PROJECT TITLE :

Field Analysis and Measurement of Antiparallel Resonant Loop for Wireless Charging

ABSTRACT:

Among electromagnetic compatibility issues, radiated emissions constitute one in every of the areas of highest concern as a result of wireless power and Communications systems operate by emitting magnetic fields. During this letter, the radiated field of the antiparallel loop is theoretically analyzed and experimentally verified at distances in the close to- and way-field regions. A reduced magnetic field strength of roughly vi dB is obtained with the proposed antiparallel loop when put next to a standard loop at the measuring distance up to ten m. Furthermore, since portable devices with an NFC perform need the configuration of straightforward structures for wireless charging, the proposed design concept for antiparallel resonant loops offers considerable benefits as it suppresses the generation of electromagnetic interference noise.


Did you like this research project?

To get this research project Guidelines, Training and Code... Click Here


PROJECT TITLE : Multimodal Change Detection in Remote Sensing Images Using an Unsupervised Pixel Pairwise-Based Markov Random Field Model ABSTRACT: The multimodal change detection (CD) problem in remote sensing imaging is addressed
PROJECT TITLE : Parallax Tolerant Light Field Stitching for Hand-Held Plenoptic Cameras ABSTRACT: Hand-held plenoptic cameras may benefit from light field (LF) stitching as a means of expanding their field of vision (FOV). There
PROJECT TITLE : Parameter-Free Gaussian PSF Model for Extended Depth of Field in Brightfield Microscopy ABSTRACT: Conventional brightfield microscopes have a restricted depth of field, which prevents them from fully focusing
PROJECT TITLE : Tensor Oriented No-Reference Light Field Image Quality Assessment ABSTRACT: Immersive media acquisition, processing, and application are becoming more dependent on the quality of light field images (LFIs). A multi-dimensional
PROJECT TITLE : A Maximum Likelihood Approach for Depth Field Estimation Based on Epipolar Plane Images ABSTRACT: From dense picture arrays, this work presents a multi-resolution approach for determining depth. Hand-held plenoptic

Ready to Complete Your Academic MTech Project Work In Affordable Price ?

Project Enquiry