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EVENT DETECTION IN TIME SERIES OF MOBILE COMMUNICATION GRAPHS
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Title: EVENT DETECTION IN TIME SERIES OF MOBILE COMMUNICATION GRAPHS
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EVENT DETECTION IN TIME SERIES OF MOBILE
COMMUNICATION GRAPHS
- Leman Akoglu Christos Faloutsos
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MOTIVATION
Anomaly and event (change-point) detection, is
the building block for many applications
- Cyber warfare
- Network intrusion
- Epidemic outbreaks
- Fault detection in engineering systems
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DATA DESCRIPTION
- Texting interactions of mobile phone users from a
phone service company in a large city in India - who-texts-whom network
- edge-weighted SMS
- gt2 million customers
- 50 million SMS interactions
- Dec. 1, 2007 to May 31, 2008
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PROBLEM STATEMENT
- Given a graph that changes over time,
- can we identify
- 1) change detection time points at which
many of the N nodes change their behavior
significantly? - 2) attribution top k nodes which contribute
to the change in behavior the most?
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PROBLEM STATEMENT
- Two main considerations
- N is very large (on the order of 106)
- ? monitoring each node independently is not
practical. - Anomaly is defined in a collective setting
- ? a time-point/node is anomalous if
different than others
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OVERVIEW OF OUR METHOD
- Extract features for nodes
- Derive the typical behavior (eigen-behavior) of
nodes - Compare eigenbehaviors over time
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FEATURE EXTRACTION
- Extract features from
- egonets for all nodes
- Indegree/outdegree
- Inweight/outweight
- Number of neighbors
- Number of edges
- Reciprocal degree
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DATA IN 3-D
Nodes (gt2 million)
Features (12)
Time (183 days)
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OVERVIEW OF OUR METHOD
- Extract features for nodes
- Derive the typical behavior (eigen-behavior) of
nodes - Compare eigenbehaviors over time
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DERIVING EIGEN-BEHAVIOR
W
N
Finweight
principal eigenvector ?typical
behavior ?eigen-behavior
active node ? high score e.g. nodes 1, 2, 6
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OVERVIEW OF OUR METHOD
- Extract features for nodes
- Derive the typical behavior (eigen-behavior) of
nodes - Compare eigenbehaviors over time
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TRACKING BEHAVIOR OVER TIME
W
W
N
Finweight
past pattern
change metric angle ?
eigen-behavior at t
eigen-behaviors
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DETECTED CHANGE POINTS
EXPERIMENTS
Finweight
Christian New Year
Hindi New Year
back to work
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DETECTED CHANGE POINTS
EXPERIMENTS
F reciprocal degree
F out-degree
Similar behavior for other features
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PROBLEM STATEMENT
- Given a graph that changes over time,
- can we identify
- 1) change detection time points at which
many of the N nodes change their behavior
significantly? - 2) attribution top k nodes which contribute
to the change in behavior the most?
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ATTRIBUTING CHANGE TO NODES
EXPERIMENTS
Finweight
DEC 26
no change zone
r(t-1)
u(t)
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ATTRIBUTING CHANGE TO NODES
EXPERIMENTS
26 DEC
26 DEC
SMS received
time (days)
Time series of top 5 nodes marked
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ATTRIBUTING CHANGE TO NODES
EXPERIMENTS
JAN 2
back to work
reciprocal degree
time (days)
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CONCLUSION
- An algorithm based on tracking eigenbehavior
patterns over time - change detection spot time-points at which
behavior changes significantly - attribution spot nodes that cause the most
change - Experiments on real, SMS messages, 2M users,
over 6 months
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THANK YOU www.cs.cmu.edu/lakoglu Email
lakoglu_at_cs.cmu.edu
attribution
change detection
