Problem 4 (25 points). Use the linear graph below of thermal system to (a) derive the transfer fu...
Problem 2 (25 points) For the rotational mechanical system with gears shown below, find the transfer function G(s)-0s(s)/T(s). The gears have inertia and bearing friction as shown T(0) Ji. D N2 N3 2. D2 14. D
Use the transfer function in the problem below. The input to this system H7jω is: x(t) = 0.6cos(12t+40°) Find the output of the system is y(t). (10 points) H7(jω)=(5000jω)/((jω+10)(jω+500))
A linear system is governed by the given initial value problem. Find the transfer function H(s) for the system and the impulse response function h(t) and give a formula for the solution to the initial value problem. y" - 6y' +34y = g(t); y(O)= 0, y' (O) = 5 Find the transfer function. H(s) = Use the convolution theorem to obtain a formula for the solution to the given initial value problem, where g(t) is piecewise continuous on (0,00) and...
Do problem 5.6 a. Obtain a complete SSR with input u and output h. Derive the system transfer function Go) Zs/u c. Derive the transfer function Y(s)/U(s) where the output is y Obtain a complete SSR for the given system, with input u = v and output 5.3 0.25t +2c-0.6w = 0 5.4 Given the nonlinear first-order system Derive the linear model by performing the linearization about the static equilibrium state a that res when the nominal input is "....
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...
Problem 2: Transfer Functions of Mechanical Systems. (20 Points) A model sketch for a two-mass mechanical system subjected to fluctuations (t) at the wall is provided in figure 2. Spring k, is interconnected with both spring ka and damper Os at the nodal point. The independent displacement of mass m is denoted by 1, the independent displacement of mass m, is denoted by r2, and the independent displacement of the node is denoted by ra. Assume a linear force-displacement/velocity relationship...
Problem 1 (25 points): Consider a system described by the differential equation: +0)-at)y(t) = 3ú(1); where y) is the system output, u) is the system input, and a(t)is a function of time t. o) (10 points): Is the system linear? Why? P(15 points): Ifa(t) 2, find the state space equations?
Answer 23, 24, and 25. thanks 23. If the input to the above system is a)2cus(4), what would be the output y0)? Use the equation below for the following problem(s): (cos(,)-1) y(t) = What is the Fourier Transform of the signal given above? 24. Use the equation(s) below to solve the following problem(s): tn-nne [2.5] Q otherwise Qctherwise what is the result of the convolution of the two signals shown above, x(n-fn]? a. (000019.5/3 6.5/3 33/20 1 0 0 b....
4. (25 points) Consider a sampled data system shown in the following figure, wherein the transfer function of the y (t) r*(t ZOH Process zero-order hold, and the process are given by 2s +1 Go(s) =--s G(s) = There parameter a is some real number, and T is the sampling time. (a) (15 points) Determine the discrete-time transfer function G(z). 4. (25 points) Consider a sampled data system shown in the following figure, wherein the transfer function of the y...
Problem 51: (25 points) Figure 5 is an example of a feedback control system that is designed to regulate the angular position θ(t) of a motor shaft to a desired value θr(t). The signal e(t) represents the error between the measured shaft angle θ(t) and the desired shaft angle θ (t). The Laplace transforms ofa,(t), θ(t), and e(t) are denoted as ΘR(s), θ(s), and E(s), respectively. The control gains Ki and K2 are chosen by the control engineer to achieve...