Problem 3: Consider the following system governed by the differential equation YOU +370 + 5 +...
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)...
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).
please help. Note: u(t) is unit-step function Consider the system with the differential equation: dyt) + 2 dy(t) + 2y(t) = dr(t) – r(e) dt2 dt where r(t) is input and y(t) is output. 1. Find the transfer function of the system. Note that transfer function is Laplace transform ratio of input and output under the assumption that all initial conditions are zero. 2. Find the impulse response of the system. 3. Find the unit step response of the system...
signal and system 8) By using Laplace transform determine the transfer function and the impulse response of the system with equation below. y) is the output and u) is the input to the system + 6 dt2 8) By using Laplace transform determine the transfer function and the impulse response of the system with equation below. y) is the output and u) is the input to the system + 6 dt2
Consider the linear system given by the following differential equation y(4) + 3y(3) + 2y + 3y + 2y = ů – u where u = r(t) is the input and y is the output. Do not use MATLAB! a) Find the transfer function of the system (assume zero initial conditions)? b) Is this system stable? Show your work to justify your claim. Note: y(4) is the fourth derivative of y. Hint: Use the Routh-Hurwitz stability criterion! c) Write the...
Problem # 1 For each system Derive the differential equation which describes the system. Use Laplace Trans form to find the Transfer Function. Specify the number of the Poles and Zeros and the value of the Gain. Determine the system's order both based on the Transfer Function and the number of the energy storage elements. Draw the Block Diagram with Input and Output C. Liquid Level System; assume q is the input and h3 is the output ! Ay Ry...
Question: given a differential equation: a. initial conditions for the plan and input are zero, derive plan's transfer function in Laplace transform b. using inverse Laplace transform, find the solution for the differential equation for the plan (find function y(t)). c. derive state-space model of the plan d. Assume open-loop system with no controller added to the plant, analyse the steady-state value of the system using final value theorem and step input e. Calculate value of the overshoot, rise time...
System Modeling and Laplace transform: In this problem we will review the modeling proce- dure for the RLC circuit as shown below, and how to find the corresponding transfer function and step response Ri R2 Cv0) i2) i,(0) 3.1 Considering the input to be V(t) and the output to be Ve(t), find the transfer function of the system. To do that, first derive the differential equations for al the three loops and then take the Laplace transforms of them. 3.2...
Suppose a system is governed by the following differential equation. Linearize this system about 0 0 radians, radians a. b. 4 Tt radians C. = (t) sin(0(t))u(t) CD Suppose a system is governed by the following differential equation. Linearize this system about 0 0 radians, radians a. b. 4 Tt radians C. = (t) sin(0(t))u(t) CD
Help me do this problem step by step LSM1 Problem (50 pts) Consider a causal continuous-time LTI system with input-output relationship dt+)t). (a) Find the transfer function H(s) of the system and specify its ROC. (b) Find the impulse response h(t) of the system. (12 pts) (12 pts) (c) Using the convolution property of the Laplace transform, find the output y(t) of the system in response to the input (t)ut) e2-u(t 1 (26 pts)