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In [[mathematics]], a '''one-parameter group''' or '''one-parameter subgroup''' usually means a [[continuous (topology)|continuous]] [[group homomorphism]] | |||
:φ : '''R''' → ''G'' | |||
from the [[real line]] '''R''' (as an [[Abelian group|additive group]]) to some other [[topological group]] ''G''. That means that it is not in fact a [[group (mathematics)|group]], strictly speaking; if φ is [[injective]] then φ('''R'''), the image, will be a subgroup of ''G'' that is isomorphic to '''R''' as additive group. | |||
==Discussion== | |||
That is, we start knowing only that | |||
:φ (''s'' + ''t'') = φ(''s'')φ(''t'') | |||
where ''s'', ''t'' are the 'parameters' of group elements in ''G''. We may have | |||
:φ(''s'') = ''e'', the [[identity element]] in ''G'', | |||
for some ''s'' ≠ 0. This happens for example if ''G'' is the [[Circle group|unit circle]] and | |||
:φ(''s'') = ''e''<sup>''is''</sup>. | |||
In that case the [[kernel (algebra)|kernel]] of φ consists of the integer multiples of 2π. | |||
The [[action (group theory)|action]] of a one-parameter group on a set is known as a [[flow (mathematics)|flow]]. | |||
A technical complication is that φ('''R''') as a [[subspace topology|subspace]] of ''G'' may carry a topology that is [[finer topology|coarser]] than that on '''R'''; this may happen in cases where φ is injective. Think for example of the case where ''G'' is a [[torus]] ''T'', and φ is constructed by winding a straight line round ''T'' at an irrational slope. | |||
Therefore a one-parameter group or one-parameter subgroup has to be distinguished from a group or subgroup itself, for the three reasons | |||
#it has a definite [[parametrization]], | |||
#the group homomorphism may not be injective, and | |||
#the induced topology may not be the standard one of the real line. | |||
==Examples== | |||
Such one-parameter groups are of basic importance in the theory of [[Lie group]]s, for which every element of the associated [[Lie algebra]] defines such a homomorphism, the [[exponential map]]. In the case of matrix groups it is given by the [[matrix exponential]]. | |||
Another important case is seen in [[functional analysis]], with ''G'' being the group of [[unitary operator]]s on a [[Hilbert space]]. See [[Stone's theorem on one-parameter unitary groups]]. | |||
In his 1957 monograph ''Lie Groups'', [[P. M. Cohn]] gives the following theorem on page 58: | |||
:Any connected 1-dimensional Lie group is analytically isomorphic either to the additive group of real numbers <math> \mathfrak{R}</math>, or to <math> \mathfrak{T}</math>, the additive group of real numbers mod 1. In particular, every 1-dimensional Lie group is locally isomorphic to '''R'''. | |||
==Physics== | |||
In [[physics]], one-parameter groups describe [[dynamical systems]].<ref>Zeidler, E. ''Applied Functional Analysis: Main Principles and Their Applications''. Springer-Verlag, 1995.</ref> Furthermore, whenever a system of physical laws admits a one-parameter group of [[derivative|differentiable]] [[symmetry group|symmetries]], then there is a [[conservation law|conserved quantity]], by [[Noether's theorem]]. | |||
In the study of [[spacetime]] the use of the [[unit hyperbola]] to calibrate spacio-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 [[versor#Hyperbolic versor|hyperbolic versor]], a concept of the nineteenth century. Mathematical physicists [[James Cockle (lawyer)|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''), where ''a'' is the hyperbolic angle and ''r'' <sup>2</sup> = +1. | |||
== See also == | |||
* [[Integral curve]] | |||
* [[One-parameter semigroup]] | |||
* [[Noether's theorem]] | |||
==References== | |||
<references/> | |||
[[Category:Lie groups]] | |||
[[Category:One]] | |||
[[Category:Topological groups]] | |||
Revision as of 16:55, 6 May 2013
In mathematics, a one-parameter group or one-parameter subgroup usually means a continuous group homomorphism
- φ : R → G
from the real line R (as an additive group) to some other topological group G. That means that it is not in fact a group, strictly speaking; if φ is injective then φ(R), the image, will be a subgroup of G that is isomorphic to R as additive group.
Discussion
That is, we start knowing only that
- φ (s + t) = φ(s)φ(t)
where s, t are the 'parameters' of group elements in G. We may have
- φ(s) = e, the identity element in G,
for some s ≠ 0. This happens for example if G is the unit circle and
- φ(s) = eis.
In that case the kernel of φ consists of the integer multiples of 2π.
The action of a one-parameter group on a set is known as a flow.
A technical complication is that φ(R) as a subspace of G may carry a topology that is coarser than that on R; this may happen in cases where φ is injective. Think for example of the case where G is a torus T, and φ is constructed by winding a straight line round T at an irrational slope.
Therefore a one-parameter group or one-parameter subgroup has to be distinguished from a group or subgroup itself, for the three reasons
- it has a definite parametrization,
- the group homomorphism may not be injective, and
- the induced topology may not be the standard one of the real line.
Examples
Such one-parameter groups are of basic importance in the theory of Lie groups, for which every element of the associated Lie algebra defines such a homomorphism, the exponential map. In the case of matrix groups it is given by the matrix exponential.
Another important case is seen in functional analysis, with G being the group of unitary operators on a Hilbert space. See Stone's theorem on one-parameter unitary groups.
In his 1957 monograph Lie Groups, P. M. Cohn gives the following theorem on page 58:
- Any connected 1-dimensional Lie group is analytically isomorphic either to the additive group of real numbers , or to , the additive group of real numbers mod 1. In particular, every 1-dimensional Lie group is locally isomorphic to R.
Physics
In physics, one-parameter groups describe dynamical systems.[1] 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 spacio-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), where a is the hyperbolic angle and r 2 = +1.
See also
References
- ↑ Zeidler, E. Applied Functional Analysis: Main Principles and Their Applications. Springer-Verlag, 1995.