A small ball with a mass of 0.1kg is suspended on the top of the inclined plane with an inclination angle of 37 ° by a thin wire, as shown in Figure 11. When the system is stationary, the rope is parallel to the inclined plane, A small ball with a mass of 0.1kg is suspended at the top of the inclined plane with an inclination of 37 degrees by a thin wire. The static state of the system is that the rope is parallel to the inclined plane, regardless of all friction, and the system accelerates. When the accelerations are 5m / s, 10m / s and 24m / s respectively, what are the pulling forces on the rope I just don't want to forget it,

A small ball with a mass of 0.1kg is suspended on the top of the inclined plane with an inclination angle of 37 ° by a thin wire, as shown in Figure 11. When the system is stationary, the rope is parallel to the inclined plane, A small ball with a mass of 0.1kg is suspended at the top of the inclined plane with an inclination of 37 degrees by a thin wire. The static state of the system is that the rope is parallel to the inclined plane, regardless of all friction, and the system accelerates. When the accelerations are 5m / s, 10m / s and 24m / s respectively, what are the pulling forces on the rope I just don't want to forget it,

In motion, the ball is subjected to downward gravity (downward direction) \ \ rope pull (along the direction of rope) \ \ inclined plane supporting force (perpendicular to the inclined plane upward). The resultant force of these forces constitutes the force to promote the forward acceleration of the ball, the size of which is mass * plus