Calculate angular acceleration from velocity change, torque/inertia, or linear acceleration. Convert between rad/s², rpm/s, deg/s², and rev/s².
Angular acceleration (α) measures how quickly an object's rotational speed changes over time. It is the rotational analog of linear acceleration and plays a fundamental role in rotational dynamics, mechanical engineering, and motor design. Angular acceleration is measured in radians per second squared (rad/s²) in SI units.
This calculator provides three ways to compute angular acceleration: from a change in angular velocity over time (α = Δω/Δt), from torque and moment of inertia (α = τ/I — the rotational version of Newton's second law), or from linear tangential acceleration and radius (α = a/r). Results are displayed in multiple units including rad/s², deg/s², rpm/s, and rev/s².
The tool also computes related quantities like tangential acceleration, angular displacement during the acceleration period, and the torque required. Presets for common scenarios — CD spin-up, car wheel braking, centrifuge operation — help build intuition for typical angular acceleration values. Check the example with realistic values before reporting.
Computing angular acceleration often involves converting between different angular units (rpm, rad/s, deg/s) which is error-prone by hand. This calculator handles all conversions automatically and provides multiple computation methods for different problem types.
The tangential acceleration and displacement calculations save extra steps, and the reference table of common angular accelerations helps students and engineers build intuition for realistic values.
Angular acceleration: α = Δω/Δt (from velocity change), α = τ/I (from torque), α = a_t/r (from tangential). Angular displacement: θ = ½αt². Tangential acceleration: a_t = αr.
Result: 36.65 rad/s²
A CD spinning up from rest to 700 rpm (73.3 rad/s) in 2 seconds has angular acceleration α = 73.3/2 = 36.65 rad/s².
Angular acceleration is to rotational motion what linear acceleration is to translational motion. The rotational analog of Newton's second law, τ = Iα, is the fundamental equation of rotational dynamics. Just as F = ma relates force to linear acceleration, τ = Iα relates torque to angular acceleration through the moment of inertia.
Electric motor selection requires matching motor torque to load inertia for desired angular acceleration. Flywheel energy storage systems optimize the balance between stored energy (½Iω²) and spin-up time (α = τ/I). Centrifuge design must limit angular acceleration to avoid stressing the rotor. CNC machine tools control angular acceleration precisely to achieve smooth cutting motions.
Angular acceleration is measured using angular rate gyroscopes (differentiating angular velocity) or MEMS accelerometers configured for rotational measurement. Modern smartphones contain MEMS gyroscopes that measure angular velocity, from which angular acceleration can be computed. Industrial applications use rotary encoders for precise measurement.
Linear acceleration describes how fast an object speeds up along a straight line. Angular acceleration describes how fast an object speeds up its rotation. They are related by a_t = αr where r is the radius.
Moment of inertia (I) is the rotational equivalent of mass. It measures how hard it is to change an object's rotation. It depends on both mass and how that mass is distributed relative to the rotation axis.
Yes. Negative angular acceleration means the rotation is slowing down (angular deceleration). A braking wheel has negative angular acceleration.
Multiply rpm/s by 2π/60 ≈ 0.1047 to get rad/s². Equivalently, multiply rad/s² by 60/(2π) ≈ 9.549 to get rpm/s.
Angular acceleration depends on the motor torque and the total moment of inertia (motor + load): α = τ/I. More torque or less inertia means faster spin-up.
Yes. Its direction is along the rotation axis. By convention (right-hand rule), counterclockwise acceleration is positive.