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15% - 3 – A system has a state variable representation as below face) = (4)...
i dont understand this problem. please show how to solve all parts using MATLAB. thank you. State-Space Representation and Analysis csys canon(sys,type) compute a canonical state-space realization type 'companion': controllable canonical form type modal: modal canonical form poles of a system controllability matrix observability matrix eig(A) ctrb(A,B) obsv(A,C) -7 L-12 0 EX A 2C-ioD0 uestions () Define the system in the state-space form (2) Determine the stability of the system (3) Determine the controllability and the observability of the system....
1- A system has a block diagram as shown. Determine a state variable representation (model) and state transition matrix Φ(s) R(s) + 25 Y(s) 25 2- A system has the following differential equation: 2 -3 Determine Ф(t) and its transform D(s) for the system
3. The transfer function of a control system is given as G(s) = (s+1)(s+2)(s45) (a) Determine a state variable representation in observer canonical form. (b) Design a full order observer of the system. Let the poles of the observer be 10 times faster than the system poles. Show the observer gain matrix. (c) Determine and plot the errors responses between the estimated output and the actual output. (d) Determine and plot the estimated state variables and determine their settling times....
Q3. The state-space representation of a dynamical system is given as follows: (2) (y = 2 x 1. By finding the eigenvalues, eigenvectors of the A matrix, compute el via the diagonal transformation. 2. Assume that the control input is u(t) = 0, compute x(1) and y(t). 3. Assume that the input is u(t) = 1 + 2e-21, compute x(t) and y(t). 4. Given your answers to the previous question, compute x(t) when 1 00
a-obtain state space representation b-obtain system eigen values c-diagnolize the system Question (3: (10 Marks) For the following system, U(s) s + 5 (s +2) (s +3) s + 1 Obtain a state space representation in the controllable canonical form. (4 marks) b) Obtain the system eigen values, (3 marks) c) Diagonalize the system. (3 marks) a) Page 2 DQMS 2/3 Question (3: (10 Marks) For the following system, U(s) s + 5 (s +2) (s +3) s + 1...
5 For a system: Y() 10.4s? +47s +160 U(s) 5+148° +568 +160 use Matlab to do: (a) obtain the state-space representation of the system. (b) transfer the state-space representation into Modal canonical form. (c) find the eigenvalues of the system matrix A, determine the system stability (d) find the controllability and observability matrixes. Determine the controllability and observability.
Problem 4: (65 points) Let a system be given by the state space representation 8 8 10 * = X+ u(t), y = [1 -1]x – u(t) 1 1 -1 0 Y(S) d) (7) Find the transfer function US) e) (5) Is the system BIBO stable? 3 f) (9) Let the initial state x(0) -3 u(t) = 0) for all t > 0. = Find the zero input response (i.e., with the input
Convert following the transfer function into state space representation (Marks 5) 3 +45² T($) = 54 +52 +7 Convert the following state space into a transfer function. (Marks 5) x = 11 * = x + ( u 21 y = [02]x + [2]u Evaluate the steady-state error of state-space system. (Marks 5) i [ 10] [21. *= 15 2]* +11 y = [ 02]x + [2]u Evaluate the steady-state error of state-space system. (Marks 5) -1 0x+lu x =...
Problem 3-Find the state-space representation in both canonical controller and phase-variable form of the transfer functions below R(s) C(s) 8s + 10 45s3 +s2 +5s + 13 5 +9s4+1383 +8s2
Given a linear time-invariant system in state-space representation: -100 5*+u(t) y=[1 0]x (i) Determine the transfer function of the system. (ii) Build an equivalent mechanical system showing all the parameters. (ii) Derive an expression x(t) for this system for step input. Is the mechanical system over damped, under damped or critically damped system?