OWMA: An improved self-regulatory woodpecker mating algorithm using opposition-based learning and allocation of local memory for solving optimization problems
Restricted accessResearch articleFirst published online January 4, 2021
OWMA: An improved self-regulatory woodpecker mating algorithm using opposition-based learning and allocation of local memory for solving optimization problems
Success of metaheuristic algorithms depends on the efficient balance between of exploration and exploitation phases. Any optimization algorithm requires a combination of diverse exploration and proper exploitation to avoid local optima. This paper proposes a new improved version of the Woodpecker Mating Algorithm (WMA), based on opposition-based learning, known as the OWMA aiming to develop exploration and exploitation capacities and establish a simultaneous balance between these two phases. This improvement consists of three major mechanisms, the first of which is the new Distance Opposition-based Learning (DOBL) mechanism for improving exploration, diversity, and convergence. The second mechanism is the allocation of local memory of personal experiences of search agents for developing the exploitation capacity. The third mechanism is the use of a self-regulatory and dynamic method for setting the Hα parameter to improve the Running Away function (RA) performance. The ability of the proposed algorithm to solve 23 benchmark mathematical functions was evaluated and compared to that of a series of the latest and most popular metaheuristic methods reviewed in the research literature. The proposed algorithm is also used as a Multi-Layer Perceptron (MLP) neural network trainer to solve the classification problem on four biomedical datasets and three function approximation datasets. In addition, the OWMA algorithm was evaluated in five optimization problems constrained by the real world. The simulation results proved the superior and promising performance of the proposed algorithm in the majority of evaluations. The results prove the superiority and promising performance of the proposed algorithm in solving very complicated optimization problems.
SaremiS., MirjaliliS. and LewisA., Grasshopper optimisation algorithm: Theory and application, Advances in Engineering Software105 (2017), 30–47.
2.
MirjaliliS. and LewisA., The whale optimization algorithm, Advances in Engineering Software95 (2016), 51–67.
3.
ShadravanS., NajiH. and BardsiriV., The Sailfish Optimizer: A novel nature-inspired metaheuristic algorithm for solving constrained engineering optimization problems, Engineering Applications of Artificial Intelligence80 (2019), 20–34.
4.
Karimzadeh PariziM., KeyniaF. and Khatibi BardsiriA., Woodpecker Mating Algorithm (WMA): a nature-inspired algorithm for solving optimization problems, International Journal of Nonlinear Analysis and Applications11 (2020), 137–157.
5.
MirjaliliS., MirjaliliS.M. and LewisA., Grey wolf optimizer, Advances in Engineering Software69 (2014), 46–61.
6.
KhisheM. and MosaviM., Chimp Optimization Algorithm, Expert Systems with Applications (2020), 113338.
7.
FaramarziA., HeidarinejadM., MirjaliliS. and GandomiA.H., Marine Predators Algorithm: A Nature-inspired Metaheuristic, Expert Systems with Applications (2020), 113377.
8.
BasarA., KabakÖ. and TopcuY.I., A tabu search algorithm for a multi-period bank branch location problem: A case study in a Turkish bank, Scientiairanica26 (2019), 3728–3746.
9.
BluskovI., Problem dependent optimization (PDO), Journal of Combinatorial Optimization31 (2016), 1335–1344.
10.
Boussaï DI., LepagnotJ. and SiarryP., A survey on optimization metaheuristics, Information Sciences237 (2013), 82–117.
11.
HasançebiO. and AzadS.K., Adaptive dimensional search: a new metaheuristic algorithm for discrete truss sizing optimization, Computers & Structures154 (2015), 1–16.
12.
Abdel-BassetM., Abdel-FatahL. and SangaiahA.K., Metaheuristic algorithms: A comprehensive review, Computational intelligence for multimedia big data on the cloud with engineering applications, Elsevier (2018), 185–231.
KennedyJ. and EberhartR., Particle swarm optimization, Proceedings of ICNN’95-International Conference on Neural Networks, IEEE, (1995), 1942–1948.
15.
StornR. and PriceK., Differential evolutiona simple and efficient heuristic for global optimization over continuous spaces, Journal of Global Optimization11 (1997), 341–359.
16.
GeemZ.W., KimJ.H. and LoganathanG.V., A new heuristic optimization algorithm: harmony search, Simulation76 (2001), 60–68.
17.
Uma MaheswariP., ManickamP., Sathesh KumarK., MaselenoA. and ShankarK., Bat optimization algorithm with fuzzy based PIT sharing (BF-PIT) algorithm for Named Data Networking (NDN), Journal of Intelligent & Fuzzy Systems37 (2019), 293–300.
18.
AbdechiriM., MeybodiM.R. and BahramiH., Gases Brownian motion optimization: an algorithm for optimization (GBMO), Applied Soft Computing13 (2013), 2932–2946.
19.
Hajiaghaei-KeshteliM. and AminnayeriM., Keshtel Algorithm (KA); a new optimization algorithm inspired by Keshtels feeding, Proceeding in IEEE conference on industrial engineering and management systems, (2013), 2249–2253.
20.
GandomiA.H., Interior search algorithm (ISA): a novel approach for global optimization, ISA transactions53 (2014), 1168–1183.
21.
Merrikh-BayatF., The runner-root algorithm: a metaheuristic for solving unimodal and multimodal optimization problems inspired by runners and roots of plants in nature, Applied Soft Computing33 (2015), 292–303.
22.
ColakM.E. and VarolA., A novel intelligent optimization algorithm inspired from circular water waves, Elektronika ir Elektrotechnika21 (2015), 3–6.
23.
AliJ., SaeedM., LuqmanM. and TabassumM.F., Artificial showering algorithm: a new meta-heuristic for unconstrained optimization, (2015).
24.
LabbiY., AttousD.B., GabbarH.A., MahdadB. and ZidanA., A new rooted tree optimization algorithm for economic dispatch with valve-point effect, International Journal of Electrical Power & Energy Systems79 (2016), 298–311.
25.
BouchekaraH., Most Valuable Player Algorithm: a novel optimization algorithm inspired from sport, Operational Research (2017), 1–57.
26.
Fathollahi-FardA.M., Hajiaghaei-KeshteliM. and Tavakkoli-MoghaddamR., The social engineering optimizer (SEO), Engineering Applications of Artificial Intelligence72 (2018), 267–293.
27.
HeidariA.A., MirjaliliS., FarisH., AljarahI., MafarjaM. and ChenH., Harris hawks optimization: Algorithm and applications, Future Generation Computer Systems97 (2019), 849–872.
28.
MoosaviS.H.S. and BardsiriV.K., Poor and rich optimization algorithm: A new human-based and multi populations algorithm, Engineering Applications of Artificial Intelligence86 (2019), 165–181.
29.
HashimF.A., HousseinE.H., MabroukM.S., Al AtabanyW. and MirjaliliS., Henry gas solubility optimization: A novel physics-based algorithm, Future Generation Computer Systems101 (2019), 646–667.
30.
LiS., ChenH., WangM., HeidariA.A. and MirjaliliS., Slime mould algorithm: A new method for stochastic optimization, Future Generation Computer Systems (2020).
31.
FaramarziA., HeidarinejadM., StephensB. and MirjaliliS., Equilibrium optimizer: A novel optimization algorithm, Knowledge-Based Systems191 (2020), 105190.
32.
NematollahiA.F., RahiminejadA. and VahidiB., A novel meta-heuristic optimization method based on golden ratio in nature, Soft Computing24 (2020), 1117–1151.
33.
Fathollahi-FardA.M., Hajiaghaei-KeshteliM. and Tavakkoli-MoghaddamR., Red deer algorithm (RDA): a new nature-inspired meta-heuristic, Soft Computing (2020), 1–29.
34.
Ghasemi-MarzbaliA., A novel nature-inspired metaheuristic algorithm for optimization: bear smell search algorithm, Soft Computing (2020), 1–33.
35.
FanQ., HuangH., LiY., HanZ., HuY. and HuangD., Beetle Antenna Strategy based Grey Wolf Optimization, Expert Systems with Applications (2020), 113882.
36.
AskariQ., SaeedM. and YounasI., Heap-based optimizer inspired by corporate rank hierarchy for global optimization, Expert Systems with Applications (2020), 113702.
37.
KavehA., SeddighianM. and GhanadpourE., Black Hole Mechanics Optimization: a novel meta-heuristic algorithm, Asian Journal of Civil Engineering (2020), 1–21.
38.
BraikM., ShetaA. and Al-HiaryH., A novel meta-heuristic search algorithm for solving optimization problems: capuchin search algorithm, Neural Computing and Applications (2020), 1–33.
39.
RashidM.F.F.A., Tiki-taka algorithm: a novel metaheuristic inspired by football playing style, Engineering Computations, (2020).
40.
DehghaniM., MontazeriZ., SaremiS., DehghaniA., MalikO.P., Al-HaddadK. and GuerreroJ.M., HOGO: Hide Objects Game Optimization.
QaisM.H., HasanienH.M. and AlghuwainemS., Transient search optimization: a newmeta-heuristic optimization algorithm, Applied Intelligence (2020), 1–16.
44.
Morales-CastañedaB., ZaldívarD., CuevasE., FaustoF. and RodríguezA., A better balance in metaheuristic algorithms: Does it exist? Swarm and Evolutionary Computation (2020), 100671.
45.
JavidiA., SalajeghehE. and SalajeghehJ., Enhanced crow search algorithm for optimum design of structures, Applied Soft Computing77 (2019), 274–289.
46.
YangX.-S., Nature-inspired algorithms: success and challenges, Engineering and Applied Sciences Optimization, Springer (2015), 129–143.
47.
HussainK., SallehM.N.M., ChengS. and ShiY., Metaheuristic research: a comprehensive survey, Artificial Intelligence Review52 (2019), 2191–2233.
48.
MirjaliliS., The ant lion optimizer, Advances in Engineering Software83 (2015), 80–98.
49.
Fathollahi-FardA.M. and Hajiaghaei-KeshteliM., A stochastic multi-objective model for a closed-loop supply chain with environmental considerations, Applied Soft Computing69 (2018), 232–249.
50.
SapreS. and MiniS., Opposition-based moth flame optimization with Cauchy mutation and evolutionary boundary constraint handling for global optimization, Soft Computing23 (2019), 6023–6041.
51.
DinkarS.K. and DeepK., Opposition based Laplacian ant lion optimizer, Journal of Computational Science23 (2017), 71–90.
52.
TizhooshH.R., Opposition-based learning: a new scheme for machine intelligence, International Conference on Computational Intelligence for Modelling, Control and Automation and International Conference on Intelligent Agents,Web Technologies and InternetCommerce (CIMCA-IAWTIC’06), IEEE, (2005), 695–701.
53.
SeifZ. and AhmadiM.B., An opposition-based algorithm for function optimization, Engineering Applications of Artificial Intelligence37 (2015), 293–306.
54.
DaiC., HuZ., LiZ., XiongZ. and SuQ., An Improved Grey Prediction Evolution Algorithm Based on Topological Opposition-Based Learning, IEEE Access8 (2020), 30745–30762.
55.
DhimanG. and KumarV., Seagull optimization algorithm: Theory and its applications for large-scale industrial engineering problems, Knowledge-Based Systems165 (2019), 169–196.
56.
TanabeR. and FukunagaA., Success-history based parameter adaptation for differential evolution, 2013 IEEE congress on evolutionary computation, IEEE, (2013), 71–78.
57.
HadavandiE., MostafayiS. and SoltaniP., A Grey Wolf Optimizer-based neural network coupled with response surface method for modeling the strength of siro-spun yarn in spinning mills, Applied Soft Computing72 (2018), 1–13.
58.
AljarahI., FarisH. and MirjaliliS., Optimizing connection weights in neural networks using the whale optimization algorithm, Soft Computing22 (2018), 1–15.
59.
LotfollahiM., SiavoshaniM.J., ZadeR.S.H. and SaberianM., Deep packet: A novel approach for encrypted traffic classification using deep learning, Soft Computing24 (2020), 1999–2012.
60.
MirjaliliS., MirjaliliS.M. and LewisA., Let a biogeographybased optimizer train your multi-layer perceptron, Information Sciences269 (2014), 188–209.
61.
MirjaliliS., How effective is the Grey Wolf optimizer in training multi-layer perceptrons, Applied Intelligence43 (2015), 150–161.
62.
BlakeC.L. and MerzC.J., UCI repository of machine learning databases, 1998 (1998).
DinkarS.K. and DeepK., An efficient opposition based Lévy Flight Antlion optimizer for optimization problems, Journal of Computational Science29 (2018), 119–141.
65.
EweesA.A., Abd ElazizM. and HousseinE.H., Improved grasshopper optimization algorithm using opposition-based learning, Expert Systems with Applications112 (2018), 156–172.
66.
ZhaoX., YangF., HanY. and CuiY., An Opposition-Based Chaotic Salp Swarm Algorithm for Global Optimization, IEEE Access8 (2020), 36485–36501.
67.
MirjaliliS., MirjaliliS.M. and HatamlouA., Multi-verse optimizer: a nature-inspired algorithm for global optimization, Neural Computing and Applications27 (2016), 495–513.
68.
KavehA. and EslamlouA.D., Water strider algorithm: A new metaheuristic and applications, Structures, Elsevier, (2020), 520–541.
69.
NematollahiA.F., RahiminejadA. and VahidiB., A novel physical based meta-heuristic optimization method known as Lightning Attachment Procedure Optimization, Applied Soft Computing59 (2017), 596–621.
