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1、信号与系统练习题集第一部分:信号与系统的时域分析一、填空题1. ( ).2. The unit step response is the zero-state response when the input signal is ( ).3. Given two continuous time signals x(t) and h(t), if their convolution is denoted by y(t), then the convolution of and is ( ).4. The convolution ( ).5. The unit impulse response is
2、 the zero-state response when the input signal is ( ).6. A continuous time LTI system is stable if its unit impulse response satisfies the condition: ( ) .7. A continuous time LTI system can be completely determined by its ( ).8. ( ).9. Given two sequences and , their convolution ( ).10. Given three
3、 LTI systems S1, S2 and S3, their unit impulse responses are , and respectively. Now, construct an LTI system S using these three systems: S1 parallel interconnected by S2, then series interconnected by S3. the unit impulse response of the system S is ( ).11. It is known that the zero-stat response
4、of a system to the input signal x(t) is , then the unit impulse response h(t) is ( ).12. The complete response of an LTI system can be expressed as a sum of its zero-state response and its ( ) response.13. It is known that the unit step response of an LTI system is , then the unit impulse response h
5、(t) is ( ).14. ( ).15. We can build a continuous-time LTI system using the following three basic operations: ( ) , ( ), and ( ).16. The zero-state response of an LTI system to the input signal is , where s(t) is the unit step response of the system, then the unit impulse response is h(t) = ( ).17. T
6、he block diagram of a continuous-time LTI system is illustrated in the following figure. The differential equation describing the input-output relationship of the system is ( ).+-+2318. The relationship between the unit impulse response h(t) and unit step response s(t) is s(t) = ( ), or h(t) = ( ).二
7、、选择题1. For each of the following equations, ( ) is true.A、 B、 C、 D、2. Given two continuous-time signals and , if the convolution of and is denoted by , then the convolution of signals and is ( ).A. B. C. D. 3. The unit impulse response of an LTI system is h(t) = , this system is ( ). A. causal and s
8、table B. causal and unstable C. noncausal and unstable D. noncausal and stable4. = ( ). A. 1 B. 3 C. 9 D. 05. For an LTI system, if the input signal is , the corresponding output response is , if the input signal is , the corresponding output response is . And if the input signal is , the correspond
9、ing output response is ( a and b are arbitrary real numbers ). Then the system is a ( ) system. A. linear B. causal C. nonlinear D. time invariant6. = ( ).A. B. C. D. 7. ( ). A. B. C. D. 8. Given two sequences and , their lengths are M and N respectively. The length of the convolution of and is ( ).
10、A B C D9. The unit impulse response of a continuous-time LTI system is , the differential equation describing the input-output relation of this system is ( ).A. B. C. D. 10. The input-output relation of a continuous-time LTI system is described by the differential equation: . The unit impulse respon
11、se of the system h(t) ( ).A . does not include B. includes C. includes D. is uncertain11. Signals and are shown in the following figures. The expression of the convolution is ( ).-1110-11(1)0(1)A. B. C. D. 12. The following block diagram represents a continuous-time LTI system. The unit impulse +-re
12、sponse h(t) satisfies ( ).A. B. C. D. 13. The input-output relationship of a causal continuous-time system is described by the differential equation: , then the unit step response ( ).A. B. C. D. 三、综合题(分析、计算题)1. The input-output relationship of a continuous-time LTI system is described by the equati
13、on: ,a. Determine the unit impulse response h(t) of the system.b. Determine the system response y(t) to the input signal .Figure 22. Given an LTI system depicted in Figure 2. Assume that the impulse response of the LTI system is h(t) = e-tu(t), the input signal x(t) = u(t) - u(t-2). Determine and sk
14、etch the output response y(t) of the system by evaluating the convolution y(t) = x(t)*h(t).3. Remember the following identities:4. Consider an LTI system S and a signal . Ifand ,determine the impulse response h(t) of S.Figure 65. Let and , as illustrated in the Figure 6.(a). Compute y(t) = x(t)*h(t)
15、.(b). Compute g(t) = dx(t)/dt * h(t).(c). How is g(t) related to y(t)?6. Let Show that for 0 t < 3, and determine the value A.7. A causal LTI system is described by the differential equation:If the input signal is , determine the zero-state response y(t) of the system.8. In this problem, we illus
16、trate one of the most important consequences of the properties of linearity and time invariance. Specifically, once we know the response of a linear system or a linear time-invariant system to a single input or responses to several inputs, we can directly compute the responses to many other input si
17、gnals. Figure 9(a)(b)(c)(d)(a). Consider an LTI system whose response to the signal x1(t) in Figure 9(a) is the signal y1(t) illustrated in Figure 9(b). Determine and sketch carefully the response of the system to the input x2(t) depicted in Figure 9(c).(b). Determine and sketch the response of the
18、system considered in part (a) to the input x3(t) shown in Figure 9(d).第二部分:信号与系统的频域分析一、填空题1. The frequency response of an ideal filter is given by , if the input signal is , the corresponding output response y(t) = ( ).2. The Fourier transform of signal is ( ).3. The Fourier transform of signal is (
19、 ).4. Assume that the Fourier transform of is denoted as , then the Fourier transform of is = ( ).5. The Fourier transform of a continuous time periodic signal is = ( ).6. It is known that the Fourier transform of is , then the Fourier transform of is ( ).7. The Fourier transform of signal is denote
20、d as , the Fourier transform of is ( ).8. A time shifting leads to a ( ).9. The frequency responses of two LTI systems are assumed to be and , the frequency response of the interconnection of cascaded by is = ( ).10. A time-domain compression corresponds to a frequency-domain ( ).11. For a signal x(
21、t), if the condition is satisfied, then the Fourier transform of x(t) exists, this condition is ( ) but not ( ).12. Figure 12 shows a continuous-time signal , its Fourier transform is denoted as , then ( ). (Without evaluating).-1110Figure 1213. For a continuous-time LTI system, if the zero-state re
22、sponse of the system to the input signal is , then the frequency response of the system is ( ).14. The Fourier transform of signal is ( ).15. The inverse Fourier transform of is ( ).16. The frequency spectrum includes two parts, one is ( ), the other is ( ).17. Let denote the Fourier transform of si
23、gnal , then the Fourier transform of signal is ( ). (Expressed using ).18. Let denote the Fourier transform of signal , then the Fourier transform of signal is ( ). (Expressed using ).19. The period of the periodic square wave increases, the space of the spectral lines ( ).20. Consider a continuous-
24、time ideal lowpass filter S whose frequency response is When the input to this filter is a signal x(t) with fundamental period T = /6 and Fourier series coefficients ak, it is found thatFor k ( ) it is guaranteed that ak = 0.21. Consider a continuous-time LTI system whose frequency response is If th
25、e input to this system is a periodic signal with period T = 8, the corresponding system output is y(t) = ( ).二、选择题1. The frequency response of an ideal lowpass filter is . If the input signal is , the output response is = ( ).A. B. C. D. 2. The Fourier transform of the rectangular pulse is ( ).A. B.
26、 C. D. 3. Let denote the Fourier transform of a signal , the Fourier transform of is ( ).A. B. C. D. 4. Let denote the Fourier transform of signal , the Fourier transform of is ( ).A. B. C. D.5. The Fourier transform of the rectangular pulse is ( ).A. B. C. D. 6. The condition for signal transmissio
27、n with no distortion is that ( ). A. The magnitude response is a constant in the passband.B. The phase response is a line cross the origin in the passband.C. The magnitude response is a constant and the phase response is a line cross the origin in the passband.D. The phase response is a constant and
28、 the magnitude response is a line cross the origin.7. The bandwidth of a signal is 20KHz, the bandwidth of signal is ( ).A.20KHz B.40KHz C.10KHz D.30KHz8. Let denote the Fourier transform of signal , the Fourier transform of is ( ).A.B. C. D. 9. Let denote the Fourier transform of signal , the Fouri
29、er transform of is ( ).A. B. C. D. 10. Let denote the Fourier transform of signal, then ( ).A. 2 B. C. D. 411. Let denote the Fourier transform of signal , the Fourier transform of is ( ).A B C D12. Let denote the Fourier transform of signal , the Fourier transform of is ( ).A. B. C. D. 13. The Four
30、ier transform of signal is ( ).A. B. C. D. 14. Let and . The Fourier transform of y(t) is ( ).A. B. C. D. 15. Consider the square wave , as decreases, the width of the main lobe of ( ).A. increases B. decreases C. does not change D. can not be determined 16. It is known that the bandwidth of x(t) is
31、, the bandwidth of is ( ).A. B. C. D. 17. The inverse Fourier transform of is ( ).A. B. C. D. 18. The Fourier transform of signal is , then the Fourier transform of signal is ( ).A. B. C. D. 19. Given an LTI system with its frequency response , it is known that the Fourier transform of the output re
32、sponse y(t) is , the input signal =( ).A. B. C. D. 20. The frequency response of an ideal lowpass filter is , its unit impulse response is h(t) = ( ).A. B. C. D. 三、综合题(分析、计算)1. Consider a continuous-time LTI system whose frequency response is If the input to this system is a periodic signal with per
33、iod T = 8, determine the corresponding system output y(t).Figure 22. The fundamental frequency of a continuous-time periodic signal is 0 = , Figure 2 shows the spectral coefficients of x(t). (a) Write out the expression of x(t).(b) If x(t) is applied to an ideal highpass filter with frequency respon
34、se , determine the output signal y(t).3. Figure 3.a illustrates a communication system. Let X1(j) and X2(j) denote the Fourier transforms of x1(t) and x2(t), respectively. It is known that 1 = 4, 2 = 8, and the frequency response of the ideal bandpass filter is H1(j), the overall output response is
35、y(t). (1). Plot the magnitude of the Fourier transform W(j) of w(t). (2). Choose an appropriate frequency 3, so that the output response is y(t) = x1(t);(3). Plot the magnitude responses of H1(j) and H2(j).Figure 3 (a)(b)Figure 44. Figure 4 shows the Fourier transform of a periodic continuous-time s
36、ignal .(1). Write out the expression of .(2). Let be the frequency response of an ideal lowpass filter, and is applied to the filter, determine the output response y(t) of the filter.。5. For a causal LTI system, the input and output signals are , , respectively.(1). Determine the frequency response
37、.(2). Determine the unit impulse response .(3). Determine the differential equation describing the input-output relationship of the system.6. The frequency response of an ideal bandpass filter is , the unit impulse response is denoted as h(t), we now have that , determine .7. A continuous-time signa
38、l is sampled by the impulse train getting , where, = 0.5s.(1). Plot the Fourier transform of .(2). Plot the Fourier transform of .(3). Let be the frequency response of an ideal bandpass filter. If is applied to the filter, the output response is denoted as y(t), plot the Fourier transform of y(t).(4
39、). By observing, write out the expression of .图48. Figure 8 illustrates a communication system, The Fourier transforms of the input and output signals and are denoted as and , respectively. If x(t) = cos(0.5t), determine y(t) and plot .Figure 89. Let X(j) denote the Fourier transform of the signal x
40、(t) depicted in Figure P4.25.Figure P4.25.a.(a). Find .(b). Find .(c). Evaluate .(d). Evaluate .(e). Evaluate .(f). Sketch the inverse Fourier transform of Re X(j).Note: You should perform all these calculations without explicitly evaluating X(j).10. Consider an LTI system whose response to the inpu
41、tis (a). Find the frequency response of this system.(b). Determine the systems impulse response.(c). Find the differential equation relating the input and the output of this system.11. Let Assuming that x(t) is real and X(j) = 0 for | 1, show that there exists an LTI system S such that x(t)g(t).(Not
42、e: find the relationship between x(t) and g(t)第三部分:信号与系统的s域分析一、填空题1. The ROC of the Laplace transform is , then the inverse transform is = ( ).2. It is known that the LTI system described by is stable, then the ROC of H(s) is ( ).3. The system function of a causal LTI system is , then the differenti
43、al equation describing the input-output relationship of the system is ( ).4. The Laplace transform of signal is ( ), the associated ROC is ( ).5. Assume that the system function of an anticausal LTI system is , then the frequency response ( ), the unit impulse response ( ).6. It is known that a caus
44、al continuous-time LTI system H(s) is stable, then all of the poles of H(s) are located in ( ).7. It is known that the Laplace transform of signal x(t) is , then ( ).8. The differential equation describes the input-output relationship of an LTI system, then the system function is H(s) = ( ).9. The L
45、aplace transform of a causal signal x(t) is denoted as X(s), then the Laplace transform of signal is ( ).10. Given a continuous-time LTI system, it is known that the zero-state response to arbitrary input x(t) is x(t-t0), t0 > 0, then the system function of the system is H(s) = ( ).11. The Laplac
46、e transform of a continuous-time signal x(t) is , then x(t) = ( ).12. Figure 1.12 illustrates an LTI system, its system function is H(s) = ( ).+-+23Figure 1.1213. It is known that a causal continuous-time LTI system with system function is stable, then the coefficient a must satisfy: ( ).14. Given t
47、wo signals and , and , then the Laplace transform of y(t) is Y(s) = ( ).15. A causal continuous-time LTI system has rational system function H(s). The sufficient and necessary condition for which the system is stable is that all of the poles of H(s) are located in the ( ) of the s-plane.二、选择题1. The
48、Laplace transform of signal is ( ).A. B. C. D. 2. The system function H(s) of an LTI system has two poles at p1 = -3, p2 = -1, and one zero at z = -2 in the finite s-plane. It is known that H(0) = 2, then the system function is ( ).A. B. C. D. 3. The Laplace transform of signal is , then the ROC of
49、X(s) is ( ).A. B. C. D. 4. Let with its ROC: , then the inverse Laplace transform is x(t) = ( ).A. B. C. D. 5. The system function of an LTI system is , then the system is ( ).A. causal and stableB. causal and unstableC. anticausal and stableD. anticausal and unstable6. The Laplace transform of sign
50、al is , then the ROC of X(s) is ( ).A. B. C. D. 7. The system function of an LTI system is, then impulse response of the system is ( ).A. B. C. D. 8. The system function of a causal LTI system is , then the system is ( ).A. stableB. unstableC. critical stable (临界稳定)D. indeterminacy9. The unit step r
51、esponse of a continuous-time LTI system is then the system function of the system is H(s) = ( ).ABCD10. The Laplace transform of a causal signal x(t) is , then x(t) = ( ).A. B. C. D. 11. A continuous-time LTI system can be described by its system function H(s), and it is known that the frequency response H(j) exists, then the system must be ( ).A. time-invariant B. causal C. stable D. linear12. Let , then the Laplace transform of y(t) is Y(s) = ( ).
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