Digital Control Systems Detailed Syllabus for Power Electronics\/ Power and Industrial Drives\/ Power Electronics and Electric Drives M.Tech first year first sem is covered here. This gives the details about credits, number of hours and other details along with reference books for the course.<\/p>\n
The detailed syllabus for Digital Control Systems M.Tech 2017-2018 (R17) first year first sem is as follows.<\/p>\n
M.Tech. I Year I Sem. Course Objectives:<\/strong><\/p>\n Course Outcomes:<\/strong> Upon the completion of the course the student will be able to<\/p>\n UNIT \u2013 I: Introduction:<\/strong> Block Diagram of typical control system- advantages of sampling in control systems \u2013 examples of discrete data and digital systems \u2013 data conversion and quantization \u2013 sample and hold devices \u2013 D\/A and A\/D conversion \u2013 sampling theorem \u2013 reconstruction of sampled signals \u2013ZOH. Z-transform: Definition and evaluation of Z-transforms \u2013 mapping between s-plane and z-plane \u2013 inverse z-plane transform \u2013 theorems of the Z-transforms \u2013limitations of z-transforms \u2013pulse transfer function \u2013pulse transfer function of ZOH \u2013relation between G(s) and G(z) \u2013 signal flow graph method applied to digital systems.<\/p>\n UNIT- II: State Space Analysis:<\/strong> State space modeling of digital systems with sample and hold \u2013 state transition equation of digital time in variant systems \u2013 solution of time in variant discrete state equations by the Z-Transformation \u2013 transfer function from the state model \u2013 Eigen values \u2013 Eigen vector and diagonalisation of the A-matrix \u2013 Jordan canonical form. Computation of state transition matrix-Transformation to phase to variable canonical form-The state diagram \u2013 decomposition of digital system \u2013 Response of sample data system between sampling instants using state approach. Stability: Definition of stability \u2013 stability tests \u2013 The second method of Liapunov.<\/p>\n UNIT- III: Time Domain Analysis:<\/strong> Comparison of time response of continuous data and digital control systems-correlation between time response and root locus j the s-plane and z-plane \u2013 effect of polezero configuration in the z-plane upon the maximum overshoot and peak time of transient response \u2013 Root loci for digital control systems \u2013 steady state error analysis of digital control systems \u2013 Nyquits plot \u2013 Bode plot-G.M and P.M.<\/p>\n UNIT- IV: Design:<\/strong> The digital control design with digital controller with bilinear transformation \u2013 Digital PID controller-Design with deadbeat response-Pole placement through state feedback-Design of full order state observer-Discrete Euler Lagrance Equation \u2013 Discrete maximum principle.<\/p>\n UNIT-V: Digital State Observer:<\/strong> Design of – Full order and reduced order observers. Design by max. Principle: Discrete Euler language equation-discrete maximum principle.<\/p>\n TEXT BOOKS:<\/strong><\/p>\n REFERENCE BOOKS:<\/strong><\/p>\n
\nPrerequisites: Linear control systems, Z-Transforms<\/strong><\/p>\n\n
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