3. (a) For the system shown below, determine Y(z)/R(z). (Do NOT use the specific values of the Laplace transforms as given in part (b) of this problem.) (b) Now assume that C(s) = 6/s, H(s) = 1/s, R(s) = 1, and G(s)= 2/(s + 2), determine Y(z) assuming T =0.1 seconds. Be sure to give the numerical values of bm, bm-1, ..., bo, an, a-l, ..., ao in your equation for Y(z). R(s) E (s) C(s) G(s) Y(G) H(s)

3. (a) For the system shown below, determine Y(z)/R(z). (Do NOT use the specific values of the Laplace transforms as given in part (b) of this problem.) (b) Now assume that C(s) = 6/s, H(s) = 1/s, R(s) = 1, and G(s)= 2/(s + 2), determine Y(z) assuming T =0.1 seconds. Be sure to give the numerical values of bm, bm-1, ..., bo, an, a-l, ..., ao in your equation for Y(z). R(s) E (s) C(s) G(s) Y(G) H(s)

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

See similar textbooks

Similar questions

Find the general solution of the second order, constant coefficient, non-homogeneous linear differential equation by Laplace transformation.
Please provide step by step explanation for the answer. Thank you. Explain and describe and discuss Poisson and Laplace equations. Suggest methods for solving them in one, two, or three-dimensional problems.
Find the general solution of the second order linear differential equation with constant coefficient number given in the picture, which is not homogeneous, by "laplace transform".
Find and graph the current i(t) in the RLC circuit of the figure, where R=1 Ω, L= 0,25 H, C=0,2 F, v(t)=377sin(20t) V for (10/π) seconds ≤ t ≤ (25/π) seconds, and v(t) = 0 for 0 ≤ t < (10/π) seconds and (25/π) seconds < t < ∞, considering the initial current and load as null. (Note: Use the Laplace method as they are causal systems)
A series circuit contains a resistor and an inductor as shown in Figure below. Determine a differential equation for the current i(f) if the resistance is R, the inductance is L, and the impressed voltage is E(t). Then determine the current i(t), with R = 4 N, L = 2 h, E (t) = cos(3t) using the ordinary variation of parameters method. Later Solve the same determined ODE using the Laplace transform (determine i(t) using Laplace transform) and compare the two Methods. for initial conditions, i(0) = 0 Finally illustrate the Laplace transform solution steps to ODES with a diagram that summarizes the steps you used to carry out your solution.
A series circuit contains a resistor and an inductor as shown in Figure below. Determine a differential equation for the current i(f) if the resistance is R, the inductance is L, and the impressed voltage is E(t). Then determine the current i(t), with R = 4 N, L = 2 h, E (t) = cos(3t) using the ordinary variation of parameters method. Later Solve the same determined ODE using the Laplace transform (determine i(t) using Laplace transform) and compare the two Methods. for initial conditions, i(0) = 0
The dynamics of a system which has an input and output of the differential equation, d^2y(t)/dt + 3dy(t)/dt + 2y(t) = r(t), where the initial conditions are given as y(0) = 0, dy(t)/dt =0, r(t) =1, t>=0. Use Laplace transform to solve for the time response of the system, (ie solve for y(t), t>=0)
the following statements given, write if each statement is true or false. a. If the complex frequency domain function, F(s), is derived using a “One-sided” Laplace Transform, the inverse of that function, f(t), is only valid for t ≥ 0. b. When using an ideal transformer, if voltage increases from primary side to secondary side, current also increases from primary side to the secondary side. c. Initial value theorem states that the initial value of a time function f(t) can be obtained from its Laplace Transform F(s) by multiplying the transform by s and letting s approach zero. ..
An electromotive force ?(?)={? volts,0≤?<10 volts,?≥1 is applied to an RC-series circuit in which the resistance is 10 ohms and the capacitance is 0.1 farad. If the initial charge ?(0)=0,(a) Specify the differential equation as an IVP for the RC-series circuit.(b) Write ?(?) in terms of unit step function.(c) Apply the second translation theorem of Laplace Transform to solve the IVP and find the charge ?(?) at any time t.
Experiment 1: Laplace transforms, Inverse Laplace transforms, and Applications Theoretical background (Provide the relevant concept s concerning the experiment.) I want Theoretical background for this experiment without Plagiarism
Signal and system The mathematical model of a system is y" (t) + ay'(t) + by(t) = a (t) + ca (t) where a=1, b=2 and c=1. 1) Find zeros and poles of the system. 2) Show them onto the S-Plane (the complex plane) 3) Discuss the BIBO stability of the system.
Calculate y(t)=x(t)*v(t) using the convolution integral for the continuous signals x(t) and v(t) given in the figure below. Write the result of y(t) as a piecewise function. Also, show the result in an approximate way by drawing a graph.