AP Physics Review FRQ 2015

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AP Physics Review FRQ 2015 2015 Mech 1. A block of mass m is projected up from the bottom of an inclined ramp with an initial velocity of magnitude v 0. The ramp has negligible friction and makes an angle θ with the horizontal. A motion sensor aimed down the ramp is mounted at the top of the incline so that the positive direction is down the ramp. The block starts a distance D from the motion sensor, as shown above. The block slides partway up the ramp, stops before reaching the sensor, and then slides back down. (a) Consider the motion of the block at some time t after it has been projected up the ramp. Express your answers in terms of m, D, v 0, t, θ, and physical constants, as appropriate. i. Determine the acceleration a of the block ii. Determine an expression for the velocity v of the block. iii. Determine an expression for the position x of the block. (b) Derive an expression for the position x min of the block when it is closest to the motion sensor. Express your answer in terms of m, D, v 0, θ, and physical constants, as appropriate. 2015 Physics C: Mechanics FRQ page 1

(c) On the axes provided below, sketch graphs of position x, velocity v, and acceleration a as functions of time t for the motion of the block while it goes up and back down the ramp. Explicitly label any intercepts, asymptotes, maxima, or minima with numerical values or algebraic expressions, as appropriate. (d) After the block slides back down and leaves the bottom of the ramp, it slides on a horizontal surface with a coefficient of friction given by µ k. Derive an expression for the distance the block slides before stopping. Express your answer in terms of m, D, v 0, θ, µ k, and physical constants, as appropriate. (e) Suppose the ramp now has friction. The same block is projected up with the same initial speed v 0 and comes back down the ramp. On the axes provided below, sketch a graph of the velocity v as a function of time t for the motion of the block while it goes up and back down the ramp, arriving at the bottom of the ramp at time t f. Explicitly label any intercepts, asymptotes, maxima, or minima with numerical values or algebraic expressions, as appropriate. 2015 Physics C: Mechanics FRQ page 2

2015 Mech 2. A small dart of mass 0.020 kg is launched at an angle of 30 above the horizontal with an initial speed of 10 m/s. At the moment it reaches the highest point in its path and is moving horizontally, it collides with and sticks to a wooden block of mass 0.10 kg that is suspended at the end of a massless string. The center of mass of the block is 1.2 m below the pivot point of the string. The block and dart then swing up until the string makes an angle θ with the vertical, as shown above. Air resistance is negligible. (a) Determine the speed of the dart just before it strikes the block. (b) Calculate the horizontal distance d between the launching point of the dart and a point on the floor directly below the block (c) Calculate the speed of the block just after the dart strikes. 2015 Physics C: Mechanics FRQ page 3

(d) Calculate the angle θ through which the dart and block on the string will rise before coming momentarily to rest. (e) The block then continues to swing as a simple pendulum. Calculate the time between when the dart collides with the block and when the block first returns to its original position. (f) In a second experiment, a dart with more mass is launched at the same speed and angle. The dart collides with and sticks to the same wooden block. i. Would the angle θ that the dart and block swing to increase, decrease, or stay the same? Increase Decrease Stay the same Justify your answer. ii. Would the period of oscillation after the collision increase, decrease, or stay the same? Increase Decrease Stay the same Justify your answer. 2015 Physics C: Mechanics FRQ page 4

2015 Mech 3. A uniform, thin rod of length L and mass M is allowed to pivot about its end, as shown in the figure above. (a) Using integral calculus, derive the rotational inertia for the rod around its end to show that it is ML 2 3. The rod is fixed at one end and allowed to fall from the horizontal position A through the vertical position B. (b) Derive an expression for the velocity of the free end of the rod at position B. Express your answer in terms of M, L, and physical constants, as appropriate. An experiment is designed to test the validity of the expression found in part (b). A student used rods of various lengths that all have a uniform mass distribution. The student releases each of the rods from the horizontal position A and uses photogates to measure the velocity of the free end at position B. The data are recorded below. Length (m) 0.25 0.50 0.75 1.00 1.25 1.50 Velocity (m/s) 2.7 3.8 4.6 5.2 5.8 6.3 2015 Physics C: Mechanics FRQ page 5

(c) Indicate below which quantities should be graphed to yield a straight line whose slope could be used to calculate a numerical value for the acceleration due to gravity g. Horizontal axis: Vertical axis: Use the remaining rows in the table above, as needed, to record any quantities that you indicated that are not given. Label each row you use and include units. (d) Plot the straight line data points on the grid below. Clearly scale and label all axes, including units as appropriate. Draw a straight line that best represents the data. (e) i. Using your straight line, determine an experimental value for g. ii. Describe two ways in which the effects of air resistance could be reduced. 2015 Physics C: Mechanics FRQ page 6

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