A New Approach to Solving Periodic Differential Systems
© The Physical Society of Japan
This article is on
A remark on renormalization group theoretical perturbation in a class of ordinary differential equations
(PTEP Editors' Choice)
Prog. Theor. Exp. Phys.
2021,
013A02
(2021)
.
Mathematicians and physicists are well acquainted with second-order ordinary differential equations (ODE), the most prominent of them being the class of equations that govern oscillatory motion.
Mathematicians and physicists are well acquainted with second-order ordinary differential equations (ODE), the most prominent of them being the class of equations that govern oscillatory motion. Often, these oscillatory-type equations involve an inhomogeneous “potential” term coupled with a perturbation term and are usually solved as a power series in the perturbation with coefficients that are polynomials in the independent variable. However, when describing time-dependent behavior of a system, i.e., the independent variable is time (t), the series solution becomes problematic due to the coefficients diverging in time, which limits the valid description of the system to time scales of the order of (1/perturbation).
In a new study, I report on an elegant (yet unnoticed) functional identity in renormalization group (RG) theoretical perturbation theory, which is useful to get rid of the divergent time-dependence and to replace it instead with a description based on “renormalized amplitudes” and their time dynamics.
I begin with a second-order ODE in time with a potential term depending on the perturbation, the independent variable and its derivative, and the “resonant harmonics,” e±it, and its naïve perturbation series solution. Next, I write the dependent variable, say y, as a perturbation series expansion and substitute it in the ODE to get an equation for each power of the perturbation. I define Y as the resulting formal solution of the power series expansion of y and write it as a Fourier expansion with coefficients that are functions of what I call “bare amplitudes,” A, B. I will formally refer to them as “secular coefficients.”
I go on to prove an identity and a relation between the secular coefficients that are key to my results. I next define the “renormalized amplitudes” Ar(t) and Br(t) as a function of the “resonant” secular coefficient and use the proved relation to express the bare amplitudes as a function of Ar(t) and Br(t). Using the identity proved before, I further establish the renormalized series expansion in terms of Ar and Br, which is free from the secular time dependence.
Further, the dynamics of Ar(t) and Br(t) is solely determined by the resonant secular coefficients to all orders of perturbation.
This work has important implications in studies involving the classic cases of Van der Pol, Mathieu, Duffing, and Rayleigh equations and may trigger new theoretical development of a RG-based approach to solving differential equations.
A remark on renormalization group theoretical perturbation in a class of ordinary differential equations
(PTEP Editors' Choice)
Prog. Theor. Exp. Phys.
2021,
013A02
(2021)
.
Share this topic
Fields
Related Articles
-
A Promising Solution to Nucleon–Nucleon Inverse Scattering Problem
General and Mathematical Physics
Mathematical methods, classical and quantum physics, relativity, gravitation, numerical simulation, computational modeling
Nuclear physics
2024-10-7
This study deals with the inverse elastic two-body quantum scattering problem using Volterra approximations and neural networks, offering a novel approach for solving complex nonlinear systems.
-
A New Method for Finding Bound States in the Continuum
General and Mathematical Physics
Mathematical methods, classical and quantum physics, relativity, gravitation, numerical simulation, computational modeling
Nuclear physics
2024-10-1
This study presents a general theory for constructing potentials supporting bound states in the continuum, offering a method for identifying such states in real quantum systems.
-
General Quasi-Joint Probabilities on Finite-State Quantum Systems
Mathematical methods, classical and quantum physics, relativity, gravitation, numerical simulation, computational modeling
2024-8-15
This study investigates the properties of general quasi-joint probability distributions in finite-state quantum systems, revealing the Kirkwood-Dirac distribution as among the most favorable. This highlights the importance of complex distributions in understanding quantum probability.
-
Solving a Stochastic Differential Equation is Solving a Mean-Field Quantum Spin System
Magnetic properties in condensed matter
Mathematical methods, classical and quantum physics, relativity, gravitation, numerical simulation, computational modeling
Statistical physics and thermodynamics
2024-5-16
The replica method maps matrix-valued geometric Brownian motion to a mean-field quantum spin system. This correspondence makes it possible to obtain an exact solution for matrix-valued geometric Brownian motion.
-
Quantum Mechanics of One-Dimensional Three-Body Contact Interactions
Mathematical methods, classical and quantum physics, relativity, gravitation, numerical simulation, computational modeling
Theoretical Particle Physics
2024-2-13
The quantum mechanical description of topologically nontrivial three-body contact interactions in one dimension is not well understood. This study explores the Hamiltonian description of these interactions using the path-integral formalism.