基于异构多源自监督的深度空间预测

IF 1.2 Q4 REMOTE SENSING
Minxing Zhang, Dazhou Yu, Yun-Qing Li, Liang Zhao
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引用次数: 0

摘要

空间预测是根据收集的地理空间数据,预测目标变量在任意位置的值,如PM2.5值和温度。在获取异质空间信息(如土壤条件、降水率、小麦产量)以用于地方、区域和全球范围的地理建模和决策方面,它极大地影响了地球科学的关键研究课题。地面原位传感器收集的原位数据和卫星或飞机收集的遥感数据是这项任务的两个重要数据来源。现场数据相对准确,但稀疏且分布不均。遥感数据覆盖空间大,但时空分辨率低、粗糙,易受干扰。如何协同这两种数据类型的互补优势仍然是一个巨大的挑战。此外,在处理空间自相关和异质性之间的权衡时,很难对未知的空间预测映射进行建模。第三,在没有大量信息损失的情况下表示空间关系也是一个关键问题。为了应对这些挑战,我们提出了一种新的异构自监督空间预测(HSSP)框架,该框架通过最小化原位观测和遥感观测之间的不一致性来协同多源数据。我们提出了一种新的深度几何空间插值模型作为预测骨干,该模型通过考虑距离和方向信息,基于现有观测结果自动插值未知位置的目标变量的值。我们提出的插值器被证明是流行插值方法的一般形式,并保留了空间信息。通过一种新颖的误差补偿框架来增强空间预测,以捕捉由于空间异质性引起的预测不一致性。在真实世界的数据集上进行了大量实验,证明了我们的模型在性能上优于最先进的模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Spatial Prediction via Heterogeneous Multi-source Self-supervision
Spatial prediction is to predict the values of the targeted variable, such as PM2.5 values and temperature, at arbitrary locations based on the collected geospatial data. It greatly affects the key research topics in geoscience in terms of obtaining heterogeneous spatial information (e.g., soil conditions, precipitation rates, wheat yields) for geographic modeling and decision-making at local, regional, and global scales. In situ data, collected by ground-level in situ sensors, and remote sensing data, collected by satellite or aircraft, are two important data sources for this task. In situ data are relatively accurate while sparse and unevenly distributed. Remote sensing data cover large spatial areas, but are coarse with low spatiotemporal resolution and prone to interference. How to synergize the complementary strength of these two data types is still a grand challenge. Moreover, it is difficult to model the unknown spatial predictive mapping while handling the tradeoff between spatial autocorrelation and heterogeneity. Third, representing spatial relations without substantial information loss is also a critical issue. To address these challenges, we propose a novel Heterogeneous Self-supervised Spatial Prediction (HSSP) framework that synergizes multi-source data by minimizing the inconsistency between in situ and remote sensing observations. We propose a new deep geometric spatial interpolation model as the prediction backbone that automatically interpolates the values of the targeted variable at unknown locations based on existing observations by taking into account both distance and orientation information. Our proposed interpolator is proven to both be the general form of popular interpolation methods and preserve spatial information. The spatial prediction is enhanced by a novel error-compensation framework to capture the prediction inconsistency due to spatial heterogeneity. Extensive experiments have been conducted on real-world datasets and demonstrated our model’s superiority in performance over state-of-the-art models.
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来源期刊
CiteScore
4.40
自引率
5.30%
发文量
43
期刊介绍: ACM Transactions on Spatial Algorithms and Systems (TSAS) is a scholarly journal that publishes the highest quality papers on all aspects of spatial algorithms and systems and closely related disciplines. It has a multi-disciplinary perspective in that it spans a large number of areas where spatial data is manipulated or visualized (regardless of how it is specified - i.e., geometrically or textually) such as geography, geographic information systems (GIS), geospatial and spatiotemporal databases, spatial and metric indexing, location-based services, web-based spatial applications, geographic information retrieval (GIR), spatial reasoning and mining, security and privacy, as well as the related visual computing areas of computer graphics, computer vision, geometric modeling, and visualization where the spatial, geospatial, and spatiotemporal data is central.
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