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This study introduces a new parameterized Newton-Raphson method for faster and more robust root-finding. Inspired by physics, it offers an annealing approach for numerical methods.

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Area of Science:

  • Numerical Analysis
  • Computational Physics

Background:

  • The Newton-Raphson method is a cornerstone for solving equations numerically.
  • Its applications span various scientific disciplines, including physics.
  • Enhancing its convergence and robustness remains an active research area.

Purpose of the Study:

  • To introduce a novel parameterized variant of the Newton-Raphson method.
  • To leverage physical principles for improved numerical root-finding.
  • To explore connections with series expansion methods.

Main Methods:

  • Development of a parameterized Newton-Raphson algorithm.
  • Analytical validation of the method's properties.
  • Empirical testing for convergence and robustness.
  • Establishing links to the Adomian series method.

Main Results:

  • The parameterized method demonstrates enhanced robustness.
  • Faster convergence rates were observed in root-finding iterations.
  • A novel annealing approach was enabled by the introduced parameter.
  • Connections to the Adomian series were mathematically established.

Conclusions:

  • The parameterized Newton-Raphson method offers significant improvements over the standard technique.
  • The physics-inspired parameter provides a new dimension for numerical optimization.
  • This work opens avenues for advanced iterative root-finding algorithms.