The design of modern machines

The future of mechanical engineering

The relationship between efficiency, mechanical advantage, and velocity ratio

The history of machines

The ratio of input to output

The ratio of output to input

The sum of input and output

The difference between input and output

The power consumption of the machine

The distance moved by the machine

The ratio of load lifted to effort applied

The speed of the machine

The ratio of distance moved by the load to the distance moved by the effort

The ratio of distance moved by the effort to the distance moved by the load

The ratio of speed to time

The ratio of power to load

The difference between power and load

The sum of power and load

The product of load and distance moved by the load

The product of power and distance moved by the effort

The difference between work done by and on the machine

The sum of work done by and on the machine

Work done on the machine divided by work done by the machine

Work done by the machine divided by work done on the machine

Efficiency = Mechanical Advantage + Velocity Ratio

Efficiency = Mechanical Advantage * Velocity Ratio

Efficiency = Mechanical Advantage / Velocity Ratio

Efficiency = Mechanical Advantage - Velocity Ratio

As a decimal

As a ratio

As a percentage

As a fraction

Mechanical advantage is the sum of efficiency and velocity ratio

Mechanical advantage is unrelated to efficiency and velocity ratio

Mechanical advantage is the product of efficiency and velocity ratio

Mechanical advantage is the difference between efficiency and velocity ratio