What is the angular velocity ω2 of the pendulum immediately after the impact? b) What is the maximum angular deflection θ of the pendulum after the impact? c) Assume another case for the system at the same time instant given in Figure 1. This time the metal ball hits the block A with the same speed (v = 250 m/s), but with an angle of β = 0◦ However, this time, the coefficient of restitution is e = 0.6 (so they do not become embedded). Determine the velocities of the metal ball and the block just after the collision, and calculate the loss of energy during the collision.

What is the angular velocity ω2 of the pendulum immediately after the impact? b) What is the maximum angular deflection θ of the pendulum after the impact? c) Assume another case for the system at the same time instant given in Figure 1. This time the metal ball hits the block A with the same speed (v = 250 m/s), but with an angle of β = 0◦ However, this time, the coefficient of restitution is e = 0.6 (so they do not become embedded). Determine the velocities of the metal ball and the block just after the collision, and calculate the loss of energy during the collision.

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