1 / 39

Case Injected Genetic Algorithms

Explore how combining case-based reasoning with genetic algorithms enhances performance in combinational logic circuit design. Cover motivation, techniques, evaluation, results, and conclusions.

jtheiss
Download Presentation

Case Injected Genetic Algorithms

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Case Injected Genetic Algorithms Sushil J. Louis Genetic Algorithm Systems Lab (gaslab) University of Nevada, Reno http://www.cs.unr.edu/~sushil http://gaslab.cs.unr.edu/ sushil@cs.unr.edu

  2. Learning from Experience: Case Injected Genetic Algorithm Design of Combinational Logic Circuits Sushil J. Louis Genetic Algorithm Systems Lab (gaslab) University of Nevada, Reno http://www.cs.unr.edu/~sushil http://gaslab.cs.unr.edu/ sushil@cs.unr.edu

  3. Outline • Motivation • What is the technique? • Genetic Algorithm and Case-Based Reasoning • Is it useful? • Evaluate performance on Combinational Logic Design • Results • Conclusions

  4. Outline • Motivation • What is the technique? • Genetic Algorithm and Case-Based Reasoning • Is it useful? • Combinational Logic Design • Strike Force Asset Allocation • TSP • Scheduling • Conclusions

  5. Genetic Algorithm • Non-Deterministic, Parallel, Search • Poorly understood problems • Evaluate, Select, Recombine • Population search • Population member encodes candidate solution • Building blocks combine to make progress • More resistant to local optima • Iterative, requiring many evaluations

  6. Motivation • Deployed systems are expected to confront and solve many problems over their lifetime • How can we increase genetic algorithm performance with experience? • Provide GA with a memory

  7. Case-Based Reasoning • When confronted by a new problem, adapt similar (already solved) problem’s solution to solve new problem • CBR  Associative Memory + Adaptation • CBR: Indexing (on problem similarity) and adaptation are domain dependent

  8. Case Injected Genetic AlgoRithm • Combine genetic search with case-based reasoning • Case-base provides memory • Genetic algorithm provides adaptation • Genetic algorithm generates cases • Any member of the GA’s population is a case

  9. System

  10. Related work • Seeding:Koza, Greffensttette, Ramsey, Louis • Lifelong learning: Thrun • Key Differences • Store and reuse intermediate solutions • Solve sequences of similar problems

  11. Combinational Logic Design • An example of configuration design • Given a function and a target technology to work with design an artifact that performs this function subject to constraints • Target technology: Logic gates • Function: Parity checking • Constraints: 2-D gate array

  12. Encoding

  13. Encoding

  14. Parity

  15. Which cases to inject? • Problem distance metric (Louis ‘97) • Domain dependent • Solution distance metric • Genetic algorithm encodings • Binary – hamming distance • Real – euclidean distance • Permutation – longest common substring • …

  16. Problem similarity

  17. Lessons • Storing and Injecting solutions may not improve solution quality • Storing and Injecting partial solutions does lead to improved quality

  18. OSSP Performance

  19. Solution Similarity

  20. Periodic Injection Strategies • Closest to best • Furthest from worst • Probabilistic closest to best • Probabilistic furthest from worst • Randomly choose a case from case-base • Create random individual

  21. Setup • 50, 6-bit combinational logic design problems • Randomly select and flip bits in parity output to define logic function • Compare performance • Quality of final design solution (correct output) • Time to this final solution (in generations)

  22. Population size: 30 No of generations: 30 CHC (elitist) selection Scaling factor: 1.05 Prob. Crossover: 0.95 Prob. Mutation: 0.05 Store best individual every generation Inject every 5 generations (2^5 = 32) Inject 3 cases (10%) Multiple injection strategies Parameters Averages over 10 runs

  23. Problem distribution

  24. Performance - Quality

  25. Performance - Time

  26. Injection Strategies

  27. Solution distribution

  28. Strike force asset allocation • Allocate platforms to targets • Dynamic • Changing Priority • Battlefield conditions • Popup • Weather • …

  29. Factors in allocation • Pilot proficiency • Asset suitability • Priority • Risk • Route • Other assets (SEAD) • Weather

  30. Maximize mission success • Binary encoding • Platform to multiple targets • Target can have multiple platforms • Dynamic battle-space • Strong time constraints

  31. Setup • 50 problems. • 10 platforms, 40 assets, 10 targets • Each platform could be allocated to two targets • Problems varied in risk matrix • Popsize=80, Generations=80, Pc=1.0, Pm=0.05, probabilistic closest to best, injection period=9, injection % = 10% of popsize

  32. Results

  33. TSP • Find the shortest route that visits every city exactly once (except for start city) • Permutation encoding. Ex: 35412 • Similarity metric: Longest common subsequence (Cormen et al, Introduction to Algorithms) • 50 problems, move city locations

  34. TSP performance

  35. Scheduling • Job shop scheduling problems • Permutation encoding (Fang) • Similarity metric: Longest common subsequence (Cormen et al, Introduction to Algorithms) • 50 problems, change task lengths

  36. JSSP Performance (10x10)

  37. JSSP Performance (15x15)

  38. Summary • Case Injected Genetic AlgoRithm: A hybrid system that combines genetic algorithms with a case-based memory • Defined problem-similarity and solution-similarity metrics • Defined performance metrics and showed empirically that CIGAR learns to increase performance for sequences of similar problems

  39. Conclusions • Case Injected Genetic AlgoRithm is a viable system for increasing performance with experience • Implications for system design • Increases performance with experience • Generates cases during problem solving • Long term navigable store of expertise • Design analysis by analyzing case-base

More Related