25- for the following systems trasfer functions determines the stability of the system (s2 + 4)2(s+5)
D. Question 4 Evaluate the stability of the systems with each of these transfer functions: H(s) =-100 8+200 . H (s)=804 H(s) 15s . H(s)=7741029 2 +4s+29 3s2+12 s2-4s+29
control systems
1) Using Routh Hurwitz Stability Criteria, determine whether the following system of equation is stable or not. a) S4+253+3S2+45+5=0 2) Using the Routh Hurwitz stability criterion, determine the range of K for stability of the following characteristic equation. a) s4+2s8+(4+K)s2+9s+25=0 3)Sketch the root-locus of the following systems a) G(s)H(s) = s(s+1)(s+2) b) G(s)H(s) = 52(8+3.6) K(5+1)
2. (25 points) Consider the following characteristic equation: $4 +253 + (4 +K)s2 +95 + 25 = 0 Using the Routh stability criterion, determine the range of K for stability.
LTI Systems-Stability Consider an LTI system with system function: s-1 H (s) = If the system is non-causal and un-stable, determine the time domain impulse response
Find the inverse Laplace transform of each of the following functions. a. F(s) = 5 $4(s2 + 4) t f(t) = 2*4{F($)}(6) = dw b. G(s) = 4s (s + 5)2( 32 +81) g(t) = •{F()}(t) = dw
1. Evaluate stability of the following systems: a) A continuous time system described by the following transfer function: 4 2s2 +4s 5 b) A continuous time system described by the following transfer function (s-6)(5s3 +3s +7s + 1) c) A discrete time system described by the following transfer function: 0.3 (z-0.4) (z +0.7) d) A second order discrete time system with the following poles: z1 0.8+0.75i, z2 0.8-0.75i
Question 1- Plot the root loci for the closed-loop control systems with K s b) Gs)H(S)425+2 s2+2s+2 c) G (s)H(s) = K+22+2 K(s+2) K (s+6) K(s+18) K(s+4.5) = (s+5)(s2 +25+5) f) G (s)H(s) K (s2+3s+9) g) G (s)H(S)-(s+5)(s2+2s+s) h) G (s)H(s) = (s+5)(S2 + 25+5) i) G (s)H(s) = s(s+5)(s2+2s +5)
Question 1- Plot the root loci for the closed-loop control systems with K s b) Gs)H(S)425+2 s2+2s+2 c) G (s)H(s) = K+22+2 K(s+2) K (s+6) K(s+18) K(s+4.5) = (s+5)(s2...
Show all your work II of the following transfer functions. Also function represents a stable system. (5+2)(5-5) a. (s+4)(s2 +65)(s2+25) s(s+4)(s+7) b. (5-1)(s+7)(s+9) (S-2)(+3)(s2+16) (83+652-125)(s+1)(s2+4s+4) (2) Draw the frequency response for the following transfer functions: 10 (5+105)(s+107) a. (s+104)(s+108)
Question 4 Deduce the conditions for stability for a control system with the following configurations G, ($) (s + 1)(0.58 +1) Pl-controller with Kc = 5 and 7, = 0.25 Assume the transfer functions of the measuring device and final control elements equal 1. (ii) What will the stability be if a P-controller of the same gain is used instead?
Show all your work leading up to tne laT JUlu (1) Plot the poles and zeros of the following transfer functions. Also, identify if the transfer function represents a stable system. (20) (s+2)(s-5) (s+4) (s2+6s)(s2 +16) s(s+4)(s+7) (s+2) (s+3) (s2+9) (s2+4s2+13s) (s-1)(s2+10s+34) C. (22
Show all your work leading up to tne laT JUlu (1) Plot the poles and zeros of the following transfer functions. Also, identify if the transfer function represents a stable system. (20) (s+2)(s-5) (s+4) (s2+6s)(s2 +16)...