An LTIC system is specified by the equation (??2 + 4?? + 4) ??(??) = ??x(??)
- Find the characteristic polynomial, characteristic equation, characteristic roots, and characteristic modes of the system.
- Find ??0(??), the zero-input component of the response ??(??) for t = 0, if the initial conditions are ??0(0) = 3 and ???0(0) = -4
- An LTIC system is specified by the equation (??2 + 5?? + 6) ??(??) = (?? + 1)x(??)
- Find the characteristic polynomial, characteristic equation, characteristic roots, and characteristic modes of the system.
- Find ??0(??), the zero-input component of the response ??(??) for t = 0, if the initial conditions are ??0(0) = 2 and ???0(0) = -1
- Explain with reasons whether the LTIC systems are asymptotically stable, marginally stable, or unstable?
- (??2 + 8?? + 12) ??(??) = (??-1)x(??)
- D(??2 + 3?? + 2) ??(??) = (?? + 5)x(??)
- For the following signal find its Fourier series:
- For the following signal find its amplitude, frequency, period, angular frequency, and phase.
??(??) = 45 ??????(2??880?? + ??/5)
- Figure below shows signal x(t). Sketch and describe mathematically this signal timecompressed by factor 3 and delayed by 5.
- For the following signal find its Fourier series:
- For a LTI system with the unit impulse response h(??) = ??(-10??)??(??), determine the response y(t) for the input ??(??) = ??(-??)??(??) + ??(-3??)??(??).
- Determine the impulse response for the system: (??2 + 5?? + 6)??(??) = ????(??).
- Find y(t) for the system mentioned in question 10 for input ??(??) = 5??(-2??)??(??) when
??0(0) = 2 and ???0(0) = -1.
- For the following signal find its Fourier series:
- A continuous-time signal ??(??) is shown. Sketch the signals 3??(0.25?? + 4).
- The unit impulse response of an LTI system is h(??) = [2??(-3??)– ??(-2??)]??(??) . Find the system’s zero-state response y(t) if the input ??(??) = ??(-??)??(??).
- Noisy Sinewave
- Generate a vector signal with 4 cycles of 1kHz sinewave at a sampling frequency of 44.1kHz and an amplitude of 1V.
- Plot the signal on the screen and label the X and Y axes with the correct labels.
- Convert your Matlab code into a function in an M-file.
- Use ‘help’ to lookup the description of the built-in function randn().
- Generate a normally distributed random noise signal, also at 44.1KHz with the same number of samples as your sine wave. The rms value of the noise should be 0.1V.
- Add the noise to your original signal and plot it.
- Plot all three signals as a combined
- Find Fourier Series of the following signal (this part needs to be done by hand)
Plot the signal in Matlab
T=pi/2;%Time period w=2*pi/T; %angular frequency
t=0:0.01:10 %time we wan to plot the square wave over
F=(2*square(w*t)); % square wave should be multiplied by 2 because our square was has amplitude of 2 plot(t,F)
- Using Matlab, find the Fourier Series Coefficients (a0, an, bn). syms t
T=pi/2; % Time period of the periodic function
n=1:5; % Number of terms
% int(Your function, Your variable, Lower bound of integration, Upper bound of integration)
a0=(1/T)*int(2,t,0,pi/4)-(1/T)*int(2,t,pi/4,pi/2)
an=(2/T)*int(2*cos(n*t*2*pi/T),t,0,pi/4)-(2/T)*int(2*cos(n*t*2*pi/T),t,pi/4,pi/2) bn=(2/T)*int(2*sin(n*2*pi/T*t),t,0,pi/4)-(2/T)*int(2*sin(n*2*pi/T*t),t,pi/4,pi/2)
- Write a code in Matlab that reconstructs the initial signal using a0, an, and bn coefficients.
A=a0; for i=1:length(an);
A=A+an(1,i)*cos(i*t)+bn(1,i)*sin(i*t); end
- repeat all parts of question 16 for the following example: