Decentralized Movement Pattern Detection amongst Mobile Geosensor Nodes

Laube, Patrick; Duckham, Matt; Wolle, Thomas

doi:10.1007/978-3-540-87473-7_13

Cited by 24 publications

(14 citation statements)

References 28 publications

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“…Benkert et al (2008) presented several efficient centralized algorithms for approximating the flock detection problem for short flock contiguities (small k). Similarly, Laube et al (2008) presented a decentralized algorithm based on a local extrapolation heuristic, and an analysis of the inevitable errors of omission and/or commission associated with any heuristic. In both cases the results of the presented algorithms depend very much on the characteristics of the input point sets and there is no single best solution on offer.…”

Section: Refinementioning

confidence: 99%

“…In contrast to the decentralized flock detector FLAGS presented in Laube et al (2008), the DDIG algorithm discussed here requires localized sensor nodes. Constant localization has obvious advantages but comes at a potentially high price in terms of battery life, weight, and hardware costs.…”

Section: Experiments #1: Deferred Processingmentioning

confidence: 99%

“…Although GPS provides one possible positioning technology, many other positioning technologies are available and more suited to low-power, low-cost geosensor networks (such as WiFi triangulation, RF or ultrasound range-and direction-finding, Zhao and Guibas 2004). Whereas localization may be part of the initialization of a static network, in mobile wireless sensor networks (mWSN, Laube et al 2008), a node's position constantly changes and needs to be constantly updated. Previous work on the decentralized detection of flocking patterns did not imply position knowledge , this paper by contrast explicitly aims at exploiting the advantage of sensor nodes knowing their coordinate position.…”

Section: Introductionmentioning

confidence: 99%

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Deferred decentralized movement pattern mining for geosensor networks

Laube

Duckham

Palaniswami

2011

International Journal of Geographical Information Science

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This paper presents an algorithm for decentralized (in-network) data mining of the movement pattern flock amongst mobile geosensor nodes. The algorithm DDIG (Deferred Decentralized Information Grazing) allows roaming sensor nodes to 'graze' over time more information than they could access through their spatially limited perception range alone. The algorithm requires an intrinsic temporal deferral for pattern mining, as sensor nodes must be enabled to collect, memorize, exchange, and integrate their own and their neighbors' most current movement history before reasoning about patterns. A first set of experiments with trajectories of simulated agents showed that the algorithm accuracy increases with growing deferral. A second set of experiments with trajectories of actual tracked livestock reveals some of the shortcomings of the conceptual flocking model underlying DDIG in the context of a smart farming application. Finally, the experiments underline the general conclusion that decentralization in spatial computing can result in imperfect, yet useful knowledge. This paper presents an algorithm for decentralized (in-network) data mining of the movement pattern flock amongst mobile geosensor nodes. The algorithm DDIG (Deferred Decentralized Information Grazing) allows roaming sensor nodes to 'graze' over time more information than they could access through their spatially limited perception range alone. The algorithm requires an intrinsic temporal deferral for pattern mining, as sensor nodes must be enabled to collect, memorize, exchange, and integrate their own and their neighbors' most current movement history before reasoning about patterns. A first set of experiments with trajectories of simulated agents showed that the algorithm accuracy increases with growing deferral. A second set of experiments with trajectories of actual tracked livestock reveals some of the shortcomings of the conceptual flocking model underlying DDIG in the context of a smart farming application. Finally, the experiments underline the general conclusion that decentralization in spatial computing can result in imperfect, yet useful knowledge.

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Section: Refinementioning

confidence: 99%

Section: Experiments #1: Deferred Processingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Deferred decentralized movement pattern mining for geosensor networks

Laube

Duckham

Palaniswami

2011

International Journal of Geographical Information Science

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“…Decentralized algorithms are an active area of research in spatial computing and spatial information science (e.g. [1][2][3][4]), in part because they are well suited to use with new technologies like wireless sensor networks and vehicle ad hoc networks (VANETs). Using a decentralized algorithm enables queries about spatiotemporal events to be satisfied partly or wholly in the network, without the need to communicate and collate information about object movements within a single, centralized information system.…”

Section: Introductionmentioning

confidence: 99%

“…if count(*) from tmp ≥ n and (select time from g i > select time from last.j ) then 18: insert into j values (i d, time 2 , f ids 2 ) 19: send (link, j , n, l) to cordon with ID (select c from g i ) 20: if count(*) from j ≥ l then 21: return j as record of group movement Algorithm 5. In this algorithm, each cordon stores groups of at least n fish passing in the same direction within the time period t. This group table also includes the time fish passed the cordon and the ID of the cordon they were swimming toward.…”

mentioning

confidence: 99%

Decentralized Monitoring of Moving Objects in a Transportation Network Augmented with Checkpoints

Both

Duckham

Laube

et al. 2012

The Computer Journal

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This paper examines efficient and decentralized monitoring of objects moving in a transportation network. Previous work in moving object monitoring has focused primarily on centralized information systems, like moving object databases and geographic information systems. In contrast, in this paper monitoring is in-network, requiring no centralized control and allowing for substantial spatial constraints to the movement of information. The transportation network is assumed to be augmented with fixed checkpoints that can detect passing mobile objects. This assumption is motivated by many practical applications, from traffic management in vehicle ad hoc networks to habitat monitoring by tracking animal movements. In this context, this paper proposes and evaluates a family of efficient decentralized algorithms for capturing, storing and querying the movements of objects. The algorithms differ in the restrictions they make on the communication and sensing constraints to the mobile nodes and the fixed checkpoints. The performance of the algorithms is evaluated and compared with respect to their scalability (in terms of communication and space complexity), and their latency (the time between when a movement event occurs, and when all interested nodes are updated with records about that event). The conclusions identify three key principles for efficient decentralized monitoring of objects moving past checkpoints: structuring computation around neighboring checkpoints; taking advantage of mobility diffusion and separating the generation and querying of movement information.

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Computational Movement Analysis

Laube

2014

SpringerBriefs in Computer Science

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Decentralized Movement Pattern Detection amongst Mobile Geosensor Nodes

Cited by 24 publications

References 28 publications

Deferred decentralized movement pattern mining for geosensor networks

Deferred decentralized movement pattern mining for geosensor networks

Decentralized Monitoring of Moving Objects in a Transportation Network Augmented with Checkpoints

Computational Movement Analysis

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