Deep learning for time series data:
"Arun Kejariwal (Independent) and Ira Cohen (Anodot) share a novel two-step approach for building more reliable prediction models by integrating anomalies in them. The first step uses anomaly detection algorithms to discover anomalies in a time series in the training data. In the second, multip...
Gespeichert in:
| Beteilige Person: | |
|---|---|
| Weitere beteiligte Personen: | |
| Format: | Elektronisch Video |
| Sprache: | Englisch |
| Veröffentlicht: |
[Place of publication not identified]
O'Reilly
2019
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| Schlagwörter: | |
| Links: | https://learning.oreilly.com/library/view/-/0636920339632/?ar |
| Zusammenfassung: | "Arun Kejariwal (Independent) and Ira Cohen (Anodot) share a novel two-step approach for building more reliable prediction models by integrating anomalies in them. The first step uses anomaly detection algorithms to discover anomalies in a time series in the training data. In the second, multiple prediction models, including time series models and deep networks, are trained, enriching the training data with the information about the anomalies discovered in the first step. Anomaly detection for individual time series is a necessary but insufficient step due to the fact that anomaly detection over a set of live data streams may result in anomaly fatigue, thereby limiting effective decision making. One way to address the above is to carry out anomaly detection in a multidimensional space. However, this is typically very expensive computationally and hence not suitable for live data streams. Another approach is to carry out anomaly detection on individual data streams and then leverage correlation analysis to minimize false positives, which in turn helps in surfacing actionable insights faster. Anomaly detection for individual time series is a necessary but insufficient step due to the fact that anomaly detection over a set of live data streams may result in anomaly fatigue, thereby limiting effective decision making. One way to address the above is to carry out anomaly detection in a multidimensional space. However, this is typically very expensive computationally and hence not suitable for live data streams. Another approach is to carry out anomaly detection on individual data streams and then leverage correlation analysis to minimize false positives, which in turn helps in surfacing actionable insights faster."--Resource description page |
| Beschreibung: | Title from title screen (viewed November 14, 2019) |
| Umfang: | 1 Online-Ressource (1 streaming video file (42 min., 29 sec.)) |
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| spelling | Kejariwal, Arun VerfasserIn aut Deep learning for time series data Arun Kejariwal, Ira Cohen [Place of publication not identified] O'Reilly 2019 1 Online-Ressource (1 streaming video file (42 min., 29 sec.)) zweidimensionales bewegtes Bild tdi rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Title from title screen (viewed November 14, 2019) "Arun Kejariwal (Independent) and Ira Cohen (Anodot) share a novel two-step approach for building more reliable prediction models by integrating anomalies in them. The first step uses anomaly detection algorithms to discover anomalies in a time series in the training data. In the second, multiple prediction models, including time series models and deep networks, are trained, enriching the training data with the information about the anomalies discovered in the first step. Anomaly detection for individual time series is a necessary but insufficient step due to the fact that anomaly detection over a set of live data streams may result in anomaly fatigue, thereby limiting effective decision making. One way to address the above is to carry out anomaly detection in a multidimensional space. However, this is typically very expensive computationally and hence not suitable for live data streams. Another approach is to carry out anomaly detection on individual data streams and then leverage correlation analysis to minimize false positives, which in turn helps in surfacing actionable insights faster. Anomaly detection for individual time series is a necessary but insufficient step due to the fact that anomaly detection over a set of live data streams may result in anomaly fatigue, thereby limiting effective decision making. One way to address the above is to carry out anomaly detection in a multidimensional space. However, this is typically very expensive computationally and hence not suitable for live data streams. Another approach is to carry out anomaly detection on individual data streams and then leverage correlation analysis to minimize false positives, which in turn helps in surfacing actionable insights faster."--Resource description page Machine learning Electronic data processing Apprentissage automatique Electronic data processing (OCoLC)fst00906956 Machine learning (OCoLC)fst01004795 Electronic videos Cohen, Ira M. MitwirkendeR ctb |
| spellingShingle | Kejariwal, Arun Deep learning for time series data Machine learning Electronic data processing Apprentissage automatique Electronic data processing (OCoLC)fst00906956 Machine learning (OCoLC)fst01004795 Electronic videos |
| subject_GND | (OCoLC)fst00906956 (OCoLC)fst01004795 |
| title | Deep learning for time series data |
| title_auth | Deep learning for time series data |
| title_exact_search | Deep learning for time series data |
| title_full | Deep learning for time series data Arun Kejariwal, Ira Cohen |
| title_fullStr | Deep learning for time series data Arun Kejariwal, Ira Cohen |
| title_full_unstemmed | Deep learning for time series data Arun Kejariwal, Ira Cohen |
| title_short | Deep learning for time series data |
| title_sort | deep learning for time series data |
| topic | Machine learning Electronic data processing Apprentissage automatique Electronic data processing (OCoLC)fst00906956 Machine learning (OCoLC)fst01004795 Electronic videos |
| topic_facet | Machine learning Electronic data processing Apprentissage automatique Electronic videos |
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