For question 22 please answer Part A & D

(4%) Problem 22: A block of mass m is located on an inclined plane that makes an angle 0 with the horizontal. The coefcient of kinetic friction between the block and the inclined plane is it] . The block presses against, but is not attached to, a spring with constant k1 . When the spring is at its equilibrium position, the block is at a height h above the ground, as shown. The initial position of the block, from which it is released, is a bit further up the inclined plane such that the spring is initially compressed by Ax. At the bottom of the inclined plane is a horizontal plane with a different coefcient of friction, it: , for the rst distance, cl, after which the surface is frictionless, and the equilibrium position of a spring with constant k2 is encountered - .' lilctwpt'rtiuxmn Q 25% Part (3) Suppose that numeric values are chosen such that the block comes to rest before reaching the bottom of the ramp. Let x be the distance traveled from the equilibrium position of the block towards the bottom of the ramp. Enter an expression for x. Grade Summary X = i Deductions Potential 101] % Submissions Attempts remaining: 7 (_ per attempt) detailed view Submit Hint I I give up] Hints: deduction per hint. Hints remaining: _ Feedback: deduction per feedback. Submission History AH Dare time's m? di.tpi1l_\\1'cfi11 Central .S'liutu'wn' Trme .Rri! submission date time's [minute i'tirs' work Date Time Answer Hints Feedback ' - etween the block A 25 % Part (d) The block travels a distance d: 0.19 111 along the surface with friction coefcient [12- 7 0.13. The horizontal surface then becomes frictionless, at the equilibrium position of a spring with constant k2 - 7. 5 N/m. Calculate the distance As in meters ,by which the spring is compressed as the block comes to rest