We have a signal s(t) = A for 0 < t < 1 and 2 <...

Suppose a full-scale voice signal with bandwidth 10 kHz is sampled at the Nyquist rate and...

Suppose a full-scale voice signal with bandwidth 10 kHz is sampled at the Nyquist rate and quantized by using a b-bit uniform quantizer. The bit stream is then transmitted using binary PAM over an AWGN channel that is capable of passing frequencies in the range of [0, 200kHz]. 1. Suppose that the signal is transmitted at the maximum bit rate and the two-sided spectral density of noise at the receiver is 10-6 W/Hz. What is the required signal power to...

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

A signal x(t)=2 sin⁡(62.8 t)*u(t) is sampled at a rate of 5 Hz, and then filtered by a low-pass filter with a cutoff frequency of 12 Hz. Determine and sketch the output of the filter.

A carrier signal, Vc(t) = 5cos(1π3000t) F is frequency modulated by a modulating signal of 4...

A carrier signal, Vc(t) = 5cos(1π3000t) F is frequency modulated by a modulating signal of 4 kHz with a modulation index of 2. The FM wave is transmitted through a 50 Ω antenna. With the aid of Bessel Function Table, determine the: number of sets of significant sidebands, frequency deviation, carrier swing, minimum and maximum frequency of the FM signal, bandwidth using Bessel Function Table, frequencies of all the significant sidebands, total power of the FM signal. Hence, sketch and...

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')...

The receiver in an optical communications system uses a photodetector that counts the number of photons...

The receiver in an optical communications system uses a photodetector that counts the number of photons that arrive during one time unit. Suppose that the number X of photons can be modeled as a Poisson random variable with rate λ1 when a signal is present (say bit “1” is transmitted) and a Poisson random variable with rate λ0 < λ1 when a signal is absent (say bit “0” is transmitted). Let p denote the probability that the transmitted bit is...

Q No 1: Here R=18 A continuous time signal x(t) is defined as x(t) = {...

Q No 1: Here R=18 A continuous time signal x(t) is defined as x(t) = {               -2R,           -0.65 < t < 0                     R,               0 < t < 1               0.5R,                1 < t < 1.25                    0,                 otherwise Then sketch and label following signals (i) x(-t) [u(t+1.25)-u(t-0.75)] (ii) Ev{x(t)} (iii) Od{x(t)} (iv) x(2.5t) (v) x(0.25t)

2-5.5 - A common method for detecting a signal in a presence of noise is to...

2-5.5 - A common method for detecting a signal in a presence of noise is to establish a threshold value and compare the value of any observation with this threshold. If the threshold is exceeded, it is decided that a signal is present. Sometimes, of course, noise alone will exceed the threshold and this is known as a “false alarm”. Usually, it is desired to make the probability of a false alarm very small. At the same time, we would...

MATLAB FIR filter design. The audio file, covering the frequency range of roughly 0 to 3000...

MATLAB FIR filter design. The audio file, covering the frequency range of roughly 0 to 3000 Hz, is very badly corrupted with high?level noise. Your problem is to design a digital filter that will sufficiently attenuate the noise so that the audio speech is intelligible. (sorry but chegg doesn't allow me to attach the wav file) Here is the design template: clear, clc % clear all variables %% Read in the noisy audio signal from the file 'CapnJ.wav' using audioread...

Given the second order initial value problem y′′+25y=5δ(t−1),  y(0)=2,  y′(0)=−10y″+25y=5δ(t−1),  y(0)=2,  y′(0)=−10Let Y(s)Y(s) denote the Laplace transform of yy. Then...

Given the second order initial value problem y′′+25y=5δ(t−1),  y(0)=2,  y′(0)=−10y″+25y=5δ(t−1),  y(0)=2,  y′(0)=−10Let Y(s)Y(s) denote the Laplace transform of yy. Then Y(s)=Y(s)=  . Taking the inverse Laplace transform we obtain y(t)=

Given the second order initial value problem y′′−3y′=12δ(t−2),  y(0)=0,  y′(0)=3y″−3y′=12δ(t−2),  y(0)=0,  y′(0)=3Let Y(s)Y(s) denote the Laplace transform of yy. Then...

Given the second order initial value problem y′′−3y′=12δ(t−2),  y(0)=0,  y′(0)=3y″−3y′=12δ(t−2),  y(0)=0,  y′(0)=3Let Y(s)Y(s) denote the Laplace transform of yy. Then Y(s)=Y(s)=  . Taking the inverse Laplace transform we obtain y(t)=