稳定快速的地理加权Poisson回归的线性化

IF 4.3 1区 地球科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS
D. Murakami, N. Tsutsumida, T. Yoshida, T. Nakaya, Binbin Lu, P. Harris
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引用次数: 0

摘要

摘要尽管地理加权泊松回归(GWPR)是空间索引计数数据的一种流行回归,但与线性地理加权回归(GWR)相比,它的发展相对有限,后者提出了许多扩展(如多尺度GWR、可扩展GWR)。GWPR的薄弱发展可归因于支撑泊松回归模型的计算成本和识别问题。本研究通过在GWPR模型中引入对数线性近似来克服这些瓶颈,提出了线性化的GWPR(L-GWPR)。由于L-GWPR模型与高斯GWR模型相同,因此它不存在识别问题,易于实现,计算效率高,并具有类似的扩展潜力。具体来说,L-GWPR不需要双环算法,这使得GWPR对于大样本来说很慢。此外,我们通过引入脊正则化来扩展L-GWPR以增强其稳定性(正则化L-GWPR)。蒙特卡罗实验的结果证实了正则化L-GWPR在计算上准确有效地估计局部系数。最后,我们通过东京的犯罪分析,比较了GWPR和正则化L-GWPR。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A linearization for stable and fast geographically weighted Poisson regression
Abstract Although geographically weighted Poisson regression (GWPR) is a popular regression for spatially indexed count data, its development is relatively limited compared to that found for linear geographically weighted regression (GWR), where many extensions (e.g. multiscale GWR, scalable GWR) have been proposed. The weak development of GWPR can be attributed to the computational cost and identification problem in the underpinning Poisson regression model. This study proposes linearized GWPR (L-GWPR) by introducing a log-linear approximation into the GWPR model to overcome these bottlenecks. Because the L-GWPR model is identical to the Gaussian GWR model, it is free from the identification problem, easily implemented, computationally efficient, and offers similar potential for extension. Specifically, L-GWPR does not require a double-loop algorithm, which makes GWPR slow for large samples. Furthermore, we extended L-GWPR by introducing ridge regularization to enhance its stability (regularized L-GWPR). The results of the Monte Carlo experiments confirmed that regularized L-GWPR estimates local coefficients accurately and computationally efficiently. Finally, we compared GWPR and regularized L-GWPR through a crime analysis in Tokyo.
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来源期刊
CiteScore
11.00
自引率
7.00%
发文量
81
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.
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