environmental interface (probe wire) defined by IEEE Std 776 is provided in this Recommended Practice. Procedures for determining the source of the problem are given. Mitigation theory and philosophy are discussed, and mitigation devices are described. The application of typical mitigation apparatus are addressed. Advice for determining the best engineering solution is offered, and general safety considerations are discussed.

  • Experimental Study of Inductive Energy Transfer in Strong Coupling Mode

    Specific geometry of inductively coupled coils can be distinguished for transcutaneous energy powering of implantable medical devices. Characteristic dimensions of the transmitter and receiver are of order 0.1...1 cm, distance between the coils is less than their characteristic dimension. "Strong coupling" phenomenon and appearance of the "frequency splitting" effect occur, if quality factors are high and coupling between the coils is good. An experimental scheme was developed for studying of a strongly coupled system. The analysis of RLC-circuits was carried out and ratios between coupling and frequency splitting coefficients were determined. Frequency response in the "strong coupling" mode in the range of axial distances from 5 to 70 mm and frequencies from 780 to 2460 kHz was obtained. The designed scheme can be used for the researches of wireless energy transfer and for verification frequency tuning methods.

  • Study of fast vacuum switching

    Interruption ability of a fast triggered vacuum switch is tested. The influence of geometrical and physical parameters on switching performance are studied. Thus a breaking capacity more than 1 GV.A is obtained with a 44 kA current pulse and 32 kV recovery voltage.



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