## Instructions

Use this calculator to compute the power output of a servomotor. Enter the torque and angular velocity, select the appropriate units, and click "Calculate Power" to see the result.

The calculation uses the formula: P = T * ω, where:

- P is the power output in Watts (W)
- T is the torque in Newton-meters (Nm)
- ω (omega) is the angular velocity in radians per second (rad/s)

### Relation Between Torque, Power, and Angular Velocity

Power, calculated as P = T * ω, represents the rate of work done by a motor. This relationship illustrates how motors convert energy into mechanical work. By increasing torque or angular velocity, power output is enhanced, which is crucial for high-performance industrial applications requiring efficient energy use and increased productivity.

### Importance in Industrial Automation

By calculating the interplay between torque, power, and angular velocity, engineers can select motors with the most suitable specifications for their applications. This leads to enhanced efficiency, precision, and overall performance in automation processes, thereby supporting advancements in industrial technologies.

## Instructions

Use this calculator to compute the power output of a servomotor. Enter the torque and angular velocity, select the appropriate units, and click "Calculate Power" to see the result.

The calculation uses the formula: P = T * ω, where:

- P is the power output in Watts (W)
- T is the torque in Newton-meters (Nm)
- ω (omega) is the angular velocity in radians per second (rad/s)

### Relation Between Torque, Power, and Angular Velocity

Power, calculated as P = T * ω, represents the rate of work done by a motor. This relationship illustrates how motors convert energy into mechanical work. By increasing torque or angular velocity, power output is enhanced, which is crucial for high-performance industrial applications requiring efficient energy use and increased productivity.

### Importance in Industrial Automation

By calculating the interplay between torque, power, and angular velocity, engineers can select motors with the most suitable specifications for their applications. This leads to enhanced efficiency, precision, and overall performance in automation processes, thereby supporting advancements in industrial technologies.