The modelling of quasi-resonant and multi-resonant boost converters

Szabo, Adrian

January 1998

No description available.

621.3192

DC analysis; Small-signal modelling

Small signal modelling of power electronic converters, for the study of time-domain waveforms, harmonic domain spectra, and control interactions

Love, Geoffrey Neal

January 2007

This thesis describes the development of several small signal analysis methods for the modelling of power electronic converters. The methods are written generally and are intended to be able to be applied to all converter classes. In the penultimate chapter these general models are used to model the capacitor commutated converter. All the contained methods are based around a time domain small signal model. This time domain small model is a linearization of a power electronic system of passive components and ideal switches described as a hybrid system. The key problem in the derivation of the small signal model is the correct determination and description of the linearized effect of switching instant variation. Three analysis methods based upon the small signal model are advanced in this thesis, these are; time domain sensitivity matrices for use in a Newton determination of the cyclic steady state of a power electronic converter, partial waveform construction of harmonic sensitivity matrices for studying sensitivity of converters to harmonic disturbances, and harmonic state space models also for the construction of harmonic sensitivity matrices and for study of dynamic systems. Each modelling technique is applied to the more common converter topologies of the Buck-Boost converter and the Graetz Bridge before being finally applied to the capacitor commutated converter. Each technique is compared to PSCAD-EMTDC simulations for verification.

Small signal modelling

Power Electronics

Time domain

Harmonic domain

Time Varying Harmonics

Millimeter Wave Indium Phosphide Heterojunction Bipolar Transistors: Noise Performance and Circuit Applications

ayata, metin

07 November 2014

The performance of III-V heterojunction bipolar transistors (HBTs) has improved significantly over the past two decades. Today’s state of the art Indium Phosphide (InP) HBTs have a maximum frequency of oscillation greater than 800 GHz and have been used to realize an amplifier operating above 600 GHz . In comparison to silicon (Si) based devices, III-V HBTs have superior transport properties that enables a higher gain, higher speed, and noise performance, and much higher Johnson figure- of-merit . From this perspective, the InP HBT is one of the most promising candidates for high performance mixed signal electronic systems.

InP

HBT

LNA

Modelling

Transistor

Small-signal modelling

Nanotechnology Fabrication

Analysis and Comparison of Popular Models for Current-Mode Control of Switch Mode Power Supplies

Kotecha, Ramchandra M.

16 March 2011

No description available.

Electrical Engineering

Current-mode control

SMPS

Switch Mode Power Supplies

Power Electronics

Peak current-mode control

voltage mode control

control schemes for pwm dc-dc converters

pwm dc-dc converters