In physics angular velocity is the speed at which something rotates and the direction it rotates in, concerned with direction (rather than absolute location.) It is usually measured in degrees per time or revolutions per time. For example, a record (music) spins at an angular velocity of either 33 or 45 revolutions per minute clockwise.

In mathematical terms, angular velocity is the pseudovector physical quantity which represents the rate of rotation (or change of orientation). It is analogous to translational velocity, and is defined in terms of the derivative of orientation with respect to time, just as translational velocity is the derivative of displacement with respect to time. It is customary to introduce the concept of velocity by first defining average velocity as displacement divided by time. There the analogy with angular velocity is less useful: for example, if a body is rotating at a constant angular velocity of one revolution per minute, then over a one-minute period the 'average angular velocity' of the body is zero, because the orientation is exactly the same at the beginning of the time period as it is at the end.

More precisely, if $A(t)$ is the special orthogonal linear transformation which describes the orientation, the angular velocity is defined as $A(t)^\{-1\}\{d\backslash over\; dt\}A(t)$. It follows that angular velocity is a skew-adjoint linear transformation . It is useful to restrict attention to two or three dimensions and represent the three-dimensional Lie algebra of skew-adjoint linear transformations of V$\{\}\_3$(R) by R³. The commutator operation, which is the Lie product of the algebra, is represented by the cross product in R³. The rest of this article is devoted to a discussion in that style.

Circular motion

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Angular velocity is usually represented by the symbol omega (Ω or ω). The magnitude of the angular velocity is the angular speed (or angular frequency) and is denoted by ω. The line of direction of the angular velocity is given by the axis of rotation, and the right hand rule indicates the positive direction, namely:

If you curl the fingers of your right hand to follow the direction of the rotation, then the direction of the angular velocity vector is indicated by your right thumb.

In SI units, angular velocity is measured in radians per second, (rad/s), although a direction must also be given. The dimensions of angular velocity are T ^-1, since radians are dimensionless.

For any particle of a moving and spinning body we have

$\backslash mathbf\{v\}\; =\; \backslash mathbf\{v\}\_t\; +\; \backslash boldsymbol\backslash omega\; \backslash times\; (\backslash mathbf\{r\}\; -\; \backslash mathbf\{r\}\_c)$

where $\backslash mathbf\{v\}$ is the total velocity of the particle, $\backslash mathbf\{v\}\_t$ the translational velocity, $\backslash mathbf\{r\}$ the position of the particle, and $\backslash mathbf\{r\}\_c$ the position of the center of the body.

To describe the motion the "center" can be any particle of the body or imaginary point that is rigidly connected to the body (the translation vector depends on the choice) but typically the center of mass is chosen, because it simplifies some formulas.

When the cross product is written in matrix form we have a skew-symmetric matrix with zeros on the main diagonal and plus and minus the components of the angular velocity as the other elements; see also above.

With constant angular acceleration, the angular velocity conforms to the rotational equations of motion, equivalent to the standard linear equations of motion under constant linear acceleration.

Angular frequency is also used instead of normal frequency in some situations that don't actually involve rotation especially in electronics as it makes the expression of sinusoids and various equations that are obtained by calculus on sinusoids simpler. (ωt rather than 2πft).

Non-circular motion

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If the motion of a particle is described by a position vector-valued function r(t) — with respect to a fixed origin — then the angular velocity vector is

$\backslash boldsymbol\backslash omega\; =\; \{\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}\; \backslash over\; |\backslash mathbf\{r\}|^2\}\; \backslash qquad\; \backslash qquad\; (1)$

where

$\backslash mathbf\{v\}(t)\; =\; \backslash mathbf\{r\text{'}\}(t)$

is the linear velocity vector. Equation (1) is applicable to non-circular motions, e.g. elliptic orbits.

Derivation

Vector v can be resolved into a pair of components: $\backslash mathbf\{v\}\_\backslash perp$ which is perpendicular to r, and $\backslash mathbf\{v\}\_\backslash |$ which is parallel to r. The motion of the parallel component is completely linear and produces no rotation of the particle (with regard to the origin), so for purposes of finding the angular velocity it can be ignored. The motion of the perpendicular component is completely circular, since it is perpendicular to the radial vector, just like any tangent to a point on a circle.

The perpendicular component has magnitude

$|\backslash mathbf\{v\}\_\backslash perp|\; =\; \{|\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}|\; \backslash over\; |\backslash mathbf\{r\}|\}\; \backslash qquad\; \backslash qquad\; (2)$

where the vector $\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}$ represents the area of the parallelogram two of whose sides are the vectors r and v. Dividing this area by the magnitude of r yields the height of this parallelogram between r and the side of the parallelogram parallel to r. This height is equal to the component of v which is perpendicular to r.

In the case of pure circular motion, the angular velocity is equal to linear velocity divided by the radius. In the case of generalized motion, the linear velocity is replaced by its component perpendicular to r, viz.

$\backslash omega\; =\; \{|\backslash mathbf\{v\}\_\backslash perp|\; \backslash over\; |\backslash mathbf\{r\}|\}\; \backslash qquad\; \backslash qquad\; (3)$

therefore, putting equations (2) and (3) together yields

$\backslash omega\; =\; \{|\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}|\; \backslash over\; |\backslash mathbf\{r\}|^2\}\; =\; |\backslash boldsymbol\backslash omega|.\; \backslash qquad\; \backslash qquad\; (4)$

Equation (4) gives the magnitude of the angular velocity vector. The vector's direction is given by its normalized version:

$\backslash hat\backslash boldsymbol\backslash omega\; =\; \{\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}\; \backslash over\; |\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}|\}.\; \backslash qquad\; \backslash qquad\; (5)$

Then the entire angular velocity vector is given by putting together its magnitude and its direction:

$\backslash boldsymbol\backslash omega\; =\; \backslash omega\; \backslash hat\backslash boldsymbol\backslash omega$

which, due to equations (4) and (5), is equal to

$\backslash boldsymbol\backslash omega\; =\; \{\backslash mathbf\{r\}\; \backslash times\; \backslash mathbf\{v\}\; \backslash over\; |\backslash mathbf\{r\}|^2\},$

which was to be demonstrated.

See also

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• Introductory
  • Angular momentum
  • Angular frequency
  • Areal velocity
• Advanced
  • Isometry
  • Orthogonal group
  • Rotation group
  • Lie algebra

External links

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• Rotations and Angular Momentum on the Classical Mechanics page of the website of John Baez, especially Questions 1 and 2.

References

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• Peter M. Neumann; Gabrielle A. Stoy; Edward C. Thompson. Groups and Geometry, Oxford 1994, ISBN 01798534515. See pp. 108-110, 163-165 .

Physical quantity | Rotational symmetry | Angle

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