Abstract
Spatio-temporal databases aim at appropriately managing moving objects so as to support various types of queries. While much research has been conducted on developing query processing techniques, less effort has been made to address the issue of when and how to update location information of moving objects. Previous work shifts the workload of processing updates to each object which usually has limited CPU and battery capacities. This results in a tremendous processing overhead for each moving object. In this paper, we focus on designing efficient update strategies for two important types of moving objects, free-moving objects (FMOs) and network-constrained objects (NCOs), which are classified based on object movement models. For FMOs, we develop a novel update strategy, namely the FMO update strategy (FMOUS), to explicitly indicate a time point at which the object needs to update location information. As each object knows in advance when to update (meaning that it does not have to continuously check), the processing overhead can be greatly reduced. In addition, the FMO update procedure (FMOUP) is designed to efficiently process the updates issued from moving objects. Similarly, for NCOs, we propose the NCO update strategy (NCOUS) and the NCO update procedure (NCOUP) to inform each object when and how to update location information. Extensive experiments are conducted to demonstrate the effectiveness and efficiency of the proposed update strategies.
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Project supported by the National Science Council of Taiwan (Nos. NSC-102-2119-M-244-001 and MOST-103-2119-M-244-001)
A preliminary version was presented at AINA, March 25–28, 2013, Barcelona, Spain
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Huang, YK., Lin, LF. Designing a location update strategy for free-moving and network-constrained objects with varying velocity. J. Zhejiang Univ. - Sci. C 15, 675–686 (2014). https://doi.org/10.1631/jzus.C1300337
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DOI: https://doi.org/10.1631/jzus.C1300337