Obtain the step response of the following ODE assuming zero initial conditions. (t)3x 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...
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Consider the following second-order ODE representing a spring-mass-damper system for zero initial conditions (forced response): 2x + 2x + x=u, x(0) = 0, *(0) = 0 where u is the Unit Step Function (of magnitude 1). a. Use MATLAB to obtain an analytical solution x(t) for the differential equation, using the Laplace Transforms approach (do not use DSOLVE). Obtain the analytical expression for x(t). Also obtain a plot of .x(t) (for a simulation of 14 seconds)...
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2. Assuming zero initial conditions, let R = 200 ?, and C = 0.001 F in the ideal Op-Amp circuit below. v, (t) vo(t) Wtih vi(t) the voltage waveform below, plot vo(t) over 0sts 15 v,t) t-8 14 r-04
ECE 202 Lab 5 Poles & Zeros, Impulse Response II Prelab 1. Assuming the initial conditions are zero, determine the transfer function H(s), for the circuit shown below. Also, inverse transform the transfer function to obtain the impulse response for the circuit, h() IN(S) 100? 1mH V out IN 0.01 ?F 2 What values of corespon o the poles and aeros df H)7 What yoe of signal will produce zero steady state output? constant) for this circuit? produce a zero...
Problem 1 Given the circuit shown below in Fig. 1.1: Write the ordinary differential equation (ODE) for the capacitor voltage. Find the zero-state unit step responses of v(t) and i(t) if vs-u(t) V using each of the following three methods of solving the ODE: a. b. i. ii. Solve the ODE by integrating for the solution; Solve the ODE by assuming homogeneous and particular solutions; Solve the ODE by using the general form solution for a 1st order ODE. iii....
1.7-3 For a certain LTI system with the input f(t), the output y(t) and the two initial conditions (0) and 2(0), following observations were made 1(0) z2(0) eu(t) e(3+2)u(t) 2u(t) 0 0 (t) Determine v(t) when both the initial conditions are zero and the input f(t) is as shown in Fig. P1.7-3. Hint: There are three causes: the input and each of the two initial conditions. Because of linearity property, if a cause is increased by a factor k, the...
We will simulate and measure DC step response. In this circuit, Vs 1V. Assume zero initial conditions (voltage on the capacitor and current in the circuit are both zero att 0. Function generator Oscilloscope 100 ohm external resistor; C=1uF, L=0.068H Find the voltage on the capacitor as a function of time vt),
Use Z transform methods to find the solution of the following equation assuming zero initial conditions yIn +2] +yin + 1]+y[n] u[n]
Write the laplace transform of the following, assuming zero initial conditions, i.e f(0) 0 f (0) 0 Part D- Dynamic Systems1 Keep X(s) terms on the left and Y(s) terms on the right of the equation. Do not group your terms and write your final answer in the order of the equation given vec 5s +4s +6X(s) (s+6)Y(s) Submit Previous Answers Request Answer XIncorrect: Try Again The correct answer involves the function sX, which was not part of your answer....
Consider the system 0.28 +0.2x + 2x = f(t), where f(t) is a unit step function, and the initial conditions are zero. (a) Use MATLAB to plot the step response of the system. Attach the MATLAB plot and the script used to create the plot. Using only the printed MATLAB plot, extract by hand (i.e. use a ruler) the (b) maximum percent overshoot, (c) rise time, and (d) peak time, and then using the extracted values, estimate the (e) damping...