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Root-locus procedure analysis for phase-locked loop systemsAltinbuken, Metin. January 1977 (has links)
Thesis (M.S.)--Wisconsin. / Includes bibliographical references (leaves 29-87).
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Root-Locus Theory for Infinite-Dimensional SystemsMonifi, Elham January 2007 (has links)
In this thesis, the root-locus theory for a class of diffusion systems is studied. The input and output boundary operators are co-located in the sense that their highest order derivatives occur at the same endpoint. It is shown that infinitely many root-locus branches lie on the negative real axis and the remaining finitely many root-locus branches lie inside a fixed closed contour. It is also shown that all closed-loop poles vary continuously as the feedback gain varies from zero to infinity.
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Root-Locus Theory for Infinite-Dimensional SystemsMonifi, Elham January 2007 (has links)
In this thesis, the root-locus theory for a class of diffusion systems is studied. The input and output boundary operators are co-located in the sense that their highest order derivatives occur at the same endpoint. It is shown that infinitely many root-locus branches lie on the negative real axis and the remaining finitely many root-locus branches lie inside a fixed closed contour. It is also shown that all closed-loop poles vary continuously as the feedback gain varies from zero to infinity.
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Designing feedback compensators by using the Root-Locus methodKorkmaz, Levent 12 1900 (has links)
Approved for public release; distribution is unlimited / The purpose of this thesis is to find suitable ways to design feedback compensators for high order systems by using Root-Locus methods.
As a starting point we will examine a motor amplidyne system and a position control system that were previously designed using Bode methods. Then we generalize the method and extend it to other systems.
The final subject of this thesis is to design feedback compensators as filters by using state feedback coefficients to define zeros of the filter, then we extend this idea to build cascade filters. / http://archive.org/details/designingfeedbac00kork / Lieutenant, Junior Grade, Turkish Navy
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Properties of multivariable root lociYagle, Andrew Emil January 1981 (has links)
Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1981. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND ENGINEERING. / Includes bibliographical references. / by Andrew Emil Yagle. / M.S.
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Equations for the angles of arrival and departure for multivariable root loci using frquency-domain methodsJanuary 1981 (has links)
Andrew E. Yagle and Bernard C. Levy. / Bibliography: leaves 8-9. / "July 1981." / NASA Ames Research Center Grant NASA/NGL-22-009-124
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Asymptotic unbounded root loci : formulae and computationJanuary 1981 (has links)
S.S. Sastry and C.A. Desoer. / Bibliography: leaf 3. / Caption title. "August, 1981." / Supported by NSF under Grant ENG-78-09032-A01 NASA Grant NGL-22-009-124
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Large deflection analysis of a circular plate with a concentrically supporting overhangZabad, Ibrahim Abdul-Jabbar January 1981 (has links)
No description available.
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Root Locus Plotter for a Dual Tank System Under Feedback ControlDecatrel, John M. 01 January 1986 (has links) (PDF)
A root locus graphics routine was written in Turbo Pascal for the analysis and design of a linearized dual tank control system. The routine is a subprogram to be incorporated with an editor written by L. Fadden. This editor allows for the saving and changing of parameters to the system.
The dual tank system is a good example for classical feedback control analysis. A brief description of the process and system is presented. The system may be described by linearized differential and algebraic equations. From these, a characteristic equation is derived, which gives rise to the root locus. The root locus is a plot of the poles of the closed loop system. Poles or roots of the characteristic equation are found using the Lin-Bairstow algorithm. This method may be used to solve for the zeroes of an nth degree polynomial.
The root locus plotter was exercised by attempting to optimally tune the system’s controller. Corroboration of the results was provided by step response plots from the TUTSIM simulation program.
Minor modifications allow the root locus plotter to run without the editor. Graphics subroutines are provided by the Turbo Graphix Toolbox. When run under the editor, the plotter is one interactive design module of the dual tank system analysis and design program. The subprogram was designed principally for user ease, error checking, and effective graphics.
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Developing root locus stability diagrams using a personal computerSvrcek, Ben C. January 1987 (has links)
Companies which design automation control for the metal rolling industry are faced with a growing demand for systems with higher performance standards than ever before. Along with these demanding specifications is always the problem of system stability at any given speed. A multi-ton rolling stand with uncontrolled oscillations not only destroys the product being rolled but may cause serious damage to the plant and endanger the lives of mill personnel. Therefore stability analysis is critical whether modeling individual mills or analyzing old products and strategies so as to invent better, cheaper control methods.
Cost is another major consideration for the firm ordering these systems and the companies which design them. Suppliers are trimming time from design and production schedules wherever possible in order to compete in the world market. It is for these, and other reasons that computer aided stability analysis is so important. The object is to ensure a safe and stable system and yet minimize the time (and therefore cost) needed For design and installation. This paper describes a program (ROOT LOCUS) which was created to fill this need while using the tools and methods readily at hand. It was written for personal computers as these machines are rapidly proving to be cost effective solutions to problems in computing power. / Master of Science
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