Mechanical advantage equals resistance force.
Mechanical advantage the resistance force. Mechanical advantage is equal output force divided by input force.
Ideal Mechanical Advantage for an Inclined Plane is equal to the length of the incline divided by the height of the incline.
The mechanical advantage of a wedge in this case would be 1, as the input force is equal to the work done. This means that the wedge is not providing any mechanical advantage, as the force required is equal to the work accomplished.
radius of the wheel divided by the radius of the axle.
The mechanical advantage (MA) of a machine that has an output force equal to its input force is 1. This means that the machine does not provide any mechanical advantage, as the output force is equal to the input force.
mechanical advantage
Efficiency of a machine or mechanical advantage
The ideal mechanical advantage of a pulley system is two times the number of pulleys in the system. This is the amount of force required to get the system moving.
It only takes half the effort to move an object but twice the distance
To analyze the mechanical advantage of a pulley system, you calculate it by dividing the output force (load) by the input force (applied force). The mechanical advantage of a pulley system is equal to the number of rope sections supporting the load. More rope sections mean a greater mechanical advantage.
If a machine was 100 percent efficient, the AMA would be equal to the IMA. This is because in an ideal scenario where the machine loses no energy to friction or other factors, the AMA (actual mechanical advantage) would be the same as the IMA (ideal mechanical advantage).
The mechanical advantage of an inclined plane is equal to length divided by height (l/h). Therefore, if the length is less than than the height, the mechanical advantage would be less than one.