A Novel Method for Curvefitting the Stretched Exponential Function to Experimental Data.

Biomedical engineering research Pub Date : 2013-12-01 DOI:10.5963/ber0204001

Ronald K June, John P Cunningham, David P Fyhrie

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引用次数: 11

Abstract

The stretched exponential function has many applications in modeling numerous types of experimental relaxation data. However, problems arise when using standard algorithms to fit this function: we have observed that different initializations result in distinct fitted parameters. To avoid this problem, we developed a novel algorithm for fitting the stretched exponential model to relaxation data. This method is advantageous both because it requires only a single adjustable parameter and because it does not require initialization in the solution space. We tested this method on simulated data and experimental stress-relaxation data from bone and cartilage and found favorable results compared to a commonly-used Quasi-Newton method. For the simulated data, strong correlations were found between the simulated and fitted parameters suggesting that this method can accurately determine stretched exponential parameters. When this method was tested on experimental data, high quality fits were observed for both bone and cartilage stress-relaxation data that were significantly better than those determined with the Quasi-Newton algorithm.

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拉伸指数函数与实验数据曲线拟合的新方法。

拉伸指数函数在模拟多种类型的实验松弛数据方面具有广泛的应用。然而，当使用标准算法拟合该函数时，问题出现了:我们已经观察到不同的初始化会导致不同的拟合参数。为了避免这个问题，我们开发了一种新的算法来拟合拉伸指数模型到松弛数据。这种方法的优点在于它只需要一个可调参数，而且不需要在解空间中进行初始化。我们在模拟数据和骨和软骨的应力松弛实验数据上测试了这种方法，与常用的准牛顿方法相比，发现了良好的结果。对于模拟数据，模拟参数与拟合参数之间存在较强的相关性，表明该方法可以准确地确定拉伸指数参数。当对实验数据进行测试时，观察到骨和软骨应力松弛数据的高质量拟合，明显优于准牛顿算法确定的数据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Biomedical engineering research

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