His primary areas of investigation include Control theory, Electronic engineering, Chaotic, Electronic circuit and Memristor. The study incorporates disciplines such as Buck converter and Forward converter in addition to Control theory. Herbert Ho-Ching Iu has researched Electronic engineering in several fields, including Distributed generation, Converters, Voltage and Hall effect sensor.
His Chaotic research includes elements of Dynamical systems theory, Synchronization of chaos, Attractor and Oscillation. His study in Electronic circuit is interdisciplinary in nature, drawing from both Component, Terminal device and Capacitor. His work in Memristor addresses issues such as Lyapunov exponent, which are connected to fields such as Phase portrait, Topology, Embedding, Spectral density and Band-stop filter.
His main research concerns Control theory, Electronic engineering, Memristor, Voltage and Bifurcation. His Control theory study combines topics from a wide range of disciplines, such as Buck converter, Converters and Electric power system. His research investigates the connection between Buck converter and topics such as Forward converter that intersect with issues in Flyback converter and Ćuk converter.
The various areas that Herbert Ho-Ching Iu examines in his Electric power system study include Kalman filter, Wind power and Control engineering. Herbert Ho-Ching Iu works mostly in the field of Electronic engineering, limiting it down to topics relating to Microgrid and, in certain cases, Photovoltaic system, as a part of the same area of interest. Herbert Ho-Ching Iu studied Memristor and Chaotic that intersect with Oscillation.
His scientific interests lie mostly in Control theory, Memristor, Electronic engineering, Topology and Voltage. His study in the field of Discrete time and continuous time also crosses realms of Modular design. His Memristor research incorporates elements of Electronic circuit, Artificial neural network, Chaotic, Logic gate and Integrated circuit.
Herbert Ho-Ching Iu has included themes like Oscillation and Nonlinear system in his Chaotic study. In his research on the topic of Electronic engineering, Crossbar switch and CMOS is strongly related with Resistive random-access memory. As a part of the same scientific family, Herbert Ho-Ching Iu mostly works in the field of Attractor, focusing on Bifurcation and, on occasion, Initial value problem.
Herbert Ho-Ching Iu mainly investigates Control theory, Memristor, Attractor, Electronic engineering and Chaotic. His Control theory research includes themes of Buck converter, Control and Maximum power point tracking. His Memristor research focuses on subjects like Electronic circuit, which are linked to Capacitor, Terminal, Reduction and Neuromorphic engineering.
The Attractor study combines topics in areas such as Discrete mathematics and Nonlinear system, Conditional symmetry, Bifurcation. His Electronic engineering research incorporates themes from Topology and Resistive random-access memory. Herbert Ho-Ching Iu usually deals with Chaotic and limits it to topics linked to Statistical physics and Numerical analysis, Polarity and Hyperbolic function.
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Current Sensing Techniques: A Review
S. Ziegler;R.C. Woodward;H.H.-C. Iu;L.J. Borle.
IEEE Sensors Journal (2009)
Hybrid Particle Swarm Optimization With Wavelet Mutation and Its Industrial Applications
S.H. Ling;H.H.C. Iu;K.Y. Chan;H.K. Lam.
systems man and cybernetics (2008)
A Single-Stage AC/DC Converter With High Power Factor, Regulated Bus Voltage, and Output Voltage
D.D.-C. Lu;H.H.-C. Iu;V. Pjevalica.
IEEE Transactions on Power Electronics (2008)
Improved Hybrid Particle Swarm Optimized Wavelet Neural Network for Modeling the Development of Fluid Dispensing for Electronic Packaging
S.H. Ling;H. Iu;F.H.F. Leung;K.Y. Chan.
IEEE Transactions on Industrial Electronics (2008)
Quantum-Inspired Particle Swarm Optimization for Power System Operations Considering Wind Power Uncertainty and Carbon Tax in Australia
Fang Yao;Zhao Yang Dong;Ke Meng;Zhao Xu.
IEEE Transactions on Industrial Informatics (2012)
Hopf bifurcation and chaos in a free-running current-controlled Cuk switching regulator
C.K. Tse;Y.M. Lai;H.H.C. Iu.
IEEE Transactions on Circuits and Systems I-regular Papers (2000)
Bifurcation behavior in parallel-connected buck converters
H.H.C. Iu;C.K. Tse.
IEEE Transactions on Circuits and Systems I-regular Papers (2001)
Controlling Chaos in a Memristor Based Circuit Using a Twin-T Notch Filter
H H C Iu;D S Yu;A L Fitch;V Sreeram.
IEEE Transactions on Circuits and Systems I-regular Papers (2011)
A critical review of cascading failure analysis and modeling of power system
Hengdao Guo;Ciyan Zheng;Herbert Ho Ching Iu;Tyrone Fernando.
Renewable & Sustainable Energy Reviews (2017)
A review of coordination strategies and protection schemes for microgrids
Sachit A. Gopalan;Victor Sreeram;Herbert H.C. Iu.
Renewable & Sustainable Energy Reviews (2014)
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