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The ordered exponential, also called the path-ordered exponential, is a mathematical operation defined in non-commutative algebras, equivalent to the exponential of the integral in the commutative algebras. In practice the ordered exponential is used in matrix and operator algebras. It is a kind of product integral, or Volterra integral.
Definition
editLet A be an algebra over a field K, and a(t) be an element of A parameterized by the real numbers,
The parameter t in a(t) is often referred to as the time parameter in this context.
The ordered exponential of a is denoted
where the term n = 0 is equal to 1 and where is the time-ordering operator. It is a higher-order operation that ensures the exponential is time-ordered, so that any product of a(t) that occurs in the expansion of the exponential is ordered such that the value of t is increasing from right to left of the product. For example:
Time ordering is required, as products in the algebra are not necessarily commutative.
The operation maps a parameterized element onto another parameterized element, or symbolically,
There are various ways to define this integral more rigorously.
Product of exponentials
editThe ordered exponential can be defined as the left product integral of the infinitesimal exponentials, or equivalently, as an ordered product of exponentials in the limit as the number of terms grows to infinity:
where the time moments {t0, ..., tN} are defined as ti ≡ i Δt for i = 0, ..., N, and Δt ≡ t / N.
The ordered exponential is in fact a geometric integral[broken anchor].[1][2][3]
Solution to a differential equation
editThe ordered exponential is unique solution of the initial value problem:
Solution to an integral equation
editThe ordered exponential is the solution to the integral equation:
This equation is equivalent to the previous initial value problem.
Infinite series expansion
editThe ordered exponential can be defined as an infinite sum,
This can be derived by recursively substituting the integral equation into itself.
Example
editGiven a manifold where for a with group transformation it holds at a point :
Here, denotes exterior differentiation and is the connection operator (1-form field) acting on . When integrating above equation it holds (now, is the connection operator expressed in a coordinate basis)
with the path-ordering operator that orders factors in order of the path . For the special case that is an antisymmetric operator and is an infinitesimal rectangle with edge lengths and corners at points above expression simplifies as follows :
Hence, it holds the group transformation identity . If is a smooth connection, expanding above quantity to second order in infinitesimal quantities one obtains for the ordered exponential the identity with a correction term that is proportional to the curvature tensor.
See also
editReferences
edit- ^ Michael Grossman and Robert Katz. Non-Newtonian Calculus, ISBN 0912938013, 1972.
- ^ A. E. Bashirov, E. M. Kurpınar, A. Özyapıcı. Multiplicative calculus and its applications, Journal of Mathematical Analysis and Applications, 2008.
- ^ Luc Florack and Hans van Assen."Multiplicative calculus in biomedical image analysis", Journal of Mathematical Imaging and Vision, 2011.