Angular Velocity to Linear Velocity Converter

Calculate rotational motion instantly with precision

Angular Velocity (ω)

Radius (r)

Result Unit

Quick Conversions

Popular Conversions

Angular Velocity	Radius	Linear Velocity	Common Application
60 RPM	1.0 m	6.28 m/s	Electric motor
120 RPM	0.5 m	6.28 m/s	Ceiling fan
3000 RPM	0.05 m	15.71 m/s	Car engine
500 RPM	0.3 m	15.71 m/s	Washing machine drum
33.33 RPM	0.15 m	0.52 m/s	Vinyl record player
7.29×10⁻⁵ rad/s	6,371 km	464 m/s	Earth’s rotation (equator)
1.99×10⁻⁷ rad/s	149.6 million km	29.78 km/s	Earth’s orbit around Sun
1800 RPM	0.35 m	65.97 m/s	Industrial machinery

Conversion Formula & Steps

The relationship between angular velocity and linear velocity:

v = ω × r

Where:
v = Linear velocity (m/s)
ω = Angular velocity (rad/s)
r = Radius (m)

Calculation Steps

Convert angular velocity to rad/s: If your angular velocity is in different units (RPM, degrees/s, Hz), first convert to radians per second. Use: 1 RPM = 0.10472 rad/s, 1 degree/s = 0.01745 rad/s, 1 Hz = 6.28319 rad/s
Convert radius to meters: Ensure your radius is in meters. If using feet, multiply by 0.3048. If using inches, multiply by 0.0254.
Apply the formula: Multiply the angular velocity (in rad/s) by the radius (in meters) to get linear velocity in m/s.
Convert result if needed: Convert m/s to your desired unit. For km/h multiply by 3.6, for mph multiply by 2.237.

Example Calculation

Problem: A wheel with radius 0.5 meters rotates at 120 RPM. What is the linear velocity at the edge?

Step 1: Convert 120 RPM to rad/s
ω = 120 × 0.10472 = 12.566 rad/s

Step 2: Radius is already in meters: r = 0.5 m

Step 3: Calculate linear velocity
v = ω × r = 12.566 × 0.5 = 6.283 m/s

Alternative: Convert to km/h: 6.283 × 3.6 = 22.62 km/h

Comparative Rotational Speeds

Earth Rotation

0.0000729 rad/s

At equator: 464 m/s
One rotation: 24 hours

Car Wheel (Highway)

88.5 rad/s

Speed: 100 km/h
Wheel radius: 0.314 m

Helicopter Rotor

30-40 rad/s

Speed: 200+ m/s
Blade length: ~5-7 m

CD Player

52.4 rad/s

Speed: 1.2-1.4 m/s
Read speed: 500 RPM

Real-World Applications

Automotive Engineering

Converting wheel RPM to vehicle speed is essential for speedometer calibration. A tire with a rolling radius of 0.314 m rotating at 800 RPM produces a vehicle speed of approximately 26.3 m/s or 95 km/h. Tire size changes affect this calculation, which is why changing wheel dimensions requires speedometer recalibration.

Robotics & Automation

Robotic arms use angular velocity sensors at joints combined with arm segment lengths to calculate end-effector speed. A robot arm segment of 0.6 m length rotating at 2 rad/s moves its endpoint at 1.2 m/s. This calculation is crucial for motion planning and collision avoidance in automated manufacturing.

Aerospace & Aviation

Helicopter rotor tips must not exceed the speed of sound (approximately 343 m/s). For a rotor blade 7 meters long, the maximum safe angular velocity is about 49 rad/s (468 RPM). This limitation significantly impacts helicopter design and maximum forward flight speed.

Sports Equipment

Baseball pitchers generate ball spin rates of 2000-2500 RPM. For a baseball with a 3.7 cm radius, this produces a surface velocity of 7.7-9.7 m/s, creating the Magnus effect that causes curveballs and other pitch movements. Tennis serves can exceed 5000 RPM, creating even more dramatic ball trajectories.

Power Generation

Wind turbine blades can be 40-80 meters long and rotate at 10-20 RPM. Despite the slow rotation, blade tips travel at 60-80 m/s. This high linear velocity is why turbines can efficiently capture wind energy even with relatively slow angular speeds.

Medical Devices

Centrifuges used in medical laboratories separate blood components by spinning samples at high speeds. A typical centrifuge rotating at 3000 RPM with a 0.15 m radius produces forces equivalent to 15 g (where the linear velocity is 47.1 m/s). This separates plasma, platelets, and red blood cells effectively.

Frequently Asked Questions

What is the difference between angular velocity and linear velocity?

Angular velocity measures how fast an object rotates around an axis, expressed in radians per second (rad/s) or revolutions per minute (RPM). Linear velocity measures how fast a point moves along a path, expressed in meters per second (m/s) or miles per hour (mph). For circular motion, linear velocity depends on both angular velocity and the distance from the rotation center (radius). Points farther from the center move faster even though the angular velocity is the same.

Why do we need to use radians in the formula v = ωr?

The formula v = ωr requires angular velocity in radians per unit time because radians are dimensionless (they’re a ratio of arc length to radius). This makes the mathematics work correctly: when you multiply rad/s by meters, the radian unit effectively cancels, leaving you with m/s. If you use degrees, you must convert to radians first: multiply by π/180. One complete revolution equals 2π radians or 360 degrees.

How do I convert RPM to rad/s?

To convert revolutions per minute (RPM) to radians per second (rad/s), multiply by 2π and divide by 60. The formula is: ω (rad/s) = RPM × (2π/60) = RPM × 0.10472. For example, 300 RPM = 300 × 0.10472 = 31.416 rad/s. This conversion accounts for: one revolution = 2π radians, and one minute = 60 seconds.

Does the linear velocity change at different points on a rotating object?

Yes, linear velocity varies with distance from the rotation center. All points on a rigid rotating object have the same angular velocity, but points farther from the center have higher linear velocity. For example, on a rotating disk with ω = 10 rad/s, a point at radius 1 m has v = 10 m/s, while a point at radius 2 m has v = 20 m/s. The center point has zero linear velocity despite rotating.

What is tangential velocity and how does it relate to linear velocity?

Tangential velocity and linear velocity are the same thing in circular motion. “Tangential” emphasizes that the velocity direction is tangent to the circular path (perpendicular to the radius). The point moves in a direction perpendicular to the line connecting it to the rotation center. This is why objects released from rotating systems (like a slingshot) fly off tangent to the circle, not radially outward.

Can I use this formula for non-circular motion?

The formula v = ωr applies specifically to circular motion or motion that can be approximated as circular at an instant. For elliptical or irregular paths, the relationship becomes more complex. However, for instantaneous calculations, you can use the instantaneous radius of curvature. The formula works for any circular arc, whether it’s a complete circle, partial rotation, or momentary circular movement.

How does this apply to gears and pulleys?

For connected gears or pulleys, the linear velocity at the contact point must be identical. If gear A (radius r₁, angular velocity ω₁) drives gear B (radius r₂, angular velocity ω₂), then r₁ω₁ = r₂ω₂. This means a smaller gear rotating faster can drive a larger gear rotating slower, or vice versa. This principle enables gear ratios to convert between speed and torque in mechanical systems.

What happens to linear velocity if I double the angular velocity?

Linear velocity is directly proportional to angular velocity (v = ωr). If you double the angular velocity while keeping the radius constant, you exactly double the linear velocity. Similarly, if you triple ω, you triple v. This linear relationship makes it straightforward to predict how changes in rotation speed affect the motion of points on a rotating object.