Analysis of different Mathematical Models for Different Case Studies Using Statistical Fitting
Abstract
Curve fitting is a fundamental technique in engineering and scientific research, serving as a critical tool for extracting insights from data. This study explores the application of various statistical equations to estimate outcomes in three distinct case studies: population dynamics, temperature variations within buildings, and market equilibrium prices. The efficacy of each fitting is evaluated through rigorous error criteria, including Sum of Squares Error (SSE), R-squared (R), Degrees of Freedom Error (DFE), Adjusted R-squared (Adj. R), and Root Mean Square Error (RMSE). Our findings reveal that the selection of mathematical functions and the order of equations are contingent upon the specific nature of the model being analyzed. In the first case study concerning population dynamics, a fractional exponential function emerges as the optimal equation. Conversely, the second and third case studies, which focus on temperature fluctuations in buildings and market price equilibrium, respectively, find the best fit with a sinusoidal function employing three terms. Additionally, we compare the fitted curves and empirical equations with experimental data from the literature to comprehensively assess their predictive accuracy. By establishing the most suitable mathematical models for diverse case studies, researchers and practitioners can enhance their ability to make accurate predictions and informed decisions.
Cite
@article{arxiv.2502.09515,
title = {Analysis of different Mathematical Models for Different Case Studies Using Statistical Fitting},
author = {Hamidreza Moradi and Hamideh Hossei and Erfan Kefayat},
journal= {arXiv preprint arXiv:2502.09515},
year = {2025}
}