h56255 s 00004/00001/00335 d D 1.34 24/12/15 18:51:29 bevans 34 33 c Updated e s 00004/00003/00332 d D 1.33 24/12/03 23:41:15 bevans 33 32 c Updated e s 00001/00002/00334 d D 1.32 24/08/27 13:43:32 bevans 32 31 c Updated e s 00003/00000/00333 d D 1.31 24/08/17 11:21:53 bevans 31 30 c Added Fall 2023 final exam e s 00004/00001/00329 d D 1.30 23/12/03 08:25:10 bevans 30 29 c Up e s 00009/00006/00321 d D 1.29 23/11/27 23:08:05 bevans 29 28 c Up e s 00001/00001/00326 d D 1.28 21/12/13 23:15:23 bevans 28 27 c Updated e s 00003/00000/00324 d D 1.27 21/12/13 11:22:27 bevans 27 26 c Updated e s 00000/00023/00324 d D 1.26 19/08/12 19:26:13 bevans 26 25 c Updated e s 00003/00000/00344 d D 1.25 18/12/22 00:55:38 bevans 25 24 c Updated e s 00002/00002/00342 d D 1.24 18/12/14 16:45:05 bevans 24 23 c Updated e s 00004/00003/00340 d D 1.23 18/12/14 08:57:18 bevans 23 22 c Updated e s 00004/00001/00339 d D 1.22 18/12/14 08:53:51 bevans 22 21 c Updated e s 00038/00000/00302 d D 1.21 18/12/13 22:43:28 bevans 21 20 c Updatewd e s 00007/00011/00295 d D 1.20 18/12/10 18:40:35 bevans 20 19 c Updated e s 00053/00041/00253 d D 1.19 18/12/10 18:38:22 bevans 19 18 c Updated e s 00001/00013/00293 d D 1.18 18/12/10 09:37:42 bevans 18 17 c Updated e s 00020/00001/00286 d D 1.17 18/12/03 16:43:13 bevans 17 16 c Updated e s 00058/00001/00229 d D 1.16 18/11/12 21:27:15 bevans 16 15 c Updated e s 00001/00001/00229 d D 1.15 18/06/07 15:12:08 bevans 15 14 c Updated e s 00001/00014/00229 d D 1.14 18/06/07 15:06:54 bevans 14 13 c Updated e s 00001/00001/00242 d D 1.13 18/01/03 11:22:34 bevans 13 12 c Updatef e s 00032/00003/00211 d D 1.12 17/12/21 00:54:32 bevans 12 11 c Updared e s 00009/00001/00205 d D 1.11 17/12/21 00:47:03 bevans 11 10 c Updated e s 00003/00000/00203 d D 1.10 17/12/18 11:28:28 bevans 10 9 c Updated e s 00001/00000/00202 d D 1.9 17/11/30 01:58:01 bevans 9 8 c Updated e s 00002/00002/00200 d D 1.8 17/11/29 20:47:55 bevans 8 7 c Updated e s 00003/00001/00199 d D 1.7 17/11/28 22:40:15 bevans 7 6 c pdated e s 00025/00018/00175 d D 1.6 17/11/27 21:38:41 bevans 6 5 c Updated e s 00011/00002/00182 d D 1.5 17/11/22 22:13:24 bevans 5 4 c Updated e s 00001/00001/00183 d D 1.4 17/11/09 23:32:26 bevans 4 3 c Updated e s 00005/00005/00179 d D 1.3 17/11/09 23:20:02 bevans 3 2 c Updated e s 00001/00001/00183 d D 1.2 17/07/08 15:31:24 bevans 2 1 c Changed background color e s 00184/00000/00000 d D 1.1 17/07/08 15:30:11 bevans 1 0 c date and time created 17/07/08 15:30:11 by bevans e u U f i f e 0 t T I 1 EE313 Linear Systems and Signals - Final Exam D 2 E 2 I 2 E 2

EE313 Linear Systems and Signals - Final Exam

D 29 The final will be an open book, open notes, open laptop, comprehensive E 29 I 29 D 32 Final exam will be on Monday, December 11, 2023, 8am-10am, in ECJ 1.202, which seats 172. E 32 I 32 D 33 Final exam will be on Thursday, December 12, 2024, 8am-10am, room TBA. E 33 I 33 Final exam will be on Thursday, December 12, 2024, 3:30-5:30pm, CPE 2.208. CPE 2.208 seats 140 people. With 70 students in the class, each student would have an aisle or empty seat on either side of them. E 33 E 32

The final exam will be an open book, open notes, open laptop, comprehensive E 29 exam that is scheduled to last the entire final exam period. The laptop must have all external networking connections disabled. D 29 Because the final exam is an open book, notes and laptop exam, you'll E 29 I 29 Because the final exam is an open book, notes and laptop exam, you'll E 29 likely need to move quickly through the exam but also need to think deeply about possible ways to solve the problems. D 29 To this end, having a week of regular sleep, eating, and exercise will be very helpful. E 29 I 29 To this end, having a full week of regular sleep, eating, and exercise will be very helpful. E 29 D 26

D 14 The final exam will be on Monday, December 18th, 9:00am-12:00pm, D 5 room TBA. With 60 students in the class, you should have several empty E 5 I 5 in EERC 1.516 and EERC 1.518. Each room has an identical layout of tables with 122 seats. Each seat has a power outlet. E 14 I 14 D 15 The final exam will be on Wednesday, December 20th, 2:00pm-5:00pm. E 15 I 15 D 17 The final exam will be on Wednesday, December 19th, 2:00-5:00pm. E 17 I 17 The final exam will be on Wednesday, December 19th, 2:00-5:00pm, in the following rooms: E 17 E 15 E 14 I 17

Current enrollment is 72 students. In both rooms, there should be an aisle or three empty seats on either side of you.

Office Hours and Review Session

E 26 E 17 D 14 With 59 students in the class, you should have three empty E 5 seats or an aisle on either side of you. The extra space will help you be more comfortable to arrange your books, notes, and laptop for the final exam. E 14 D 11

Previous Final Exams

E 11 I 11

Previous Exams

E 11 D 29 Here are several example final exams: E 29 I 29 D 30 Here are several previous final exams for this course: E 30 I 30 Final exams prior to fall 2022 were three hours long, and final exams since fall 2022 are two hours long.

Here are the previous final exams given by Prof. Evans for this course: E 30 E 29

I 11 Also, please visit the Web pages for the following old exams: E 11 D 18

Office Hours

D 6 Prof. Evans will be holding office hours for final exam preparation as follows: E 6 I 6 Office hours to help you with final exam studying will be held on the following dates/times: E 6

E 18 I 7

Coverage

E 7 You will be responsible for the following sections of the Signal Processing First textbook by McClellan, Schafer and Yoder:

You will also be responsible for the material covered on all homework assignments, hints and solutions, as well as in all D 6 handouts and lectures. E 6 I 6 handouts and lectures: E 6 I 6

E 6

D 33 There will be 8-10 questions on the final exam. E 33 There won't be any questions about Matlab. D 16

E 16 I 16

Other Questions

E 16 I 19

Fall 1999 Final Exam

D 23 Problem 2 on Fall 1999 Midterm #2
E 23 I 23 Problem 2 on Fall 1999 Midterm #2

E 23 This problem gives the step response of an LTI system, which we'll call ystep(t). It then asks you to find the response to a new signal x(t). Here are two different approaches for solving this problem:

Fall 2003 Final Exam

E 19 D 12 Problem 6 on fall 2003 final exam. E 12 I 12 Problem 6 on Fall 2003 final exam. E 12 D 23 On problem 6(b) of the fall 2003 final exam, the E 23 I 23 On problem 6(b) of the Fall 2003 final exam, the E 23 solution set (which I didn't write) is making the improper substitution 
f(w) d(w) = f(0) d(w)
where d(w) is the Dirac delta functional. That is, 
10 - j 2 w           10
---------- pi d(w) = -- pi d(w)
 4 + j w              4
which again is not valid.

Now, later in the problem, an inverse Fourier transform will be taken, and at that time, one can apply the property 

       oo
 1    /            j w t        1
---   | f(w) d(w) e      dw = ---- f(0)
2 pi  /                       2 pi
     -oo
Under integration, we can simplify expressions involving the Dirac delta, and one should obtain the same answer that is given in the solution set. D 19

E 19 I 19

Spring 2009 Final Exam

E 19 D 12 Problem 3 on fall 2010 final exam. E 12 I 12 Problem 1 on Spring 2009 final exam. E 12

I 12 Differential Equation Rhythm. The initial conditions are not zero, so the system is not LTI. See Section 16-11.1 on page 50 of the supplemental Chapter 16 on The Laplace Transform in the Signal Processing First book for a similar example.

I 21 Problem 2 on Spring 2009 final exam.

I 22 The system is LTI, which means that all initial conditions must be zero. The initial conditions are y(0-) and y'(0-).

E 22 (a) Take the Laplace transform of both sides of the differential equation: 

s^2 Y(s) + 7 s Y(s) + 10 Y(s) = X(s)
(s^2 + 7s + 10) Y(s) = X(s)
Y(s)         1
---- =  ------------- = H(s)
X(s)    s^2 + 7s + 10
(b) Poles are the roots of the denominator. 
s^2 + 7s + 10 = (s + 2)(s + 5)
Poles are at s = -2 and s = -5. Zeros are the roots of the numerator. No zeros.

(c) Region of convergence for H(s) is the intersection of the region of convergence for the pole at s = -2 which is Re(s) > -2 and the region of convergence for the pole at s = -5 which is Re(s) > -5. The intersection gives Re(s) > -2.

(d) Step response means the system response to a unit step u(t) input. The output is y(t) = h(t) * u(t) or equivalently Y(s) = H(s) X(s). When x(t) = u(t), X(s) = 1/s. So, Y(s) = 1 / ( s (s+2) (s+5) ). Region of convergence is Re(s) > 0. We can apply partial fractions decomposition on Y(s): 

              1        1/10   1/6   1/15
Y(s) = ------------- = ---- - --- + ----
       s (s+2) (s+5)    s     s+2   s+5
Then take the inverse Laplace transform: 
y(t) = (1/10) u(t) - (1/6) exp(-2 t) u(t) + (1/15) exp(- 5 t) u(t)

E 21 D 19 Problem 7 on Fall 2009 final exam. E 19 I 19 Problem 7 on Spring 2009 final exam. E 19

Discrete-Time Filter Design. A notch filter is needed to remove the interfering frequency at 2 pi f0 / fs = pi / 2 and of course -pi /2. Pole radii of 0.9 would work. D 19

E 19 I 19

Fall 2010 Final Exam

E 19 Problem 3 on Fall 2010 final exam.

E 12 (a) The transfer function for the LTI system is H(s) = s^2 / ((s+1)(s+2)).

(b) There are two zeros at s = 0. The poles are s = -1 and s = -2.

D 22 (c) ROC: Re{s} > -1. The ROC is the intersection of Re{s} > -2 and Re{s} > -1 due to the poles. E 22 I 22 (c) ROC: Re{s} > 1. The ROC is the intersection of Re{s} > -2 and Re{s} > -1 due to the poles. E 22

(d) Because the ROC includes the imaginary axis, we can substitute s = j w into the transfer function H(s) to obtain the frequency response:

Hfreq(w) = H(j w) = (j w)^2 / ((j w + 1)(j w + 2))

(e) There many possible approaches.

Approach #1: Compute magnitude responses for a few frequency values. w = 0 rad/s is a good place to start. Based on the denominator, w = 1 rad/s and w = 2 rad/s look interesting, too.

| Hfreq(0) | = 0

| Hfreq(1) | = | -1 / ((1 + j)(2 + j)) | = 1 / ( |1 + j| |2 + j| ) = 1 / ( sqrt(2) sqrt(5) ) = 1 / sqrt(10) = 0.3162

| Hfreq(2) | = | -4 / ((1 + 2j)(2 + 2j)) | = 4 / sqrt(40) = 0.635

Looks highpass.

Approach #2: Start evaluating the magnitude response by evaluating different values of w:

Hfreq(w) = |j w - 0|^2 / ( |j w - (-1)| |j w - (-2) | )

The term |j w - s0| is the Euclidean distance between the point j w and the point s0 in the complex s plane. That is, it's the length of the vector whose head is j w and whose tail is s0. Highpass filter.

Approach #3: Map the zeros and poles from the s plane to the z-plane using z = exp(s T) where T is the sampling time and then evaluate the magnitude response. In the z-domain, the zeros are at z = 1. The pole locations go to the positive real line in the z-domain at exp(-T) and exp(-2 T). Highpass filter.

D 12 Problem 5 on fall 2010 final exam E 12 I 12 Problem 4 on Fall 2010 final exam. E 12

I 12 Discrete-Time Stability. Involves the determination of the range of a free parameter K to keep the discrete-time system bounded-input bounded-output (BIBO) stable. Different values of K that give BIBO stability will also give different frequency responses for the system. Analyze the transfer function to determine what values of K keep both poles inside the unit circle. The answer is 0.6 < K < 1. Values of K from 0.6 to 0.7 or so will yield a lowpass system. As K increases, the frequency response becomes bandpass.

D 23 Problem 5 on fall 2010 final exam. E 23 I 23 Problem 5 on Fall 2010 final exam. E 23

E 12 D 28 (a) When the input is x(t) = cos(2 π t), the output is y(t) = 1⁄2 + 1⁄2 cos(4 π t). The input has only one frequency at 1 Hz, but the output has frequencies at 0 Hz and 2 Hz present. A linear time-invariant system cannot create new frequencies. The only frequencies on the output must be present on the input.The system cannot be linear and time-invariant. E 28 I 28 (a) When the input is x(t) = cos(2 pi t), the output is y(t) = 1/2 + 1/2 cos(4 pi t). The input has only one frequency at 1 Hz, but the output has frequencies at 0 Hz and 2 Hz present. A linear time-invariant system cannot create new frequencies. The only frequencies on the output must be present on the input.The system cannot be linear and time-invariant. E 28

(b) For an input of cos(w0 t), the output is 1/2 + 1/2 cos(2 w0 t). In the Fourier domain, cos(w0 t) is a pair of Dirac deltas at frequencies -w0 and w0, each with an area of pi. Also, 1/2 + 1/2 cos(2 w0 t) has Dirac deltas at frequencies -2 w0, 0, and 2 w0, with areas of pi/2, pi and pi/2, respectively. The input signal cos(w0 t) has been modulated by cos(w0 t). However, the system can't be multiplication by cos(w0 t) due the step response of the system, which is a step function. The output of the system is the square of its input. I 16

Is the region of convergence in the Laplace transform affected when there is a time shift?

The region of convergence is not affected by a time shift. A time shift simply causes the Laplace transform to have a multiplication term in the form on exp(-s t0) where t0 is the time shift.

Also, if it is a unilateral Laplace transform, do we need to worry about how to find the region of convergence (in lecture slide 11-10 it states that there is no need to specify a region of convergence)?

The region of convergence is not necessary if one is computing the inverse Laplace transform and the time-domain signal that will result is causal. However, for other reasons, such as BIBO stability checking for transfer functions and converting transfer functions to frequency responses, knowing the region of convergence is critical. D 19

Problem 2 on Fall 1999 Midterm #2
This problem gives the step response of an LTI system, which we'll call ystep(t). It then asks you to find the response to a new signal x(t). Here are two different approaches for solving this problem:

E 19 E 16

Last updated %G%. Send comments to bevans@ece.utexas.edu. E 1