A-GWR:基于增强型地理加权回归的快速准确地理空间推断

Proceedings of the 29th International Conference on Advances in Geographic Information Systems Pub Date : 2021-11-02 DOI:10.1145/3474717.3484260

Mohammad Reza Shahneh, Samet Oymak, A. Magdy

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引用次数: 2

摘要

地理加权回归(GWR)是一种在地理空间数据分析中有着广泛应用的开创性技术。然而，在大数据时代，它在表达能力(即预测能力和可扩展性)方面存在严重缺陷。这项工作提出了增强GWR (A-GWR)来缓解这些缺点。a - gwr采用了一种新的技术，即无状态mgwr或S-MGWR，通过允许不同的训练数据特征在不同的空间尺度上产生影响，从而丰富了预测能力。S-MGWR采用定制的黑盒优化方法，快速有效地发现最优参数。此外，A-GWR还将S-MGWR与随机森林模型等通用模型模块化结合。此外，A-GWR通过对分区数据进行操作来实现可伸缩性，以适应紧张的计算预算。我们在各种真实和合成数据集上的广泛实验表明，与最先进的竞争对手相比，所提出的技术具有可扩展性和准确性方面的优势。

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A-GWR: Fast and Accurate Geospatial Inference via Augmented Geographically Weighted Regression

Geographically Weighted Regression (GWR) is a seminal technique with rich applications in geospatial data analysis. However, it has critical drawbacks in the age of big data in terms of expressiveness, i.e., predictive power, and scalability. This work proposes Augmented GWR (A-GWR) that alleviates these drawbacks. A-GWR adapts a novel technique, Stateless-MGWR or S-MGWR, that enriches the predictive power by allowing different training data features to influence at different spatial scales. S-MGWR uses a customized black-box optimization approach for discovering optimal parameters in a fast and efficient way. In addition, A-GWR modularly combines S-MGWR with versatile models such as random forest models. Moreover, A-GWR enables scalability by operating on partitioned data to adapt to tight computational budgets. Our extensive experiments on various real and synthetic datasets demonstrate the scalability and accuracy benefits of the proposed techniques over state-of-the-art competitors.

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Proceedings of the 29th International Conference on Advances in Geographic Information Systems

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