subject-DSP 1)y(n)=2x^2(n-1) determine the system is(and justify your decision) a)linear b)time invariant c)stable d)causal

A discrete time system can be i. Linear or non-linear ii. Time invariant or Time Variant...

A discrete time system can be i. Linear or non-linear ii. Time invariant or Time Variant iii. Causal or noncausal iv. Stable or unstable v. Static Vs Dynamic Examine the following systems with respect to every property mentioned above and give a brief explanation. a. y[n] = x[n]δ[n − 1] b. y[n] = x[n] + nu[n + 1] c. y(n) = x(2. n) d. y(n) = 3. x(n)

Which of the following systems are dynamical? Stable? Causal? Time-invariant? Linear? 1. y(t) = 5x(t) 2....

Which of the following systems are dynamical? Stable? Causal? Time-invariant? Linear? 1. y(t) = 5x(t) 2. y(t) = x(t)^4 3. y(t) = x(t−1)^2 4. dy/dt = x(t) 5. dy/dt = y(t) + x(t) 6. dy/dt = −y(t) + x(t)^2 7. dy/dt = −y(t) + x(t + 4) 8. dy/dt = tx(t)

Demonstrate step by step if the following system is: 1. Static or dynamic. 2. Linear or...

Demonstrate step by step if the following system is: 1. Static or dynamic. 2. Linear or non-linear. 3. Invariant or variant in time. 4. Causal or not causal. 5. Stable or unstable. y(n)=x(n)+nx(n-2)

Determine if the system ?[?]=sin⁡(0.2?∙?[?])is (1) linear, (2) time-invariant.

Determine if the system ?[?]=sin⁡(0.2?∙?[?])is (1) linear, (2) time-invariant.

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...

1.28 Dectermine which of the properties listed in 1.27 hold and which do not hold for...

1.28 Dectermine which of the properties listed in 1.27 hold and which do not hold for each of the following discrite-time systems. Justify your answers. In each example, y[n] denotes the system output and x[n] is the system input. b) y[n] = x[n-2]-2x[n-8] c) y[n]=nx[n] system may or may not be: 1) Memoryless 2) Time invariant 3) Linear 4) causal

Given a input x(t) output y(t) relation as y(t) = x(0.5+t) + e^( - | x(0.5-t)...

Given a input x(t) output y(t) relation as y(t) = x(0.5+t) + e^( - | x(0.5-t) | ). Determine the system is (a) Memoryless (b) Time invariant (c) Linear (d) Causal (e) stable.

2. Consider the following impulse responses h[n] of linear time-invariant (LTI) systems. In each case, (i)...

2. Consider the following impulse responses h[n] of linear time-invariant (LTI) systems. In each case, (i) provide the transfer function H(z) (ZT of h[n]) and its ROCh, (ii) sketch the ROCh in the z-plane, (iii) mark the pole and zero locations of H(z) (on the same plot in the z-plane), and (iv) discuss whether or not the LTI system is stable. (a) h1[n] = (0.4)^n u[n] + (2 - 3j)^n u(n -2) (b) h2[n] = (0.2)^(n+2) u[n] + (2 -...

Consider a causal LTI system described by the difference equation: y[n] = 0.5 y[n-1] + x[n]...

Consider a causal LTI system described by the difference equation: y[n] = 0.5 y[n-1] + x[n] – x[n-1] (a) Determine the system function H(z) and plot a pole-zero pattern in the complex z-plane. (b) Find the system response using partial fraction expansion when the input is x[n] = 2u[n]. Plot the result.

elementary linear algebra Solve the system. x+y+z=1 x+y-2z=3 2x+y+z=2

elementary linear algebra Solve the system. x+y+z=1 x+y-2z=3 2x+y+z=2