5. A dynamic system is modeled as (ult) u2t) to the output (vi(t) (u) un 0 80 Calculate the trans...
20% 5. A dynamic system is modeled as [2 o][B(t).11 ol.[A(Ol+[30 70].ly,(이_A(1) Calculate the transfer function matrix connecting the input (ult) uzlt) to the output vat) V2 y2(t), all initial conditions equal to 0 20% 5. A dynamic system is modeled as [2 o][B(t).11 ol.[A(Ol+[30 70].ly,(이_A(1) Calculate the transfer function matrix connecting the input (ult) uzlt) to the output vat) V2 y2(t), all initial conditions equal to 0
5. A two-input, two-output dynamic system is defined by the following differential equations system 2x, (t) ) +3x1(t) -2x2 () fi(t) x2 t) -2x,(t) +2x2(t) f2(t) Determine its transfer function matrix considering that the input is (fi (t) f2(t) and the output is x, (t) x2 (t)J. 5. A two-input, two-output dynamic system is defined by the following differential equations system 2x, (t) ) +3x1(t) -2x2 () fi(t) x2 t) -2x,(t) +2x2(t) f2(t) Determine its transfer function matrix considering that...
A system is modeled by the following LTI ODE: ä(t) +5.1640.j(t) + 106.6667x(t) = u(t) where u(t) is the input, and the outputs yı(t) and yz(t) are given by yı(t) = x(t) – 2:i(t), yz(t) = 5ä(t) 1. Find the system's characteristic equation 2. Find the system's damping ratio, natural frequency, and settling time 3. Find the system's homogeneous solution, x(t), if x(0) = 0 and i(0) = 1 4. Find ALL system transfer function(s) 5. Find the pole(s) (if...
Find the frqeuncy response and impulse response of the system with the output y(t) for the next input x(t) Please, Solve (a) and (c) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult) x)e u(t), ()eu(te ult)
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...
10. Consider the nonlinear state equation di(t) = z{(t) – u(t)zy(t) + W T ult) éz(t) = x2(t) + 2x1(t) - u(t)xi(t) For homogeneous initial conditions, compute the nominal solution correspond- ing to the nominal input ū(t) = t for all t > 0. (Hint: search for monomial solutions in time.) Then, linearize the dynamics about the nominal solution. Is the linear system time-varying?
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...
A linear, time-invariant system is modeled by the ordinary differential equation y(t) + 7y(t) = 14f(t) Let f(t) = e^-t cos(2t)u(t) and y(0-) = -1. (a) Find the transfer function of the system and place your answer in the standard form H(s) = bms^m + bm-1s^m-1 + ... + b1s + bo / s^n + an-1s^n-1 + ... + a1s + a0 (b) Determine the output of the system as Y(s) = Yzs(s) + Yzi(s) and place both the zero...
5- For the following system: x( Input: x(t)s u(t) Output: y() With the initial condition y(0) 1, y(O)-0, RI-1, R2-12, CI-2F, C2-1F. Identify the natural and forced response of the system a) Find the zero input response. b) Unit impulse response. c) zero state response. d) The total response. e Identify the natural and forced response of the system. 5- For the following system: x( Input: x(t)s u(t) Output: y() With the initial condition y(0) 1, y(O)-0, RI-1, R2-12, CI-2F,...
(3) For the system modeled by with output defined as a) Find the system's transfer function(s) E(t) +3z(t) +2x(t)-Sult) b) Find the system's pole(s) (if any) and zero(s) (if any) c) Find n(t →x) if u(t)-G 120) 0 t<0 e) Find the frequency response function corresponding to output y 1) Find steady-state ya(t) if u(t) 3sin(21)