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

Determine if pure resonance occur in the following undamped mass-spring system my''+ ky = f(t) where...

Determine if pure resonance occur in the following undamped mass-spring system my''+ ky = f(t) where m = 1kg, k = 9N/m and the driving force f(t) is given by the 2π-periodic function f(t) = ( −1, 0 < t < π 1, π < t < 2π

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

6. Consider a causal linear system whose (zero-state) response to an input signal, f(t) = e...

6. Consider a causal linear system whose (zero-state) response to an input signal, f(t) = e −3tu(t), is y(t) = (−e −t + 4e −2t − 3e −3t )u(t). ( a) Find the transfer function H(s) of the system. (b) Write the differential equation that describes the system. (c) Plot the pole-zero diagram of system. Is the system stable? (d) Plot the frequency response of the system, |H(w)|. (e) Whats the systems zero-state response to another input signal, f1(t) =...

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.

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

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

If the results of a steady-state stability analysis determine that the system isn't stable what system...

If the results of a steady-state stability analysis determine that the system isn't stable what system actions might be taken (for example, do you make changes to operating points, do you make system configuration changes, etc)? How about if it was the result of a transient stability analysis that predicted the system would not be stable?

The frequency response H(f) of a linear system is given by: , where f is frequency...

The frequency response H(f) of a linear system is given by: , where f is frequency in Hz. (repeat - y(f)/x(f) = H(f) = j2f ) Find the output y(t) of this system for a 10 Hz cosinusoidal input with an an amplitude of 3, i.,e . Again (x(t) = 3*cos(2*pi*10*t) A.) y(t) = 60*cos[2pi10t + (pi/2)] B.) y(t) = j60cos(2*pi*10t) C.) y(t) = 3*cos(2pi*60*t) D.) y(t) = 60*cos[2*pi*10*t - (pi/2)]

Determine the steady-state temperature distribution T(x,y, t -> ∞) in a 1m x 1m slab if...

Determine the steady-state temperature distribution T(x,y, t -> ∞) in a 1m x 1m slab if the flat surfaces are insulated and the edge (boundary) conditions are T(0,y)=0, T(x,0)=0, T(x,1)=100, ∂T(1,y)/∂x=0.

For the LTI system described by the following system functions, determine (i) the impulse response (ii)...

For the LTI system described by the following system functions, determine (i) the impulse response (ii) the difference equation representation (iii) the pole-zero plot, and (iv) the steady state output y(n) if the input is x[n] = 3cos(πn/3)u[n]. a. H(z) = (z+1)/(z-0.5), causal system (Hint: you need to express H(z) in z-1 to find the difference equation ) b. H(z) = (1 + z-1+ z-2)/(1-1.7z-1+0.6z-2), stable system c. Is the system given in (a) stable? Is the system given in...

Solve and plot the response of the model for 0<=t<=1.5, where input is f(t)=5t and the...

Solve and plot the response of the model for 0<=t<=1.5, where input is f(t)=5t and the initial conditions are zero. 3x'' + 21x' + 30x = f(t)