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2(a) Peter who is on a moving trolley throws a ball to John (who is stationary) as shown in Fig. Q2 a. The trolley is moving at a constant speed of 3.4 m/s to the right. If the ball leaves the boy with a velocity of 5.4 m/s with the angle, Fig. Q2(a) (i) If John is to catch the ball, find the time taken for the ball to reach John. (5 marks) (ii) Find the distance, X m, between Peter and John at the start of the motion, when the ball leaves Peter. (5 marks) (iii) Find the position of Peter from John when the ball reach John. (5 marks)

2(a) Peter who is on a moving trolley throws a ball to John (who is stationary) as shown in Fig. Q2 a. The trolley is moving at a constant speed of 3.4 m/s to the right. If the ball leaves the boy with a velocity of 5.4 m/s with the angle, Fig. Q2(a) (i) If John is to catch the ball, find the time taken for the ball to reach John. (5 marks) (ii) Find the distance, X m, between Peter and John at the start of the motion, when the ball leaves Peter. (5 marks) (iii) Find the position of Peter from John when the ball reach John. (5 marks)

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2(a) Peter who is on a moving trolley throws a ball to John (who is stationary) as shown in Fig. Q2a. The trolley is moving at a constant speed of 3.4 m / s to the right. If the ball leaves the boy with a velocity of 5.4 m / s with the angle, Fig. Q2(a) (i) If John is to catch the ball, find the time taken for the ball to reach John. ( 5 marks ) (ii) Find the distance, X m , between Peter and John at the start of the motion, when the ball leaves Peter. ( 5 marks ) (iii) Find the position of Peter from John when the ball reach John. ( 5 marks )

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