Given an input signal x[n], and the impulse response h[n], compute the output signal. x[n] =...

The signal x[n] is the input of an LTI system with impulse function of h[n]. x[n]...

The signal x[n] is the input of an LTI system with impulse function of h[n]. x[n] = (0.4)^n u[n] and h[n] = (0.2)^n u[n]. (a) What is the DTFT of the output of the LTI system? (b) What are the Energy density spectrums of the input and output signals? (c) What would be the inverse DTFT: X(w) = 1/(1-0.25e^-j(w-2)) (d) How would part (c) differ for the DTFT: X(w) = 1/(1-0.25e^-j(w-2)) + 1/(1-0.25e^-j(w+2))

Solve this signal problem. Suppose the output y[n] of a DT LTI system with input x[n]...

Solve this signal problem. Suppose the output y[n] of a DT LTI system with input x[n] is y[n-1] - 10/3y[n] + y[n+1] = x[n] The system is stable and the impulse response of h[n] = A1*(B1)^n*C1 + A2*(B2)^n*C2 is then, What is A1? What is B1? What is C1? What is A2? What is B2? What is C2?

An LTI system has an impulse answer of h[n] = a^(n)H[n], H[n] is the Heaviside step...

An LTI system has an impulse answer of h[n] = a^(n)H[n], H[n] is the Heaviside step function. Obtain the output y[n] from the system when the input is x[n]=H[n]. 2. Consider the discrete system defined by> y[n] - ay[n-1] =x[n] Find the output when the input is x[n] = Kb^(n)H[n], and y[-1]=y_(-1)\ Find the output when the input is x[n] = K ẟ [n], and y[-1]=a Find the impulse response when the system is initially at rest. Find the Heaviside...

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...

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).

Find the pole and zero values for the system whose input-output relation is given below and...

Find the pole and zero values for the system whose input-output relation is given below and show them in the z plane. Also calculate the impulse response of this system. y[n-1] - (10/3)y[n] + y[n+1] = x[n]

The impulse response of an LTI system is h[n] = 3u[n+2]. a) Is this system BIBO...

The impulse response of an LTI system is h[n] = 3u[n+2]. a) Is this system BIBO stable? Justify. b) Is the system causal? Justify.

a) If the transfer function of a system is H(z) = 2+z^(-2), what is its impulse...

a) If the transfer function of a system is H(z) = 2+z^(-2), what is its impulse response? b) If the transfer function of a system is 2z/(z-0.5) and it is valid for when |z| > 0.5, what is its impulse response? c) If the transfer function of a system is 1/(z-2), what is its impulse response? d) x[n] = (-4)^n U[n]. (U[n] is the unit step function). What is its z-transform and the region of convergence of its z-transform? e)...

A linear time invariant system has an impulse response given by ℎ[?] = 2(−0.5) ? ?[?]...

A linear time invariant system has an impulse response given by ℎ[?] = 2(−0.5) ? ?[?] − 3(0.5) 2? ?[?] where u[n] is the unit step function. a) Find the z-domain transfer function ?(?). b) Draw pole-zero plot of the system and indicate the region of convergence. c) Is the system stable? Explain. d) Is the system causal? Explain. e) Find the unit step response ?[?] of the system, that is, the response to the unit step input. f) Provide...

For an LTI system h[n], the output is given by y[n] = 2δ[n-1], given that x[n]...

For an LTI system h[n], the output is given by y[n] = 2δ[n-1], given that x[n] = δ[n]-2δ[n-1]+ 2δ[n-2]. a) Find the transfer function H(z) (7 Points). b) Find the difference equation of the overall system (8 Points). c) Given that the system is causal find h[n] (10 Points). d) Given that the system does not have Fourier Transform, find h[n] (10 Points).