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Auteur principal: singh, Amanpreet
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Publié: Zenodo 2025
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Accès en ligne:https://doi.org/10.5281/zenodo.17334501
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author singh, Amanpreet
author_facet singh, Amanpreet
contents <p>his research introduces a systematic method for solving Transcendental Geometric Programming (TGP) problems where variables appear as exponential terms in both objective functions and constraints. By expanding transcendental functions into power series and truncating at successive terms, the TGP is reduced to Standard Geometric Programming Problems (SGPP) solvable through Karush–Kuhn–Tucker (KKT) conditions and Taylor series linearization. Computational implementation in Python (Google Colab) verifies convergence, stability, and feasibility across multiple truncation levels. Results show that third-order approximations yield efficient, accurate, and computationally stable solutions, making this methodology suitable for real-world optimization scenarios involving transcendental behavior.</p>
format Recurso digital
id zenodo_https___doi_org_10_5281_zenodo_17334501
institution Zenodo
language
publishDate 2025
publisher Zenodo
record_format zenodo
spellingShingle Transcendental Optimization in Geometric Programming via Power Series Approximations
singh, Amanpreet
Transcendental Geometric Programming, Power Series Approximation, Karush-Kuhn-Tucker Conditions, Taylor Series Expansion, Optimization, Python Programming
<p>his research introduces a systematic method for solving Transcendental Geometric Programming (TGP) problems where variables appear as exponential terms in both objective functions and constraints. By expanding transcendental functions into power series and truncating at successive terms, the TGP is reduced to Standard Geometric Programming Problems (SGPP) solvable through Karush–Kuhn–Tucker (KKT) conditions and Taylor series linearization. Computational implementation in Python (Google Colab) verifies convergence, stability, and feasibility across multiple truncation levels. Results show that third-order approximations yield efficient, accurate, and computationally stable solutions, making this methodology suitable for real-world optimization scenarios involving transcendental behavior.</p>
title Transcendental Optimization in Geometric Programming via Power Series Approximations
topic Transcendental Geometric Programming, Power Series Approximation, Karush-Kuhn-Tucker Conditions, Taylor Series Expansion, Optimization, Python Programming
url https://doi.org/10.5281/zenodo.17334501