Gradient-based optimization for multi-scale geographically weighted regression

IF 4.3 1区地球科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

International Journal of Geographical Information Science Pub Date : 2023-08-24 DOI:10.1080/13658816.2023.2246154

Xiao-liang Zhou, R. Assunção, H. Shao, Cheng-Chia Huang, Mark V. Janikas, H. Asefaw

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引用次数: 0

Abstract

Abstract Multi-scale geographically weighted regression (MGWR) is among the most popular methods to analyze non-stationary spatial relationships. However, the current model calibration algorithm is computationally intensive: its runtime has a cubic growth with the sample size, while its memory use grows quadratically. We propose calibrating MGWR with gradient-based optimization. This is obtained by analytically deriving the gradient vector and the Hessian matrix of the corrected Akaike information criterion (AICc) and wrapping them with a trust-region optimization algorithm. We evaluate the model quality empirically. Our method converges to the same coefficients and produces the same inference as the current method but it has a substantial computational gain when the sample size is large. It reduces the runtime to quadratic convergence and makes the memory use linear with respect to sample size. Our new algorithm outperforms the existing alternatives and makes MGWR feasible for large spatial datasets.

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基于梯度的多尺度地理加权回归优化

摘要多尺度地理加权回归（MGWR）是分析非平稳空间关系最常用的方法之一。然而，当前的模型校准算法是计算密集型的：其运行时间随着样本量的增加而呈三次增长，而其内存使用量则呈二次增长。我们建议使用基于梯度的优化来校准MGWR。这是通过解析推导校正的Akaike信息准则（AICc）的梯度向量和Hessian矩阵并用信赖域优化算法包裹它们来获得的。我们对模型质量进行了实证评估。我们的方法收敛到相同的系数，并产生与当前方法相同的推断，但当样本量较大时，它具有显著的计算增益。它将运行时间减少到二次收敛，并使内存使用相对于样本大小呈线性。我们的新算法优于现有的替代算法，使MGWR适用于大型空间数据集。

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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来源期刊

International Journal of Geographical Information Science 地学-计算机：信息系统

CiteScore

11.00

自引率

7.00%

发文量

审稿时长

9 months

期刊介绍： International Journal of Geographical Information Science provides a forum for the exchange of original ideas, approaches, methods and experiences in the rapidly growing field of geographical information science (GIScience). It is intended to interest those who research fundamental and computational issues of geographic information, as well as issues related to the design, implementation and use of geographical information for monitoring, prediction and decision making. Published research covers innovations in GIScience and novel applications of GIScience in natural resources, social systems and the built environment, as well as relevant developments in computer science, cartography, surveying, geography and engineering in both developed and developing countries.