both 2 and 3 For the force system shown in Fig. 21.16, find the values of...
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...
The Space X engineering group has been asked to design a mission to send a satellite in orbit around the Earth. The satellite has a mass m_s = 500 kg, and the rocket has a mass m_R = 2000 kg. The satellite is required to revolve with an elliptic orbit around the Earth with velocity v_B = 25 km/s when it is located in point B, at a distance to the earth r_B = 10 Mm. Assuming the mass of...
1. There is a mass-spring-damper system as shown in Fig. 1 (a) Find the total response(x(t)). In addition, find the transient response and the steady state response in the total response. Assuming, the initial values are zero. (b) Draw the total response using MATLAB or Excel. 2 Ao Fig. 1 1. There is a mass-spring-damper system as shown in Fig. 1 (a) Find the total response(x(t)). In addition, find the transient response and the steady state response in the total...
For each system shown in Fig. 3, find the following: 3. The system type a. The appropriate steady-state error constant The input waveform to yield a non-zero constant error The steady state error with input from Part c b. c. d. Page 1 of 2 0(s 10 C(s) R(s) s(s+2) (s+ 4) System 0(s10 R(s) C(s) s(s+2) (s) System 2 Fig. 3
2. Determine the forces P and Q in the force system shown in the figure below. All the forces are in equilibrium YE) 50 lb
Q/1 For the force system shown below and by using both graphical and algebra solutions, determine: (a) The required tension force F3, if the resultant (R) of the three forces directed as shown below. (b) The corresponding magnitude of the resultant (R). F,? 65 35° 250 R F-75 kN W=5 kg
4) Consider the circuits shown in Fig. 3 represented both in the time domain and also in the s-domain. Determine the values of A, C, L, Ri, and R2 a) ( ② ) "A" is equal to (A) 8.2 V: (B) 4.2 V: (C) 4 V: (D) 82n(s) V. C is equal to (A) 25 F: (B) 4 F: (C) 40 mF: (D) 4 mF c) ( D -) "L" is equal to (A) 1.8s H: (B) īls H: (C)...
Find the critical load Por of the bar-spring system shown in Fig Q1 using (i) equilibrium approach; and (2) energy approach 1. ks1 ks2 Fig. Q1 Determine the post-buckling behaviour of the perfect system for ks1/ks2L2 0.01 and ks1/ks2l2 10 and discuss its stability behaviour. Find the critical load Por of the bar-spring system shown in Fig Q1 using (i) equilibrium approach; and (2) energy approach 1. ks1 ks2 Fig. Q1 Determine the post-buckling behaviour of the perfect system for...
Ill): The system shown in Fig. 3 is in equilibrium when ф :00. Knowing that initially ф-1500 and that block C is given a slight nudge when the system is in that position, determine the speed of the block as it passes through the equilibrium position ф-00. Neglect the weight of the rod. (20 points) 32 8 3S 2 Fig 3 5.3R Ill): The system shown in Fig. 3 is in equilibrium when ф :00. Knowing that initially ф-1500 and...
4) a) Simplify and then find the transfer function of the system shown in Fig. 2; b) Determine the position, velocity and acceleration error constants for the transfer function to be found in a) to the unit step, unit ramp and unit parabolic inputs; c) Model the system given in Fig. 2 by Mat Lab/Simulink if it is possible and plot the output variable to the unit step and ramp functions Fig. 2