Magnus expansion

In mathematics and physics, the Magnus expansion, named after Wilhelm Magnus (1907–1990), provides an exponential representation of the solution of a first order homogeneous linear differential equation for a linear operator. In particular it furnishes the fundamental matrix of a system of linear ordinary differential equations of order $n$ with varying coefficients. The exponent is aggregated as an infinite series whose terms involve multiple integrals and nested commutators.

Magnus approach and its interpretation

Given the $n \times n$ coefficient matrix $A (t)$ , one wishes to solve the initial value problem associated with the linear ordinary differential equation

Y^{{\prime }}(t)=A(t)Y(t),\qquad \qquad Y(t_{0})=Y_{{0}}

for the unknown $n$ -dimensional vector function $Y (t)$ .

When n = 1, the solution simply reads

Y(t)=\exp \left(\int _{{t_{0}}}^{{t}}A(s)\,ds\right)Y_{{0}}.

This is still valid for n > 1 if the matrix $A (t)$ satisfies $A (t 1) A (t 2) = A (t 2) A (t 1)$ for any pair of values of t, t₁ and t₂. In particular, this is the case if the matrix $A$ is independent of $t$ . In the general case, however, the expression above is no longer the solution of the problem.

The approach introduced by Magnus, to solve the matrix initial value problem, is to express the solution by means of the exponential of a certain $n \times n$ matrix function $Ω (t, t 0)$ ,

Y(t)=\exp \left(\Omega (t,t_{0})\right)\,Y_{0}~,

which is subsequently constructed as a series expansion,

\Omega (t)=\sum _{{k=1}}^{{\infty }}\Omega _{{k}}(t),

where, for simplicity, it is customary to write $Ω (t)$ for $Ω (t, t 0)$ and to take t₀ = 0.

Magnus appreciated that, since $(d ⁄ dt e Ω) e -Ω = A (t)$ , using a Poincaré−Hausdorff matrix identity, he could relate the time-derivative of $Ω$ to the generating function of Bernoulli numbers and the adjoint endomorphism of $Ω$ ,

\Omega '={\frac {\operatorname {ad}_{\Omega }}{\exp(\operatorname {ad}_{\Omega })-1}}~A~,

to solve for $Ω$ recursively in terms of $A$ , "in a continuous analog of the CBH expansion", as outlined in a subsequent section.

The equation above constitutes the Magnus expansion or Magnus series for the solution of matrix linear initial value problem. The first four terms of this series read

{\begin{aligned}\Omega _{1}(t)&=\int _{0}^{t}A(t_{1})\,dt_{1},\\\Omega _{2}(t)&={\frac {1}{2}}\int _{0}^{t}dt_{1}\int _{0}^{{t_{1}}}dt_{2}\ \left[A(t_{1}),A(t_{2})\right],\\\Omega _{3}(t)&={\frac {1}{6}}\int _{0}^{t}dt_{1}\int _{0}^{{t_{1}}}dt_{2}\int _{0}^{{t_{2}}}dt_{3}{\Bigl (}\left[A(t_{1}),\left[A(t_{2}),A(t_{3})\right]\right]+\left[A(t_{3}),\left[A(t_{2}),A(t_{{1}})\right]\right]{\Bigr )},\\\Omega _{4}(t)&={\frac {1}{12}}\int _{0}^{t}dt_{1}\int _{0}^{{t_{1}}}dt_{2}\int _{0}^{{t_{2}}}dt_{3}\int _{0}^{{t_{3}}}dt_{4}{\Bigl (}\left[\left[\left[A_{1},A_{2}\right],A_{3}\right],A_{4}\right]\\&\quad +\left[A_{1},\left[\left[A_{2},A_{3}\right],A_{4}\right]\right]+\left[A_{1},\left[A_{2},\left[A_{3},A_{4}\right]\right]\right]+\left[A_{2},\left[A_{3},\left[A_{4},A_{1}\right]\right]\right]{\Bigr )}\end{aligned}}

where $[A, B] \equiv A B - B A$ is the matrix commutator of A and B.

These equations may be interpreted as follows: $Ω 1 (t)$ coincides exactly with the exponent in the scalar ( $n$ = 1) case, but this equation cannot give the whole solution. If one insists in having an exponential representation (Lie group), the exponent needs to be corrected. The rest of the Magnus series provides that correction systematically: $Ω$ or parts of it are in the Lie algebra of the Lie group on the solution.

In applications, one can rarely sum exactly the Magnus series and one has to truncate it to get approximate solutions. The main advantage of the Magnus proposal is that the truncated series very often shares important qualitative properties with the exact solution, at variance with other conventional perturbation theories. For instance, in classical mechanics the symplectic character of the time evolution is preserved at every order of approximation. Similarly the unitary character of the time evolution operator in quantum mechanics is also preserved (in contrast, e.g., to the Dyson series solving the same problem).

Convergence of the expansion

From a mathematical point of view, the convergence problem is the following: given a certain matrix $A (t)$ , when can the exponent $Ω (t)$ be obtained as the sum of the Magnus series?

A sufficient condition for this series to converge for $t \in [0, T)$ is

\int _{0}^{T}\|A(s)\|_{2}ds<\pi

where $\|\cdot \|_{2}$ denotes a matrix norm. This result is generic, in the sense that one may construct specific matrices $A (t)$ for which the series diverges for any $t > T$ .

Magnus generator

A recursive procedure to generate all the terms in the Magnus expansion utilizes the matrices $S n (k)$ , defined recursively through

S_{{n}}^{{(j)}}=\sum _{{m=1}}^{{n-j}}\left[\Omega _{{m}},S_{{n-m}}^{{(j-1)}}\right],\qquad \qquad 2\leq j\leq n-1

S_{{n}}^{{(1)}}=\left[\Omega _{{n-1}},A\right],\qquad S_{{n}}^{{(n-1)}}={\mathrm {ad}}_{{\Omega _{{1}}}}^{{n-1}}(A)~,

which then furnish

\Omega _{{1}}=\int _{{0}}^{{t}}A(\tau )d\tau

\Omega _{{n}}=\sum _{{j=1}}^{{n-1}}{\frac {B_{{j}}}{j!}}\int _{{0}}^{{t}}S_{{n}}^{{(j)}}(\tau )d\tau ,\qquad \qquad n\geq 2.

Here, ad^k_Ω is a shorthand for an iterated commutator, (see adjoint endomorphism),

{\mathrm {ad}}_{{\Omega }}^{0}A=A,\qquad {\mathrm {ad}}_{{\Omega }}^{{k+1}}A=[\Omega ,{\mathrm {ad}}_{{\Omega }}^{k}A],

while $B j$ are the Bernoulli numbers with $B 1 = -1/2$ .

Finally, when this recursion is worked out explicitly, it is possible to express $Ω n (t)$ as a linear combination of n-fold integrals of n−1 nested commutators involving $n$ matrices $A$ ,

\Omega _{n}(t)=\sum _{{j=1}}^{{n-1}}{\frac {B_{j}}{j!}}\,\sum _{{k_{1}+\cdots +k_{j}=n-1 \atop k_{1}\geq 1,\ldots ,k_{j}\geq 1}}\,\int _{0}^{t}\,{\mathrm {ad}}_{{\Omega _{{k_{1}}}(\tau )}}\,{\mathrm {ad}}_{{\Omega _{{k_{2}}}(\tau )}}\cdots \,{\mathrm {ad}}_{{\Omega _{{k_{j}}}(\tau )}}A(\tau )\,d\tau \qquad n\geq 2,

an expression which becomes increasingly intricate with $n$ .

Applications

Since the 1960s, the Magnus expansion has been successfully applied as a perturbative tool in numerous areas of physics and chemistry, from atomic and molecular physics to nuclear magnetic resonance^[1] and quantum electrodynamics. It has been also used since 1998 as a tool to construct practical algorithms for the numerical integration of matrix linear differential equations. As they inherit from the Magnus expansion the preservation of qualitative traits of the problem, the corresponding schemes are prototypical examples of geometric numerical integrators.

References

↑ 1.Haeberlen, U. & Waugh, J. S. Coherent Averaging Effects in Magnetic Resonance. Phys. Rev. 175, 453–467 (1968).

W. Magnus (1954). "On the exponential solution of differential equations for a linear operator". Comm. Pure and Appl. Math. VII (4): 649–673. doi:10.1002/cpa.3160070404.
S. Blanes; F. Casas; J.A. Oteo; J. Ros (1998). "Magnus and Fer expansions for matrix differential equations: The convergence problem". J. Phys. A: Math. Gen. 31 (1): 259–268. doi:10.1088/0305-4470/31/1/023.
A. Iserles; S.P. Nørsett (1999). "On the solution of linear differential equations in Lie groups". Phil. Trans. R. Soc. Lond. A. 357 (1754): 983–1019. doi:10.1098/rsta.1999.0362.
S. Blanes; F. Casas; J.A. Oteo; J. Ros (2009). "The Magnus expansion and some of its applications". Phys. Rep. 470 (5-6): 151–238. doi:10.1016/j.physrep.2008.11.001.

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