Locating complex singularities of Burgers’ equation using exponential asymptotics and transseries
Locating complex singularities of Burgers’ equation using exponential asymptotics and transseries
Burgers' equation is an important mathematical model used to study gas dynamics and traffic flow, among many other applications. Previous analysis of solutions to Burgers' equation shows an infinite stream of simple poles born at t=0+, emerging rapidly from the singularities of the initial condition, that drive the evolution of the solution for t>0. We build on this work by applying exponential asymptotics and transseries methodology to an ordinary differential equation that governs the small-time behaviour in order to derive asymptotic descriptions of these poles and associated zeros. Our analysis reveals that subdominant exponentials appear in the solution across Stokes curves; these exponentials become the same size as the leading order terms in the asymptotic expansion along anti-Stokes curves, which is where the poles and zeros are located. In this region of the complex plane, we write a transseries approximation consisting of nested series expansions. By reversing the summation order in a process known as transasymptotic summation, we study the solution as the exponentials grow, and approximate the pole and zero location to any required asymptotic accuracy. We present the asymptotic methods in a systematic fashion that should be applicable to other nonlinear differential equations.
complex-plane singularities, exponential asymptotics, resurgence, transseries
Lustri, Christopher J.
fca62c45-bfaf-4fa4-a1d5-ddd55411eaef
Aniceto, Ines
0061ca0c-1ad8-4510-9b12-008e5c27a7ea
VandenHeuvel, Daniel J.
b73d4138-01ae-4e5b-84ef-8b34c8ff2cd1
McCue, Scott W.
2c51b1c8-b4d5-4b1a-99ea-bf0e8edad96f
18 October 2023
Lustri, Christopher J.
fca62c45-bfaf-4fa4-a1d5-ddd55411eaef
Aniceto, Ines
0061ca0c-1ad8-4510-9b12-008e5c27a7ea
VandenHeuvel, Daniel J.
b73d4138-01ae-4e5b-84ef-8b34c8ff2cd1
McCue, Scott W.
2c51b1c8-b4d5-4b1a-99ea-bf0e8edad96f
Lustri, Christopher J., Aniceto, Ines, VandenHeuvel, Daniel J. and McCue, Scott W.
(2023)
Locating complex singularities of Burgers’ equation using exponential asymptotics and transseries.
Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 479 (2278), [20230516].
(doi:10.1098/rspa.2023.0516).
Abstract
Burgers' equation is an important mathematical model used to study gas dynamics and traffic flow, among many other applications. Previous analysis of solutions to Burgers' equation shows an infinite stream of simple poles born at t=0+, emerging rapidly from the singularities of the initial condition, that drive the evolution of the solution for t>0. We build on this work by applying exponential asymptotics and transseries methodology to an ordinary differential equation that governs the small-time behaviour in order to derive asymptotic descriptions of these poles and associated zeros. Our analysis reveals that subdominant exponentials appear in the solution across Stokes curves; these exponentials become the same size as the leading order terms in the asymptotic expansion along anti-Stokes curves, which is where the poles and zeros are located. In this region of the complex plane, we write a transseries approximation consisting of nested series expansions. By reversing the summation order in a process known as transasymptotic summation, we study the solution as the exponentials grow, and approximate the pole and zero location to any required asymptotic accuracy. We present the asymptotic methods in a systematic fashion that should be applicable to other nonlinear differential equations.
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lustri-et-al-2023-locating-complex-singularities-of-burgers-equation-using-exponential-asymptotics-and-transseries
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Accepted/In Press date: 26 September 2023
Published date: 18 October 2023
Additional Information:
Funding Information:
The authors are grateful for valuable discussions with John R. King. C.J.L. acknowledges the support of Australian Research Council Discovery Project DP190101190. I.A. acknowledges the support of the EPSRC Early Career Fellowship EP/S004076/1. C.J.L., I.A. and S.W.M. would like to thank the Isaac Newton Institute for Mathematical Sciences, Cambridge, for support and hospitality during the programme ‘Applicable resurgent asymptotics: towards a universal theory’, where much of the work on this paper was undertaken. The programme was supported by the EPSRC grant no. EP/R014604/1.
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© 2023 The Authors.
Keywords:
complex-plane singularities, exponential asymptotics, resurgence, transseries
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Local EPrints ID: 483291
URI: http://eprints.soton.ac.uk/id/eprint/483291
ISSN: 1364-5021
PURE UUID: 9c99d0fb-5b0e-4056-b21f-66e914005f35
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Date deposited: 27 Oct 2023 16:39
Last modified: 06 Jun 2024 02:04
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Author:
Christopher J. Lustri
Author:
Daniel J. VandenHeuvel
Author:
Scott W. McCue
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