Problem (1) Find the equivalent sampled impulse response sequence and the equivalent z-transfer function for the cascade of the two analog systems with sampled input 10 Hi(s) = s+6 (a) If the systems are directly connected (b) If the systems are separated by a sampler Problem (1) Find the equivalent sampled impulse response sequence and the equivalent z-transfer function for the cascade of the two analog systems with sampled input 10 Hi(s) = s+6 (a) If the systems are directly...
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...
Find the transfer function Y(s)/R(s) in the given SFG. Use fx to input your answer. H2 Н. L L2 G2 G3 G4 R(S) Gs GS G6 G7 Y(S) L3 L4 Ho H7 Using SFG, find the transfer function C(s)/R(s). Use fx to input your answer here. R(S) C(s) X x G1 H1 H2 Find the transfer function C/R for the given SFG. Use fx to input your answer. G1 X1 G2 X2 R С -H Reduce into a single transfer...
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 find the transfer function, H(s) o output B2 M2F input 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 find the transfer function, H(s) o output B2...
Consider the following reaction: H2 (g) + I2 (g) ⇌ 2 HI (g) Complete the following table. Assume that all concentrations are equilibrium concentrations in M. T(∘C) [H2] [I2] [HI] [Kc] 25 0.0355 0.0388 0.922 − 340 − 4.55×10−2 M 0.384 M 90.6 445 4.90×10−2 M 4.74×10−2 M − 50.2 Find Kc at 25 ∘C. Find [H2] at 340 ∘C. Find [HI] at 445 ∘C.
Find the transfer function for the network 2) and the transfer function Vogus for the network vilgw). Vigw) . 2/5 + If Nogw)
Find G(s)= H2(s)/Q(s) 1.- - For the system shown in the figure, ?+q> Tanque 2 Tanque HEMU H + hz H+hi * 0+2 Q1 +91 where Q(s) is the input liquid flow, H(s) is the height of tank 1, H2(S) is the height of tank 2. Qe(s) is the output liquid flow, R and R2 are the valves resistance and C and C2 are the capacitance of tank 1 and tank 2. Obtain the Block Diagram and the Transfer Function...
May 99, Weet Final EE 326 Control Systems (Q1) Find the closed loop transfer function of t Final p transfer function of the following arrangt (en C(o) and R) R(s) Gi C(8) 2Ga H1 H2 May 99, Weet Final EE 326 Control Systems (Q1) Find the closed loop transfer function of t Final p transfer function of the following arrangt (en C(o) and R) R(s) Gi C(8) 2Ga H1 H2
For the reaction N2(g) + 3 H2(g)→2 NH3(g), ∆rH=−45.94kJ/mol At 298K,∆rG=−32.8kJ/mol Estimate∆rG of the same reaction at 0C.
For the reactionN2(g) + 3 H2(g)−−→2 NH3(g),∆rH=−45.94kJ/mol.At 298K,∆rG=−32.8kJ/mol. Estimate ∆rG of the same reaction at 0C. Use Gibbs-Helmholtz equation.