Derive an expression for the position min x of the block when it is closest to the motion sensor. Express your answer in terms of m, D, 0v , q , and physical constants, as appropriate. 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 in Suppose the ramp now has friction. The same block is projected up with the same initial speed 0v 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 f t . Explicitly label any intercepts, asymptotes, maxima, or minima with numerical values or algebraic expressions, as appropriate.
Derive an expression for the position min x of the block when it is closest to the motion sensor. Express your answer in terms of m, D, 0v , q , and physical constants, as appropriate.
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 in
Suppose the ramp now has friction. The same block is projected up with the same initial speed 0v 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 f t . Explicitly label any intercepts, asymptotes, maxima, or minima with numerical values or algebraic expressions, as appropriate.
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