The sampling-and-learning framework: A statistical view of evolutionary algorithms

Evolutionary algorithms (EAs), a large class of general purpose optimization algorithms inspired from the natural phenomena, are widely used in various industrial optimizations and often show excellent performance. This paper presents an attempt towards revealing their general power from a statistical view of EAs. By summarizing a large range of EAs into the sampling-and-learning framework, we show that the framework directly admits a general analysis on the probable-absolute-approximate (PAA) query complexity. We particularly focus on the framework with the learning subroutine being restricted as a binary classification, which results in the sampling-and-classification (SAC) algorithms. With the help of the learning theory, we obtain a general upper bound on the PAA query complexity of SAC algorithms. We further compare SAC algorithms with the uniform search in different situations. Under the error-target independence condition, we show that SAC algorithms can achieve polynomial speedup to the uniform search, but not super-polynomial speedup. Under the one-side-error condition, we show that super-polynomial speedup can be achieved. This work only touches the surface of the framework. Its power under other conditions is still open.

[1]  Kenji Toda,et al.  Real-world applications of analog and digital evolvable hardware , 1999, IEEE Trans. Evol. Comput..

[2]  Per Kristian Lehre,et al.  Black-Box Search by Unbiased Variation , 2010, GECCO '10.

[3]  Yuren Zhou,et al.  Performance Analysis of Evolutionary Algorithms for the Minimum Label Spanning Tree Problem , 2014, IEEE Transactions on Evolutionary Computation.

[4]  Frank Neumann,et al.  More Effective Crossover Operators for the All-Pairs Shortest Path Problem , 2010, PPSN.

[5]  J. A. Lozano,et al.  Estimation of Distribution Algorithms: A New Tool for Evolutionary Computation , 2001 .

[6]  Gregory S. Hornby,et al.  Automated Antenna Design with Evolutionary Algorithms , 2006 .

[7]  Michael I. Jordan,et al.  Advances in Neural Information Processing Systems 30 , 1995 .

[8]  Frank Neumann,et al.  Approximating Covering Problems by Randomized Search Heuristics Using Multi-Objective Models , 2010, Evolutionary Computation.

[9]  Ingo Wegener,et al.  Fitness Landscapes Based on Sorting and Shortest Paths Problems , 2002, PPSN.

[10]  Ning Chen,et al.  On the complexity of trial and error , 2012, STOC '13.

[11]  Benjamin Doerr,et al.  Multiplicative Drift Analysis , 2010, GECCO '10.

[12]  Thomas Jansen,et al.  A New Framework for the Valuation of Algorithms for Black-Box Optimization , 2002, FOGA.

[13]  Olivier Teytaud,et al.  Lower Bounds for Comparison Based Evolution Strategies Using VC-dimension and Sign Patterns , 2011, Algorithmica.

[14]  John R. Koza,et al.  What's AI Done for Me Lately? Genetic Programming's Human-Competitive Results , 2003, IEEE Intell. Syst..

[15]  Adam Tauman Kalai,et al.  Analysis of Perceptron-Based Active Learning , 2009, COLT.

[16]  Yang Yu,et al.  A new approach to estimating the expected first hitting time of evolutionary algorithms , 2006, Artif. Intell..

[17]  Pedro Larrañaga,et al.  Estimation of Distribution Algorithms , 2002, Genetic Algorithms and Evolutionary Computation.

[18]  Benjamin Doerr,et al.  Towards a Complexity Theory of Randomized Search Heuristics: Ranking-Based Black-Box Complexity , 2011, CSR.

[19]  Lih-Yuan Deng,et al.  The Cross-Entropy Method: A Unified Approach to Combinatorial Optimization, Monte-Carlo Simulation, and Machine Learning , 2006, Technometrics.

[20]  Thomas Jansen,et al.  The Analysis of Evolutionary Algorithms—A Proof That Crossover Really Can Help , 2002, Algorithmica.

[21]  Carsten Witt,et al.  Approximating Covering Problems by Randomized Search Heuristics Using Multi-Objective Models , 2007, Evolutionary Computation.

[22]  Mauro Birattari,et al.  Model-Based Search for Combinatorial Optimization: A Critical Survey , 2004, Ann. Oper. Res..

[23]  Frank Neumann,et al.  Fixed-Parameter Evolutionary Algorithms and the Vertex Cover Problem , 2012, Algorithmica.

[24]  Yang Yu,et al.  An analysis on recombination in multi-objective evolutionary optimization , 2011, GECCO '11.

[25]  Thomas Bäck,et al.  Evolutionary algorithms in theory and practice - evolution strategies, evolutionary programming, genetic algorithms , 1996 .

[26]  Anthony G. Pipe,et al.  Design innovation for real world applications, using evolutionary algorithms , 2009, 2009 IEEE Congress on Evolutionary Computation.

[27]  Frank Neumann,et al.  Bioinspired computation in combinatorial optimization: algorithms and their computational complexity , 2012, GECCO '12.

[28]  David E. Goldberg,et al.  Genetic Algorithms in Search Optimization and Machine Learning , 1988 .

[29]  Yang Yu,et al.  An analysis on recombination in multi-objective evolutionary optimization , 2013, Artif. Intell..

[30]  Zhi-Hua Zhou,et al.  Ieee Transactions on Knowledge and Data Engineering 1 Training Cost-sensitive Neural Networks with Methods Addressing the Class Imbalance Problem , 2022 .

[31]  Frank Neumann,et al.  Bioinspired computation in combinatorial optimization: algorithms and their computational complexity , 2010, GECCO '12.

[32]  Dirk Sudholt,et al.  A New Method for Lower Bounds on the Running Time of Evolutionary Algorithms , 2011, IEEE Transactions on Evolutionary Computation.

[33]  John R. Koza,et al.  Genetic programming as a means for programming computers by natural selection , 1994 .

[34]  Charles Elkan,et al.  The Foundations of Cost-Sensitive Learning , 2001, IJCAI.

[35]  David H. Wolpert,et al.  No free lunch theorems for optimization , 1997, IEEE Trans. Evol. Comput..

[36]  Umesh V. Vazirani,et al.  An Introduction to Computational Learning Theory , 1994 .

[37]  Riccardo Poli,et al.  Particle swarm optimization , 1995, Swarm Intelligence.

[38]  Thomas Jansen,et al.  Analyzing Evolutionary Algorithms , 2015, Natural Computing Series.

[39]  Xin Yao,et al.  On the approximation ability of evolutionary optimization with application to minimum set cover , 2010, Artif. Intell..

[40]  Per Kristian Lehre,et al.  Crossover Can Be Constructive When Computing Unique Input Output Sequences , 2008, SEAL.

[41]  R. Paul Wiegand,et al.  Black-box search by elimination of fitness functions , 2009, FOGA '09.

[42]  Frank Neumann,et al.  A Parameterized Runtime Analysis of Evolutionary Algorithms for the Euclidean Traveling Salesperson Problem , 2012, AAAI.

[43]  Zhi-Hua Zhou,et al.  Multi-View Active Learning in the Non-Realizable Case , 2010, NIPS.

[44]  Dong Zhou,et al.  The use of tail inequalities on the probable computational time of randomized search heuristics , 2012, Theor. Comput. Sci..

[45]  Tobias Storch,et al.  On the Choice of the Parent Population Size , 2008, Evolutionary Computation.

[46]  Kenneth A. De Jong,et al.  Design and Management of Complex Technical Processes and Systems by Means of Computational Intelligence Methods on the Choice of the Offspring Population Size in Evolutionary Algorithms on the Choice of the Offspring Population Size in Evolutionary Algorithms , 2004 .

[47]  Marco Tomassini,et al.  Evolutionary Algorithms , 1995, Towards Evolvable Hardware.

[48]  Carsten Witt,et al.  Population size versus runtime of a simple evolutionary algorithm , 2008, Theor. Comput. Sci..

[49]  Xin Yao,et al.  Drift analysis and average time complexity of evolutionary algorithms , 2001, Artif. Intell..

[50]  X. Yao,et al.  An analysis of evolutionary algorithms for finding approximation solutions to hard optimisation problems , 2003, The 2003 Congress on Evolutionary Computation, 2003. CEC '03..

[51]  Marco Dorigo,et al.  Ant system: optimization by a colony of cooperating agents , 1996, IEEE Trans. Syst. Man Cybern. Part B.

[52]  Xin Yao,et al.  Unpacking and Understanding Evolutionary Algorithms , 2012, WCCI.

[53]  Hans-Paul Schwefel,et al.  Evolution strategies – A comprehensive introduction , 2002, Natural Computing.

[54]  Xin Yao,et al.  A New Approach for Analyzing Average Time Complexity of Population-Based Evolutionary Algorithms on Unimodal Problems , 2009, IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics).

[55]  Anne Auger,et al.  Theory of Randomized Search Heuristics: Foundations and Recent Developments , 2011, Theory of Randomized Search Heuristics.

[56]  Thomas Jansen,et al.  Fixed budget computations: a different perspective on run time analysis , 2012, GECCO '12.

[57]  Thomas Jansen,et al.  On the analysis of the (1+1) evolutionary algorithm , 2002, Theor. Comput. Sci..

[58]  Per Kristian Lehre,et al.  Crossover can be constructive when computing unique input–output sequences , 2011, Soft Comput..

[59]  JansenThomas,et al.  On the analysis of the (1+ 1) evolutionary algorithm , 2002 .