Problem #2 Find the (a) Thevenin's equivalent and (b) the Norton's equivalent for the subsystem enclosed in dashed lines for the system shown. Then (c), use either of these equivalents to fin...
Problem #2: In the circuit shown below use Thevenin's equivalent circuit method to determine: a) The output current lo b) How is the maximum power delivered to the load? © 24V
Problem #2: In the circuit shown below use Thevenin's equivalent circuit method to determine: a) The output current lo. b) How is the maximum power delivered to the load? 12K M - 12v 0 Gama 6 24V
C(8) for the system shown in Figure 1. R(S Find the equivalent transfer function, Geg (s) 1 Cix) Figure 1. Block diagram 2s+1 s(5s+6Ge(s) = and Figure 2 shows a closed-loop transfer function, where G(s) 2. proper H(s) K+s. Find the overall closed-loop transfer function and express is as rational function. C(s) Ea (s) Controller R(s) +/ Plant G(s) Ge (s) Feedback H(s) Figure 2. Closed loop transfer function Construct the actuation Error Transfer Function associated with the system shown...
4, (a) (20%) Find the transfer function Xi(s) / U(s) for the system shown in Fig. 2. (b) (20%) obtain a state-space model of the system shown in Fig. 2, where u is the input and x is the output. k2 kj m2 b2
Question 13 For the control system shown below the input signal is x(C) and the output signal in ), the fransfer function is 10s +50 s +12s+ 100 10s +50 o HCs)--S-10s + 150 10s +50 s2 + 22s 101 10s+50 H(s) HS)2 + 22s 150 50 O H(s)- s2 +22s 150 For the control system shown below the input signal is X() and the output signal is VCt), the transfer function is H(S)- HS) 3 +252 +51 Question 1...
4 C(s) حرام | A system has a block diagram as shown. The input is "R(s) and the output is C(s). a) Using only the block diagram reduction method, R(S) find the transfer function of the system. b) Determine the characteristic function and the order of the system c) Find the characteristic roots of the system. d) Find the natural frequency of the system. e) Find the damped natural frequency of the system. 8 * NOTE: All stages of block...
c(s), A system has a block diagram as shown. The input is R(s) and the output is C(s). a) Using only the block diagram reduction method", find the transfer function of the system. b) Determine the characteristic function and the order of the system. c) Find the characteristic roots of the system. d) Find the natural frequency of the system. e) Find the damped natural frequency of the system. 8 * NOTE: All stages of block diagram reduction must be...
1. 4 R(S) 1 s 1 S C(s) b) A system has a block diagram as shown. The input is R(s) and the output is C(s). a) Using only the block diagram reduction method*, find the transfer function of the system. Determine the characteristic function and the order of the system c) Find the characteristic roots of the system. Find the natural frequency of the system. e) Find the damped natural frequency of the system. 8 *NOTE: All stages of...
3. Consider an LTI system with transfer function H(s). Pole-zero plot of H(s) is shown below. Im O--- Re (a) How many ROCs can be considered for this system? (b) Assume system is causal. Find ROC of H(S) (c) Assume y(t) is system output with step unit as input. Given lim yết) = 5 , Find H(s). (d) (optional) Find y(2) (y(t) for t = 2).
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...