Ordered exponential

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The ordered exponential (also called Path-ordered exponential) is a mathematical object, defined in non-commutative algebras, which is equivalent to the exponential function of the integral in the commutative algebras. Therefore it is a function, defined by means of a function from real numbers to a real or complex associative algebra. In practice the values lie in matrix and operator algebras.

For the element A(t) from the algebra $(g, * )$ (set g with the non-commutative product *), where t is the "time parameter", the ordered exponential $OE[A](t):\equiv \left(e^{\int_0^t dt' A(t')}\right)_+$ of A can be defined via one of several equivalent approaches:

As the limit of the ordered product of the infinitesimal exponentials:

$OE[A](t) = \lim_{N \rightarrow \infty} \left\{ e^{\epsilon A(t_N)}*e^{\epsilon A(t_{N-1})}* \cdots *e^{\epsilon A(t_1)}*e^{\epsilon A(t_0)}\right\}$

where the time moments ${t 0, t 1,... t N}$ are defined as $t j = j * ε$ for $j=\overline{0,N}$ , and $ε = t / N$ .

Via the initial value problem, where the OE[A](t) is the unique solution of the system of equations:

$\frac{\partial OE[A](t)}{\partial t} = A(t) * OE[A](t),$

O E [A](0) = 1.

Via an integral equation:

$OE[A](t) = 1 + \int_0^t dt' A(t') * OE[A](t').$

Via Taylor series expansion:

$OE[A](t) = 1 + \int_0^t dt_1 A(t_1) + \int_0^t dt_1 \int_0^{t_1} dt_2 A(t_1)*A(t_2)$

$+ \int_0^t dt_1 \int_0^{t_1} dt_2 \int_0^{t_2} dt_3 A(t_1)*A(t_2)*A(t_3) + \cdots$

Related: Path-ordered exponential describes the same concept.

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Category: Abstract algebra

Ordered exponential

From Wikipedia, the free encyclopedia

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