Research Article
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Year 2023, Volume: 15 Issue: 1, 36 - 51, 03.05.2023
https://doi.org/10.24107/ijeas.1223160

Abstract

References

  • Ceranic, B., Fryer, C., Baines, R.W., An application of simulated annealing to the optimum design of reinforced concrete retaining structures. Computers & Structures, 79(17), 1569-1581, 2001.
  • Yepes, V., Alcala, J., Perea, C., Gonzalez-Vidosa, F., A parametric study of optimum earth-retaining walls by simulated annealing. Engineering Structures, 30(3), 821-830, 2008.
  • Khajehzadeh, M., Taha, M.R., El-Shafie, A., Eslami, M., Modified particle swarm optimization for optimum design of spread footing and retaining wall. Journal of Zhejiang University-Science A, 12(6), 415-427, 2011.
  • Kayhan, A.H., Demir, A., Betonarme konsol istinat duvarlarının parçacık sürü optimizasyonu ile optimum tasarımı. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 22(3), 129-135, 2016.
  • Temur, R., Bekdas, G., Teaching learning-based optimization for design of cantilever retaining walls. Structural Engineering and Mechanics, 57(4), 763-783, 2016.
  • Molina-Moreno, F., Garcia-Segura, T., Marti, J.V., Yepes, V., Optimization of buttressed earth-retaining walls using hybrid harmony search algorithms. Engineering Structures, 134, 205-216, 2017.
  • Temür, R., Bekdaş, G., Betonarme konsol istinat duvarlarının optimum tasarımı. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 24(6), 1043-1050, 2018.
  • Camp, C.V., Akin, A., Design of Retaining Walls Using Big Bang-Big Crunch Optimization. Journal of Structural Engineering, 138(3), 438-448, 2012.
  • Talatahari, S., Sheikholeslami, R., Shadfaran, M., Pourbaba, M., Optimum Design of Gravity Retaining Walls Using Charged System Search Algorithm. Mathematical Problems in Engineering, 2012, 2012.
  • Khajehzadeh, M., Taha, M.R., Eslami, M., Efficient gravitational search algorithm for optimum design of retaining walls. Structural Engineering and Mechanics, 45(1), 111-127, 2013.
  • Khajehzadeh, M., Taha, M.R., Eslami, M., Multi-objective optimisation of retaining walls using hybrid adaptive gravitational search algorithm. Civil Engineering and Environmental Systems, 31(3), 229-242, 2014.
  • Aydoğdu, İ., Betonarme konsol istinat duvarların çok amaçlı (maliyet ve karbondioksit) optimizasyonunda meta-sezgisel yöntemlerin karşılaştırılması. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 23(3), 221-231, 2017.
  • ÖZTÜRK, H.T., Betonarme Konsol İstinat Duvarlarının Minimum Maliyet ve Ağırlıkla Optimum Tasarımı. Düzce Üniversitesi Bilim ve Teknoloji Dergisi, 6(4), 1258-1268, 2018.
  • Kashani, A.R., Gandomi, A.H., Azizi, K., Camp, C.V., Multi-objective optimization of reinforced concrete cantilever retaining wall: a comparative study. Structural and Multidisciplinary Optimization, 65(9), 2022.
  • Arama, Z.A., Kayabekir, A.E., Bekdas, G., Kim, S., Geem, Z.W., The Usage of the Harmony Search Algorithm for the Optimal Design Problem of Reinforced Concrete Retaining Walls. Applied Sciences-Basel, 11(3), 2021.
  • Ukritchon, B., Chea, S., Keawsawasvong, S., Optimal design of Reinforced Concrete Cantilever Retaining Walls considering the requirement of slope stability. Ksce Journal of Civil Engineering, 21(7), 2673-2682, 2017.
  • Moayyeri, N., Gharehbaghi, S., Plevris, V., Cost-Based Optimum Design of Reinforced Concrete Retaining Walls Considering Different Methods of Bearing Capacity Computation. Mathematics, 7(12), 2019.
  • Khajehzadeh, M., Kalhor, A., Tehrani, M.S., Jebeli, M., Optimum design of retaining structures under seismic loading using adaptive sperm swarm optimization. Structural Engineering and Mechanics, 81(1), 93-102, 2022.
  • Kaveh, A., Hamedani, K.B., Bakhshpoori, T., Optimal Design of Reinforced Concrete Cantilever Retaining Walls Utilizing Eleven Meta-Heuristic Algorithms: A Comparative Study. Periodica Polytechnica-Civil Engineering, 64(1), 156-168, 2020.
  • Yucel, M., Kayabekir, A.E., Bekdas, G., Nigdeli, S.M., Kim, S., Geem, Z.W., Adaptive-Hybrid Harmony Search Algorithm for Multi-Constrained Optimum Eco-Design of Reinforced Concrete Retaining Walls. Sustainability, 13(4), 2021.
  • Cohn, M.Z., Lounis, Z., Optimum Limit Design of Continuous Prestressed Concrete Beams. Journal of Structural Engineering-Asce, 119(12), 3551-3570, 1993.
  • Altun, F., Haktanir, T., A comparative experimental study of steel fibre-additive reinforced concrete beams. Materiales De Construccion, 54(276), 5-15, 2004.
  • Deliktaş, B., Bikçe, M., Coşkun, H., Türker, H.T., Betonarme Kirişlerin Optimum Tasarımında Genetik Algoritma Parametrelerinin Etkisinin Belirlenmesi. Firat University Journal of Engineering, 21(2), 2009.
  • Bordignon, R., Kripka, M., Optimum design of reinforced concrete columns subjected to uniaxial flexural compression. Computers and Concrete, 9(5), 327-340, 2012.
  • Kayabekir, A.E., Bekdas, G., Nigdeli, S.M., Apak, S., Cost and Environmental Friendly Multi-Objective Optimum Design of Reinforced Concrete Columns. Journal of Environmental Protection and Ecology, 23(2), 890-899, 2022.
  • Kwak, H.G., Kim, J., Optimum design of reinforced concrete plane frames based on predetermined section database. Computer-Aided Design, 40(3), 396-408, 2008.
  • Perea, C., Alcala, J., Yepes, V., Gonzalez-Vidosa, F., Hospitaler, A., Design of reinforced concrete bridge frames by heuristic optimization. Advances in Engineering Software, 39(8), 676-688, 2008.
  • Paya-Zaforteza, I., Yepes, V., Hospitaler, A., Gonzalez-Vidosa, F., CO2-optimization of reinforced concrete frames by simulated annealing. Engineering Structures, 31(7), 1501-1508, 2009.
  • Akin, A., Saka, M.P., Harmony search algorithm based optimum detailed design of reinforced concrete plane frames subject to ACI 318-05 provisions. Computers & Structures, 147, 79-95, 2015.
  • Tapao, A., Cheerarot, R., Optimal parameters and performance of artificial bee colony algorithm for minimum cost design of reinforced concrete frames. Engineering Structures, 151, 802-820, 2017.
  • Chutani, S., Singh, J., Use of modified hybrid PSOGSA for optimum design of RC frame. Journal of the Chinese Institute of Engineers, 41(4), 342-352, 2018.
  • Gharehbaghi, S., Damage controlled optimum seismic design of reinforced concrete framed structures. Structural Engineering and Mechanics, 65(1), 53-68, 2018.
  • Amirsardari, A., Rajeev, P., Lumantarna, E., Goldsworthy, H.M., Suitable intensity measure for probabilistic seismic risk assessment of non-ductile Australian reinforced concrete buildings. Bulletin of Earthquake Engineering, 17(7), 3753-3775, 2019.
  • Martins, A.M.B., Simoes, L.M.C., Negrao, J.H.J.O., Lopes, A.V., Sensitivity analysis and optimum design of reinforced concrete frames according to Eurocode 2. Engineering Optimization, 52(12), 2011-2032, 2020.
  • Babaei, M., Mollayi, M., Multiobjective optimal design of reinforced concrete frames using two metaheuristic algorithms. Journal of Engineering Research, 9(4b), 166-192, 2021.
  • Arab, M., Riahi, H.T., Daei, M., Optimum displacement profile for the direct displacement-based design of steel moment-resisting frames. Structures, 44, 323-342, 2022.
  • Bekdas, G., Yucel, M., Nigdeli, S.M., Generation of eco-friendly design for post-tensioned axially symmetric reinforced concrete cylindrical walls by minimizing of CO2 emission. Structural Design of Tall and Special Buildings, 31(13), 2022.
  • Salimi, P., Bondarabadi, H.R., Kaveh, A., Optimal Design of Reinforced Concrete Frame Structures Using Cascade Optimization Method. Periodica Polytechnica-Civil Engineering, 2022.
  • Ahmadkhanlou, F., Adeli, H., Optimum cost design of reinforced concrete slabs using neural dynamics model. Engineering Applications of Artificial Intelligence, 18(1), 65-72, 2005.
  • Sahab, M.G., Ashour, A.F., Toropov, V., Cost optimisation of reinforced concrete flat slab buildings. Engineering Structures, 27(3), 313-322, 2005.
  • Kaveh, A., Abadi, A.S.M., Cost optimization of a composite floor system using an improved harmony search algorithm. Journal of Constructional Steel Research, 66(5), 664-669, 2010.
  • Aldwaik, M., Adeli, H., Cost optimization of reinforced concrete flat slabs of arbitrary configuration in irregular highrise building structures. Structural and Multidisciplinary Optimization, 54(1), 151-164, 2016.
  • Stochino, F., Gayarre, F.L., Reinforced Concrete Slab Optimization with Simulated Annealing. Applied Sciences-Basel, 9(15), 2019.
  • Saka, P.M., Akın, A., Aydoğdu, İ., Betonarme ve çelik yapıların deprem yüklerinin de göz önüne alınarak optimum boyutlandırılması. 2009.
  • Yucel, M., Nigdeli, S.M., Bekdas, G., Generation of sustainable models with multi-objective optimum design of reinforced concrete (RC) structures. Structures, 40, 223-236, 2022.
  • Aslay, S.E., Dede, T., 3D cost optimization of 3 story RC constructional building using Jaya algorithm. Structures, 40, 803-811, 2022.
  • ATABAY, Ş., GÜLAY, F.G., Genetik algoritmalar ile perdeli yapı sisteminin maliyet optimizasyonu. İTÜDERGİSİ/d, 3(6), 2010.
  • Aydin, Z., Ayvaz, Y., Overall cost optimization of prestressed concrete bridge using genetic algorithm. Ksce Journal of Civil Engineering, 17(4), 769-776, 2013.
  • Esra, U., ÇITIRIK, B.N., Modifiye Yapay Arı Kolonisi Algoritması ile Konsol Dayanma Duvarının Türkiye Bina Deprem Yönetmeliği 2018’e Göre Optimum Tasarımı. Avrupa Bilim ve Teknoloji Dergisi, (26), 61-67, 2021.
  • Alshboul, O., Almasabha, G., Shehadeh, A., Al Hattamleh, O., Almuflih, A.S., Optimization of the Structural Performance of Buried Reinforced Concrete Pipelines in Cohesionless Soils. Materials, 15(12), 2022.
  • Saka, M.P., Optimum Design of Skeletal Structures: A Review, in Progress in Civil and Structural Engineering Computing, J.M.A. B.H.V. Topping, F.J. Pallarés, R. Bru and M.L. Romero, Editor. 2003, Saxe-Coburg Publications; Stirlingshire, UK, 237-284,2003.
  • Saka, M.P., Shape and Topology Optimization Design of Skeletal Structures using Metaheuristic Algorithms: A Review. Computational Technology Reviews, 9, 31-68, 2014.
  • Saka, M.P., Geem, Z.W., Mathematical and Metaheuristic Applications in Design Optimization of Steel Frame Structures: An Extensive Review. Mathematical Problems in Engineering, 2013, 2013.
  • Aydogdu, I., Comparison of metaheuristics on multi objective (cost&CO2) optimization of RC cantilever retaining walls. Pamukkale University Journal of Engineering Sciences-Pamukkale Universitesi Muhendislik Bilimleri Dergisi, 23(3), 221-231, 2017.
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Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method

Year 2023, Volume: 15 Issue: 1, 36 - 51, 03.05.2023
https://doi.org/10.24107/ijeas.1223160

Abstract

The study presents the investigation of the elastic behavior of the soil in the optimal design of continuous foundations according to the rigid solid case. For the investigation, the optimization algorithm that can find optimal section and reinforcement details of continuous foundations has been developed. The developed algorithm uses one of the well-known meta-heuristic methods named the artificial Bee Colony method to find the optimal design. The Winkler spring hypothesis (analytic solution) is used to calculate internal forces and stresses in elastic continuous foundations. We used the real-size design example previously used in the literature to test the elastic soil effect and algorithm performance. The obtained results show that the current algorithm performs well, and lower cost values are obtained in the elastic design.

References

  • Ceranic, B., Fryer, C., Baines, R.W., An application of simulated annealing to the optimum design of reinforced concrete retaining structures. Computers & Structures, 79(17), 1569-1581, 2001.
  • Yepes, V., Alcala, J., Perea, C., Gonzalez-Vidosa, F., A parametric study of optimum earth-retaining walls by simulated annealing. Engineering Structures, 30(3), 821-830, 2008.
  • Khajehzadeh, M., Taha, M.R., El-Shafie, A., Eslami, M., Modified particle swarm optimization for optimum design of spread footing and retaining wall. Journal of Zhejiang University-Science A, 12(6), 415-427, 2011.
  • Kayhan, A.H., Demir, A., Betonarme konsol istinat duvarlarının parçacık sürü optimizasyonu ile optimum tasarımı. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 22(3), 129-135, 2016.
  • Temur, R., Bekdas, G., Teaching learning-based optimization for design of cantilever retaining walls. Structural Engineering and Mechanics, 57(4), 763-783, 2016.
  • Molina-Moreno, F., Garcia-Segura, T., Marti, J.V., Yepes, V., Optimization of buttressed earth-retaining walls using hybrid harmony search algorithms. Engineering Structures, 134, 205-216, 2017.
  • Temür, R., Bekdaş, G., Betonarme konsol istinat duvarlarının optimum tasarımı. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 24(6), 1043-1050, 2018.
  • Camp, C.V., Akin, A., Design of Retaining Walls Using Big Bang-Big Crunch Optimization. Journal of Structural Engineering, 138(3), 438-448, 2012.
  • Talatahari, S., Sheikholeslami, R., Shadfaran, M., Pourbaba, M., Optimum Design of Gravity Retaining Walls Using Charged System Search Algorithm. Mathematical Problems in Engineering, 2012, 2012.
  • Khajehzadeh, M., Taha, M.R., Eslami, M., Efficient gravitational search algorithm for optimum design of retaining walls. Structural Engineering and Mechanics, 45(1), 111-127, 2013.
  • Khajehzadeh, M., Taha, M.R., Eslami, M., Multi-objective optimisation of retaining walls using hybrid adaptive gravitational search algorithm. Civil Engineering and Environmental Systems, 31(3), 229-242, 2014.
  • Aydoğdu, İ., Betonarme konsol istinat duvarların çok amaçlı (maliyet ve karbondioksit) optimizasyonunda meta-sezgisel yöntemlerin karşılaştırılması. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 23(3), 221-231, 2017.
  • ÖZTÜRK, H.T., Betonarme Konsol İstinat Duvarlarının Minimum Maliyet ve Ağırlıkla Optimum Tasarımı. Düzce Üniversitesi Bilim ve Teknoloji Dergisi, 6(4), 1258-1268, 2018.
  • Kashani, A.R., Gandomi, A.H., Azizi, K., Camp, C.V., Multi-objective optimization of reinforced concrete cantilever retaining wall: a comparative study. Structural and Multidisciplinary Optimization, 65(9), 2022.
  • Arama, Z.A., Kayabekir, A.E., Bekdas, G., Kim, S., Geem, Z.W., The Usage of the Harmony Search Algorithm for the Optimal Design Problem of Reinforced Concrete Retaining Walls. Applied Sciences-Basel, 11(3), 2021.
  • Ukritchon, B., Chea, S., Keawsawasvong, S., Optimal design of Reinforced Concrete Cantilever Retaining Walls considering the requirement of slope stability. Ksce Journal of Civil Engineering, 21(7), 2673-2682, 2017.
  • Moayyeri, N., Gharehbaghi, S., Plevris, V., Cost-Based Optimum Design of Reinforced Concrete Retaining Walls Considering Different Methods of Bearing Capacity Computation. Mathematics, 7(12), 2019.
  • Khajehzadeh, M., Kalhor, A., Tehrani, M.S., Jebeli, M., Optimum design of retaining structures under seismic loading using adaptive sperm swarm optimization. Structural Engineering and Mechanics, 81(1), 93-102, 2022.
  • Kaveh, A., Hamedani, K.B., Bakhshpoori, T., Optimal Design of Reinforced Concrete Cantilever Retaining Walls Utilizing Eleven Meta-Heuristic Algorithms: A Comparative Study. Periodica Polytechnica-Civil Engineering, 64(1), 156-168, 2020.
  • Yucel, M., Kayabekir, A.E., Bekdas, G., Nigdeli, S.M., Kim, S., Geem, Z.W., Adaptive-Hybrid Harmony Search Algorithm for Multi-Constrained Optimum Eco-Design of Reinforced Concrete Retaining Walls. Sustainability, 13(4), 2021.
  • Cohn, M.Z., Lounis, Z., Optimum Limit Design of Continuous Prestressed Concrete Beams. Journal of Structural Engineering-Asce, 119(12), 3551-3570, 1993.
  • Altun, F., Haktanir, T., A comparative experimental study of steel fibre-additive reinforced concrete beams. Materiales De Construccion, 54(276), 5-15, 2004.
  • Deliktaş, B., Bikçe, M., Coşkun, H., Türker, H.T., Betonarme Kirişlerin Optimum Tasarımında Genetik Algoritma Parametrelerinin Etkisinin Belirlenmesi. Firat University Journal of Engineering, 21(2), 2009.
  • Bordignon, R., Kripka, M., Optimum design of reinforced concrete columns subjected to uniaxial flexural compression. Computers and Concrete, 9(5), 327-340, 2012.
  • Kayabekir, A.E., Bekdas, G., Nigdeli, S.M., Apak, S., Cost and Environmental Friendly Multi-Objective Optimum Design of Reinforced Concrete Columns. Journal of Environmental Protection and Ecology, 23(2), 890-899, 2022.
  • Kwak, H.G., Kim, J., Optimum design of reinforced concrete plane frames based on predetermined section database. Computer-Aided Design, 40(3), 396-408, 2008.
  • Perea, C., Alcala, J., Yepes, V., Gonzalez-Vidosa, F., Hospitaler, A., Design of reinforced concrete bridge frames by heuristic optimization. Advances in Engineering Software, 39(8), 676-688, 2008.
  • Paya-Zaforteza, I., Yepes, V., Hospitaler, A., Gonzalez-Vidosa, F., CO2-optimization of reinforced concrete frames by simulated annealing. Engineering Structures, 31(7), 1501-1508, 2009.
  • Akin, A., Saka, M.P., Harmony search algorithm based optimum detailed design of reinforced concrete plane frames subject to ACI 318-05 provisions. Computers & Structures, 147, 79-95, 2015.
  • Tapao, A., Cheerarot, R., Optimal parameters and performance of artificial bee colony algorithm for minimum cost design of reinforced concrete frames. Engineering Structures, 151, 802-820, 2017.
  • Chutani, S., Singh, J., Use of modified hybrid PSOGSA for optimum design of RC frame. Journal of the Chinese Institute of Engineers, 41(4), 342-352, 2018.
  • Gharehbaghi, S., Damage controlled optimum seismic design of reinforced concrete framed structures. Structural Engineering and Mechanics, 65(1), 53-68, 2018.
  • Amirsardari, A., Rajeev, P., Lumantarna, E., Goldsworthy, H.M., Suitable intensity measure for probabilistic seismic risk assessment of non-ductile Australian reinforced concrete buildings. Bulletin of Earthquake Engineering, 17(7), 3753-3775, 2019.
  • Martins, A.M.B., Simoes, L.M.C., Negrao, J.H.J.O., Lopes, A.V., Sensitivity analysis and optimum design of reinforced concrete frames according to Eurocode 2. Engineering Optimization, 52(12), 2011-2032, 2020.
  • Babaei, M., Mollayi, M., Multiobjective optimal design of reinforced concrete frames using two metaheuristic algorithms. Journal of Engineering Research, 9(4b), 166-192, 2021.
  • Arab, M., Riahi, H.T., Daei, M., Optimum displacement profile for the direct displacement-based design of steel moment-resisting frames. Structures, 44, 323-342, 2022.
  • Bekdas, G., Yucel, M., Nigdeli, S.M., Generation of eco-friendly design for post-tensioned axially symmetric reinforced concrete cylindrical walls by minimizing of CO2 emission. Structural Design of Tall and Special Buildings, 31(13), 2022.
  • Salimi, P., Bondarabadi, H.R., Kaveh, A., Optimal Design of Reinforced Concrete Frame Structures Using Cascade Optimization Method. Periodica Polytechnica-Civil Engineering, 2022.
  • Ahmadkhanlou, F., Adeli, H., Optimum cost design of reinforced concrete slabs using neural dynamics model. Engineering Applications of Artificial Intelligence, 18(1), 65-72, 2005.
  • Sahab, M.G., Ashour, A.F., Toropov, V., Cost optimisation of reinforced concrete flat slab buildings. Engineering Structures, 27(3), 313-322, 2005.
  • Kaveh, A., Abadi, A.S.M., Cost optimization of a composite floor system using an improved harmony search algorithm. Journal of Constructional Steel Research, 66(5), 664-669, 2010.
  • Aldwaik, M., Adeli, H., Cost optimization of reinforced concrete flat slabs of arbitrary configuration in irregular highrise building structures. Structural and Multidisciplinary Optimization, 54(1), 151-164, 2016.
  • Stochino, F., Gayarre, F.L., Reinforced Concrete Slab Optimization with Simulated Annealing. Applied Sciences-Basel, 9(15), 2019.
  • Saka, P.M., Akın, A., Aydoğdu, İ., Betonarme ve çelik yapıların deprem yüklerinin de göz önüne alınarak optimum boyutlandırılması. 2009.
  • Yucel, M., Nigdeli, S.M., Bekdas, G., Generation of sustainable models with multi-objective optimum design of reinforced concrete (RC) structures. Structures, 40, 223-236, 2022.
  • Aslay, S.E., Dede, T., 3D cost optimization of 3 story RC constructional building using Jaya algorithm. Structures, 40, 803-811, 2022.
  • ATABAY, Ş., GÜLAY, F.G., Genetik algoritmalar ile perdeli yapı sisteminin maliyet optimizasyonu. İTÜDERGİSİ/d, 3(6), 2010.
  • Aydin, Z., Ayvaz, Y., Overall cost optimization of prestressed concrete bridge using genetic algorithm. Ksce Journal of Civil Engineering, 17(4), 769-776, 2013.
  • Esra, U., ÇITIRIK, B.N., Modifiye Yapay Arı Kolonisi Algoritması ile Konsol Dayanma Duvarının Türkiye Bina Deprem Yönetmeliği 2018’e Göre Optimum Tasarımı. Avrupa Bilim ve Teknoloji Dergisi, (26), 61-67, 2021.
  • Alshboul, O., Almasabha, G., Shehadeh, A., Al Hattamleh, O., Almuflih, A.S., Optimization of the Structural Performance of Buried Reinforced Concrete Pipelines in Cohesionless Soils. Materials, 15(12), 2022.
  • Saka, M.P., Optimum Design of Skeletal Structures: A Review, in Progress in Civil and Structural Engineering Computing, J.M.A. B.H.V. Topping, F.J. Pallarés, R. Bru and M.L. Romero, Editor. 2003, Saxe-Coburg Publications; Stirlingshire, UK, 237-284,2003.
  • Saka, M.P., Shape and Topology Optimization Design of Skeletal Structures using Metaheuristic Algorithms: A Review. Computational Technology Reviews, 9, 31-68, 2014.
  • Saka, M.P., Geem, Z.W., Mathematical and Metaheuristic Applications in Design Optimization of Steel Frame Structures: An Extensive Review. Mathematical Problems in Engineering, 2013, 2013.
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There are 78 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Seda Turan 0000-0001-8626-440X

İbrahim Aydoğdu 0000-0002-8281-2365

Engin Emsen 0000-0002-5904-2737

Publication Date May 3, 2023
Acceptance Date April 28, 2023
Published in Issue Year 2023 Volume: 15 Issue: 1

Cite

APA Turan, S., Aydoğdu, İ., & Emsen, E. (2023). Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method. International Journal of Engineering and Applied Sciences, 15(1), 36-51. https://doi.org/10.24107/ijeas.1223160
AMA Turan S, Aydoğdu İ, Emsen E. Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method. IJEAS. May 2023;15(1):36-51. doi:10.24107/ijeas.1223160
Chicago Turan, Seda, İbrahim Aydoğdu, and Engin Emsen. “Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method”. International Journal of Engineering and Applied Sciences 15, no. 1 (May 2023): 36-51. https://doi.org/10.24107/ijeas.1223160.
EndNote Turan S, Aydoğdu İ, Emsen E (May 1, 2023) Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method. International Journal of Engineering and Applied Sciences 15 1 36–51.
IEEE S. Turan, İ. Aydoğdu, and E. Emsen, “Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method”, IJEAS, vol. 15, no. 1, pp. 36–51, 2023, doi: 10.24107/ijeas.1223160.
ISNAD Turan, Seda et al. “Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method”. International Journal of Engineering and Applied Sciences 15/1 (May 2023), 36-51. https://doi.org/10.24107/ijeas.1223160.
JAMA Turan S, Aydoğdu İ, Emsen E. Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method. IJEAS. 2023;15:36–51.
MLA Turan, Seda et al. “Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method”. International Journal of Engineering and Applied Sciences, vol. 15, no. 1, 2023, pp. 36-51, doi:10.24107/ijeas.1223160.
Vancouver Turan S, Aydoğdu İ, Emsen E. Optimum Design Of Elastic Continuous Foundations With The Artificial Bee Colony Method. IJEAS. 2023;15(1):36-51.

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