5. Find the transfer function X (3) F(s) and X:(5) F(s) for the mechanical system below...
Can you show step by step calculation. Thank you Find the transfer function X (5) F(s) and X2() for the mechanical system below F(8) X (1) Ki = 4 N/m K2 = 5 N/m 0000 0000 tvi = 3 N-s/m My = 1 kg fv2 = 3 N-s/m fin 2 N-s/m M2 = 2 kg fv3 =
4. Determine the transfer function G(s) = for the system shown below. F(s) K1 = 4 N/m + X(t) →xj(t) K = 5 N/m 0000 M = 1 kg 1v2 = 3 N-s/m M2 = 2 kg f(t) HHH
If possible can you show step by step because I'm new in this subject X1(S) X2(S) Find the transfer function and for the mechanical system below F(S) F(S) K1 = 4 N/m X;(1) K2= 5 N/m -X2(1) 0000 0000 fv1 = 3 N-s/m M1 =1 kg|v2 = 3 N-s/m M2 = 2 kg Sva= 2 N-s/m HE
question 1 Question 3 a) Develop the transfer function X (s)/F(s) of the mechanical system shown in Figure 3(a). Give and explain one example the real application where you can relate with this system. (5 marks) b) Routh's stability criterion is of limited usefulness in linear control systems analysis mainly because it does not suggest how to stabilize an unstable system. Thus, we should evaluate the stability range of a parameter value. Consider the servo system with tachometer feedback as...
a) Develop the transfer function X:(s)/F(s) of the mechanical system shown in Figure 3(a). Give and explain one example the real application where you can relate with this system. (5 marks) b) Routh's stability criterion is of limited usefulness in linear control systems analysis mainly because it does not suggest how to stabilize an unstable system. Thus, we should evaluate the stability range of a parameter value. Consider the servo system with tachometer feedback as shown in Figure 3(b). Evaluate...
θ2(s)/T(s) for the following rotational mechanical system Problem 4: Find the transfer function G(s) TO) N1 = 4 Di 1 N-m-s/rad N2 121 kg-m2 N3-4 D2-2 N-m-s/rad K 64 N-m/rad- N4 16 D3 32 N-m-s/rad -16 kg-m2 000
Find the transfer function, X1(s)/F(s) for the diagram below A consultant engineer is assigned by his manager to obtain the transfer function X1 F(s) for train carriage model as shown in Figure below. Given that K1 -5 N/m, K2 = 7 N/m, fv1 = 4 N-s/m.fv2 = 3 N-s/m.fv3 = 2 N-5/m and M1-M2 = 1kg. X1 (t) Xz(t) fv1 M fit Frictionless
For the system shown in Fig. 1, solve the following problems. (a) Find the transfer function, G(s)X2 (s)/F(s) (b) Does the system oscillate with a unit step input (f (t))? Explain the reason (c) Decide if the system(x2 (t)) is stable with a unit step input (f (t))? Explain the reason 1. 320) 8 kg 2 N/m 4N-s/m 2N-s/m Fig. 1 2. There are two suspensions for a car as shown in Fig. 2 (a) Find the equations of each...
Problem 2 Determine the transfer function 01(s)/M(s) for the shaft-gear mechanical system in the figure, where 1(s) and Ms) are the Laplace transforms of the angle 01(t) and of the moment m(t). Use the time-domain mathematical model of this system. Known are J1, ki, J2, c, k2, Ni and N2. N. 1000 0,m 0 000 N Problem 3 By using the transfer function 1(s)/Ms), determined in Problem 2, calculate and plot 01(t) using the step input command of MATLAB. Known...
Question 3 a) Develop the transfer function X. (s)/F(s) of the mechanical system shown in Figure 3(a). Give and explain one example the real application where you can relate with this system. (5 marks) b) Routh's stability criterion is of limited usefulness in linear control systems analysis mainly because it does not suggest how to stabilize an unstable system. Thus, we should evaluate the stability range of a parameter value. Consider the servo system with tachometer feedback as shown in...