Michael Neath
University of Auckland
23 Papers
100 Citations
Michael Neath is an academic researcher from University of Auckland. The author has contributed to research in topics: Maximum power transfer theorem & Control theory. The author has an hindex of 11, co-authored 23 publications.
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Papers
A Power–Frequency Controller for Bidirectional Inductive Power Transfer Systems
TL;DR: This paper proposes a new controller, which is based on power-frequency droop characteristics of IPT systems, to regulate its power flow in both directions without a dedicated communication link and shows that the proposed droop controller can successfully be used to regulate the two-way power flow.
229
An Optimal PID Controller for a Bidirectional Inductive Power Transfer System Using Multiobjective Genetic Algorithm
TL;DR: Simulated and experimental results of a 1-kW prototype bidirectional IPT system are presented to demonstrate the effectiveness of the GA-tuned controller as well as to show that gain selection through multiobjective GA using the weighted objective function yields the best performance of the PID controller.
215
A Synchronization Technique for Bidirectional IPT Systems
TL;DR: This paper proposes a novel technique that synchronizes converters on both the primary and pickup sides of bidirectional IPT systems and presents a mathematical model for the proposed technique and investigates its sensitivity for component tolerances.
180
A Dynamic EV Charging System for Slow Moving Traffic Applications
Adeel Zaheer,Michael Neath,Hui Zhi Zak Beh,Grant A. Covic +3 more
- 23 May 2017
TL;DR: In this paper, the magnetic design of an IPT system for a dynamic EV charging application, to continuously deliver a power of 15 kW to an EV, along the direction of travel within the lateral misalignment of ±200 mm.
174
A Dynamic Multivariable State-Space Model for Bidirectional Inductive Power Transfer Systems
TL;DR: In this paper, a state-space-based model is developed in a multivariable framework and mapped into frequency domain to compute the transfer function matrix of eight-order bidirectional IPT systems.
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