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International Journal of Machine Learning and Cybernetics
Erschienen in: International Journal of Machine Learning and Cybernetics 12/2022

06.08.2022 | Original Article

A hyper-heuristic guided by a probabilistic graphical model for single-objective real-parameter optimization

verfasst von: Diego Oliva, Marcella S. R. Martins, Salvador Hinojosa, Mohamed Abd Elaziz, Paulo Victor dos Santos, Gelson da Cruz, Seyed Jalaleddin Mousavirad

Erschienen in: International Journal of Machine Learning and Cybernetics | Ausgabe 12/2022

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Abstract

Metaheuristics algorithms are designed to find approximate solutions for challenging optimization problems. The success of the algorithm over a given optimization task relies on the suitability of its search heuristics for the problem-domain. Thus, the design of custom metaheuristic algorithms leads to more accurate solutions. Hyper-heuristics (HH) are important tools commonly used to select low-level heuristics (LLHs) to solve a specific problem. HH are able to acquire knowledge from the problems where they are used. However, as other artificial intelligence tools it is necessary to identify how the knowledge affects the performance of the algorithm. One way to generate such knowledge is to capture interactions between variables using probabilistic graphical models such as Bayesian networks (BN) in conjunction with estimation of distribution algorithms (EDA). This article presents a method based on that used an EDA based on BN as a high-level selection mechanism for HH called Hyper-heuristic approach based on Bayesian learning and evolutionary operators (HHBNO). Here the knowledge is extracted form BN to evolve the sequences of LLHs in an online learning process by exploring the inter-dependencies among the LLHs. The proposes approach is tested over CEC’17 set of benchmark function of single-objective real-parameter optimization. Statical tests verifies that the HHBNO  presents competitive results in comparison with other metaheuristic algorithms with high performance in terms of convergence. The generated BN is further visually investigated to display the acquired knowledge during the evolutionary process, and it is constructed with the probabilities of each LLHs.
Vorheriger Artikel Representation learning from noisy user-tagged data for sentiment classification
Nächster Artikel CorrNet: pearson correlation based pruning for efficient convolutional neural networks

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Literatur
1.
Finkel DE (2005) Global optimization with the DIRECT algorithm. North Carolina State University, Raleigh
2.
Baker CA, Watson LT, Grossman BM, Mason WH, Haftka RT (2000) Parallel global aircraft configuration design space exploration. Department of Computer Science, Virginia Polytechnic Institute & State University
3.
Jones DR, Schonlau M, Welch WJ (1998) Efficient global optimization of expensive black-box functions. J Glob Optim 13(4):455–492MathSciNetMATHCrossRef
4.
Regis RG, Shoemaker CA (2005) Constrained global optimization of expensive black box functions using radial basis functions. J Glob Optim 31(1):153–171MathSciNetMATHCrossRef
5.
6.
Strongin RG, Sergeyev YD (1992) Global multidimensional optimization on parallel computer. Parallel Comput 18(11):1259–1273MathSciNetMATHCrossRef
7.
Kvasov DE, Sergeyev YD (2015) Deterministic approaches for solving practical black-box global optimization problems. Adv Eng Softw 80:58–66CrossRef
8.
9.
Glover FW, Kochenberger GA (2006) Handbook of Metaheuristics, vol 57. Springer, BerlinMATH
10.
Nesmachnow S (2014) An overview of metaheuristics: accurate and efficient methods for optimisation. Int J Metaheuristics 3(4):320–347CrossRef
11.
Sabar NR, Ayob M, Kendall G, Qu R (2014) Automatic design of a hyper-heuristic framework with gene expression programming for combinatorial optimization problems. IEEE Trans Evolut Comput 19(3):309–325CrossRef
12.
Drake JH, Hyde M, Ibrahim K, Ozcan E (2014) A genetic programming hyper-heuristic for the multidimensional knapsack problem. Kybernetes 43(9/10):1500–1511CrossRef
13.
14.
Burke EK, Gendreau M, Hyde M, Kendall G, Ochoa G, Özcan E, Qu R (2013) Hyper-heuristics: a survey of the state of the art. J Oper Res Soc 64(12):1695–1724CrossRef
15.
García S, Luengo J, Herrera F (2015) Data preprocessing in data mining. Springer, BerlinCrossRef
16.
El Yafrani M, Martins M, Wagner M, Ahiod B, Delgado M, Lüders R (2018) A hyperheuristic approach based on low-level heuristics for the travelling thief problem. Genet Program Evolvable Mach 19(1):121–150CrossRef
17.
Ferreira TN, Lima JAP, Strickler A, Kuk JN, Vergilio SR, Pozo A (2017) Hyper-heuristic based product selection for software product line testing. IEEE Comput Intell Mag 12(2):34–45CrossRef
18.
Cao P, Fan Z, Gao R, Tang J (2017) A manufacturing oriented single point search hyper-heuristic scheme for multi-objective optimization. In: International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, Vol. 58134, American Society of Mechanical Engineers, pp V02BT03A031
19.
Li W, Özcan E, John R (2017) A learning automata-based multiobjective hyper-heuristic. IEEE Transactions on Evolutionary Computation 23(1):59–73CrossRef
20.
Asta S, Özcan E (2015) A tensor-based selection hyper-heuristic for cross-domain heuristic search. Inf Sci 299:412–432CrossRef
21.
Choong SS, Wong L-P, Lim CP (2018) Automatic design of hyper-heuristic based on reinforcement learning. Inf Sci 436:89–107MathSciNetCrossRef
22.
Mühlenbein H, Paass G (1996) September). From recombination of genes to the estimation of distributions I. Binary parameters. Springer, Berlin, Heidelberg, pp 178–187
23.
Koller D, Friedman N (2009) Probabilistic Graphical Models: Principles and Techniques. The MIT Press, CambridgeMATH
24.
Qu R, Pham N, Bai R, Kendall G (2015) Hybridising heuristics within an estimation distribution algorithm for examination timetabling. Appl Intell 42(4):679–693CrossRef
25.
Uludag G, Kiraz B, Uyar AŞE, Özcan E (2012) Heuristic selection in a multi-phase hybrid approach for dynamic environments. In: 2012 12th UK Workshop on Computational Intelligence (UKCI), IEEE, pp 1–8
26.
Martins MSR, El Yafrani M, Delgado MRBS, Wagner M, Ahiod B, Lüders R (2017) HSEDA: a heuristic selection approach based on estimation of distribution algorithm for the travelling thief problem. In: Proceedings of the genetic and evolutionary computation conference. GECCO’17, pp 361–368. ACM, New York
27.
Awad N, Ali M, Liang J, Qu B, Suganthan P (2016) Problem definitions and evaluation criteria for the CEC 2017 special session and competition on single objective real-parameter numerical optimization. Nanyang Technological University, Jordan University of Science and Technology and Zhengzhou University, Singapore and Zhenzhou, China, Technical Report 201611
28.
Cuesta-Cañada A, Garrido L, Terashima-Marín H (2005) Building hyper-heuristics through ant colony optimization for the 2D bin packing problem. In: Proceedings of the 9th international conference, KES 2005. Springer, Melbourne, pp 654–660
29.
Burke EK, Hyde M, Kendall G, Ochoa G, Özcan E, Woodward JR (2010) A Classification of Hyper-heuristic Approaches. Springer, Boston, pp 449–468
30.
Sosa-Ascencio A, Ochoa G, Terashima-Marin H, Conant-Pablos SE (2016) Grammar-based generation of variable-selection heuristics for constraint satisfaction problems. Genet Program Evolvable Mach 17(2):119–144CrossRef
31.
Drake JH, Hyde M, Ibrahim K, Ozcan E (2014) A genetic programming hyper-heuristic for the multidimensional knapsack problem. Kybernetes 43(9/10):1500–1511CrossRef
32.
Cowling P, Kendall G, Soubeiga E (2000) A hyperheuristic approach to scheduling a sales summit. In: Proceedings of the third international conference on practice and theory of automated timetabling, PATAT 2000. Springer, Konstanz, pp 176–190
33.
Cowling P, Kendall G, Soubeiga E (2001) A parameter-free hyperheuristic for scheduling a sales summit. In: Proceedings of the 4th Metaheuristic International Conference, MIC, Vol. 2001, pp 127–131
34.
Krasnogor N, Smith J (2001) Emergence of profitable search strategies based on a simple inheritance mechanism. In: Proceedings of the 3rd annual conference on genetic and evolutionary computation. GECCO’01. Morgan Kaufmann Publishers Inc., San Francisco, pp 432–439
35.
Burke EK, Kendall G, Soubeiga E (2003) A Tabu-search hyperheuristic for timetabling and rostering. J Heuristics 9(6):451–470CrossRef
36.
Ross P, Marín-Blázquez JG, Schulenburg S, Hart E (2003) Learning a procedure that can solve hard bin-packing problems: a new GA-based approach to hyper-heuristics. In: Proceedings of the genetic and evolutionary computation 2003, GECCO’03. Springer, Chicago, pp 1295–1306
37.
Dowsland KA, Soubeiga E, Burke E (2007) A simulated annealing based hyperheuristic for determining shipper sizes for storage and transportation. Eur J Oper Res 179(3):759–774MATHCrossRef
38.
39.
Wei D, Wang F, Ma H (2019) Autonomous path planning of AUV in large-scale complex marine environment based on swarm hyper-heuristic algorithm. Appl Sci 9(13):2654CrossRef
40.
41.
Lin J, Li Y-Y, Song H-B (2022) Semiconductor final testing scheduling using q-learning based hyper-heuristic. Expert Syst Appl 187:115978CrossRef
42.
Song H-B, Lin J (2021) A genetic programming hyper-heuristic for the distributed assembly permutation flow-shop scheduling problem with sequence dependent setup times. Swarm Evolut Comput 60:100807MathSciNetCrossRef
43.
Hong L, Woodward JR, Özcan E, Liu F (2021) Hyper-heuristic approach: automatically designing adaptive mutation operators for evolutionary programming. Complex Intell Syst 7(6):3135–3163CrossRef
44.
Cruz-Duarte JM, Amaya I, Ortiz-Bayliss JC, Conant-Pablos SE, Terashima-Marín H, Shi Y (2021) Hyper-heuristics to customise metaheuristics for continuous optimisation. Swarm Evolut Comput 66:100935CrossRef
45.
Olgun B, Koç Ç, Altıparmak F (2021) A hyper heuristic for the green vehicle routing problem with simultaneous pickup and delivery. Comput Ind Eng 153:107010CrossRef
46.
de Carvalho VR, Özcan E, Sichman JS (2021) Comparative analysis of selection hyper-heuristics for real-world multi-objective optimization problems. Appl Sci 11(19):9153CrossRef
47.
Larrañaga P, Lozano JA (2002) Estimation of Distribution Algorithms: A New Tool for Evolutionary Computation, vol 2. Springer, DordrechtMATH
48.
Martins MSR, Delgado MRBS, Santana R, Lüders R, Gonçalves RA, de Almeida CP (2016) HMOBEDA: hybrid multi-objective Bayesian estimation of distribution algorithm. In: Proceedings of the 2016 on genetic and evolutionary computation conference. GECCO’16. ACM, New York, pp 357–364
49.
Martins MS, Delgado M, Lüders R, Santana R, Gonçalves RA, de Almeida CP (2018) Exploring the probabilistic graphic model of a hybrid multi-objective Bayesian estimation of distribution algorithm. Appl Soft Comput 73:328–343CrossRef
50.
Scoczynski M, Delgado M, Lüders R, Oliva D, Wagner M, Sung I, El Yafrani M (2021) Saving computational budget in Bayesian network-based evolutionary algorithms. Nat Comput 20(4):775–790MathSciNetCrossRef
51.
Martins MS, Yafrani ME, Delgado M, Lüders R, Santana R, Siqueira HV, Akcay HG, Ahiod B (2021) Analysis of Bayesian network learning techniques for a hybrid multi-objective Bayesian estimation of distribution algorithm: a case study on MNK landscape. J Heuristics 27(4):549–573CrossRef
52.
Pearl J (1988) Probabilistic reasoning in intelligent systems: networks of plausible inference. Morgan Kaufmann, San MateoMATH
53.
Bengoetxea E (2002) Inexact graph matching using estimation of distribution algorithms. PhD thesis, University of the Basque Country, Basque Country
54.
De Campos LM, Fernández-Luna JM, Huete JF, Rueda-Morales MA (2010) Combining content-based and collaborative recommendations: a hybrid approach based on Bayesian networks. Int J Approx Reason 51(7):785–799CrossRef
55.
Smith JQ, Daneshkhah A (2010) On the robustness of Bayesian networks to learning from non-conjugate sampling. Int J Approx Reason 51(5):558–572MathSciNetMATHCrossRef
56.
Cheng Y, Diakonikolas I, Kane D, Stewart A (2018) Robust learning of fixed-structure Bayesian networks. Advances in Neural Information Processing Systems, 31
57.
Cooper G, Herskovits E (1992) A Bayesian method for the induction of probabilistic networks from data. Mach Learn 9(4):309–347MATHCrossRef
58.
Tsamardinos I, Aliferis CF, Statnikov AR, Statnikov E (2003) Algorithms for large scale Markov blanket discovery. In: FLAIRS conference, vol 2. AAAI Press, St. Augustine, pp 376–380
59.
Colombo D, Maathuis MH (2014) Order-independent constraint-based causal structure learning. J Mach Learn Res 15(1):3741–3782MathSciNetMATH
60.
Scutari M, Ness R (2012) bnlearn: Bayesian network structure learning, parameter learning and inference. R package version 3
61.
Tsamardinos I, Brown LE, Aliferis CF (2006) The max-min hill-climbing Bayesian network structure learning algorithm. Mach Learn 65(1):31–78MATHCrossRef
62.
Moran S, He Y, Liu K (2009) Choosing the best Bayesian classifier: an empirical study. IAENG Int J Comput Sci 36(4):322–331
63.
Behjati S, Beigy H (2020) Improved k2 algorithm for Bayesian network structure learning. Eng Appl Artif Intell 91:103617CrossRef
64.
Eshelman LJ, Schaffer JD (1993) Real-coded genetic algorithms and interval-schemata. In: Foundations of genetic algorithms, vol 2. Elsevier, Amsterdam, pp 187–202
65.
Deb K, Joshi D, Anand A (2002) Real-coded evolutionary algorithms with parent-centric recombination. In: Proceedings of the 2002 Congress on evolutionary computation. CEC’02 (Cat. No. 02TH8600), vol 1. IEEE, New York, pp 61–66
66.
Ortiz-Boyer D, Hervás-Martínez C, García-Pedrajas N (2007) Improving crossover operator for real-coded genetic algorithms using virtual parents. J Heuristics 13(3):265–314CrossRef
67.
Deb K, Beyer H-G (2001) Self-adaptive genetic algorithms with simulated binary crossover. Evolut Comput 9(2):197–221CrossRef
68.
Ono I (1997) Real-coded genetic algorithm for function optimization using unimodal normal distribution crossover. In: Proceedings of 7th ICGA, pp 246–253
69.
Kita H, Ono I, Kobayashi S (2000) Multi-parental extension of the unimodal normal distribution crossover for real-coded genetic algorithms. Trans Soc Instrum Control Eng 36(10):875–883CrossRef
70.
Deb K (2005) A population-based algorithm-generator for real-parameter optimization. Soft Comput 9(4):236–253MATHCrossRef
71.
Tizhoosh HR (2005) Opposition-based learning: a new scheme for machine intelligence. In: International conference on computational intelligence for modelling, control and automation, 2005 and international conference on intelligent agents, web technologies and internet commerce, vol 1. IEEE, New York, pp 695–701
72.
Higashi N, Iba H (2003) Particle swarm optimization with Gaussian mutation. In: Proceedings of the 2003 IEEE swarm intelligence symposium. SIS’03 (Cat. No. 03EX706). IEEE, New York, pp 72–79
73.
Esquivel SC, Coello CC (2003) On the use of particle swarm optimization with multimodal functions. In: The 2003 Congress on evolutionary computation, 2003. CEC’03, vol 2. IEEE, New York, pp 1130–1136
74.
Michalewicz Z (1996) Genetic algorithms + data structures = evolution programs. Springer, BerlinMATHCrossRef
75.
Qin AK, Huang VL, Suganthan PN (2008) Differential evolution algorithm with strategy adaptation for global numerical optimization. IEEE Trans Evolut Comput 13(2):398–417CrossRef
76.
Eberhart R, Kennedy J (1995) Particle swarm optimization. In: Proceedings of the IEEE international conference on neural networks, Vol. 4, pp. 1942–1948
77.
Lipowski A, Lipowska D (2012) Roulette-wheel selection via stochastic acceptance. Phys A Stat Mech Appl 391(6):2193–2196CrossRef
78.
Thierens D, Goldberg D (1994) Convergence models of genetic algorithm selection schemes. In: International conference on parallel problem solving from nature. Springer, Berlin, pp 119–129
79.
Goldberg DE (2006) Genetic algorithms. Pearson Education India, Delhi
80.
Civicioglu P (2012) Transforming geocentric Cartesian coordinates to geodetic coordinates by using differential search algorithm. Comput Geosci 46:229–247CrossRef
81.
Auger A, Hansen N (2012) Tutorial CMA-ES: evolution strategies and covariance matrix adaptation. In: Proceedings of the 14th annual conference companion on Genetic and evolutionary computation, pp 827–848
82.
Gharehchopogh FS, Gholizadeh H (2019) A comprehensive survey: Whale Optimization Algorithm and its applications. Swarm Evol Comput 48:1–24CrossRef
83.
Mirjalili SM, Mirjalili SZ, Saremi S, Mirjalili S (2020) Sine cosine algorithm: theory, literature review, and application in designing bend photonic crystal waveguides. Nature-inspired optimizers, pp 201–217
84.
Mohamed AW, Hadi AA, Mohamed AK (2020) Gaining-sharing knowledge based algorithm for solving optimization problems: a novel nature-inspired algorithm. Int J Mach Learn Cybern 11(7):1501–1529CrossRef
85.
Heckerman D, Geiger D, Chickering D (1995) Learning Bayesian networks: the combination of knowledge and statistical data. Mach Learn 20(3):197–243MATHCrossRef
86.
DeGroot MH (2005) Optimal statistical decisions, vol 82. Wiley, New YorkMATH
87.
Henrion M (1988) Propagating uncertainty in Bayesian networks by probabilistic logic sampling. In: Machine intelligence and pattern recognition, North-Holland, vol 5, pp 149–163
88.
Conover WJ (1999) Practical nonparametric statistics, 3rd edn. Wiley, New York
89.
Casella G, Berger RL (2001) Statistical inference, 2nd edn. Duxbury
90.
Fan G-F, Yu M, Dong S-Q, Yeh Y-H, Hong W-C (2021) Forecasting short-term electricity load using hybrid support vector regression with grey catastrophe and random forest modeling. Util Policy 73:101294CrossRef
Metadaten
Titel
A hyper-heuristic guided by a probabilistic graphical model for single-objective real-parameter optimization
verfasst von
Diego Oliva
Marcella S. R. Martins
Salvador Hinojosa
Mohamed Abd Elaziz
Paulo Victor dos Santos
Gelson da Cruz
Seyed Jalaleddin Mousavirad
Publikationsdatum
06.08.2022
Verlag
Springer Berlin Heidelberg
Erschienen in
International Journal of Machine Learning and Cybernetics / Ausgabe 12/2022
Print ISSN: 1868-8071
Elektronische ISSN: 1868-808X
DOI
https://doi.org/10.1007/s13042-022-01623-6

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