The frequency response H(f) of a linear system is given by: , where f is frequency...

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...

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) =...

y[n] =b(ax[n] +x[n-1]+ax[n-2]) where a&b >0. Find the frequency response of the system H(e^jw). Determine the...

y[n] =b(ax[n] +x[n-1]+ax[n-2]) where a&b >0. Find the frequency response of the system H(e^jw). Determine the values of a & b, if the magnitude response of the filter at w = 0 is 1 and at w =pi÷2 is 0.5. thanks

Consider the cascade of two filters with frequency responses H 1 ( j Ω )   =   j Ω...

Consider the cascade of two filters with frequency responses H 1 ( j Ω )   =   j Ω H 2 ( j Ω )   =   1 e^{ - j Ω} (1) Indicate what each of the filters does. (2) Suppose that the input to the cascade is x ( t )   =   p ( t )   cos ( πt / 2 ) ,  w h e r e   p ( t )   =   u ( t + 1 ) - u ( t - 1 ). Find the output y(t) of...

I am trying to calculate the frequency response of a pressure transducer (PX302-030GV) which is usually...

I am trying to calculate the frequency response of a pressure transducer (PX302-030GV) which is usually a second-order system. How I can calculate the damping ratio of a second-order system if the frequency is 2000Hz (according to datasheet). Is it possible to calculate the frequency response using this transfer function? H(s) = (wn )2 / (s2+ 2*ζ*wn*s+ wn2) Where, wn= natural frequency= 2*pi*f and f=2000Hz ζ = damping ratio

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...

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...

A continuous-time system, with time t in seconds (s), input f(t), and output y(t), is specified...

A continuous-time system, with time t in seconds (s), input f(t), and output y(t), is specified by the equations: y(t) = f(sin(t)) y(t) = f(cos(t)) a) are these systems causal? Justify your answer. b) are these systems linear? Clearly show and explain your work

Problem 1 ...... you can use Matlan i got one so all what i need is...

Problem 1 ...... you can use Matlan i got one so all what i need is 2, 3 and 4 one of them or all of them .. thanks The following Scilab code generates a 10-second “chirp” with discrete frequencies ranging from 0 to 0.2 with a sampling frequency of 8 kHz. clear; Fs = 8000; Nbits = 16; tMax = 10; N = Fs*tMax+1; f = linspace(0.0,0.2,N); x = zeros(f); phi = 0; for n=0:N-1 x(n+1) = 0.8*sin(phi); phi...

In the study of Signal and System, it is important to understand the system characteristics such...

In the study of Signal and System, it is important to understand the system characteristics such as linearity, time invariance, stability, causality and invariability. In this experiment, write a function that uses inputs x1[n]=3?[n] and x2[n]=7?[n] to determine if the system output Y[n]={tan (3(pi)n/11)}2 + sin(6(pi)n/21) + cos(7(pi)n/21){x[n] + 1} represents the output of a linear system. Using MATLAB