Dynamic Loads and Different Soil Characteristics Examination on Optimum Design of Cantilever Retaining Walls Utilizing Harmony Search Algorithm

Uray, Esra; Çarbaş, Serdar

doi:10.24107/ijeas.1033802

Cited by 5 publications

(5 citation statements)

References 20 publications

(23 reference statements)

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“…e harmony search (HS) is also able to perform local and randomization searches and replace bad solutions with those of good harmony due to its memory function. It has also been used by several studies to optimize retaining wall design and has proven its effectiveness and robustness; see, for example, the papers of Uray and Tan [30], Kaveh and Abadi [40], Kaveh and Behnam [46], Sheikholeslami et al [50], Kaveh and Mahdavi [53], Kaveh and Farhoudi [56], Sheikholeslami et al [57], Temür and Bekdas [58], Uray et al [71], Kayabekir et al [75], Yücel et al [85], Uray and Çarbas [89], Uray et al [92], Temür [99], and Uray et al [102]. e HS has also been improved over the years by updating its memory considering rate, randomization, and local search capabilities.…”

Section: Harmony Search (Hs)mentioning

confidence: 99%

“…Although the design codes advise coarse aggregates as prescribed material for backfill, it may not be feasible to provide them in all cases. Some studies have researched this aspect and tried to optimize the design for backfill with different types of soil with different cohesion, unit weight, bearing, and internal angle of friction values (Al Sebai et al [31], Srivastavaa et al [32], Yepes et al [37], Kaveh and Abadi [40], Kaveh and Behnam [46], Kaveh and Laien [60], Konstandakopoulou et al [76], Uray et al [83], Uray and Çarbas ¸ [89], and Dodigović et al [94]). e backfill included coarse granular fill (gravel), granular soils with more than 12% of fines (GW, GS, SM, and SL), and fine soils with more than 25% of coarse grains (CL-ML).…”

Section: Structural and Geotechnical Design Investigationsmentioning

confidence: 99%

“…[38], Khajehzadeh et al[41], Khajehzadeh and Eslami[43], Talatahari and Sheikholeslami[51], Gandomi et al[52], Kaveh and Mahdavi[53], Temür and Bekdas[58], Kumar and Suribabu[63], Moayyeri et al[69], Mergos and Mantoglou[77], Kalemci et al[78], Kashani et al[82], Uray and Çarbas ¸[89], Tutus ¸et al[98], and Temür[99] to optimize RC cantilever retaining walls. e above studies evidence the speed of convergence of PSO and standard deviation is superior to other classical algorithms.…”

mentioning

confidence: 99%

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Design Optimization of Reinforced Concrete Cantilever Retaining Walls: A State‐of‐the‐Art Review

Shakeel

Azam

Riaz

et al. 2022

Advances in Civil Engineering

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The booming growth of computational abilities in the 21st century has led to its assimilation and benefit in all horizons of engineering. For civil engineers, these advancements have led to groundbreaking technologies such as BIM, automation, and optimization. Unfortunately, even in an era of dwindling resources and dire need for sustainability, optimization has failed to attract implementation in practice. Despite an exponential growth as an area of research interest, the optimization of engineering structures such as reinforced concrete (RC) is still a complex task that requires multidisciplinary knowledge, hindering its practicability. Although past review papers have delved into this topic, they have only been able to cover the breadth of information available by covering broader aspects of optimization of structures. This study on the other hand aims to cover this topic in depth to uncover problem specific trends and issues, by focusing only on optimization of RC cantilever retaining walls. Although there is an abundance of research studies on this topic, there is an absence of any critical review to tie them up, and concurrently with its broader scope, it suffers the same lack of applicability in the field. The in-depth review presents a summarization of all the online publications including research articles, conference papers, and theses to the best of authors’ knowledge on the topic of RC cantilever retaining wall optimization. Geographical trends, regional developments, and prominent journals have been identified. The design codes, problem formulation, objectives, constraints, variables, and their optimization techniques are tabulated for ease of understanding. Unique areas of development investigated by the different researchers have been highlighted. Lastly, comprehensive recommendations for future works have been detailed with a focus on improving its applicability and assimilation into the construction industry.

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Section: Harmony Search (Hs)mentioning

confidence: 99%

Section: Structural and Geotechnical Design Investigationsmentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Design Optimization of Reinforced Concrete Cantilever Retaining Walls: A State‐of‐the‐Art Review

Shakeel

Azam

Riaz

et al. 2022

Advances in Civil Engineering

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“…If the algorithm does not show improvement over a certain number of iterations, except for the best individual, individuals in the population are replaced with randomly generated agents. The studies on optimum design of cantilever retaining walls several soil properties such as different soil characteristics [18], soil heterogeneity [8], permeability [19], particle size [20] were considered using above-mentioned optimization algorithms.…”

Section: Introductionmentioning

confidence: 99%

Optimization Of Cantilever Retaining Wall Design Using Improved Teaching-Learning-Based Optimization Algorithms

Tayfur,

Kamiloğlu

2024

Firat University Journal of Experimental and Computational Engineering

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Retaining structures play a crucial role in geotechnical engineering to support soil levels, prevent slope failure, and create flat surfaces for construction. Designing these structures involves optimizing internal and external stability while minimizing material usage and cost. This study focused on optimizing reinforced concrete cantilever retaining walls using the Teaching-Learning Based Optimization (TLBO) algorithm and an improved version (I-TLBO) with agents. In the context of the study, geometric-structural design variables, geotechnical -structural constraints, and optimization processes were examined. Minimizing weight and minimizing cost of the wall were the objectives considered in the cantilever retaining wall design process. The optimization results were compared with other algorithms in the literature, such as genetic algorithms, evolutionary strategies, and particle swarm optimization. The improved TLBO algorithm demonstrated superior performance, achieved lower design dimensions, and reduced costs. It provided more efficient solutions that pushed design constraints closer to their limits, resulting in a cost-effective and structurally sound cantilever retaining wall design. As a result of the study, the I-TLBO algorithm was found to be more cost and weight-effective than other methods in the optimization of cantilever retaining wall design.

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“…Mergos and Mantoglou employed FPA for the cost optimization of RC cantilever-type retaining walls [33]. Uray and Carbas evaluated the optimum design of RC-retaining walls via HS by using different soil characteristics and earthquake loads [34]. Sanchez-Olivares and Tomas employed a modified firefly algorithm and optimized RC members, which were subjected to compression and biaxial bending based on two design codes, including Eurocode 2 and ACI318 [35].…”

Section: Introductionmentioning

confidence: 99%

Modified Harmony Search Algorithm-Based Optimization for Eco-Friendly Reinforced Concrete Frames

et al. 2022

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Cost and CO2 are two factors in the optimum design of structures. This study proposes a modified harmony search methodology for optimization of reinforced concrete beams with minimum CO2 emissions. The optimum design was developed in detail by considering all possible combinations of variable loads, including dynamic force resulting from earthquake motion. Moreover, time-history analyses were performed, and requirements of the ACI-318 building code were considered in the reinforced concrete design. The results show that the optimum design based on CO2 emission minimization is greatly different from the optimum cost design results. According to these results, using recycled members provides a sustainable design.

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Dynamic Loads and Different Soil Characteristics Examination on Optimum Design of Cantilever Retaining Walls Utilizing Harmony Search Algorithm

Cited by 5 publications

References 20 publications

Design Optimization of Reinforced Concrete Cantilever Retaining Walls: A State‐of‐the‐Art Review

Design Optimization of Reinforced Concrete Cantilever Retaining Walls: A State‐of‐the‐Art Review

Optimization Of Cantilever Retaining Wall Design Using Improved Teaching-Learning-Based Optimization Algorithms

Modified Harmony Search Algorithm-Based Optimization for Eco-Friendly Reinforced Concrete Frames

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