Consider the first-order system yn = 0.5xn + 0.7xn-1. Find the system DTFT. Plot the system's...

Draw the Bode plot of magnitude and phase for the following system. Find the magnitude at...

Draw the Bode plot of magnitude and phase for the following system. Find the magnitude at corner frequencies. G(s)=10^2(s+30)(s/10+30)^2/(s+3)2 In moodle write down the corner frequencies and the exact magnitude at corner frequencies

Consider the following second-order differential equation: ?"(?)−?′(?)−6?(?)=?(?) (1) Let ?(?)=−12e^t. Find the general solution to the...

Consider the following second-order differential equation: ?"(?)−?′(?)−6?(?)=?(?) (1) Let ?(?)=−12e^t. Find the general solution to the above equation. (2) Let ?(?)=−12. a) Convert the above second-order differential equation into a system of first-order differential equations. b) For your system of first-order differential equations in part a), find the characteristic equation, eigenvalues and their associated eigenvectors. c) Find the equilibrium for your system of first-order differential equations. Draw a phase diagram to illustrate the stability property of the equilibrium.

[8] Let Y1<Y2<...<Yn be the order statistics of n independent observations from U(0, 1). (i) Find...

[8] Let Y1<Y2<...<Yn be the order statistics of n independent observations from U(0, 1). (i) Find the p.d.f. of the r-th order statistics Yr. (ii) Find the mean and variance of Yr.

1. Write a MATLAB function to determine the discrete-time Fourier Transform (H(?)) of the following sequence....

1. Write a MATLAB function to determine the discrete-time Fourier Transform (H(?)) of the following sequence. Plot its magnitude and phase. You can use the dtft command and use the abs, angle and plot commands to plot the results. x(n) = {4, 3, 2, 1, 2, 3, 4}. 2. Analytically determine H(z) and plot its magnitude and phase for the following system using freqz. y(n) = 2x(n) + x(n ? 1) ? 0.25y(n ? 1) + 0.25y(n ? 2). 3....

Consider the linear first order system [16] x′ = x + y (1) y′ =4x−2y. (2)...

Consider the linear first order system [16] x′ = x + y (1) y′ =4x−2y. (2) (a) Determine the equilibria of System (1)-(2) as well as their stability. [6] (b) Compute the general solution of System (1)-(2). [6] (c) Determine the solution of the initial value problem associated with System (1)-(2), with initial condition x(0) = 1, y(0) = 2.

Given a nonlinear system   x(t)" + cx(t)' + sin(x(t)) = 0                       (3-1) a) Consider its phase...

Given a nonlinear system   x(t)" + cx(t)' + sin(x(t)) = 0                       (3-1) a) Consider its phase plane by assuming proper parameters of c. Do you have singular points with the cases of CENTER FOCUS, NODE and SADDLE ? Are those stable? asymptotic stable or unstable? b) When c = 0, plot the phase plane and find these singular points

Find general solution to the linear system of first-order differential equation. Explain and show all steps...

Find general solution to the linear system of first-order differential equation. Explain and show all steps X' = [ 6 -1 ] X [ 5 4 ]

1. Consider a low pass filter using R=1 k Ω and C=10 nF . (a) Find...

1. Consider a low pass filter using R=1 k Ω and C=10 nF . (a) Find the frequency where the gain is 50% ( f 3dB) ? (b) Plot the Bode plot ( log Gain vs. log f ). (c) Plot the phase shift versus log f.

give a real example of a first order system and a second order system! and show...

give a real example of a first order system and a second order system! and show the transfer function!

Consider two parallel first order reactions yielding the same product. (a)Derive the dependence of the concentration...

Consider two parallel first order reactions yielding the same product. (a)Derive the dependence of the concentration of all species involved on time. (b)Predict the behavior of the Arrhenius plot for this type of reaction. (i.e. is it linear plot? Why) (The question is from the physical chemistry course)