Relate to MATLAB and please do it by hand. Thanks
Summary - it is basic problem so I have shown step by step solution
1. Given the following physical system described by the following differential equation. a. Solve...
Relate to MATLAB and please do it by hand. Thanks 1. Given the following physical system described by the following differential equation. a. Solve for y(t), assume all initial conditions are zero. Use the Laplace transform approach. b. What MatLab command would you use to find the residues c. What is a residue? d. What command would you use to simulate and graph the step response? e. What is the purpose of the partial fractions operation? +12+3 32(0 dt dt
Given the following differential equation, solve for y() if all initial conditions are zero. Use the Laplace transform. dt
Solve the following differential equation using the Laplace transform and assuming the given initial conditions. [Note: Laplace table is provided in the page 6] dt2 dt dix x(0) = 1 ; (0) = 1 dt
Q.4) [25 Marks] a) [15] Consider a CT LTI system described by the following differential equation (assume zero initial conditions): dºy(t) _6dy(t) + 3 dy(t) = 2x(6) dt3-6 dt2 +8 dt = 2x(t) [5] Using Laplace transform and its properties determine the transfer function H(s) [5] Draw the pole-zero diagram of H(s) (5) Write down all possible Region-of-Convergence (ROC) for the H(s) (iii) [5] white b) (10) Determine the signal x(t) ( assume it to be right-sided signal) when the...
Consider a CTLTI system described by the following ordinary differential equation with constant coefficients: N M dky(t) 2 ak ak dtk , dkx(t) Ok atk bk - 2 k=0 k=0 The system function H(s) is defined as the Laplace transform of the impulse response h(t) of the system. Write and prove the expression of H(s) as a function of the coefficients of the differential equation. Justify each single step of the proof from first principles (hypothesis, thesis, proof).
3. (l’+2° +1²=4') Topic: Laplace transform, CT system described by differential equations, LTI system properties. Consider a differential equation system for which the input x(t) and output y(t) are related by the differential equation d’y(t) dy(t) -6y(t) = 5x(t). dt dt Assume that the system is initially at rest. a) Determine the transfer function. b) Specify the ROC of H(s) and justify it. c) Determine the system impulse response h(t).
Given the following differential equation, which represents the model of a physical system, determine (A) the time constant of the system, (B) the input function in the s domain, and (C) the equation for the time response of the system. The input to the system is a step input with a gain of 10. Write only your final answer in the boxes. ONLY WHAT IS WRITTEN IN THE BOXES WILL BE GRADED. NO PARTIAL CREDIT. 5.46 +25.c =r(t)
3. Consider the Linear Time-Invariant (LTI) system decribed by the following differential equation: dy +504 + 4y = u(t) dt dt where y(t) is the output of the system and u(t) is the input. This is an Initial Value Problem (IVP) with initial conditions y(0) = 0, y = 0. Also by setting u(t) = (t) an input 8(t) is given to the system, where 8(t) is the unit impulse function. a. Write a function F(s) for a function f(t)...
Consider the following second-order ODE representing a spring-mass-damper system for zero initial conditions (forced response): where u is the Unit Step Function (of magnitude 1 a. Use MATLAB to obtain an analytical solution x() for the differential equation, using the Laplace Transforms approach (do not use DSOLVE). Obtain the analytical expression for ao. Also obtain a plot of x() (for a simulation of 14 seconds) b. Obtain the Transfer Function representation for the system. c. Use MATLAB to obtain the...
slove in Matlab AP2. A system is modeled by the following differential equation in which X(t) is the output and (() is the input: *+ 2x(t) + 5x(t) = 3u(t), x(0) = 0, X(t) = 2 a. Create a state-space representation of the system. b. Plot the following on the same figure for 0 st s 10 sec : i. the initial condition response (use the initial function) il the unit step response (use the step function) iii. the total...