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Learning and Inference in the Knowledge Plane

Learning and Inference in the Knowledge Plane. Thomas G. Dietterich School of EECS Oregon State University Corvallis, Oregon 97331 http://www.eecs.oregonstate.edu/~tgd. Traffic. Network Model. Performance Measures. Configurations. Claim: KP applications will be driven by learned models.

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Learning and Inference in the Knowledge Plane

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  1. Learning and Inference in the Knowledge Plane Thomas G. Dietterich School of EECS Oregon State University Corvallis, Oregon 97331 http://www.eecs.oregonstate.edu/~tgd

  2. Traffic Network Model Performance Measures Configurations Claim: KP applications will be driven by learned models Example: configuration/traffic model captures the tripartite relationship between network configurations, traffic properties, and network performance measures. Configuration X + Traffic Y ) Performance level Z

  3. Traffic Performance Measures Configurations Network Model Drives Configuration traffic mix performance objectives Network Model Configuration Engine proposed network configuration

  4. Roles for Learning • Learn network model • measure… • configuration information • traffic properties (protocol mix, session lengths, error rates …) • performance measures (throughput, E2E delays, errors, application-level measures) • fit model

  5. Roles for Learning (2) • Improving the configuration engine • Learn repair rules • Observe operator-initiated repairs • Learn heuristics for rapidly finding good solutions • Cache previous good solutions

  6. Traffic Sensor Performance Measures Configurations Variables Measured, Error Bounds, Costs Models for WHY Sensor Model Network Model

  7. Sensor Model Network Model observed anomaly or user’s complaint Diagnosis Engine Sensors Interventions diagnosis and recommended repair Network and Sensor Models Drive Diagnosis and Repair DE chooses measurement or intervention DE executes measurement or intervention DE outputs diagnosis User makes complaint DE receives results

  8. Example: Bayesian Network Drives Diagnosis

  9. Semantics • Every node stores a conditional probability distribution:

  10. Diagnostic Process • Interventions: • Observation: Observe Radio • Repair attempts: Fill gas tank • Observe & Repair: Inspect fuel pump, replace if bad • Algorithm: • Compute P(component is bad | evidence) • Repair component that maximizes P(bad)/cost • Choose observation that maximizes value of information

  11. Example Choose SparkPlugs as next component to repair. Repair it. Update probabilities, and repeat.

  12. Role for Learning • Learn sensor model • Basic sensor model is manually engineered • Learn error bounds and costs (e.g., time delay, traffic impact)

  13. Anomaly Detection Models Monitor network for unusual traffic, configurations, and routes Measure of “Normalness” Traffic Measure of “Normalness” Configurations Measure of “Normalness” Routes Anomalies are phenomena to be understood, not alarms to be raised.

  14. Role for Learning • Learn these models by observing traffic, configurations, routes

  15. Model Properties • Spatially Distributed • Replicated/Cached • Hierarchical • Multiple levels of abstraction • Constantly Maintained

  16. Available Technology:Configuration Engine • Existing formulations: constraint-satisfaction problems (CSP) with objective function • Systematic and repair-based methods • Some ideas for how to incorporate learning

  17. Available Technology (2):Diagnostic Engine • Special cases where optimal diagnosis is tractable • Single fault; all actions are repair attempts • Single fault; all actions are pure observations • Widely-used heuristic • One-step value of information (greedy approx) • Fully-general approach • Partially-observable Markov Decision Process • Some approximation algorithms are available

  18. Available Technology (3): Anomaly Detection • Unsupervised Learning Methods • Clustering • Probability Density Estimation • One-class Classification Formulation

  19. Research Gaps (1): Spatially-distributed multi-level models of traffic • What are the right variables to model? • Packet-level statistics (RTT, throughput, jitter, …) • Connection-level statistics • Routing statistics • Application statistics • What levels reveal anomalies? • What levels can best be related to performance goals and configuration settings?

  20. Research Gaps (2): Learning models of configurations • Network components • Switches, routers, firewalls, web servers, file servers, wireless access points, … • LANs and WANs • Autonomous Systems • What are the right levels of abstraction? • Can these things be observed?

  21. Research Gaps (3): Relational learning • Network models are relational • (traffic, configuration, performance) • network structure is a graph • routes are paths with attached properties • Relational modeling is a relatively young area of ML

  22. Research Gaps (4): Distributed learning and reasoning • Distributed model construction • Bottom-up summary statistics (easy) • Mixed (bottom-up/top-down) information flow (unexplored) • Essential for higher-level modeling • Opportunities for data sharing at lower levels • Distributed configuration • Distributed diagnosis • Opportunities for inference sharing

  23. Research Gap (5):Openness • Standard AI Models assume a fixed set of classes/categories/faults/components • How do we reason about the possible existence of new classes, new components, new protocols (including intrusions/worms)? • How do we evaluate such systems?

  24. Application/Model Interface • Subscription? • Applications subscribe to regular model updates/summaries • Applications specify the models they want the KP to build/maintain • Query? • Applications make queries to models?

  25. Application/KP Interface: Two possibilities • KP provides inference services in addition to model services • WHY? client sends end-user complaint to TP where inference engine operates • Inference is performed on end-user machine? • WHY? client does inference, just sends queries to TPs • Some inference about end-user’s machine needs to happen locally. Maybe view as local TP?

  26. Concluding Remarks • KP Applications will be driven by learned models • traffic models • sensor models • models of “normalness” • Models are acquired by mix of human authoring and machine learning • Main research challenges arise from multiple levels of abstraction and world-wide distribution

  27. KP support for learning models • Example: HP Labs email loop detection system • Bronstein, Das, Duro, Friedrich, Kleyner, Mueller, Singhal, Cohen (2001) • Convert mail log data into four “detectors” and combine using a Bayesian network

  28. KP support for learning models(2) • Variables to be measured: • Raw sensors: mail log (when received, from, to, size, time of delivery attempt, status of attempt) • Derived variables (10-minute windows) • IM: # incoming msgs • IMR: # incoming msgs / # outgoing msgs • PEAK: magnitude of peak bin in message size histogram • SHARPNESS: ratio of magnitude of peak bin to average size of four neighboring non-empty bins (excluding 2 nearest-nbr bins on either side of peak bin) • Summary statistics • mean and standard deviation of the derived variables trimmed to remove outliers beyond ±3.5 σ

  29. KP Services • Provide a language so that I can define • raw features • derived features • summary statistics • Provide subscription service so that I can collect the summary statistics • automatic or semi-automatic support for aggregating summary statistics from multiple sources (e.g., multiple border SMTP servers) • Provide subscription service so that I can sample the derived features (to build a supervised training data set)

  30. Statistical Aggregation Middleware • Routines for aggregating statistics • Example: given • S1 = i x1,i and N1 • S2 = j x2,j and N2, from two independent sources • I can compute • S3 = S1 + S2 and N3 = N1 + N2 • From these, I can compute the mean value: •  = S3/N3 • To compute variance, I need SS1 = i x21,i

  31. Model-Fitting Middleware • Given summary statistics, compute probabilities in a Bayesian network Mail Loop IM IMR PEAK SHARPNESS

  32. Sufficient Statistics • Andrew Moore (CMU): For nearly every learning algorithm, there is a set of statistics sufficient to permit that algorithm to fit its models • There is usually a scalable way of collecting and aggregating these sufficient statistics

  33. One KP Goal • Design the services for defining sensors, defining derived variables, defining sufficient statistics, and defining aggregation methods • Scalable, secure, etc.

  34. Hierarchical Modeling • Abstract (or aggregate) model could treat conclusions/assertions of other models as input variables • “One model’s inference is another model’s raw data” • probably requires associated meta-data: provenance, age of original data • major issue: assessing the independence of multiple data sources (don’t want to double-count evidence): requires knowledge of KP/network topology

  35. Fusing Multiple Subscriptions • Multiple KPs and/or multiple KPapps may register for the same sufficient statistics • Fuse their subscriptions to save computation • Keep meta data on non-independence

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