The Experts below are selected from a list of 20241 Experts worldwide ranked by ideXlab platform
Pavel A. Belov - One of the best experts on this subject based on the ideXlab platform.
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Colossal permittivity resonators for Wireless Power Transfer systems
2017 11th European Conference on Antennas and Propagation (EUCAP), 2017Co-Authors: Mingzhao Song, Pavel A. Belov, Polina KapitanovaAbstract:Colossal permittivity dielectric resonators for magnetic resonant Wireless Power Transfer systems are proposed. The Wireless Power Transfer system based on two dielectric resonators with the permittivity e=1000 operating at the frequency 230 MHz is established. Numerical simulation and experimental investigation of the WPT system efficiency are performed. The measured efficiency of 50% is achieved at separation between the resonators d=16 cm (3.8 radii of the resonator). The Power Transfer efficiency as a function of distance, misalignment and rotation angle is calculated and experimentally tested. A test of the system operation with a real load is demonstrated.
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Experimental investigation of Wireless Power Transfer systems based on dielectric resonators
2016 46th European Microwave Conference (EuMC), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Pavel A. BelovAbstract:Original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is presented. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on spherical dielectric resonators with the permittivity e=80 and disk dielectric resonators with the permittivity e=1000 are reported. For the Wireless Power Transfer system based on spherical resonators operating at magnetic dipole mode and magnetic quadrupole mode the maximal efficiency of 60% and 80% is verified experimentally in GHz frequency range. The Wireless Power Transfer system based on disk dielectric resonators with the permittivity e=1000 operates at the frequency of 220 MHz and provides 50% efficiency at 7 cm resonator separation. The test with a real load is also performed.
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Wireless Power Transfer system based on ceramic resonators
2016 10th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (METAMATERIALS), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:An original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is proposed. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on ceramic resonators with the permittivity e=80 are reported.
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Metamaterials and resonators for Wireless Power Transfer
2015 Radio and Antenna Days of the Indian Ocean (RADIO), 2015Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:In this paper a recent progress of mid-range applications of Wireless Power Transfer is presented. It outlines Wireless Power Transfer standards as well as research activities in the last decade on near-field magnetic coupling Wireless Power Transfer with the transmission distance in the order of or greater than the coil dimension. It also covers metamaterials application to improve the Wireless Power Transfer efficiency.
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Metamaterials for Wireless Power Transfer
2015 Days on Diffraction (DD), 2015Co-Authors: Mingzhao Song, Polina Kapitanova, Ivan Iorsh, Pavel A. BelovAbstract:We review recent progress of the mid-range applications of Wireless Power Transfer (WPT) technology and introduce its main standards. In the last decade, extensive research has been carried out on magnetic coupling Wireless Power Transfer with the transmission distance comparable or greater than the coil dimension. Metamaterials show great abilities to increase the WPT efficiency by controlling the near electromagnetic field.
Polina Kapitanova - One of the best experts on this subject based on the ideXlab platform.
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Colossal permittivity resonators for Wireless Power Transfer systems
2017 11th European Conference on Antennas and Propagation (EUCAP), 2017Co-Authors: Mingzhao Song, Pavel A. Belov, Polina KapitanovaAbstract:Colossal permittivity dielectric resonators for magnetic resonant Wireless Power Transfer systems are proposed. The Wireless Power Transfer system based on two dielectric resonators with the permittivity e=1000 operating at the frequency 230 MHz is established. Numerical simulation and experimental investigation of the WPT system efficiency are performed. The measured efficiency of 50% is achieved at separation between the resonators d=16 cm (3.8 radii of the resonator). The Power Transfer efficiency as a function of distance, misalignment and rotation angle is calculated and experimentally tested. A test of the system operation with a real load is demonstrated.
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Experimental investigation of Wireless Power Transfer systems based on dielectric resonators
2016 46th European Microwave Conference (EuMC), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Pavel A. BelovAbstract:Original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is presented. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on spherical dielectric resonators with the permittivity e=80 and disk dielectric resonators with the permittivity e=1000 are reported. For the Wireless Power Transfer system based on spherical resonators operating at magnetic dipole mode and magnetic quadrupole mode the maximal efficiency of 60% and 80% is verified experimentally in GHz frequency range. The Wireless Power Transfer system based on disk dielectric resonators with the permittivity e=1000 operates at the frequency of 220 MHz and provides 50% efficiency at 7 cm resonator separation. The test with a real load is also performed.
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Wireless Power Transfer system based on ceramic resonators
2016 10th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (METAMATERIALS), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:An original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is proposed. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on ceramic resonators with the permittivity e=80 are reported.
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Metamaterials and resonators for Wireless Power Transfer
2015 Radio and Antenna Days of the Indian Ocean (RADIO), 2015Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:In this paper a recent progress of mid-range applications of Wireless Power Transfer is presented. It outlines Wireless Power Transfer standards as well as research activities in the last decade on near-field magnetic coupling Wireless Power Transfer with the transmission distance in the order of or greater than the coil dimension. It also covers metamaterials application to improve the Wireless Power Transfer efficiency.
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Metamaterials for Wireless Power Transfer
2015 Days on Diffraction (DD), 2015Co-Authors: Mingzhao Song, Polina Kapitanova, Ivan Iorsh, Pavel A. BelovAbstract:We review recent progress of the mid-range applications of Wireless Power Transfer (WPT) technology and introduce its main standards. In the last decade, extensive research has been carried out on magnetic coupling Wireless Power Transfer with the transmission distance comparable or greater than the coil dimension. Metamaterials show great abilities to increase the WPT efficiency by controlling the near electromagnetic field.
G. F. Wang - One of the best experts on this subject based on the ideXlab platform.
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Analysis and Simulation of Wireless Power Transfer System Based on Magnetic Resonances
Electrical Power & Energy Systems Pts 1 and 2, 2012Co-Authors: M L Qu, X. Z. Shi, C. Qi, G. F. WangAbstract:Wireless Power Transfer brings the possibility of connector-free for electric devices. Because there is no electric connection between Power source and load, the system employs Wireless Power Transfer based on magnetic resonance becomes safer, more convenient and more reliable. The Wireless Power Transfer system of four-coils based on magnetic resonances is analyzed, including phenomenon of frequency splitting, effect of the angle between the source coil and the device coil, and effect of external objects. Simulation results are presented in this paper.
Mingzhao Song - One of the best experts on this subject based on the ideXlab platform.
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Colossal permittivity resonators for Wireless Power Transfer systems
2017 11th European Conference on Antennas and Propagation (EUCAP), 2017Co-Authors: Mingzhao Song, Pavel A. Belov, Polina KapitanovaAbstract:Colossal permittivity dielectric resonators for magnetic resonant Wireless Power Transfer systems are proposed. The Wireless Power Transfer system based on two dielectric resonators with the permittivity e=1000 operating at the frequency 230 MHz is established. Numerical simulation and experimental investigation of the WPT system efficiency are performed. The measured efficiency of 50% is achieved at separation between the resonators d=16 cm (3.8 radii of the resonator). The Power Transfer efficiency as a function of distance, misalignment and rotation angle is calculated and experimentally tested. A test of the system operation with a real load is demonstrated.
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Experimental investigation of Wireless Power Transfer systems based on dielectric resonators
2016 46th European Microwave Conference (EuMC), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Pavel A. BelovAbstract:Original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is presented. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on spherical dielectric resonators with the permittivity e=80 and disk dielectric resonators with the permittivity e=1000 are reported. For the Wireless Power Transfer system based on spherical resonators operating at magnetic dipole mode and magnetic quadrupole mode the maximal efficiency of 60% and 80% is verified experimentally in GHz frequency range. The Wireless Power Transfer system based on disk dielectric resonators with the permittivity e=1000 operates at the frequency of 220 MHz and provides 50% efficiency at 7 cm resonator separation. The test with a real load is also performed.
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Wireless Power Transfer system based on ceramic resonators
2016 10th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (METAMATERIALS), 2016Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:An original approach to near field magnetic resonance Wireless Power Transfer using high permittivity dielectric resonators is proposed. The results of numerical simulation and experimental investigation of the Wireless Power Transfer systems based on ceramic resonators with the permittivity e=80 are reported.
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Metamaterials and resonators for Wireless Power Transfer
2015 Radio and Antenna Days of the Indian Ocean (RADIO), 2015Co-Authors: Polina Kapitanova, Mingzhao Song, Ivan Iorsh, Pavel A. BelovAbstract:In this paper a recent progress of mid-range applications of Wireless Power Transfer is presented. It outlines Wireless Power Transfer standards as well as research activities in the last decade on near-field magnetic coupling Wireless Power Transfer with the transmission distance in the order of or greater than the coil dimension. It also covers metamaterials application to improve the Wireless Power Transfer efficiency.
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Metamaterials for Wireless Power Transfer
2015 Days on Diffraction (DD), 2015Co-Authors: Mingzhao Song, Polina Kapitanova, Ivan Iorsh, Pavel A. BelovAbstract:We review recent progress of the mid-range applications of Wireless Power Transfer (WPT) technology and introduce its main standards. In the last decade, extensive research has been carried out on magnetic coupling Wireless Power Transfer with the transmission distance comparable or greater than the coil dimension. Metamaterials show great abilities to increase the WPT efficiency by controlling the near electromagnetic field.
M L Qu - One of the best experts on this subject based on the ideXlab platform.
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Analysis and Simulation of Wireless Power Transfer System Based on Magnetic Resonances
Electrical Power & Energy Systems Pts 1 and 2, 2012Co-Authors: M L Qu, X. Z. Shi, C. Qi, G. F. WangAbstract:Wireless Power Transfer brings the possibility of connector-free for electric devices. Because there is no electric connection between Power source and load, the system employs Wireless Power Transfer based on magnetic resonance becomes safer, more convenient and more reliable. The Wireless Power Transfer system of four-coils based on magnetic resonances is analyzed, including phenomenon of frequency splitting, effect of the angle between the source coil and the device coil, and effect of external objects. Simulation results are presented in this paper.