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Evolving Insider Threat Detection

This research focuses on developing an evolving insider threat detection system using unsupervised and supervised learning methods. It explores techniques such as graph-based anomaly detection and ensemble-based stream mining to detect evolving insider threats. The proposed method involves feature extraction, selection, and online learning. Experiments and results demonstrate the effectiveness of this approach in detecting insider threats.

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Evolving Insider Threat Detection

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  1. Evolving Insider Threat Detection PallabiParveen Dr. BhavaniThuraisingham (Advisor) Dept of Computer Science University of Texas at Dallas Funded by AFOSR

  2. Evolving Insider threat Detection • Unsupervised Learning • Supervised learning Outline

  3. Evolving Insider Threat Detection System log Testing on Data from weeki+1 j Anomaly? Feature Extraction & Selection Online learning System traces System Traces Unsupervised - Graph based Anomaly detection, GBAD weeki+1 Feature Extraction & Selection weeki Learning algorithm Gather Data from Weeki Update models Supervised - One class SVM, OCSVM Ensemble of Models Ensemble based Stream Mining

  4. Insider Threat Detection using unsupervised Learning based on Graph

  5. Insider Threat • Related Work • Proposed Method • Experiments & Results Outlines: Unsupervised Learning

  6. An Insider is someone who exploits, or has the intention to exploit, their legitimate access to assets for unauthorised purposes Definition of an Insider

  7. Computer Crime and Security Survey 2001 • $377 million financial losses due to attacks • 49% reported incidents of unauthorized network access by insiders Insider Threat is a real threat

  8. Insider threat • Detection • Prevention • Detection based approach: • Unsupervised learning, Graph Based Anomaly Detection • Ensembles based Stream Mining Insider Threat : Continue

  9. "Intrusion Detection Using Sequences of System Calls," Supervised learning by Hofmeyr • "Mining for Structural Anomalies in Graph-Based Data Representations (GBAD) for Insider Threat Detection." Unsupervised learning by Staniford-Chen and Lawrence Holder • All are static in nature. Cannot learn from evolving Data stream Related work

  10. Related Approaches and comparison with proposed solutions

  11. One approach to detecting insider threat is supervised learning where models are built from training data. • Approximately .03% of the training data is associated with insider threats (minority class) • While 99.97% of the training data is associated with non insider threat (majority class). • Unsupervised learning is an alternative for this. Why Unsupervised Learning?

  12. All are static in nature. Cannot learn from evolving Data stream Current decision boundary Data Stream Data Chunk Previous decision boundary Anomaly Data Normal Data Instances victim of concept drift Why Stream Mining

  13. Graph based anomaly detection (GBAD, Unsupervised learning) [2] + Ensemble based Stream Mining Proposed Method

  14. Determine normative pattern S using SUBDUE minimum description length (MDL) heuristic that minimizes: M(S,G) = DL(G|S) + DL(S) GBAD Approach

  15. S1 Unsupervised Pattern Discovery Graph compression and the minimum description length (MDL) principle • The best graphical pattern Sminimizes the description length of S and the description length of the graph G compressed with pattern S • where description length DL(S) is the minimum number of bits needed to represent S (SUBDUE) • Compression can be based on inexact matches to pattern S1 S1 S1 S1 S2 S2 S2

  16. Three algorithms for handling each of the different anomaly categories using Graph compression and the minimum description length (MDL) principle: • GBAD-MDL finds anomalous modifications • GBAD-P (Probability) finds anomalous insertions • GBAD-MPS (Maximum Partial Substructure) finds anomalous deletions Three types of anomalies

  17. A G B A B C D G A B C A D C G D C E A B C B G D D GBAD-P (insertion) Example of graph with normative pattern and different types of anomalies GBAD-MPS (Deletion) GBAD-MDL (modification) Normative Structure

  18. Graph based anomaly detection (GBAD, Unsupervised learning) + Ensemble based Stream Mining Proposed Method

  19. Continuous flow of data • Examples: Network traffic Characteristics of Data Stream Sensor data Call center records

  20. Single Model Incremental classification • Ensemble Model based classification Ensemble based is more effective than incremental approach. DataStream Classification

  21. C1 + C2 + + x,? C3 - input Individual outputs voting Ensemble output Classifier Ensemble of Classifiers

  22. Maintain K GBAD models • q normative patterns • Majority Voting • Updated Ensembles • Always maintain K models • Drop least accurate model Proposed Ensemble based Insider Threat Detection (EIT)

  23. D1 D2 D3 D5 D4 C4 C3 C5 C2 C1 Prediction • Build a model (with q normative patterns) from each data chunk • Keep the best K such model-ensemble • Example: for K = 3 Data chunks D4 D6 D5 Update Ensemble Testingchunk Model with Normative Patterns C5 C4 Ensemble based Classification of Data Streams (unsupervised Learning--GBAD) C1 C2 C4 C3 C5 Ensemble

  24. Ensemble (Ensemble A, test Graph t, Chunk S) • LABEL/TEST THE NEW MODEL • 1: Compute new model with q normative • Substructure using GBAD from S • 2: Add new model to A • 3: For each model M in A • 4: For each Class/ normative substructure, q in M • 5: Results1  Run GBAD-P with test Graph t & q • 6: Results2 Run GBAD-MDL with test Graph t & q • 7: Result3 Run GBAD-MPS with test Graph t & q • 8: Anomalies Parse Results (Results1, Results2, Results3) • End For • End For • 9: For each anomaly N in Anomalies • 10: If greater than half of the models agree • 11: Agreed Anomalies  N 12: Add 1 to incorrect values of the disagreeing models • 13: Add 1 to correct values of the agreeing models • End For • UPDATE THE ENSEMBLE: • 14: Remove model with • lowest (correct/(correct + incorrect)) ratio • End Ensemble EIT –U pseudocode

  25. 1998 MIT Lincoln Laboratory • 500,000+ vertices • K =1,3,5,7,9 Models • q= 5 Normative substructures per model/ Chunk • 9 weeks • Each chunk covers 1 week Experiments

  26. header,150,2, execve(2),,Fri Jul 31 07:46:33 1998, + 652468777 msec path,/usr/lib/fs/ufs/quota attribute,104555,root,bin,8388614,187986,0 exec_args,1, /usr/sbin/quota subject,2110,root,rjm,2110,rjm,280,272,0-0-172.16.112.50 return,success,0 trailer,150 A Sample system call record from MIT Lincoln Dataset

  27. Token Sub-graph

  28. Performance Total Ensemble Accuracy

  29. 0 false negatives • Significant decrease in false positives • Number of Model increases • False positive decreases slowly after k=3 Performance Contd..

  30. Performance Contd.. Distribution of False Positives

  31. Performance Contd.. Summary of Dataset A & B

  32. Performance Contd.. The effect of q on TP rates for fixed K = 6 on dataset A The effect of q on FP rates for fixed K = 6 on dataset A The effect of q on runtime For fixed K = 6 on Dataset A

  33. True Positive vs # normative substructure for fixed K=6 on dataset A True Positive vs # normative substructure for fixed K=6 on dataset A Performance Contd.. The effect of K on runtime for fixed q = 4 on Dataset A The effect of K on TP rates for fixed q = 4 on dataset A

  34. Evolving Insider Threat Detection using Supervised Learning

  35. Related Work • Proposed Method • Experiments & Results Outlines: Supervised Learning

  36. Related Approaches and comparison with proposed solutions

  37. Insider threat data is minority class • Traditional support vector machines (SVM) trained from such an imbalanced dataset are likely to perform poorly on test datasets specially on minority class • One-class SVMs (OCSVM) addresses the rare-class issue by building a model that considers only normal data (i.e., non-threat data). • During the testing phase, test data is classified as normal or anomalous based on geometric deviations from the model. Why one class SVM

  38. One class SVM (OCSVM) , Supervised learning + Ensemble based Stream Mining Proposed Method

  39. Maps training data into a high dimensional feature space (via a kernel). • Then iteratively finds the maximal margin hyper plane which best separates the training data from the origin corresponds to the classification rule: • For testing, f(x) < 0. we label x as an anomaly, otherwise as normal data • f(X) = <w,x> + b • where w is the normal vector and b is a bias term One class SVM (OCSVM)

  40. Maintain K number of OCSVM (One class SVM) models • Majority Voting • Updated Ensemble • Always maintain K models • Drop least accurate model Proposed Ensemble based Insider Threat Detection (EIT)

  41. D1 D2 D3 D5 D4 C5 C3 C4 C2 C1 Prediction • Divide the data stream into equal sized chunks • Train a classifier from each data chunk • Keep the best K OCSVM classifier-ensemble • Example: for K= 3 D5 D4 D6 Labeled chunk Data chunks Unlabeled chunk Addresses infinite length and concept-drift C5 C4 Classifiers Ensemble based Classification of Data Streams (supervised Learning) C1 C4 C2 C5 C3 Ensemble

  42. Algorithm 1 Testing Input: A← Build-initial-ensemble() Du← latest chunk of unlabeled instances Output: Prediction/Label of Du • 1: FuExtract&Select-Features(Du) • //Feature set for Du • 2: for each xj∈ Fudo • 3.ResultsNULL • 4. for each model M in A • 5. Results Results U Prediction (xj, M) • end for • 6. Anomalies Majority Voting (Results) • end for EIT –S pseudo code (Testing)

  43. Algorithm 2 Updating the classifier ensemble Input: Dn: the most recently labeled data chunks, A: the current ensemble of best K classifiers Output: an updated ensemble A • 1: for each model M ∈ Ado • 2: Test M on Dn and compute its expected error • 3: end for • 4: Mn Newly trained 1-class SVM classifier (OCSVM) from data Dn • 5: Test Mn on Dn and compute its expected error • 6: A best K classifiers from Mn ∪ A based on expected error EIT –S pseudocode

  44. Time, userID, machine IP, command, argument, path, return 1 1:29669 6:1 8:1 21:1 32:1 36:0 Feature Set extracted

  45. PERFORMANCE…..

  46. Performance Contd.. Updating vs Non-updating stream approach

  47. Performance Contd.. Supervised (EIT-S) vs. Unsupervised(EIT-U) Learning Summary of Dataset A

  48. Conclusion: Evolving Insider threat detection using • Stream Mining • Unsupervised learning and supervised learning Future Work: • Misuse detection in mobile device • Cloud computing for improving processing time. Conclusion & Future Work

  49. Conference Papers: PallabiParveen, Jonathan Evans, BhavaniThuraisingham, Kevin W. Hamlen, Latifur Khan, “ Insider Threat Detection Using Stream Mining and Graph Mining,” in Proc. of the Third IEEE International Conference on Information Privacy, Security, Risk and Trust (PASSAT 2011), October 2011, MIT, Boston, USA (full paper acceptance rate: 13%). PallabiParveen, Zackary R Weger, BhavaniThuraisingham, Kevin Hamlen and Latifur Khan Supervised Learning for Insider Threat Detection Using Stream Mining, to appear in 23rd IEEE International Conference on Tools with Artificial Intelligence (ICTAI2011), Nov. 7-9, 2011, Boca Raton, Florida, USA (acceptance rate is 30%) PallabiParveen, Bhavani M. Thuraisingham: Face Recognition Using Multiple Classifiers. ICTAI 2006, 179- 186 Journal: Jeffrey Partyka, PallabiParveen, Latifur Khan, Bhavani M. Thuraisingham, ShashiShekhar: Enhanced geographically typed semantic schema matching. J. Web Sem. 9(1): 52-70 (2011). Others: NedaAlipanah, PallabiParveen, SheetalMenezes, Latifur Khan, Steven Seida, Bhavani M. Thuraisingham: Ontology-driven query expansion methods to facilitate federated queries. SOCA 2010, 1- 8 NedaAlipanah, PiyushSrivastava, PallabiParveen, Bhavani M. Thuraisingham: Ranking Ontologies Using Verified Entities to Facilitate Federated Queries. Web Intelligence 2010: 332-337 Publication

  50. W. Eberle and L. Holder, Anomaly detection in Data Represented as Graphs, Intelligent Data Analysis, Volume 11, Number 6, 2007. http://ailab.wsu.edu/subdue • W. Ling Chen, Shan Zhang, Li Tu: An Algorithm for Mining Frequent Items on Data Stream Using Fading Factor. COMPSAC(2) 2009: 172-177 • S. A. Hofmeyr, S. Forrest, and A. Somayaji, “Intrusion Detection Using Sequences of System Calls,” Journal of Computer Security, vol. 6, pp. 151-180, 1998. • M. Masud, J. Gao, L. Khan, J. Han, B. Thuraisingham, “A Practical Approach to Classify Evolving Data Streams: Training with Limited Amount of Labeled Data,”Int.Conf. on Data Mining, Pisa, Italy, December 2010. References

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