find the steady state response for the following system: y(k)-0.2y(k-1)+0.26y(k-2)=2u(k-1)-u(k-2) The input u(t) is not given.

y’’’(t) + 5y’’(t) + 7y’(t) + 3y(t) = u’(t) + 2u(t) Find a linear state space...

y’’’(t) + 5y’’(t) + 7y’(t) + 3y(t) = u’(t) + 2u(t) Find a linear state space model. Clearly define the matrices A, B, C, and D of the matrix form of the state space model

6. Consider a causal linear system whose (zero-state) response to an input signal, f(t) = e...

6. Consider a causal linear system whose (zero-state) response to an input signal, f(t) = e −3tu(t), is y(t) = (−e −t + 4e −2t − 3e −3t )u(t). ( a) Find the transfer function H(s) of the system. (b) Write the differential equation that describes the system. (c) Plot the pole-zero diagram of system. Is the system stable? (d) Plot the frequency response of the system, |H(w)|. (e) Whats the systems zero-state response to another input signal, f1(t) =...

1-Consider the following. 36y'' − y = 0, y(−4) = 1,   y'(−4) = −1 Find the...

1-Consider the following. 36y'' − y = 0, y(−4) = 1,   y'(−4) = −1 Find the solution of the given initial value problem. y(t) = ? 2- Consider the vibrating system described by the initial value problem. (A computer algebra system is recommended.) u'' + u = 9 cos ωt, u(0) = 5, u'(0) = 4 3-A spring is stretched 6 in. by a mass that weighs 8 lb. The mass is attached to a dashpot mechanism that has a...

A continuous-time system with impulse response h(t)=8(u(t-1)-u(t-9)) is excited by the signal x(t)=3(u(t-3)-u(t-7)) and the system...

A continuous-time system with impulse response h(t)=8(u(t-1)-u(t-9)) is excited by the signal x(t)=3(u(t-3)-u(t-7)) and the system response is y(t). Find the value of y(10).

For the LTI system described by the following system functions, determine (i) the impulse response (ii)...

For the LTI system described by the following system functions, determine (i) the impulse response (ii) the difference equation representation (iii) the pole-zero plot, and (iv) the steady state output y(n) if the input is x[n] = 3cos(πn/3)u[n]. a. H(z) = (z+1)/(z-0.5), causal system (Hint: you need to express H(z) in z-1 to find the difference equation ) b. H(z) = (1 + z-1+ z-2)/(1-1.7z-1+0.6z-2), stable system c. Is the system given in (a) stable? Is the system given in...

Consider a system defined by the input-output relationship given below: y(t) = x(t)x(t-2) a) Is the...

Consider a system defined by the input-output relationship given below: y(t) = x(t)x(t-2) a) Is the system memoryless? Why? b) Is the system stable? Why? c) Is the system causal? Why? d) Is the system invertible? Show why? e) Find the impulse response of the system. PLEASE ANSWER ALL QUESTIONS!

1)Find the Inverse Laplace Transform of X(s) = (s-1)/((s+1)(s+2)^2) 2)A system with the transfer function H(s)...

1)Find the Inverse Laplace Transform of X(s) = (s-1)/((s+1)(s+2)^2) 2)A system with the transfer function H(s) = (s-5)/((s+1)(s+10)) a)If the input is 2u(t), find the steady-state output of the system.

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is...

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is given by f(t) = 4 for 0<t<2π, 4π<t<6π, 8π<t<10π, … etc f(t) = 0 for 2π<t<4π, …etc

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2,...

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2, where T1 and T2 are distinct constants, and u(x,0)=0

Apply the Partial Fraction Expansion to determine the time response y(t) of the system with transfer...

Apply the Partial Fraction Expansion to determine the time response y(t) of the system with transfer function. G(s) = (1)/(s^2+6s+13) subjected to the input u(t) = 3