G(s) = K/(s+3)2 Determine the System Type (Step, Ramp, Parabola) and find the steady state error

Prove that the steady state error of type 2 feedback control system to unit step input...

Prove that the steady state error of type 2 feedback control system to unit step input is zero.

find the steady state response for the following system: y(k)-0.2y(k-1)+0.26y(k-2)=2u(k-1)-u(k-2) The input u(t) is not given.

find the steady state response for the following system: y(k)-0.2y(k-1)+0.26y(k-2)=2u(k-1)-u(k-2) The input u(t) is not given.

For the system below do what is asked, solve the manuscript calculations and do the step...

For the system below do what is asked, solve the manuscript calculations and do the step by step: Consider the system with unit feedback: G (s) = K / s * (s + 5) * (s + 20) The system without compensation has about 55% overrun and a peak instant of 0.5 seconds when Kv +10. Use frequency response methods to design a phase advance compensator to reduce the percentage overrun to 10%, keeping the peak instant and the steady...

A steady state error will not occur when there is a change to the set value...

A steady state error will not occur when there is a change to the set value with a control system operating in the mode: 1. Proportional 2. Proportional plus derivative 3. Derivative 4. Proportional plus integral

It turns out that the effect of a change in the savings rate on the steady-state...

It turns out that the effect of a change in the savings rate on the steady-state consumption is ambiguous. Let's try to show this with the power of algebra! Let A=2, L=100, and d=1/4 but do not pick a value for s. Solve for the steady-state values of K, Y and C by just leaving an "s" in there. This means that you will get functions of s as your answer! You should be able to look at K*(s) and...

please do this question just with matlab with bilinear transforming :Design digital controllers to meet the...

please do this question just with matlab with bilinear transforming :Design digital controllers to meet the desired specifications for the systems with the transfer function G(s)=1/((s+1)(s+5)) to obtain (i) zero steady-state error due to step, (ii) a settling time of less than 2 s, and (iii) an undamped natural frequency of 5 rad/s. Obtain the response due to a unit step and find the percentage overshoot, the time to the first peak and steady-state error percent due to a ramp...

1)Find the Inverse Laplace Transform of X(s) = (s-1)/((s+1)(s+2)^2) 2)A system with the transfer function H(s)...

1)Find the Inverse Laplace Transform of X(s) = (s-1)/((s+1)(s+2)^2) 2)A system with the transfer function H(s) = (s-5)/((s+1)(s+10)) a)If the input is 2u(t), find the steady-state output of the system.

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is...

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is given by f(t) = 4 for 0<t<2π, 4π<t<6π, 8π<t<10π, … etc f(t) = 0 for 2π<t<4π, …etc

what is the systems steady state response with an input of f(t)=30sin(10t), with transfer function G(s)=(1/2)/s^2+7s+10....

what is the systems steady state response with an input of f(t)=30sin(10t), with transfer function G(s)=(1/2)/s^2+7s+10. estimate phase angle in degrees

a) Find the steady-state vector for the transition matrix. .8 1 .2 0 x= ______ __________...

a) Find the steady-state vector for the transition matrix. .8 1 .2 0 x= ______ __________ b) Find the steady-state vector for the transition matrix. 1 7 4 7 6 7 3 7 These are fractions^ x= _____ ________