Basic inclined plane

Function

Intended for experimental study, physics laboratory and the performance of physics experiments on: Physics. Solid mechanics. Kinematics. Reference, position, movement and trajectory. The moving body. The trajectory and displacement. The difference between displacement and distance traveled. The Cartesian reference system in the plane, Cartesian plane. Scalar quantity. Vector quantity. The MRU and its characteristics. What is uniform rectilinear motion (MRU)? The meeting of two moving objects in MRU with opposite directions. Progressive uniform rectilinear motion (MRU). Progressive MRU (moving away from the origin). Retrograde MRU (moving towards the origin). Solution of the meeting point by overlapping graphs. Relative percentage error. Dynamics. The forces of friction and Newton's first law of motion. Static friction. The coefficient of static friction. Friction versus Newton's first law of motion. The kinetic friction force. Determining the coefficients of static and kinetic friction for sliding on an inclined plane. The coefficient of kinetic friction for sliding as a function of the tangent of the angle of inclination. The coefficient of kinetic friction for sliding for a metal test body. The effect of lubricants on the coefficients of static and kinetic friction. Statics. The force, resisting force, and mechanical advantage of an inclined plane, a simple machine. Measuring weights and masses. The resisting force. The driving force. The driving force acting on a body on an inclined plane, depends on the angle of the ramp. Measuring driving forces for different ramp angles. The inclined plane is a simple machine. Determining the mechanical advantage of an inclined plane. The equilibrium conditions of a body on an inclined plane. Measuring masses. The force of gravity of a body is directly proportional to its mass. The equilibrium of a material body (point mass) under the action of coplanar forces. Measuring and calculating forces. Diagram of coplanar forces. The balancing forces on the x and y axes. The condition for a material body (point mass) to be in equilibrium is based on Newton's first law. The value of the driving force depends on the angle of inclination, the mass involved, and the gravitational acceleration. How to calculate the relative percentage error, etc. Note: Does not include measuring instrument for time intervals.