4. Determine the transfer function G(s) = for the system shown below. F(s) K1 = 4...
5. Find the transfer function X (3) F(s) and X:(5) F(s) for the mechanical system below Kj = 4 N/m *(1) K2 = 5 N/m 00002 0000 = 3 N-s/m M =1 kg|fv2 = 3 N-s/m M2 = 2 kg Svz = 2 N-s/m E
For a mass-spring-damper mechanical systems shown below, x200) K1-1 N/m 0000 -X,(0) K-1 N/m 00004 = 1 N-s/m fr2 M1=1 kg = 2 N-s/m M2 -1 kg 13 = 1 N-s/m 1. Find the differential equations relating input force f(t) and output displacement xi(t) and x2(C) in the system. (40 marks) (Hint: K, fy and M are spring constant, friction coefficient and mass respectively) 2. Determine the transfer function G(s)= X1(s)/F(s) (20 marks)
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...
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
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 =
1. Obtain the transfer function G(s)-20 Consider the system of Figure 1. Obtain the transfer function G (s) - of the system in Figure 1 (clearly show the derivation of the model) Question 1.(15) Consider the system of Figure T(s) TO) J1 2 kg-m D1 1 N-m-s/rad J2-1 kg-m2 D2 2 N-m-s/rad K = 64 N-m/rad J-16 kg-m2 D3 32 N-m-s/rad Figure 1 1. Obtain the transfer function G(s)-20 Consider the system of Figure 1. Obtain the transfer function G...
Q2. Derive the governing differential equations for the systems shown in the following figures. fv=4 N-s/m K=5 N/mfv = 4N-s/m 000 M1 4 kg f)_ M2 4 kg fv2 4 N-s/m fv= 4 N-s/m (a) fit) Frictionless N/m -xj(t) O000 16 N-s/m 15 N/m 0000 4 N-s/m M1 8 kg M2-3 kg Frictionless Frictionless (b) Q2. Derive the governing differential equations for the systems shown in the following figures. fv=4 N-s/m K=5 N/mfv = 4N-s/m 000 M1 4 kg f)_...
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
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
2. For the system shown below find: a. The transfer function G(s) X(s)/F(s) b. Ç, con, %OS, Ts, and Tp. 33 N/ xuf fit) 15 N-s/m