Question

A motorcycle daredevil plans to ride up a 2.0-m-high, 20° ramp, sail across a 10-m-wide pool filled with hungry crocodiles, and land at ground level on the other side. He has done this stunt many times and approaches it with confidence. Unfortunately, the motorcycle engine dies just as he starts up the ramp. He is going 11 m/s at that instant, and the rolling friction of his rubber tires (coefficient 0.02) is not negligible. Does he survive, or does he become crocodile food? Justify your answer by calculating the distance he travels through the air after leaving the end of the ramp.

Accepted Answer

Step 1: Break the problem into two parts: (a) the motion of the motorcycle on the ramp and (b) the projectile motion after leaving the ramp. Start by analyzing the motion on the ramp. Use the work-energy principle to determine the velocity of the motorcycle at the top of the ramp. Account for the effects of rolling friction and gravitational potential energy. Step 2: Calculate the work done against rolling friction as the motorcycle moves up the ramp. The force of rolling friction is given by $$ F_{friction} = \mu \cdot m \cdot g \cdot \cos(	heta) $$, where $$ \mu  is $$the coefficient of rolling friction, $$ m  is $$the mass of the motorcycle and rider, $$ g  is $$the acceleration due to gravity, and $$ 	heta  is $$the angle of the ramp. The work done is $$ W_{friction} = F_{friction} \cdot d $$, where $$ d  is $$the length of the ramp. Step 3: Determine the gravitational potential energy gained by the motorcycle as it ascends the ramp. This is given by $$ U = m \cdot g \cdot h $$, where $$ h  is $$the height of the ramp (2.0 m). Subtract the work done against friction and the potential energy from the initial kinetic energy $$ KE = \frac{1}{2} m v^2  to $$find the remaining kinetic energy at the top of the ramp. Step 4: Use the remaining kinetic energy at the top of the ramp to calculate the velocity of the motorcycle as it leaves the ramp. The velocity components can be broken into horizontal and vertical components using trigonometry: $$ v_x = v \cdot \cos(	heta) $$ and $$ v_y = v \cdot \sin(	heta) . $$Step 5: Analyze the projectile motion of the motorcycle. Use the vertical motion equation $$ y = v_y t - \frac{1}{2} g t^2  to $$find the time of flight, where $$ y  is $$the vertical displacement (0 m since it lands at ground level). Then, use the horizontal motion equation $$ x = v_x t  to $$calculate the horizontal distance traveled. Compare this distance to the width of the pool (10 m) to determine if the daredevil survives.

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Key Concepts

Kinematics

Projectile Motion

Energy Conservation