In mathematics, a one-parameter group or one-parameter subgroup usually means a continuous group homomorphism
\varphi:R → G
R
G
\varphi
\varphi(R)
G
R
One-parameter groups were introduced by Sophus Lie in 1893 to define infinitesimal transformations. According to Lie, an infinitesimal transformation is an infinitely small transformation of the one-parameter group that it generates.[1] It is these infinitesimal transformations that generate a Lie algebra that is used to describe a Lie group of any dimension.
The action of a one-parameter group on a set is known as a flow. A smooth vector field on a manifold, at a point, induces a local flow - a one parameter group of local diffeomorphisms, sending points along integral curves of the vector field. The local flow of a vector field is used to define the Lie derivative of tensor fields along the vector field.
A curve
\phi:R → G
G
\phi(t)\phi(s)=\phi(s+t)
In Lie theory, one-parameter groups correspond to one-dimensional subspaces of the associated Lie algebra. The Lie group–Lie algebra correspondence is the basis of a science begun by Sophus Lie in the 1890s.
Another important case is seen in functional analysis, with
G
In his monograph Lie Groups, P. M. Cohn gave the following theorem:
Any connected 1-dimensional Lie group is analytically isomorphic either to the additive group of real numbers
ak{R}
ak{T}
\mod1
R
In physics, one-parameter groups describe dynamical systems.[4] Furthermore, whenever a system of physical laws admits a one-parameter group of differentiable symmetries, then there is a conserved quantity, by Noether's theorem.
In the study of spacetime the use of the unit hyperbola to calibrate spatio-temporal measurements has become common since Hermann Minkowski discussed it in 1908. The principle of relativity was reduced to arbitrariness of which diameter of the unit hyperbola was used to determine a world-line. Using the parametrization of the hyperbola with hyperbolic angle, the theory of special relativity provided a calculus of relative motion with the one-parameter group indexed by rapidity. The rapidity replaces the velocity in kinematics and dynamics of relativity theory. Since rapidity is unbounded, the one-parameter group it stands upon is non-compact. The rapidity concept was introduced by E.T. Whittaker in 1910, and named by Alfred Robb the next year. The rapidity parameter amounts to the length of a hyperbolic versor, a concept of the nineteenth century. Mathematical physicists James Cockle, William Kingdon Clifford, and Alexander Macfarlane had all employed in their writings an equivalent mapping of the Cartesian plane by operator
(\cosh{a}+r\sinh{a})
a
r2=+1
See also: Stone's theorem on one-parameter unitary groups. An important example in the theory of Lie groups arises when
G
GL(n;C)
n x n
Theorem: Suppose
\varphi:R → GL(n;C)
n x n
X
\varphi(t)=etX
for all
t\inR
\varphi
X
\varphi
| \left. | d\varphi(t) |
| dt |
\right|t=0=\left.
| d | |
| dt |
\right|t=0etX=\left.(XetX)\right|t=0=Xe0=X
A technical complication is that
\varphi(R)
G
R
\varphi
G
T
\varphi
T
In that case the induced topology may not be the standard one of the real line.