Knowledge Discovery in Spatial Databases

Ester, Martin; Kriegel, Hans‐Peter; Sander, Jörg

doi:10.1007/978-3-642-60243-6_1

Cited by 359 publications

(468 citation statements)

References 7 publications

(9 reference statements)

Supporting

Mentioning

461

Contrasting

Unclassified

Order By: Relevance

“…Specifically we study outlier detection in the neighborhoods based on spatial relationships and (a) JC, (b) SC and (c) JC (AND/OR) SC C. Comparison with other approaches: In order to discuss the improvements that accounting for heterogeneity will bring about in our approach, we first lay out some results with traditional approaches which give us a context for the results we obtained in our approach. Specifically, we discuss the results for -Comparison of our approach for neighborhood formation with traditional cardinality based approach (Ester et al 1999;Shekhar et al 2001). -Comparison of our approach with Graph based spatial anomaly detection technique (Shekhar et al 2001).…”

Section: Resultsmentioning

confidence: 98%

“…Thus, identifying the neighborhood based only on the spatial relationships would result in one big neighborhood. If we consider cardinality based neighborhood (Ester et al 1999;Shekhar et al 2001) we can have several possible neighborhood formations, since it is not order invariant. Moreover determination of cardinality is based on user's choice similar to our coefficient threshold choice.…”

Section: Comparison Of Neighborhood Formation With Traditional Cardinmentioning

confidence: 99%

See 1 more Smart Citation

Spatial neighborhood based anomaly detection in sensor datasets

Janeja

Adam

Atluri

et al. 2010

Data Min Knowl Disc

View full text Add to dashboard Cite

Success of anomaly detection, similar to other spatial data mining techniques, relies on neighborhood definition. In this paper, we argue that the anomalous behavior of spatial objects in a neighborhood can be truly captured when both (a) spatial autocorrelation (similar behavior of nearby objects due to proximity) and (b) spatial heterogeneity (distinct behavior of nearby objects due to difference in the underlying processes in the region) are taken into consideration for the neighborhood definition. Our approach begins by generating micro neighborhoods around spatial objects encompassing all the information about a spatial object. We selectively merge these based on spatial relationships accounting for autocorrelation and inferential relationships accounting for heterogeneity, forming macro neighborhoods. In such neighborhoods, we then identify (i) spatio-temporal outliers, where individual sensor readings are anomalous, (ii) spatial outliers, where the entire sensor is an anomaly, and (iii) spatio-temporally coalesced outliers, where a group of spatio-temporal outliers in the macro neighborhood are separated by a small time lag indicating the traversal Responsible editor: Sanjay Chawla. 123 222 V. P. Janeja et al.of the anomaly. We demonstrate the effectiveness of our approach in neighborhood formation and anomaly detection with experimental results in (i) water monitoring and (ii) highway traffic monitoring sensor datasets. We also compare the results of our approach with an existing approach for spatial anomaly detection.

show abstract

Section: Resultsmentioning

confidence: 98%

Section: Comparison Of Neighborhood Formation With Traditional Cardinmentioning

confidence: 99%

Spatial neighborhood based anomaly detection in sensor datasets

Janeja

Adam

Atluri

et al. 2010

Data Min Knowl Disc

View full text Add to dashboard Cite

show abstract

“…To calculate a clustering decision map for the given set of feature vectors, we will need to make a choice on a clustering algorithm. Within this article, we chose the DBSCAN algorithm by Ester et al [28]. In contrast to other clustering algorithms, DBSCAN is capable of identifying noisy points and, most importantly, finding clusters of non-convex shape, as we are not able to make statements about the shape of the clusters we expect to find.…”

Section: Clusteringmentioning

confidence: 99%

Anomaly detection in injection molding process data based on unsupervised learning

Schiffers¹

2018

Zeitschrift Kunststofftechnik

View full text Add to dashboard Cite

Anomaly detection in injection molding process data based on unsupervised learningPlastic processing companies in high-wage countries are facing continuously increasing cost and quality pressures. In many applications, a 100 % quality control leads to unreasonable efforts. Hence, quality forecasting or control based on process data would be desirable. Neural Networks have been applied. However, their success depends on the appropriate labeling of the process data. Since during the process, it is usually unknown whether a good or bad part has been produced in one cycle, supervised machine learning is not applicable. Here, we present approaches to anomaly detection in injection molding process data by means of unsupervised machine learning. Anomalie-Erkennung in Spritzgieß-Prozessdaten auf Basis von unüberwachtem LernenKunststoffverarbeitende Unternehmen in Hochlohnländern sind mit einem kontinuierlich steigendem Kosten-und Qualitätsdruck konfrontiert. Eine 100 %-Qualitätskontrolle ist in vielen Anwendungsfällen jedoch mit einem nicht vertretbaren Aufwand verbunden. Qualitätsprognose bzw. -regelung auf Basis von Prozessdaten wäre wünschenswert. Neuronale Netzwerke wurden bereits angewandt. Ihr Erfolg beruht aber auf dem Vorhandensein von gemäß ok/not ok annotierten Daten. Da bei der Betrachtung von Prozessdaten meist nicht bekannt ist, ob in einem Zyklus ein Gut-oder Schlechtteil produziert wurde, sind die überwachten Lernverfahren nicht anwendbar. Wir stellen deshalb Ansätze zur Anomalie-Erkennung in Spritzgieß-Prozessdaten mittels unüberwachter maschineller Lernverfahren vor. archivierte, peer-rezensierte Internetzeitschrift archival, peer-reviewed online Journal of the Scientific Alliance of Polymer Technology

show abstract

“…Peter Kriegel in 1996 [6]. In this algorithm it is assumed that in space there are «condensations» of objects that form a cluster to each other.…”

Section: Description Of the Dbscan Algorithm This Algorithm Was Propmentioning

confidence: 99%

Analysis of delays structure of interconnections in supercomputer by means of DBScan and divisive clustering algorithms

Salnikov¹,

Begaev²,

Maysuradze³

2018

Computational Mathematics and Information Technologies

View full text Add to dashboard Cite

In this paper we propose method for estimating and analysis measurements of delays in the computational cluster interconnection subsystem. Delays are combined into the set of pairs (source, destination). We have measurements of delays extracted by network_test2 utility from interconnections of following supercomputers: BlueGene/P, Lomonosov-1, Lomonosov-2 (Lomonosov MSU) and Jurope (Julich). We have clustered pairs of delays by DBscan and Divisive algorithms. Results of clusterisation revealed that DBScan is more accurate algorithm then divisive and allows to extract clusters, which correspond to the actual features in the supercomputer interconnections. Clusters gather near the same components of supercomputer network infrastructure. Gained clusters were visualized in 2-D by special tool, developed by authors.Introduction. Modern supercomputers are used to solve a wide range of problems, in particular: mathematical modeling and processing of large amounts of data. Supercomputers typically have an architecture of a computer cluster. Computations on supercomputers occur in parallel on many processing elements: cluster nodes equipped with multi-core processors, however, transfers between processors and cluster nodes can significantly slow down the parallel program. In order to minimize application performance losses, it is necessary to understand between which processors the delivery of messages occurs most quickly or vice versa slowly. It is necessary to optimally distribute the computations for the processors making up the supercomputer.

show abstract

Knowledge Discovery in Spatial Databases

Cited by 359 publications

References 7 publications

Spatial neighborhood based anomaly detection in sensor datasets

Spatial neighborhood based anomaly detection in sensor datasets

Anomaly detection in injection molding process data based on unsupervised learning

Analysis of delays structure of interconnections in supercomputer by means of DBScan and divisive clustering algorithms

Contact Info

Product

Resources

About