Question 1: (25marks) Determine whether each of the following represents a BIBO (Binary Input/Binary Output) stable...
8. Determine whether the following LTIC systems are BIBO stable and explain why or why not (a) hi(t)8(t) etu(t), (b) h2(t) -26(t-3)-te5u(t) 9. Consider the following zero-state input-output relations for a variety of systems. In each case, determine whetheir the system is zero-state linear, time invariant, and casual t-2 r2 (b) (t) f(12)dr Page l of ï 8. Determine whether the following LTIC systems are BIBO stable and explain why or why not (a) hi(t)8(t) etu(t), (b) h2(t) -26(t-3)-te5u(t) 9....
A system is BIBO (bounded-input, bounded-output) stable if every bounded input X(t) yields a bounded output y(t). A system is NOT BIBO stable if there exists any bounded input that results in an unbounded output. By "bounded", we mean that the magnitude of the signal is always less than some finite number. (The signal x(t)=sin(t) would be considered a bounded signal, but X(t)t would not be a bounded signal.) Signals that are infinite in time, but with a magnitude that...
2. Circle the causal BIBO stable ROC below. a) 1.1<\리<1.2 b) Izk1/201zP1/2 d) 0.5<Izl<0.9 e) none above 3. A linear time-invariant IIR system is always BIBO stable a) True b) False 4. If a fiter has z-transform H(z)05, then the fiter s ;z>0.5, then the filter is zz-0.5z a) Nonlinear b)FIR )R d) two-sided e) none above 5. The discrete-time frequency o in rad/ sample of the sinusoid hin] below is d) T2 e) none above hIn] -1
3) For each of the following systems with input xfin] and output y/nl, determine whether it is linear, time invariant, causal, and/or stable. lineax - time-varient
Please show detailed steps, thank you! 1. The transfer function of a BIBO stable discrete system is given as H(z) = In((1-1.2z-1)(1-0.9z-1)) (a) Find h(n). (b) Find the ROC for H(z). (c) Find the pole-zero location for the system W(z) = dH(z) 2an (d) If x(n)-2 cos(EN, } 3 r(n-6), goes through the H(z) system above, find y(n).
Solve these examples in detailed step wise EXAMPLE 3.4.5 Determine the partial-fraction expansion of the proper function X(2) = 1- 1.52-1 +0.52-2 EXAMPLE 3.4.7 Determine the partial-fraction expansion of (1+z-1)(1 - 2-1)2 EXAMPLE 3.4.8 Determine the inverse z-transform of X (2) = 1-1.52-1 +0.52-? (a) ROC: Iz/ > 1 (b) ROC: Iz1 <0.5 (e) ROC: 0,5 < Iz <1 EXAMPLE 3.4.10 Determine the causal signal x(n) having the z-transform X(z) = (1 + 2-1) (1 - 2-1)2 EXAMPLE 3.5.2 A...
determine whether 20 total pts] For each of the following systems described by their input-output behavior, or not the system is (1) linear,(2) time-invariant, (3) causal. For each case, make sure that you explain why. a. (5 pts] y[n] Axn] +B where A and B are nonzero constants d. 5 pts] y[n] x[n cos(0.25n)
Assume amplitude a = 4 The input to an LTI system is shown in the graph below. Assume a = 4. X(t) 20 t @ by 0 Ingineering Given that the Laplace transform of the output is Y(s) = - (s + 3)(1 – e-45)2 s(s + 5)2 a) Find the transfer function of the system and the region of convergence for o = Re(s). H(s) = RoC: For regions of convergence, answer in interval notation e.g. (-INF, a),(a,b) or...
1. Consider a discrete-time system H with input x[n] and output y[n]Hn (a) Define the following general properties of system H () memoryless;(ii BIBO stable; (ii) time-invariant. (b) Consider the DT system given by the input-output relation Indicate whether or not the above properties are satisfied by this system and justify your answer.
signals and systems How to solve if coefficients are: A= -2 B = 1 C = 2 zBzC (b) (24 points) For the additional information given in each case below, determine the output ya for all n. (i) The system is causal and ipatn Inl (ii) The system is stable and input z--1 ii) The system is causal and stable, while the (bilateral) a-transform of input n has ROC of al<1 In (c) (8 points) For the (non-causal) system implied...