SOLVING ENGINEERING OPTIMIZATION PROBLEMS WITH THE SWARM INTELLIGENCE METHODS

An important stage in problem solving process for aerospace and aerostructures designing is calculating their main characteristics optimization. The results of the four constrained optimization problems related to the design of various technical systems: such as determining the best parameters of welded beams, pressure vessel, gear, spring are presented. The purpose of each task is to minimize the cost and weight of the construction. The object functions in optimization practical problem are nonlinear functions with a lot of variables and a complex layer surface indentations. That is why using classical approach for extremum seeking is not efficient. Here comes the necessity of using such methods of optimization that allow to find a near optimal solution in acceptable amount of time with the minimum waste of computer power. Such methods include the methods of Swarm Intelligence: spiral dynamics algorithm, stochastic diffusion search, hybrid seeker optimization algorithm. The Swarm Intelligence methods are designed in such a way that a swarm consisting of agents carries out the search for extremum. In search for the point of extremum, the particles exchange information and consider their experience as well as the experience of population leader and the neighbors in some area. To solve the listed problems there has been designed a program complex, which efficiency is illustrated by the solutions of four applied problems. Each of the considered applied optimization problems is solved with all the three chosen methods. The obtained numerical results can be compared with the ones found in a swarm with a particle method. The author gives recommendations on how to choose methods parameters and penalty function value, which consider inequality constraints.

Swarm Intelligence, optimization methods, global extremum, penalty function

1. Dulnev G.N., Zarichnyak Yu.P. Teploprovodnost’ smesei i kompozitsionnykh materialov. [Heat conductivity of mixtures and composite materials.]. Leningrad: Energia [Leningrad: Energia], 1974. 264 p. (in Russian)

2. Khoroshun L.P., Soltanov N.S. Termouprugost’ dvukhkomponentnykh smesei [Thermoelasticity of two-component mixtures]. Kiev: Naukova Dumka [Kiev: Naukova Dumka], 1984. 111 p. (in Russian)

3. Shermergor T.D. Teoria uprugosti mikroneodnorodnykh sred [Theory of elasticity of micro-heterogeneous media]. Мoscow, Nauka, 1977. 399 p. (in Russian)

4. Zarubin V.S., Kuvyrkin G.N., Savelyeva I.Yu. Effektivny koefficient teploprovodnosti kompozita s sharovymi vklucheniami [Effective heat conductivity coefficient of a composite material with ball inclusions]. Teplovyye processy v tekhnike [Thermal processes in technology], 2012, no. 10, pp. 470–474. (in Russian)

5. Zarubin V.S., Kuvyrkin G.N., Effektivnye koefficienty teploprovodnosti kompozita s ellipsoidalnymi vklucheniami [Effective coefficients of heat conductivity of composites with ellipsoidal inclusions]. Vestnik MGTU im. N.E. Baumana [Vestnik BMSTU]. Ser. Estestvennye nauki [ser. Natural sciences], 2012, № 3, pp. 76–85.

6. Zarubin V.S., Kuvyrkin G.N., Savelyeva I.Yu. Sravnitelny analiz ocenok koefficienta teploprovodnosti kompozita s sharovymi vklucheniami [Comparing analysis of evaluations of heat conductivity coefficients of composite materials with ball inclusions]. Nauka i obrazovanie [Science and education]. Electronic edition, 2013, № 7, pp. 299–318. DOI: 10.7463/0713.0569319.

7. Pugachev O.V., Han Z.T. Nahozhdeniye effektivnoi teploprovodnosti kompozita metodom momentov [Evaluation of effective heat conductivity of composite materials by the method of momenta]. Vestnik MGTU im. N.E. Baumana. Seriya Estestvennyye nauki [Vestnik BMSTU, ser. Natural Sciences], 2016, no. 4. DOI: 10.18698/1812-3368-2016-4-28-39. (in Russian)

8. Pugachev O.V., Han Z.T. Teploprovodnost’ kompozita s neteploprovodnymi sharovymi vklyucheniyami [Heat conductivity of composite materials with included balls of zero heat conductivity]. Nauka I obrazovaniye. MGTU im. N.E. Baumana. Elektronnyi zhurnal [Science and Education. BMSTU. Electronic journal], 2015, no. 5, pp. 205–217. DOI: 10.7463/0515.0776224. (in Russian)

9. Chen Y.-M., Ting J.-M. Ultra high thermal conductivity polymer composites. Carbon. 2002, vol. 40, pp. 359–362.

10. Nan C.-W., Birringer R., Clarke D.R., Gleiter H. Effective thermal conductivity of particulate composites with interfacial thermal resistance. Journal of Applied Physics, 1997, vol. 81, pp. 6692–6699.