代做CAN207 Continuous and Discrete Time Signals and Systems Assignment 1代做留学生SQL 程序

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CAN207

Continuous and Discrete Time Signals and Systems

Assignment 1

Assignment 1 : CT Signals and Systems

Deadline: Nov. 11th, 9:00 a.m.

Submission: Submit the electronic version to Learning Mall.

Information: This assignment takes 15% in the total mark.

Late submission: 5% each day, less than 1 day is counted as 1 day.

Submissions later than 5 working days won’t be accepted.

Question 1 ( L3-4) 20 marks

(a) For the signal x(t) shown below, plot 2x(2t + 2)

(b) Express the signal shown below using scaled and time shifted unit step function u(t).

I) x(t) = sin(3t − 2/π)

II) x(t) = u(t) − 0.5

(d) For the given signals, if the signal is periodic, find its fundamental period

and its fundamental frequency; otherwise, prove that the signal is not periodic.

I) x(t) = 4cos(4t + 40°) + 3e−j12t

II) x(t) = cos(2πt) + sin(6t)

(e) Determine whether the following signals are power signal, energy signal or neither:

I) x(t) = e−2tu(t)

II) x(t) = ej(2t+π/4)

Question 2 ( L5-6) 20 marks

(a) For the systems given below, decide whether they are causal, stable, linear and time-invariant? Conclusions only.

I) Input-output relationship: y[n] = x [3 − 2n];

II) Input-output relationship: y(t) = cos(πt)x(t);

III) Impulse response: ℎ(t) = u(t + 3) − u(t − 3);

IV) Impulse response: ℎ[n] = 5nu [ − n].

(b) Suppose the following systems take x(t) as the input and y(t) as the

corresponding output. Find the impulse response ℎ(t).

I) y(t) = x(t − 7);

II) y(t) = x(t − 7)d;

Express the system impulse response as a function of the impulse responses of the subsystems.

(d) Suppose the systems with impulse response ℎ(t) take x(t) as the input.

Find the output y(t).

x(t) = u(1 − t) and ℎ(t) = e−tu(t − 2);

(e) For the convolution between two time-domain signals f(t) and g(t), the

diferentiation property is:

Question 3 ( L7-9) 20 marks

(a) Find the Fourier coefficients of the exponential form.

x(t) = 2sin24t + cos4t and

(b) Calculate the Fourier coefficients for each signal:

Calculate the Fourier transform. of x(at)cos(w0 t), with 0 < a < 1.

(d) The magnitude and phase spectrum of a LTI system are plotted below:

If input signal is x(t) = 1 + 2cos(2πt), find the corresponding output.

Question 4 ( L10-11) 20 marks

(a) A stable system is characterized by the transfer function: 10

I) Draw the zero-pole plot of the system;

II) Determine the ROC of the system;

III) Find the impulse response of the system;

IV) Decide whether the system’s magnitude response is lowpass, highpass, bandpass or bandstop.

(b) The characteristic equation of a continuous-time causal system is given:

D(S) = S2 + 2S + a

For the system to be stable, decide the range of the real value a in the equation.

Use Fourier transform. properties to show that g(t) has the form. like: g(t) = AY(Bt), and determine the values of A and B.

Question 5 ( L12-13) 20 marks

(a) The following differential equation is used to model a RLC circuit whose input is x(t) = e−tu(t):

y'' (t) + 5y' (t) + 6y(t) = x(t)

With the initial conditions:

y(0− ) = 1 and y' (0− ) = 0

Solve the differential equation in time domain to get:

i) Zero-input response;

ii) Zero-state response;

iii) Overall response.

(b) Solve sub-question c) in frequency domain.