A signal x(t)=2 sin⁡(62.8 t)*u(t) is sampled at a rate of 5 Hz, and then filtered...

The signal x(t)=sinc2(100t) is sampled with frequency fs=150sample/sec 1. Determine the spectral representation of the sampled...

The signal x(t)=sinc2(100t) is sampled with frequency fs=150sample/sec 1. Determine the spectral representation of the sampled signal (n=-3 to n=3). 2. Plot the spectral representation of the sampled signal and determine if the signal has aliasing. 3. Determine the minimum frequency of sampling (Nyquist sampling frequency) so that the signal can be reconstructed using an ideal low pass filter. Justify your answer.

The signal x(t)=2a/(t^2+a^2) , - infinity < t < infinity is passing through a band-limiting low-pass...

The signal x(t)=2a/(t^2+a^2) , - infinity < t < infinity is passing through a band-limiting low-pass filter with bandwidth B Hz. Determine the minimum value of B in terms of a so that the output of the filter has 99% of the energy of the input signal.

Question : Design the low and high pass filter for the signal, x(t) = 10 sin...

Question : Design the low and high pass filter for the signal, x(t) = 10 sin (10 t) + 1 sin (1000 t) by MATLAB Is below answer right? at ?High pass , 5row shouldn't this change from sin(100*t) ? sin(1000*t) x = 10*sin(10*t) + 1*sin(100*t); ?   x = 10*sin(10*t) + 1*sin(1000*t); ??? ..................................................................................................................................................... ?Low pass clc; rng default Fs=2000; t=linspace(0,1,Fs); x=10*sin(10*t)+sin(1000*t)%given signal n=0.5*randn(size(t));%noise x1=x+n; fc=150; Wn=(2/Fs)*fc; b=fir1(20,Wn,'low',kaiser(21,3)); %fvtool(b,1,’Fs’,Fs) y=filter(b,1,x1); plot(t,x1,t,y) xlim([0 0.1]) xlabel('Time (s) ') ylabel('Amplitude') legend('Original Signal','Filtered Data')...

Consider the signal x(t) = 3 cos 2π(30)t + 4 . (a) Plot the spectrum of...

Consider the signal x(t) = 3 cos 2π(30)t + 4 . (a) Plot the spectrum of the signal x(t). Show the spectrum as a function of f in Hz. ?π? For the remainder of this problem, assume that the signal x(t) is sampled to produce the discrete-time signal x[n] at a rate of fs = 50 Hz. b Sketch the spectrum for the sampled signal x[n]. The spectrum should be a function of the normalized frequency variable ωˆ over the...

Assuming a continuous is given as x(t)=10cos(2pi.5,500t)+5sin(2pi.7,500t),for t>0(greater than or equal to zero) sampled at a...

Assuming a continuous is given as x(t)=10cos(2pi.5,500t)+5sin(2pi.7,500t),for t>0(greater than or equal to zero) sampled at a rate upyo 8,000Hz, a.sketch a spectrum of the sampled signal upto 20KHz; b.sketch tge recovered analog signal spctrum if an ideal filter with a cutoff frequency of 4KHz is used to sampled signal if order to recover the original signal; c.determine the frequency /frequencies of aliasing noise

A signal given by 5 Cos (20*pi*t) + 20 Sin (40*pi*t) is sampled at a rate...

A signal given by 5 Cos (20*pi*t) + 20 Sin (40*pi*t) is sampled at a rate of 50 Hz. Is the Nyquist theorem violated?

Consider a signal x(t) = 20 sinc(10t) is to be represented by samples using ideal (impulses)...

Consider a signal x(t) = 20 sinc(10t) is to be represented by samples using ideal (impulses) sampling. a) Sketch the signal spectral density X(f). b) Find the minimum sampling frequency that allows reconstruction of x(t) from its samples. c) Sketch the sampled spectrum Xs(f) in the range [-55, 55] with sampling frequency fs = 25 Hz.

1) Find the even and odd components of x(t)=e^(jt) 2) Determine whether x(t)=cos⁡t+sin⁡√2 t is a...

1) Find the even and odd components of x(t)=e^(jt) 2) Determine whether x(t)=cos⁡t+sin⁡√2 t is a periodic signal?

Let x(t) = t (u(t) − u(t − 2) ) . Is this a power signal...

Let x(t) = t (u(t) − u(t − 2) ) . Is this a power signal or an energy signal? (Justify your answer.)

Given signal x(t) = sinc(t): 1. Find out the Fourier transform of x(t), find X(f), sketch...

Given signal x(t) = sinc(t): 1. Find out the Fourier transform of x(t), find X(f), sketch them. 2. Find out the Nyquist sampling frequency of x(t). 3. Given sampling rate fs, write down the expression of the Fourier transform of xs(t), Xs(f) in terms of X(f). 4. Let sampling frequency fs = 1Hz. Sketch the sampled signal xs(t) = x(kTs) and the Fourier transform of xs(t), Xs(f). 5. Let sampling frequency fs = 2Hz. Repeat 4. 6. Let sampling frequency...