Angular displacement
Part of a series of articles about 
Classical mechanics 

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Core topics

Angular displacement of a body is the angle in radians (degrees, revolutions) through which a point revolves around a centre or line has been rotated in a specified sense about a specified axis. When an object rotates about its axis, the motion cannot simply be analyzed as a particle, as in circular motion it undergoes a changing velocity and acceleration at any time (t). When dealing with the rotation of an object, it becomes simpler to consider the body itself rigid. A body is generally considered rigid when the separations between all the particles remains constant throughout the objects motion, so for example parts of its mass are not flying off. In a realistic sense, all things can be deformable, however this impact is minimal and negligible. Thus the rotation of a rigid body over a fixed axis is referred to as rotational motion.
Example
In the example illustrated to the right (or above in some mobile versions), a particle or object P is at a fixed distance r from the origin, O, rotating counterclockwise. It becomes important to then represent the position of particle P in terms of its polar coordinates (r, θ). In this particular example, the value of θ is changing, while the value of the radius remains the same. (In rectangular coordinates (x, y) both x and y vary with time). As the particle moves along the circle, it travels an arc length s, which becomes related to the angular position through the relationship:
Measurements
Angular displacement may be measured in radians or degrees. Using radians provides a very simple relationship between distance traveled around the circle and the distance r from the centre.
For example, if an object rotates 360° around a circle of radius r, the angular displacement is given by the distance traveled around the circumference  which is 2πr  divided by the radius: which easily simplifies to: . Therefore, 1 revolution is radians.
When a particle travels from point P to point Q over
, as it does in the illustration to the left, the radius of the circle goes through a change in angle
which equals the angular displacement.
Three dimensions
In three dimensions, angular displacement is an entity with a direction and a magnitude. The direction specifies the axis of rotation, which always exists by virtue of the Euler's rotation theorem; the magnitude specifies the rotation in radians about that axis (using the righthand rule to determine direction). This entity is called an axisangle.
Despite having direction and magnitude, angular displacement is not a vector because it does not obey the commutative law for addition.^{[1]} Nevertheless, when dealing with infinitesimal rotations, second order infinitesimals can be discarded and in this case commutativity appears.
Several ways to describe angular displacement exist, like rotation matrices or Euler angles. See charts on SO(3) for others.
Matrix notation
Given that any frame in the space can be described by a rotation matrix, the displacement among them can also be described by a rotation matrix. Being and two matrices, the angular displacement matrix between them can be obtained as . When this product is performed having a very small difference between both frames we will obtain a matrix close to the identity.
In the limit, we will have an infinitesimal rotation matrix.
Infinitesimal rotation matrices
An infinitesimal angular displacement is a infinitesimal rotation matrix:
 As any rotation matrix has a single real eigenvalue, which is +1, this eigenvalue shows the rotation axis.
 Its module can be deduced from the value of the infinitesimal rotation.
 The shape of the matrix is like this:
We can introduce here the infinitesimal angular displacement tensor or rotation generator associated:
Such that its associated rotation matrix is . When it is divided by the time, this will yield the angular velocity vector.
Generators of rotations
Suppose we specify an axis of rotation by a unit vector [x, y, z] , and suppose we have an infinitely small rotation of angle Δθ about that vector. Expanding the rotation matrix as an infinite addition, and taking the first order approach, the rotation matrix ΔR is represented as:
A finite rotation through angle θ about this axis may be seen as a succession of small rotations about the same axis. Approximating Δθ as θ/N where N is a large number, a rotation of θ about the axis may be represented as:
It can be seen that Euler's theorem essentially states that all rotations may be represented in this form. The product is the "generator" of the particular rotation, being the vector (x,y,z) associated with the matrix A. This shows that the rotation matrix and the axisangle format are related by the exponential function.
One can derive a simple expression for the generator G. One starts with an arbitrary plane^{[2]} defined by a pair of perpendicular unit vectors a and b. In this plane one can choose an arbitrary vector x with perpendicular y. One then solves for y in terms of x and substituting into an expression for a rotation in a plane yields the rotation matrix R which includes the generator G = ba^{T} − ab^{T}.
To include vectors outside the plane in the rotation one needs to modify the above expression for R by including two projection operators that partition the space. This modified rotation matrix can be rewritten as an exponential function.
Analysis is often easier in terms of these generators, rather than the full rotation matrix. Analysis in terms of the generators is known as the Lie algebra of the rotation group.
Relationship with Lie algebras
The matrices in the Lie algebra are not themselves rotations; the skewsymmetric matrices are derivatives, proportional differences of rotations. An actual "differential rotation", or infinitesimal rotation matrix has the form
where dθ is vanishingly small and A ∈ so(n), for instance with A = L_{x},
The computation rules are as usual except that infinitesimals of second order are routinely dropped. With these rules, these matrices do not satisfy all the same properties as ordinary finite rotation matrices under the usual treatment of infinitesimals.^{[3]} It turns out that the order in which infinitesimal rotations are applied is irrelevant. To see this exemplified, consult infinitesimal rotations SO(3).
Exponential map
Connecting the Lie algebra to the Lie group is the exponential map, which is defined using the standard matrix exponential series for e^{A}^{[4]} For any skewsymmetric matrix A, exp(A) is always a rotation matrix.^{[nb 1]}
An important practical example is the 3 × 3 case. In rotation group SO(3), it is shown that one can identify every A ∈ so(3) with an Euler vector ω = θ u, where u = (x,y,z) is a unit magnitude vector.
By the properties of the identification su(2) ≅ ℝ^{3}, u is in the null space of A. Thus, u is left invariant by exp(A) and is hence a rotation axis.
Using Rodrigues' rotation formula on matrix form with θ = ^{θ}⁄_{2} + ^{θ}⁄_{2}, together with standard double angle formulae one obtains,
where c = cos ^{θ}⁄_{2}, s = sin ^{θ}⁄_{2}.
This is the matrix for a rotation around axis u by the angle θ in halfangle form. For full detail, see exponential map SO(3).
Notice that for infinitesimal angles second order terms can be ignored and remains exp(A) = I + A
See also
References
 ↑ Note that this exponential map of skewsymmetric matrices to rotation matrices is quite different from the Cayley transform discussed earlier, differing to 3rd order,
Conversely, a skewsymmetric matrix A specifying a rotation matrix through the Cayley map specifies the same rotation matrix through the map exp(2arctanhA).
 ↑ Kleppner, Daniel; Kolenkow, Robert (1973). An Introduction to Mechanics. McGrawHill. pp. 288–89.
 ↑ in Euclidean space
 ↑ (Goldstein, Poole & Safko 2002, §4.8)
 ↑ (Wedderburn 1934, §8.02)