Non-Inertial Reference

A wheel of radius R rolls without slipping along a straight line on a horizontal surface at a constant speed v. A small pebble of mass m is gently placed on the top of the wheel. The coefficient of static friction between the pebble and the wheel is μ.

A uniform rubber band of mass $m$, natural radius $r_1$, and stiffness coefficient $k$ is placed horizontally on a vertical cylinder of radius $r_2$ ($r_2 > r_1$). The mass distribution of the band remains uniform. The coefficient of static friction between the band and the cylinder is $\mu$. The cylinder rotates about its vertical axis with angular velocity $\omega$.

A double pendulum system consists of two inextensible light strings of lengths $l_1$ and $l_2$, and two small balls A and B with masses $m_1$ and $m_2$ respectively. Ball A is is connected with string $l_1$ from the ceiling, and ball B is at the bottom, connected to ball A via string $l_2$. The system is initially in a vertical equilibrium position. A third ball C, also with mass $m_1$, collides elastically with ball A at a horizontal velocity $v_0$.

Two conveyor belts are in the same horizontal plane, moving perpendicularly to each other. Belt 1 moves at speed $v_1$, and belt 2 moves at speed $v_2$. An object of mass $m$ is delivered from belt 1 onto belt 2. The coefficient of kinetic friction between the object and the belts is $\mu$. The point where the object lands on belt 2 is the origin O of a stationary coordinate system, with belt 1's motion along the x-axis and belt 2's motion along the y-axis. The belts are sufficiently wide.

An inclined plane with side ratios 3:4:5 is fixed on a horizontal turntable. A wooden block is placed on the inclined plane and remains stationary at a distance $r = 40$ cm from the center of the turntable. The coefficient of static friction between the block and the plane is $\mu_s = 1/4$.

A wedge ABC of mass $M$ and height $h$ has an inclined surface AC with an angle $\theta$. A small object of mass $m$ is placed at the top A and slides down from rest. All contact surfaces are frictionless. Find:

A curved section of railway track has a radius of curvature $r$. The distance between the two rails is $L$, as shown in the figure.