A regularisation method to obtain analytical solutions to de Broglie-Bohm wave equation

• URL: http://arxiv.org/abs/2512.18555v1
• Date: Sun, 21 Dec 2025 01:00:21 GMT
• Title: A regularisation method to obtain analytical solutions to de Broglie-Bohm wave equation
• Authors: Anand Aruna Kumar, S. K. Srivatsa, Rajesh Tengli,
• Abstract summary: An action functional obtained by coupling a Fisher information term produces a parametrically equivalent form of the de Broglie Bohm dBB equations.<n>We show that generalized Euler Lagrange equations can provide analytical solutions of dBB equations for certain simple stationary systems.
• Score: 0.18665975431697424
• License: http://creativecommons.org/licenses/by-nc-sa/4.0/
• Abstract: We present an analytical method to solve de Broglie Bohm equation for the wave function by combining concepts from the Hamilton Jacobi equations of mechanics, continuity equations, and information theory. From a statistical point of view, the probabilistic description of particle motion provides a middle ground for transitioning from classical to quantum mechanics. An action functional obtained by coupling a Fisher information term produces a parametrically equivalent form of the de Broglie Bohm dBB equations. Next, we show that generalized Euler Lagrange equations can provide analytical solutions of dBB equations for certain simple stationary systems. One- and two-dimensional examples are provided to illustrate the similarities and differences between regular QM and the wave functions obtained from our generalization. To retain the generality of the method, we do not use hbar apriori but instead introduce a parametric information-error coupling term, mu. Our emphasis is strictly limited to the regularization method and its implications for energy states. We defer formal interpretations of the foundational aspects of this subject to a separate communication.

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