M. Essam scite author profile

The calculation of all stabilizing controller parameters with the parameter space approach is a well-known method. Based on the determined stabilizing parameter space, there exist various analysis and fine-tuning tools for the design of controllers. Unfortunately, only for PID controller (of LTI systems) the parameter space approach is developed and implemented systematically now a days. This work expands the syntheses step of the classical parameter space approach to the LTV system class. It is realized by using a transformation method to bring a LTV system into a LTI system description as well as a frozen time eigenvalue based method. Therefore, this paper presents an overview of the parameter space method to design LTI state feedback controllers. After that, a short survey of LTV stability analyse methods and the transformation based method to extend the parameter space approach to LTV is given.

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M. Essam

A highly stable CMOS Self-Compensated Oscillator (SCO) based on an LC tank temperature Null concept

A Monolithic CMOS Self-compensated LC Oscillator Across Temperature

A single LC tank self-compensated CMOS oscillator with frequency stability of ±100ppm from −40°C to 85°C

Parameter space approach based state feedback control of LTV systems

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M. Essam

A highly stable CMOS Self-Compensated Oscillator (SCO) based on an LC tank temperature Null concept

A Monolithic CMOS Self-compensated LC Oscillator Across Temperature

A single LC tank self-compensated CMOS oscillator with frequency stability of &#x00B1;100ppm from &#x2212;40&#x00B0;C to 85&#x00B0;C

Parameter space approach based state feedback control of LTV systems

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A single LC tank self-compensated CMOS oscillator with frequency stability of ±100ppm from −40°C to 85°C