-1 -1 -1 yIn] -1 LTI systemas shown in the 4. Given a causal signal flow graph above where the coefficient r is real: (a) Determine the system function, H(z).(5) (b) Determine a minimummultiply I...
FE x[n] -1 4. Given a causal LTI system as shown in the signal flow graph above where the coefficien t r is real: (a) Determine the system function, H (z). (5) (b) Determine a minimum multiply I/O difference equation. (5) (c) Is the system linear phase? Yes or No and why! (10) FE-5 5/13/2019 EENG751 FE x[n] -1 4. Given a causal LTI system as shown in the signal flow graph above where the coefficien t r is real:...
can you please post the answer thanks FE yIn] x[n] -2 3. Given the causal LTI system with signal flow graph as shown (a) Determine the system function H(z) (5) (b) Determine the minimum multiply linear constant coefficient /O difference equation relating y[n] with x[n]. (10) EENG751 5/13/2019 FE yIn] x[n] -2 3. Given the causal LTI system with signal flow graph as shown (a) Determine the system function H(z) (5) (b) Determine the minimum multiply linear constant coefficient /O...
FE In] -1 -1 3. Given the causal LTI system with signal flow graph as shown: (a) Determine the system function H(z) (5) (b) Determine the minimum multiply linear constant coefficient 1/O difference equation relating [n] with x[/n]. (10) FE-4 EENG751 5/13/2019 FE In] -1 -1 3. Given the causal LTI system with signal flow graph as shown: (a) Determine the system function H(z) (5) (b) Determine the minimum multiply linear constant coefficient 1/O difference equation relating [n] with x[/n]....
A causal LTI system has the signal flow graph shown in Fig. 5. Answer the following related questions. x[n] 0.5 yin] 5 Fig. 5 a) Determine the difference equation of the above system. b) Determine the system function H(-) of the above system. c) Draw the direct form I signal flow graph implementation of the above system using the difference equation obtained from part (a). d) Which signal flow graph is better for implementation (the one in Fig. 5, or...
An LTI system has the signal flow graph shown below. Answer the following related questions. .3 a) Determine the relation(i.e., difference equation) between x[n] and w[n] b) Determine the relation (i.e., difference equation) between win] and y[n] c) Determine the difference equation of the above system (i.e., overall system) d) Determine the system function of the overall system. Plot the pole-zero diagram. If this is known to be a non-causal and non-stable system, indicate the ROC. e) Draw the direct...
please reply asap. kindly, check the negative signs or any decimals too. please.... 2. Given a causal real LTI system with 1-4z system function H(z)- 1+2z Calculate Hmi and Hz) such that H (z) = H min(2)H AP(2) where Hmn Z)is a minimum phase system and HIP(2) is an allpass system Draw the SFG for the final cascaded system with the minimum multiplica tions. (30 Points) 2. Given a causal real LTI system with 1-4z system function H(z)- 1+2z Calculate...
7. A causal LTI system has a transfer function given by H (z) = -1 (1 4 The input to the system is x[n] = (0.5)"u[n] + u[-n-1] ) Find the impulse response of the system b) Determine the difference equation that describes the system. c) Find the output y[n]. d) Is the system stable?
(2) Consider the causal discrete-time LTI system with an input r (n) and an output y(n) as shown in Figure 1, where K 6 (constant), system #1 is described by its impulse response: h(n) = -36(n) + 0.48(n- 1)+8.26(n-2), and system # 2 has the difference equation given by: y(n)+0.1y(n-1)+0.3y(n-2)- 2a(n). (a) Determine the corresponding difference equation of the system #1. Hence, write its fre- quency response. (b) Find the frequency response of system #2. 1 system #1 system #2...
Consider an LTI system for which the input rn] and the output yin] satisfy the linear onstant-coefficient difference equation 2 Please determine the algebraic equation system function H(). (5 points) 2. Please determine the poles and zeros. (5 points) 3. Please determine the impulse response hin]. (Hint: Please discuss two cases de pending on the region of convergence. (10 points) Consider an LTI system for which the input rn] and the output yin] satisfy the linear onstant-coefficient difference equation 2...
A causal LTI system is described by the following difference equation: y(n) – Ay(n-1) - 2A2y(n − 2) = x(n) – 2x(n-1) + x(n–2), where A is a real constant. Determine the z-domain transfer function, H(z), of the system in terms of A.