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In mathematics, rotation refers to a transformation that turns a figure around a fixed point called the center of rotation. This concept is fundamental in various branches of mathematics, including geometry, linear algebra, and differential equations. Rotations are used to describe the motion of objects, the behavior of functions, and the properties of spaces. | In mathematics, rotation refers to a transformation that turns a figure around a fixed point called the center of rotation. This concept is fundamental in various branches of mathematics, including geometry, linear algebra, and differential equations. Rotations are used to describe the motion of objects, the behavior of functions, and the properties of spaces. | ||
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[[Image:Detail-79516.jpg|thumb|center|A geometric figure being rotated around a fixed point.|class=only_on_desktop]] | |||
=== Definition and Properties === | === Definition and Properties === |
Latest revision as of 16:56, 18 May 2024
Rotation (mathematics)
In mathematics, rotation refers to a transformation that turns a figure around a fixed point called the center of rotation. This concept is fundamental in various branches of mathematics, including geometry, linear algebra, and differential equations. Rotations are used to describe the motion of objects, the behavior of functions, and the properties of spaces.
Definition and Properties
A rotation in the plane is a transformation that maps every point to another point such that the distance from the center of rotation is preserved, and the angle between the original and the image point is constant. Mathematically, a rotation can be described by a rotation matrix or a complex number representation.
Rotation Matrix
In two dimensions, a rotation by an angle \(\theta\) around the origin can be represented by the rotation matrix: \[ R(\theta) = \begin{pmatrix} \cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \end{pmatrix} \]
This matrix, when multiplied by a vector \((x, y)\), rotates the vector by the angle \(\theta\) counterclockwise.
Complex Number Representation
Rotations in the plane can also be represented using complex numbers. A point \((x, y)\) in the plane can be represented as a complex number \(z = x + iy\). A rotation by an angle \(\theta\) can then be achieved by multiplying \(z\) by \(e^{i\theta}\), where \(e^{i\theta} = \cos \theta + i \sin \theta\).
Rotations in Higher Dimensions
In three dimensions, rotations are more complex and can be represented using rotation matrices or quaternions. A rotation matrix in three dimensions is a \(3 \times 3\) orthogonal matrix with determinant 1. Quaternions provide a convenient way to represent rotations in three dimensions, avoiding some of the complications of rotation matrices, such as gimbal lock.
Rotation Matrices in Three Dimensions
A general rotation in three dimensions can be represented by a \(3 \times 3\) matrix: \[ R = \begin{pmatrix} R_{11} & R_{12} & R_{13} \\ R_{21} & R_{22} & R_{23} \\ R_{31} & R_{32} & R_{33} \end{pmatrix} \]
This matrix must satisfy the condition \(R^T R = I\), where \(R^T\) is the transpose of \(R\) and \(I\) is the identity matrix.
Quaternion Representation
A quaternion is a four-dimensional complex number of the form \(q = a + bi + cj + dk\), where \(a, b, c,\) and \(d\) are real numbers, and \(i, j,\) and \(k\) are the fundamental quaternion units. A rotation in three dimensions can be represented by a unit quaternion \(q\) such that \(|q| = 1\). The rotation of a vector \(\mathbf{v}\) by a quaternion \(q\) is given by \(q \mathbf{v} q^{-1}\), where \(q^{-1}\) is the inverse of \(q\).
Applications of Rotations
Rotations are used extensively in various fields of mathematics and science. In computer graphics, rotations are used to model the orientation and movement of objects. In robotics, rotations are crucial for controlling the movement of robotic arms and other devices. In physics, rotations are used to describe the motion of rigid bodies and the behavior of particles in fields.
Computer Graphics
In computer graphics, rotations are used to manipulate the orientation of objects in a scene. This is often done using rotation matrices or quaternions to ensure smooth and continuous motion. Rotations are also used in texture mapping, lighting calculations, and camera control.
Robotics
In robotics, rotations are used to control the movement and orientation of robotic arms and other devices. This involves calculating the necessary rotations to achieve a desired position or orientation. Rotations are also used in the analysis of the kinematics and dynamics of robotic systems.
Physics
In physics, rotations are used to describe the motion of rigid bodies and the behavior of particles in fields. This includes the study of angular momentum, torque, and rotational kinematics. Rotations are also used in the analysis of the symmetry properties of physical systems.
Mathematical Properties of Rotations
Rotations have several important mathematical properties that make them useful in various applications. These properties include linearity, orthogonality, and preservation of distances and angles.
Linearity
Rotations are linear transformations, meaning that they can be represented by matrices and that the rotation of a sum of vectors is the sum of the rotations of the individual vectors.
Orthogonality
Rotation matrices are orthogonal, meaning that their rows and columns are orthonormal vectors. This property ensures that rotations preserve the lengths of vectors and the angles between them.
Preservation of Distances and Angles
Rotations preserve distances and angles, meaning that the distance between any two points and the angle between any two vectors remain unchanged after a rotation. This property is crucial for many applications, including computer graphics and physics.
Group Theory and Rotations
Rotations form a group under the operation of composition, known as the rotation group. In two dimensions, this group is denoted by SO(2), and in three dimensions, it is denoted by SO(3). These groups have important properties and applications in various fields of mathematics and science.
SO(2)
The group SO(2) consists of all rotation matrices in two dimensions. This group is isomorphic to the unit circle in the complex plane, and it has a simple structure that makes it useful for many applications.
SO(3)
The group SO(3) consists of all rotation matrices in three dimensions. This group has a more complex structure than SO(2), but it is still well understood and has many important applications. The group SO(3) is related to the quaternion group, and it has connections to the study of Lie groups and Lie algebras.
Rotations in Differential Geometry
In differential geometry, rotations are used to study the properties of curves and surfaces. This includes the study of the curvature and torsion of curves, as well as the study of the Gaussian curvature and mean curvature of surfaces.
Curvature and Torsion of Curves
The curvature of a curve measures how much the curve deviates from being a straight line, while the torsion measures how much the curve deviates from being planar. Rotations are used to define these quantities and to study their properties.
Gaussian Curvature and Mean Curvature of Surfaces
The Gaussian curvature of a surface measures how much the surface deviates from being flat, while the mean curvature measures the average curvature of the surface. Rotations are used to define these quantities and to study their properties.
Rotations in Linear Algebra
In linear algebra, rotations are used to study the properties of matrices and vector spaces. This includes the study of eigenvalues and eigenvectors, as well as the study of orthogonal transformations and unitary transformations.
Eigenvalues and Eigenvectors
The eigenvalues and eigenvectors of a rotation matrix provide important information about the rotation. In two dimensions, the eigenvalues of a rotation matrix are complex numbers of the form \(e^{i\theta}\), and the eigenvectors are complex vectors that describe the direction of the rotation.
Orthogonal and Unitary Transformations
Rotations are examples of orthogonal transformations in real vector spaces and unitary transformations in complex vector spaces. These transformations preserve the lengths of vectors and the angles between them, making them useful for many applications in linear algebra.
Rotations in Quantum Mechanics
In quantum mechanics, rotations are used to describe the behavior of particles and fields. This includes the study of angular momentum, spin, and the symmetry properties of quantum systems.
Angular Momentum
The angular momentum of a particle is a measure of its rotational motion. In quantum mechanics, angular momentum is quantized, meaning that it can only take on certain discrete values. Rotations are used to describe the behavior of angular momentum and to study its properties.
Spin
The spin of a particle is a type of intrinsic angular momentum that is independent of the particle's motion. Rotations are used to describe the behavior of spin and to study its properties. This includes the study of spin operators and spin eigenstates.