Your search keyword '"Evolutionary Algorithms"' showing total 24,934 results

1. Decomposition-based multi-objective approach for a green hybrid flowshop rescheduling problem with consistent sublots.

Author

Wang, Weiwei, Zhang, Biao, Jiang, Xuchu, Jia, Baoxian, Sang, Hongyan, and Meng, Leilei

Subjects

EVOLUTIONARY algorithms, BEES algorithm, ENERGY consumption, BEES, PRODUCTION scheduling

Abstract

Rescheduling in a hybrid flowshop holds significant importance in modern industries that face uncertain events. Moreover, real-world manufacturing scenarios often utilise lot streaming to enhance market competitiveness. In light of escalating energy demands and their consequential environmental impacts, contemporary manufacturing companies are placing a heightened emphasis on energy efficiency. This study addressed a green hybrid flowshop rescheduling problem with consistent sublots (GHFRP_CS) in the context of urgent lot insertion. Initially, we establish an optimisation model aimed at minimising the makespan, total energy consumption, and system stability. To tackle this NP-hard multi-objective optimization problem, we develop a constructive heuristic generating promising solutions based on lot split, sequence, and local search rules. Further improvement is achieved through a multi-objective discrete artificial bee colony algorithm (MDABC). MDABC decomposes the problem into sub-problems, initiating solutions with the constructive heuristic and refining them through employed bee, onlooker bee, and scout bee phases. Computational experiments compare MDABC with other multi-objective evolutionary algorithms (MOEAs) on small- and large-scale problems. Results demonstrate MDABC's superiority, achieving fourfold accuracy and efficiency enhancement for small-scale instances and sixfold improvement for large-scale problems at low cost compared to other MOEAs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mixed-model sequencing with reinsertion of failed vehicles: a case study for automobile industry.

Author

Yilmazlar, I. Ozan, Kurz, Mary E., and Rahimian, Hamed

Subjects

OPTIMIZATION algorithms, EVOLUTIONARY algorithms, SEARCH algorithms, STOCHASTIC programming, PRODUCT failure

Abstract

In the automotive industry, some vehicles, failed vehicles, cannot be produced according to the planned schedule due to some reasons such as material shortage, paint failure, etc. These vehicles are pulled out of the sequence, potentially resulting in an increased work overload. On the other hand, the reinsertion of failed vehicles is executed dynamically as suitable positions occur. In case such positions do not occur enough, either the vehicles waiting for reinsertion accumulate or reinsertions are made to worse positions by sacrificing production efficiency. This study proposes a bi-objective two-stage stochastic program and formulation improvements for a mixed-model sequencing problem with stochastic product failures and integrated reinsertion process. Moreover, an evolutionary optimisation algorithm, a two-stage local search algorithm, and a hybrid approach are developed. Numerical experiments over a case study show that while the hybrid algorithm better explores the Pareto front representation, the local search algorithm provides more reliable solutions regarding work overload objective. Finally, the results of the dynamic reinsertion simulations show that we can decrease the work overload by 20% while significantly decreasing the waiting time of the failed vehicles by considering vehicle failures and integrating the reinsertion process into the mixed-model sequencing problem. [ABSTRACT FROM AUTHOR]

Published

2024

3. Quality design based on kernel trick and Bayesian semiparametric model for multi-response processes with complex correlations.

Author

Yang, Shijuan, Wang, Jianjun, Cheng, Xiaoying, Wu, Jiawei, and Liu, Jinpei

Subjects

PRINCIPAL components analysis, EVOLUTIONARY algorithms, RANDOM forest algorithms, LEAST squares

Abstract

Processes or products are typically complex systems with numerous interrelated procedures and interdependent components. This results in complex relationships between responses and input factors, as well as complex nonlinear correlations among multiple responses. If the two types of complex correlations in the quality design cannot be properly dealt with, it will affect the prediction accuracy of the response surface model, as well as the accuracy and reliability of the recommended optimal solutions. In this paper, we combine kernel trick-based kernel principal component analysis, spline-based Bayesian semiparametric additive model, and normal boundary intersection-based evolutionary algorithm to address these two types of complex correlations. The effectiveness of the proposed method in modeling and optimisation is validated through a simulation study and a case study. The results show that the proposed Bayesian semiparametric additive model can better describe the process relationships compared to least squares regression, random forest regression, and support vector basis regression, and the proposed multi-objective optimisation method performs well on several indicators mentioned in the paper. [ABSTRACT FROM AUTHOR]

Published

2024

4. Multiobjective analytical evolutionary algorithm for train stowage planning problem of steel industry.

Author

Yun Dong and Xiangling Zhao

Subjects

EVOLUTIONARY algorithms, STEEL industry, DIFFERENTIAL evolution, INTEGER programming, MACHINE learning

Abstract

The train stowage planning problem (TSPP) of the steel industry aims to select steel coils and allocate them to trains cost-effectively. It is a key component in the transportation of steel products. This study focuses on a multiobjective train stowage planning problem (MoTSPP) that maximises both the loading efficiency of the crane and the loading rate of the train. The MoTSPP also considers operation constraints related to steel coils, train wagons, and stowage modes in real-life railway transportation. An integer programming model is established to mathematically describe this problem. To obtain an efficient solution, a multiobjective analytical evolutionary algorithm (MAEA) that combines evolutionary algorithm (EA) with machine learning (ML) is presented. The EA part is a multiobjective differential evolution that introduces guided evolution and parameter adaptation to produce promising individuals and parameters, respectively. ML part adopts clustering algorithm and surrogate model to accelerate the search. Extensive comparisons and insight analyses are conducted from various perspectives to demonstrate the effectiveness and efficiency of the MAEA for solving the MoTSPP. [ABSTRACT FROM AUTHOR]

Published

2024

5. A reinforcement learning driven two-stage evolutionary optimisation for hybrid seru system scheduling with worker transfer.

Author

Yuting Wu, Ling Wang, Jing-fang Chen, Jie Zheng, and Zixiao Pan

Subjects

REINFORCEMENT learning, EVOLUTIONARY algorithms, TEA plantations, SCHEDULING, ECONOMIC lot size, TRANSFER of training, SCHOOL schedules

Abstract

As a new production pattern, the hybrid seru system (HSS) originated from the actual production scenario. In the HSS, the implementation of the worker transfer strategy can further enhance the system's flexibility but is rarely studied at present. In this paper, we develop a reinforcement learning driven two-stage evolutionary algorithm (RL-TEA) to address the hybrid seru system scheduling problem with worker transfer (HSSSP-WT). To conquer this complex problem, the HSSSP-WT is divided into worker assignment-related subproblems (WS) and batch scheduling-related subproblems (BS) according to the problem characteristics. To effectively solve the subproblems, a probability modelbased exploration and a lower bound-guided heuristic are presented for the WS, and a greedy search is designed for the BS. Meanwhile, to improve search efficiency and effectiveness, a knowledgebased selection mechanism is proposed to determine which subproblem group to optimise in each generation by fusing a reinforcement learning technique and a lower bound filtering strategy. Moreover, an elite enhancement strategy inspired by the problem property is designed to improve the solution quality. Experimental results demonstrate the effectiveness of the worker transfer strategy and the superior performance of the RL-TEA compared with the state-of-the-art algorithms in solving the HSSSP-WT. [ABSTRACT FROM AUTHOR]

Published

2024

6. Genetic algorithms for planning and scheduling engineer-to-order production: a systematic review.

Author

Neumann, Anas, Hajji, Adnene, Rekik, Monia, and Pellerin, Robert

Subjects

GENETIC algorithms, MACHINE learning, PRODUCTION scheduling, ENGINEERING design, EVOLUTIONARY algorithms

Abstract

This paper provides a systematic review of the Genetic Algorithm (GA)s proposed to solve planning and scheduling problems in Engineer-To-Order (ETO) contexts. Our review focuses on how the key characteristics of ETO projects affect both the problem studied and the GA algorithmic features. Typical ETO projects consist of one-of-a-kind products with complex structures and uncertain designs. A deep analysis of the papers published between 2000 and 2022 enables identifying 10 main characteristics of ETO projects, six activity types, 10 decision types, eight groups of constraints, and 10 optimisation objectives. Our study shows that none of the reported papers integrates all 10 ETO characteristics. The less studied ETO characteristics are incorporating design and engineering information in the problem definition and the design uncertainty. Our review also identifies 10 recurrent encoding formats and emphasises the most frequently used genetic operators. We observed that most planning and scheduling problems consider objectives and decisions related to product customisation or supply chain configuration yielding multi-objective problems. Most multi-objective GAs use a weighted sum or are based on NSGAII. Diversity maintenance methods, adaptive and parameter tunning mechanisms, or hybridisation with machine learning models are still not used in this context. A systematic review of genetic algorithms dedicated to industrial planning and scheduling Analysis on how the characteristics of ETO projects impact the design of genetic representation and operators Recommendation on approaches employed to reach high-quality solutions [ABSTRACT FROM AUTHOR]

Published

2024

7. Realization of an ultra-thin absorber with fragmented magnetic structure at L-, S-, and partial C-bands.

Author

E, Liujia, Liu, Zhongqing, Zhang, Jingwei, Xu, Zhaoxuan, Yuan, Zhenliang, Mei, Zhonglei, and Niu, Tiaoming

Subjects

*MAGNETIC structure, *RADAR cross sections, *METAMATERIALS, *EVOLUTIONARY algorithms, *COPPER plating, *MAGNETIC materials, *POLARIZATION (Nuclear physics)

Abstract

In this paper, an ultra-thin absorber with a total thickness of 9.2 mm is designed and verified at the frequency band of 1–5.34 GHz. The absorber is composed of a layer of metasurface, multi-layered magnetic substrate, a layer of fragmented magnetic structure obtained by improved MOEA/D-GO (Multi-Objective Evolutionary Algorithm based on Decomposition combined with Enhanced Genetic Operators), and a copper back plate. The absorber is achieved by two steps. First, we designed and measured an ultra-thin absorber at 0.78–2.04 GHz by adding a layer metasurface onto the top of a basic multi-layer absorber composed of magnetic materials. The fractional bandwidth (FBW) of the absorber is 89.4%, and the electrical thickness is only 0.024 λ 0 at the lowest operating frequency. Second, to broaden the bandwidth, we use an improved MOEA/D-GO to optimize one magnetic layer of the absorber. The working frequency band of the optimized absorber is 1–5.34 GHz, covering L- (1–2 GHz), S- (2–4 GHz), and partial C-bands (4–8 GHz). Furthermore, we modified the structure of the metasurface to make the absorber polarization-independent. The FBW of the final absorber is 136.4%, and the electrical thickness is 0.031 λ 0 at the lowest operating frequency. The prototype of the absorber is measured, and the experimental results agree well with the simulated performance. The results show that the improved MOEA/D-GO can be used to design and optimize sophisticated electromagnetic (EM) structures with the predesigned properties, and the absorber with ultrathin thickness and light weight verified in this paper have great application potentials in EM compatibility, EM shielding, and radar cross section reduction at the low bands of the microwave spectrum. [ABSTRACT FROM AUTHOR]

Published

2023

8. NSGA-II-MOGWO: A Novel Hybrid Algorithm for IoT-Fog Environment Resources Allocation

Author

Hussein, Balasem A., Hashem, Soukaena H., Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Fortino, Giancarlo, editor, Kumar, Akshi, editor, Swaroop, Abhishek, editor, and Shukla, Pancham, editor

Published

2025

9. Hybrid Neuro-Fuzzy Modeling for Electricity Consumption Prediction in a Middle-Income Household in Gauteng, South Africa: Utilizing Fuzzy C-means Method

Author

Oladipo, Stephen, Sun, Yanxia, Adegoke, Samson Ademola, Ghosh, Ashish, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Zhang, Haijun, editor, Li, Xianxian, editor, Hao, Tianyong, editor, Meng, Weizhi, editor, Wu, Zhou, editor, and He, Qian, editor

Published

2025

10. A new knowledge-guided multi-objective optimisation for the multi-AGV dispatching problem in dynamic production environments.

Author

Liu, Lei, Qu, Ting, Thürer, Matthias, Ma, Lin, Zhang, Zhongfei, and Yuan, Mingze

Subjects

PARTICLE swarm optimization, DISTRIBUTION (Probability theory), EVOLUTIONARY algorithms, AUTOMATED guided vehicle systems, SATISFACTION, CONSTRAINT satisfaction

Abstract

The efficiency of material supply for workstations using Automatic Guided Vehicles (AGVs) is largely determined by the performance of the AGV dispatching scheme. This paper proposes a new solution approach for the AGV dispatching problem (AGVDP) for material replenishment in a general manufacturing workshop where workstations are in a matrix layout, and where uncertainty in replenishment time of workstations and stochastic unloading efficiencies of AGVs are dynamic contextual factors. We first extend the literature proposing a mixed integer optimisation model with a delivery satisfaction soft constraint of material orders and two objectives: transportation costs and delivery time deviation. We then develop a new knowledge-guided estimation of distribution algorithm with delivery satisfaction evaluation for solving the model. Our algorithm fuses three knowledge-guided strategies to enhance optimisation capabilities at its respective execution stages. Comprehensive numerical experiments with instances built from a real-world scenario validate the proposed model and algorithm. Results demonstrate that the new algorithm outperforms three popular multi-objective evolutionary algorithms, a discrete version of a recent multi-objective particle swarm optimisation, and a multi-objective estimation of distribution algorithm. Findings of this work provide major implications for workshop management and algorithm design. [ABSTRACT FROM AUTHOR]

Published

2023

11. Evolutionary variational inference for Bayesian generalized nonlinear models.

Author

Sommerfelt, Philip Sebastian Hauglie and Hubin, Aliaksandr

Subjects

*MARKOV chain Monte Carlo, *EVOLUTIONARY algorithms, *NP-hard problems, *BAYESIAN field theory, *SCALABILITY

Abstract

In the exploration of recently developed Bayesian Generalized Nonlinear Models (BGNLM), this paper proposes a pragmatic scalable approximation for computing posterior distributions. Traditional Markov chain Monte Carlo within the populations of the Genetically Modified Mode Jumping Markov Chain Monte Carlo (GMJMCMC) algorithm is an NP-hard search problem. To linearize them, we suggest using instead variational Bayes, employing either mean-field approximation or normalizing flows for simplicity and scalability. This results in an evolutionary variational Bayes algorithm as a more scalable alternative to GMJMCMC. Through practical applications including inference on Bayesian linear models, Bayesian fractional polynomials, and full BGNLM, we demonstrate the effectiveness of our method, delivering accurate predictions, transparency and interpretations, and accessible measures of uncertainty, while improving the scalability of BGNLM inference through on the one hand using a novel variational Bayes method, but, on the other hand, enabling the use of GPUs for computations. [ABSTRACT FROM AUTHOR]

Published

2024

12. A genetic algorithm with tabu search method for 3 dimensional detect profile reconstruction using MFL measurement.

Author

Gao, Yusong, Lu, Senxiang, and Yan, Yuchen

Subjects

*MAGNETIC flux leakage, *GENETIC algorithms, *EVOLUTIONARY algorithms, *NONDESTRUCTIVE testing, *SIGNALS & signaling

Abstract

In nondestructive testing, magnetic flux leakage (MFL) inspection is extensively employed for the inversion of pipeline defects. Exact reconstruction of the defect plane with measurements is a pressing issue in the field of MFL detection. This article proposes a method that incorporates a layer-by-layer genetic algorithm with tabu search (GA-TS). During the iterative process, our objective is to utilize a tabu search based on evolutionary algorithms to avoid local optimal solutions, obtain global optimal solutions, and reconstruct defects with enhanced accuracy. In addition to enhancing the accuracy of pipeline defect categorization, our approach has two significant limitations: its limited global search capability and slow convergence rate. Finally, the method is evaluated via experiments in which MFL signals obtained from an experimental platform and simulation signals are used. Practical results and a thorough comparative study of alternative approaches confirm the model's superiority. [ABSTRACT FROM AUTHOR]

Published

2024

13. An embedded differential evolution approach to adaptive covariance inflation with the ensemble Kalman filter.

Author

Bai, Yulong, Yu, Qinghe, and Ma, Yongjie

Subjects

*OPTIMIZATION algorithms, *EVOLUTIONARY algorithms, *ADAPTIVE filters, *DIFFERENTIAL evolution, *ANALYSIS of covariance, *KALMAN filtering

Abstract

The limited ensemble sizes and the neglected model errors in ensemble-based Data Assimilation (DA) usually lead to underestimation of the error variance, and covariance inflation 'inflates' the covariance of a forecast or analysis ensemble by some positive factor in each assimilation cycle. In practice, the value of the inflation factor is often set by trial and error. Thus, a variety of adaptive covariance inflation (ACI) algorithms have been proposed to improve assimilation performance by adjusting the optimal parameters. Most of these used traditional optimization algorithms, such as gradient methods and relaxation methods. However, Evolutionary Algorithms(EAs), which encompass a range of population-based stochastic search techniques widely used in various engineering optimization problems, are rarely seen in DA. In this study, we developed a new framework for adaptive inflation factors, introducing differential evolution (DE) algorithm into local ensemble Transform Kalman filter (LETKF) that can explore the most suitable/optimal inflation factors online. A 'micro-DE' based data assimilation method can obtain better assimilation results step by step without taking a much longer time. The feasibility and effectiveness of the algorithm is demonstrated in an idealized Lorenz-96 model with simulated observations. Under both perfect and imperfect-model scenarios, it is found that the 'micro-DE'LETKF method is capable of outperforming the original LETKF with a considerable lower computational cost. The adaptive inflation factor is optimally updated at each assimilation cycle either around the upper bound or around the lower bound, which means that only an adaptive factor helps mitigate the ensemble collapse due to a lack of spread. However, the further study will consider the application of the methodology to more complex atmospheric models. [ABSTRACT FROM AUTHOR]

Published

2024

14. A novel differential evolution algorithm based on periodic intervention and systematic regulation mechanisms.

Author

Yuan, Guanyu, Sun, Gaoji, Deng, Libao, Li, Chunlei, and Yang, Guoqing

Subjects

METAHEURISTIC algorithms, EVOLUTIONARY algorithms, ALGORITHMS, DILEMMA, PROBABILITY theory

Abstract

Differential evolution (DE) has attracted widespread attention due to its outstanding optimization performance and ease of operation, but it cannot avoid the dilemmas of premature convergence or stagnation when faced with complex optimization problems. To reduce the probability of such difficulties for DE, we sort out the factors that influence the balance between global exploration and local exploitation in the DE algorithm, and we design a novel DE variant (abbreviated as PISRDE) by integrating the corresponding influence factors through a periodic intervention mechanism and a systematic regulation mechanism. The periodic intervention mechanism divides the optimization operations of PISRDE into routine operation and intervention operation, and it balances global exploration and local exploitation at the macro level by executing the two operations alternately. The systematic regulation mechanism treats the involved optimization strategies and parameter settings as an organic system for targeted design, to balance global exploration and local exploitation at the meso or micro level. To evaluate and verify the optimization performance of PISRDE, we employ seven DE variants with excellent optimization performance to conduct comparison experiments on the IEEE CEC 2014 and IEEE CEC 2017 benchmarks. The comparison results indicate that PISRDE outperforms all competitors overall, and its relative advantage is even more significant when dealing with high-dimensional and complex optimization problems. Schematic design philosophy of PISRDE [ABSTRACT FROM AUTHOR]

Published

2024

15. A clustering-based archive handling method and multi-objective optimization of the optimal power flow problem.

Author

Akbel, Mustafa, Kahraman, Hamdi Tolga, Duman, Serhat, and Temel, Seyithan

Subjects

ELECTRICAL load, EVOLUTIONARY algorithms, BENCHMARK problems (Computer science), PARETO optimum, DATA analysis

Abstract

The main challenge in finding the optimal Pareto Front (PF) and Pareto Set (PS) sets for multimodal multi-objective optimization problems (MMOPs) with conflicting objective functions is to exhibit a balanced and sustainable diversity and exploitation capability in both the objective and decision spaces. This paper introduces dynamic reference spaces based clustering (DRSC) as a new archive handling method to overcome this challenge. DRSC incorporates a niche method called dynamically switched reference spaces and adapts the K-means-based method for clustering non-dominant vectors and handling the archive. The performance of the proposed DRSC is tested on twenty-four benchmark problems. According to the results of non-parametric statistical analysis using data from four different performance metrics, DRSC-MOAGDE designed using the proposed archiving mechanism managed to achieve the best Friedman rank among thirty different competitors. According to the stability analysis results, the average success rates and average computation times of the three best performing algorithms DRSC-MOAGDE, MMODE-ICD and SSMOPSO are (88.69%, 3.01 s), (66.87%, 9.47 s) and (64.29%, 1372.49 s), respectively. It is also observed that the proposed DRSC-MOAGDE outperforms the best cost optimization values in the literature with a minimum of 0.1838 $/h and a maximum of 30.9157 $/h for the multi-objective OPF real-world problem. [ABSTRACT FROM AUTHOR]

Published

2024

16. Multifidelity surrogates-assisted multi-objective particle swarm algorithm for offline data-driven optimization.

Author

Cui, Yingying, Meng, Xi, and Qiao, Junfei

Subjects

EVOLUTIONARY algorithms, INCINERATION, BENCHMARK problems (Computer science), SOLID waste, PARTICLE swarm optimization, ALGORITHMS

Abstract

Surrogate-assisted evolutionary algorithms have been widely employed to solve data-driven optimization problems. However, for offline data-driven optimization, it is very challenging to perform evolutionary search efficiently as well as accurately since no new data is available during the optimization process. To mitigate this issue, a multifidelity surrogates-assisted multi-objective particle swarm optimization (MFSa-PSO) algorithm is proposed in this paper. First, two low-fidelity models with convergence and diversity characteristics separately and a high-fidelity model are constructed to assemble multifidelity surrogate models. Second, by adopting the knowledge transfer strategy, the multifidelity surrogates-assisted two-archive multi-objective particle swarm optimization is conducted to search optimal solutions more exactly and effectively. Third, the output solution set is achieved by associating the solutions of two archives with reference vectors. Finally, the proposed MFSa-PSO is compared with some popular surrogate-assisted evolutionary algorithms on benchmark problems to verify its effectiveness and outperformance. Additionally, a real-world application of the municipal solid waste incineration process is carried out to verify the engineering applicability of MFSa-PSO. [ABSTRACT FROM AUTHOR]

Published

2024

17. Uncertainty analysis of digital twin model of mine ventilation system.

Author

Cao, Peng, Liu, Jian, Wang, Honglin, Wang, Yu, Liu, Xue, and Wang, Dong

Subjects

*LATIN hypercube sampling, *MINE ventilation, *DIGITAL twins, *DIFFERENTIAL evolution, *EVOLUTIONARY algorithms

Abstract

The digital twin model of mine ventilation system (DTMVS) plays an important role in intelligent safety management. However, the uncertainty of the ventilation resistance coefficient, which is the core parameter of the model, makes it challenging to accurately construct a DTMVS. In this study, Latin Hypercube Sampling (LHS) and ventilation resistance coefficient estimation models (VRCEMs) are used to analyze the uncertainty. First, the LHS method was used to explore the effect of uncertainty in the simulated airflow by continuously increasing the level of uncertainty in the ventilation resistance coefficients. Subsequently, the ventilation resistance coefficients were estimated using the VRCEMs, and the uncertainty of the ventilation resistance coefficient and the simulated airflow was analyzed. The results showed that the ventilation resistance coefficients with a 5% coefficient of variation can cause the DTMVS to lose 34% of the real airflow data points. The degree of uncertainty in the ventilation resistance coefficients estimated by the VRCEM-GA (VRCEM using genetic algorithm) and VRCEM-DE (VRCEM using differential evolution algorithm) methods was enhanced by 27.4% and 4.4%, respectively, compared with VRCEM-ES (VRCEM using evolutionary strategy algorithm). The VRCEM-ES model had the least influence on the uncertainty of the simulated airflow of DTMVS. The simulated airflow of the DTMVS constructed based on VRCEMs fluctuated normally within the confidence interval. VRCEMs had a higher sensitivity to the ventilation resistance coefficients of branches with low coefficients of variation. [ABSTRACT FROM AUTHOR]

Published

2024

18. Designing high-performance ion-exchangeable glasses with multi-objective optimization and machine learning.

Author

Banapour Ghaffari, Omid, Eftekhari Yekta, Bijan, and Zakeri-Nasrabadi, Morteza

Subjects

*MACHINE learning, *GLASS construction, *GLASS transition temperature, *EVOLUTIONARY algorithms, *LANDSCAPE design

Abstract

Ion exchange typically involves replacing smaller ions with larger ions below the glass transition temperature. This study introduces an innovative computational approach for the inverse design of ion-exchangeable glasses. It aims to simultaneously achieve high depth of layer (DOL) and surface compressive stress (CS), a task complicated by the inherent trade-offs between these properties. Traditional ion exchange experimental methods are not only time-consuming and expensive, but they also involve complex practical difficulties. Addressing these challenges, this paper introduces a novel computational approach that synergistically combines a multi-objective genetic algorithm with machine learning models. The approach involves training models on a diverse set of glass compositions to predict DOL and CS, which then guide an evolutionary algorithm to optimize these properties concurrently. Physics-informed parameters further refine the search, enabling a flexible design framework in glass manufacturing. Comprehensive experimentation and subsequent analysis affirm the proposed method's capacity to efficiently and effectively traverse the intricate design landscape of glass materials. The findings elucidated the influence of distinct compositional and process parameters on DOL and CS, facilitating the manual design process. Additionally, the study identified sixteen glass composition candidates within the SiO 2 –B 2 O 3 –Al 2 O 3 –MgO–Na 2 O system, exhibiting remarkable properties. Specifically, some compositions achieved a DOL of up to 95 μm with a corresponding CS of 890 MPa, while others attained a CS of up to 1654 MPa with a DOL of 14.72 μm. [ABSTRACT FROM AUTHOR]

Published

2024

19. A Radial Memetic Algorithm to Resolve the No-Wait Job-Shop Scheduling Problem.

Author

Pérez-Rodríguez, Ricardo

Subjects

*PRODUCTION scheduling, *EVOLUTIONARY algorithms, *ALGORITHMS, *FACTORIZATION, *SCHEDULING

Abstract

A new radial memetic algorithm is proposed to resolve the no-wait job-shop scheduling problem. Basically, each sequencing solution is factorized as a distance-based ranking model, i.e., each solution is decomposed in n − 1 terms, where n is the number of jobs to be sequenced. After that, a cumulative radial distribution of hydrogen is considered to produce new factorizations using the offspring information (genes). Such radial distribution is applied in the local optimization procedure of the memetic algorithm. A benchmarking dataset is used to show the performance of this new experimental technique, as well as other current procedures. Statistical tests were implemented to confirm the performance of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2024

20. Improving Automatic Coronary Stenosis Classification Using a Hybrid Metaheuristic with Diversity Control.

Author

Gil-Rios, Miguel-Angel, Cruz-Aceves, Ivan, Hernandez-Aguirre, Arturo, Hernandez-Gonzalez, Martha-Alicia, and Solorio-Meza, Sergio-Eduardo

Subjects

*CORONARY artery stenosis, *EVOLUTIONARY algorithms, *FEATURE selection, *SUPPORT vector machines, *CORONARY angiography

Abstract

This study proposes a novel Hybrid Metaheuristic with explicit diversity control, aimed at finding an optimal feature subset by thoroughly exploring the search space to prevent premature convergence. Background/Objectives: Unlike traditional evolutionary computing techniques, which only consider the best individuals in a population, the proposed strategy also considers the worst individuals under certain conditions. In consequence, feature selection frequencies tend to be more uniform, decreasing the probability of premature convergent results and local-optima solutions. Methods: An image database containing 608 images, evenly balanced between positive and negative coronary stenosis cases, was used for experiments. A total of 473 features, including intensity, texture, and morphological types, were extracted from the image bank. A Support Vector Machine was employed to classify positive and negative stenosis cases, with Accuracy and the Jaccard Coefficient used as performance metrics. Results: The proposed strategy achieved a classification rate of 0.92 for Accuracy and 0.85 for the Jaccard Coefficient, obtaining a subset of 16 features, which represents a discrimination rate of 0.97 from the 473 initial features. Conclusions: The Hybrid Metaheuristic with explicit diversity control improved the classification performance of coronary stenosis cases compared to previous literature. Based on the achieved results, the identified feature subset demonstrates potential for use in clinical practice, particularly in decision-support information systems. [ABSTRACT FROM AUTHOR]

Published

2024

21. Design and Optimization of a Permanent Magnet Synchronous Motor for a Two-Dimensional Piston Electro-Hydraulic Pump.

Author

Qiu, Xinguo, Wang, Zhili, Li, Changlong, Shen, Tong, Zheng, Ying, and Wang, Chen

Subjects

*PERMANENT magnet motors, *RECIPROCATING pumps, *EVOLUTIONARY algorithms, *HYDRAULIC motors, *GENETIC algorithms

Abstract

A two-dimensional (2D) piston electro-hydraulic pump has been proposed further to enhance the power density of the electro-hydraulic pump. The 2D piston pump, characterized by high power density and a slender shape, is embedded within the stator of the motor in a co-rotor configuration where the piston and the motor's rotor are in tandem. The intimate design of the hydraulic pump and the motor results in a coupling between the two, with intricate relationships and influences existing between the geometric parameters of the piston pump and the dimensions of the motor's rotor. Based on the operational requirements and structure of the 2D piston pump, a permanent magnet synchronous motor (PMSM) designed for use with a 2D piston electro-hydraulic pump is developed. This study examines the impact of the motor's stator iron core geometric parameters on both the electromagnetic and mechanical properties of a PMSM and completes the necessary performance validations. The optimization objectives of the motor are determined through an analysis of the influence of the key parameters of the rotor and stator on torque, torque ripple, and motor loss. A surrogate optimization model is constructed using a metamodel of optimal prognosis (MOP) to optimize the torque, torque ripple, and motor loss. Evolutionary genetic algorithms are utilized to achieve the multi-objective optimization design. A finite element simulation is used to compare the electromagnetic performance of the initial motor and optimal motor. Based on the optimal motor parameters, a 2.5 kW motor prototype is manufactured, and the experimental results validate the feasibility and effectiveness of the motor design and optimization. [ABSTRACT FROM AUTHOR]

Published

2024

22. Modeling and control of a novel mechatronic model of a 750 kW-FSWT with power-splitting transmission using RBF neural network: a bond graph approach.

Author

Karimi, Mohssine, Zekraoui, Mustapha, Khaouch, Zakaria, and Touairi, Souad

Subjects

*RADIAL basis functions, *PARTICLE swarm optimization, *INDUCTION generators, *EVOLUTIONARY algorithms, *WIND turbines

Abstract

This work addresses issues that appear from wind turbines equipped with frequency converters and presents a new fixed-speed wind turbine (FSWT) concept based on a split power transmission, along with a Mechatronic Control Model. The wind turbine rotor drives the first transmission shaft, while a servomotor with variable speed powers the second input. The differential gear transmission output is linked to the electric grid through an asynchronous generator. To optimize the power extracted from the wind energy while minimizing excessive dynamic loads on the wind turbine, a mechatronic control model of a 750 kW-FSWT is applied using a proportional and integral controller (PI). The paper suggests employing neural networks and evolutionary algorithms for determining appropriate PI gains. For collective servomotor control of a 750 kW-FSWT, a radial basis function (RBF) neural networks based on PI controller is proposed. To acquire an optimum dataset for RBF training, the particle swarm optimization (PSO) evolutionary algorithm is harnessed. The robustness and effectiveness of the proposed model and controller are verified and confirmed through simulation results. Hands-on experience is conducted using the 20-sim software package. [ABSTRACT FROM AUTHOR]

Published

2024

23. An adaptive many-objective evolutionary algorithm based on decomposition with two archives and an entropy trigger.

Author

Cao, Li, Wang, Maocai, Vasile, Massimiliano, Dai, Guangming, and Wu, Huanqin

Subjects

*EVOLUTIONARY algorithms, *ENTROPY, *DESELECTION of library materials, *ALGORITHMS, *ARCHIVES

Abstract

This article proposes two novel mechanisms to improve the performance of many-objective evolutionary algorithms based on Chebyshev scalarization. One mechanism improves the efficiency and effectiveness of the adaptation of the descent directions in criteria space, while the other ensures that extreme solutions are preserved. Weight adaptation via WS-transformation has shown promising results, but its performance is dependent on the choice of the start of the adaptation process. In order to overcome this limitation, in this article an efficient entropy-based trigger is proposed with fast calculation of the entropy that scales favourably with the number of dimensions. The novel entropy-based method is complemented by a dual-archiving mechanism that preserves extreme solutions. The dual-archiving strategy mitigates the possibility to discard those critical individuals whose loss affects the whole evolutionary process. The new algorithm proposed in this article (called aMOEA/D-2A-ET) is compared against a set of state-of-the-art MOEAs and shown to have competitive performance. [ABSTRACT FROM AUTHOR]

Published

2024

24. Many-objective evolutionary algorithm with multi-strategy selection mechanism and adaptive reproduction operation.

Author

Li, Wei, Tang, Jingqi, and Wang, Lei

Subjects

*OPTIMIZATION algorithms, *EVOLUTIONARY algorithms, *VEHICLE routing problem, *BENCHMARK problems (Computer science), *SOCIAL problems, *REPRODUCTION

Abstract

Many-objective optimization problem is one of the most important and widely faced optimization problems in the real world. To solve many-objective optimization problems (MaOPs), numerous multi-objective evolutionary algorithms (MOEAs) have been developed to find a good convergence and well-distributed Pareto front. However, with the increase of dimensions, the distribution of solutions obtained by MOEAs becomes more complex and tends to be orthogonal, which significantly reduces the effectiveness of the algorithms. In this paper, we propose an improved many-objective evolutionary algorithm (MaOEA-MSAR), which incorporates a multi-strategy selection mechanism into an existing MOEA, and develops an adaptive reproduction operation to produce promising offspring individuals. Firstly, the selection strategy based on the angle-penalized distance is used to improve the coverage of the solutions in the objective space. Then, the selection strategy based on convergence rate is employed to strengthen the balance between diversity and convergence. Finally, an adaptive reproduction operation is used to select different reproduction strategies for the gene-level global exploration or local exploitation. A series of experiments are carried out against seven state-of-the-art many-objective optimization algorithms. Experimental results on commonly used 31 benchmark test problems with up to 15 objectives and a multi-objective vehicle routing problem have demonstrated that MaOEA-MSAR is competitive in handling various kinds of MaOPs. [ABSTRACT FROM AUTHOR]

Published

2024

25. Cost-effective clonal selection and AIS-based load balancing in cloud computing environment.

Author

Mosayebi, Melika and Azmi, Reza

Subjects

*EVOLUTIONARY algorithms, *VIRTUAL machine systems, *DISTRIBUTED algorithms, *CLOUD computing, *DATA reduction

Abstract

Cloud computing faces challenges in increasing efficiency through task scheduling and load balancing. Various load-balancing methods, including the Throttled policy, help evenly distribute user requests among virtual machines. The article compares the cost of the clonal selection algorithm with the throttled load-balancing policy and the clonal selection algorithm with the distributed service broker policy. It also introduces two new algorithms based on the artificial immune system, aiming to efficiently respond to user requests at the lowest cost. Additionally, the article presents two new algorithms resulting from combining an evolutionary algorithm with artificial immune system mechanisms. These algorithms have been evaluated and compared using the Cloud Analyst simulator, demonstrating their superior performance in terms of response time, data center processing time, data transfer cost, and overall cost. The results indicate that ACODTH algorithm has an average response time of 0.35 milliseconds shorter than ACO. Additionally, the ACONSA algorithm shows a 0.44-millisecond reduction in average data center processing time compared to ACONSA. When considering the overall cost, the AIS_DSBP algorithm is projected to be 3.13$ cheaper than AIS_TLP. Similarly, the CSA_DSBP algorithm is expected to have a total data transfer cost of 3.14$ lower than CSA. [ABSTRACT FROM AUTHOR]

Published

2024

26. ALMO: Active Learning-Based Multi-Objective Optimization for Accelerating Constrained Evolutionary Algorithms.

Author

Singh, Karanpreet and Kapania, Rakesh K.

Subjects

OPTIMAL designs (Statistics), BENCHMARK problems (Computer science), CONSTRAINED optimization, PREDICTION models, ALGORITHMS

Abstract

In multi-objective optimization, standard evolutionary algorithms, such as NSGA-II, are computationally expensive, particularly when handling complex constraints. Constraint evaluations, often the bottleneck, require substantial resources. Pre-trained surrogate models have been used to improve computational efficiency, but they often rely heavily on the model's accuracy and require large datasets. In this study, we use active learning to accelerate multi-objective optimization. Active learning is a machine learning approach that selects the most informative data points to reduce the computational cost of labeling data. It is employed in this study to reduce the number of constraint evaluations during optimization by dynamically querying new data points only when the model is uncertain. Incorporating machine learning into this framework allows the optimization process to focus on critical areas of the search space adaptively, leveraging predictive models to guide the algorithm. This reduces computational overhead and marks a significant advancement in using machine learning to enhance the efficiency and scalability of multi-objective optimization tasks. This method is applied to six challenging benchmark problems and demonstrates more than a 50% reduction in constraint evaluations, with varying savings across different problems. This adaptive approach significantly enhances the computational efficiency of multi-objective optimization without requiring pre-trained models. [ABSTRACT FROM AUTHOR]

Published

2024

27. Exploring Evolutionary Algorithms for Multi-Objective Optimization in Seismic Structural Design.

Author

Göktepe Körpeoğlu, Seda and Yılmaz, Süleyman Mesut

Subjects

METAHEURISTIC algorithms, EVOLUTIONARY algorithms, EVOLUTIONARY computation, GENETIC algorithms, BIBLIOMETRICS, EARTHQUAKE resistant design

Abstract

The seismic design of structures is an emerging practice in earthquake-resistant construction. Therefore, using energy-dissipation devices and optimizing these devices for various purposes are important. Evolutionary computation, nature-inspired, and meta-heuristic algorithms have been studied more in recent years for the optimization of these devices. In this study, the development of evolutionary algorithms for seismic design in the context of multi-objective optimization is examined through bibliometric analysis. In particular, evolutionary algorithms such as genetic algorithms and particle swarm optimization are used to optimize the performance of structures to meet seismic loads. While genetic algorithms are used to improve both the cost and seismic performance of the structure, particle swarm optimization is used to optimize the vibration and displacement performance of structures. In this study, a bibliometric analysis of 661 publications is performed on the Web of Science and Scopus databases and on how the research in this field has developed since 1986. The R-studio program with the biblioshiny package is used for the analyses. The increase in studies on the optimization of energy dissipation devices in recent years reveals the effectiveness of evolutionary algorithms in this field. [ABSTRACT FROM AUTHOR]

Published

2024

28. Cognitively Inspired Three-Way Decision Making and Bi-Level Evolutionary Optimization for Mobile Cybersecurity Threats Detection: A Case Study on Android Malware.

Author

Jerbi, Manel, Chelly Dagdia, Zaineb, Bechikh, Slim, and Said, Lamjed Ben

Abstract

Malicious apps use a variety of methods to spread infections, take over computers and/or IoT devices, and steal sensitive data. Several detection techniques have been proposed to counter these attacks. Despite the promising results of recent malware detection strategies, particularly those addressing evolving threats, inefficiencies persist due to potential inconsistency in both the generated malicious malware and the pre-specified detection rules, as well as their crisp decision-making process. In this paper, we propose to address these issues by (i) considering the detection rules generation process as a Bi-Level Optimization Problem, where a competition between two levels (an upper level and a lower one) produces a set of effective detection rules capable of detecting new variants of existing and even unseen malware patterns. This bi-level strategy is subtly inspired by natural evolutionary processes, where organisms adapt and evolve through continuous interaction and competition within their environments. Furthermore, (ii) we leverage the fundamentals of Rough Set Theory, which reflects cognitive decision-making processes, to assess the true nature of artificially generated malicious patterns. This involves retaining only the consistent malicious patterns and detection rules and categorizing these rules into a three-way decision framework comprising accept, abstain, and reject options. Our novel malware detection technique outperforms several state-of-the-art methods on various Android malware datasets, accurately predicting new apps with a 96.76% accuracy rate. Moreover, our approach is versatile and effective in detecting patterns applicable to a variety of cybersecurity threats. [ABSTRACT FROM AUTHOR]

Published

2024

29. Abrasive waterjet drilling process enhancement using machine learning and evolutionary algorithms.

Author

Nagarajan, Lenin, Mahalingam, Siva Kumar, and Vasudevan, Balaji

Subjects

MACHINE learning, RANDOM forest algorithms, EVOLUTIONARY algorithms, CAPABILITIES approach (Social sciences), INCONEL

Abstract

To improve the abrasive waterjet drilling procedure for yttrium-stabilized zirconia-coated Inconel 718 superalloy, this study suggests an integrated approach using machine learning and an evolutionary algorithm. The objective is to simultaneously minimize the erosion diameter and taper angle of the drilled holes by identifying the best combination of drilling parameters such as stand-off distance, abrasive flow rate, waterjet pressure, and angle of impact. The machine learning models are developed using the random forest algorithm after tuning its hyperparameters to predict the erosion diameter and taper angle. The multi-verse optimization (MVO) algorithm is used to identify the best combination of drilling parameters. The comparison of results proved the efficacy of MVO over other algorithms. Confirmation experiment results are also in line with the results of MVO, since the percentage of deviation is meager. This integrative approach has the capability of significantly improving aerospace and industrial abrasive waterjet drilling operations. [ABSTRACT FROM AUTHOR]

Published

2024

30. Enhancing UAV-based edge computing: a study on nonhovering operations and two-stage optimization strategies.

Author

Qin, Lishu, Zheng, Ye, and Gao, Yu

Subjects

MOBILE computing, EDGE computing, DRONE aircraft, EVOLUTIONARY algorithms, COMPUTER systems, DATA transmission systems, WIRELESS communications

Abstract

In the domain of 5G/6G wireless communications, mobile edge computing (MEC) technology is widely utilized for efficient data transmission. Unmanned aerial vehicles (UAVs) have emerged as the most recent transmission carriers in this landscape. However, the challenges associated with UAV deployment and path planning are often regarded as NP-hard, nonconvex, and nonlinear problems. Traditional optimization techniques struggle to address these complexities effectively. To address this issue, this study proposes "Edge-UAV", a novel mobile edge computing system specifically designed for UAVs. The primary objective of Edge-UAV is to minimize energy consumption and optimize the operational efficiency of UAVs. To achieve this goal, this study introduces a two-stage optimization strategy and a nonhovering transmission strategy. First, the coordinate updating operation of the UAVs' hovering points is decoupled from the path planning task. Additionally, the perturbation-inheritance algorithm is employed to enhance the coordinate updating process. In the second stage, the nonhovering transmission strategy enables UAVs to perform data transmission tasks while in flight, effectively optimizing their working time. This paper provides a detailed elucidation of the roles played by these innovative strategies within the Edge-UAV system. To assess the superiority of the proposed strategies, eight sets of comparative experiments involving 60–200 individual devices awaiting data transmission are conducted. The experimental results demonstrate the significant advantages of the Edge-UAV system in terms of reducing total energy consumption and optimizing the operational hours of UAVs. Through comprehensive experimentation and analysis, this study contributes to the advancement of UAV-assisted mobile edge computing in 5G/6G wireless communication networks. The proposed strategies exhibit promising potential for enhancing the efficiency and performance of UAVs. [ABSTRACT FROM AUTHOR]

Published

2024

31. An effective evolutionary algorithm for solving uncertain fixed charge transportation problem with damageable items.

Author

Das, Rajeev, Das, Kedar Nath, and Mallik, Saurabh

Abstract

This paper aims to showcase the potential application of the metaheuristic approach Quadratic Approximation based Jaya (JaQA) in addressing a single-objective uncertain Fixed Charge Transportation Problem with Damageable items (FCTPD). The incorporation of uncertainties and damage rates for items adds realism to the selected problem model. Subsequently, a comprehensive examination of the FCTPD model is conducted, considering both expected value and chance-constrained cases based on uncertainty theory. Equivalent deterministic formulations are considered for these scenarios. The performance of JaQA is comprehensively benchmarked on a set of ten popular benchmarks of single-objective fixed charge transportation problems (FCTP) from the OR library. In addition to this, it is also evaluated on the deterministic forms of the expected value and chance-constrained cases, and the computational results are compared with other widely recognized approaches such as Jaya algorithm, Genetic Algorithm (GA) and Particle Swarm Optimization (PSO) for five numerical instances A thorough investigation of statistical, convergence, and sensitivity analysis are presented to shed light on the efficacy and stability levels of JaQA over its counterparts. The simulation outcomes and exhaustive statistical analysis show that for all the problems considered, JaQA performed better out of GA, PSO, and Jaya. More specifically, it indicated that the utilization of JaQA provided significant profit maximization of the transportation system, thereby ensuring a promising value of the optimal solution. [ABSTRACT FROM AUTHOR]

Published

2024

32. Autoencoder evolutionary algorithm for large-scale multi-objective optimization problem.

Author

Hu, Ziyu, Xiao, Zhixing, Sun, Hao, and Yang, He

Abstract

Multi-objective optimization problems characterized by a substantial number of decision variables, which are also called large-scale multi-objective optimization problems (LSMOPs), are becoming increasingly prevalent. Traditional evolutionary algorithms may deteriorate drastically when tackling a large number of decision variables. For LSMOPs, the dimensionality of the decision variables needs to be reduced and the algorithm needs to be designed according to the characteristics of divide-and-conquer. The autoencoder evolutionary algorithm (AEEA) is proposed based on autoencoder dimensionality reduction, the grouping of decision variables, and the application of divide-and-conquer strategies. The proposed algorithm is compared with other classical algorithms. The experiment result shows that AEEA achieves excellent convergence and diversity, and still performs well in decision variables of higher dimensions. Finally, it is verified that the autoencoder improves the running time of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2024

33. Improving part-load performance of combined-cycle gas turbines by optimizing variable geometry control strategy for compressor and power turbine combined adjustment.

Author

Xie, Qi-an, Wu, Hu, and Deng, Li-ping

Subjects

GAS turbines, GENETIC algorithms, EVOLUTIONARY algorithms, DIFFERENTIAL evolution, GEOMETRIC modeling

Abstract

The variable geometry methods currently used in combined-cycle gas turbines are compressor variable inlet guide vanes (VIGV) or power turbine variable area nozzles (VAN). On this basis, this study presents the optimal variable geometry control strategy for compressor and power turbine combined adjustment ( (VIGV + VAN) opt ) using the Differential Evolutionary Algorithm with the LM2500+ gas turbine. The aim is to further improve the part-load performance of the combined-cycle gas turbine. Firstly, a part-load performance prediction model for variable geometry gas turbines is established based on the component method. Subsequently, a variable geometry gas turbine part-load performance optimization model is developed by combining the Differential Evolution Algorithm. Finally, the optimum combination of stagger angles for the compressor inlet vane and power turbine nozzle is calculated at each part-load condition. Compared to the VIGV and VAN control strategies, the (VIGV + VAN) opt control strategy proposed in this paper shows a higher stability margin and better economy. The (VIGV + VAN) opt control strategy maintains a constant exhaust temperature within a part load range from 20% to 100% with the stability margin exceeding 14%. In comparison with the VAN control strategy, the fuel flow rate decreases by 1.152% at 45% relative load power and by 3.435% at 20.0% relative load power with the (VIGV + VAN) opt control strategy. [ABSTRACT FROM AUTHOR]

Published

2024

34. Analysis of Optimal Solutions of a Benchmark Water Distribution Network for Exploring the Global Optimality of the Current-best Solution.

Author

Gangwani, Laxmi, Palod, Nikita, Dongre, Shilpa, and Gupta, Rajesh

Subjects

WATER distribution, EVOLUTIONARY algorithms, OPTIMIZATION algorithms, HYDRAULICS, EVOLUTIONARY computation

Abstract

The optimal design of water distribution networks (WDNs) has always attracted the attention of researchers due to the complexities involved. The general cost optimization problem is categorized as the NLP-Hard problem. Several evolutionary algorithms (EAs) that can explore the entire search from multiple starting points have been developed in the last three decades. The EAs have more chances of reaching the global optimal solution. However, whether these algorithms converge to a global optimal solution or not is always doubtful, as these algorithms do not guarantee the same solution in the two different runs. A two-source benchmark network is considered for which several better solutions have been reported by different researchers in the last 15 years. The available solutions of this network are analysed based on certain parameters, usually observed in the global optimal solution. The main objective of the study is to explore the possibility of achieving a better than the current best-solution, as the global optimality of the current best is not confirmed. Further, the proposed methodology is applied to test the current best solutions of two additional networks. [ABSTRACT FROM AUTHOR]

Published

2024

35. A metaheuristic based filter-wrapper approach to feature selection for fake news detection.

Author

Zaheer, Hamza, Rehman, Saif Ur, Bashir, Maryam, Ahmad, Mian Aziz, and Ahmad, Faheem

Subjects

FEATURE selection, EVOLUTIONARY algorithms, FAKE news, SENTIMENT analysis, CURIOSITY

Abstract

Due to ease of dissemination, humankind is facing an "infodemic" that has spread through electronic and social media. Therefore, there is a need to combat fake news using text classification techniques. However, textual data contains a lot of redundant useless features which can cause issues during the learning and classification phase. Therefore, an effective feature selection method is required to select the important features only. Filter-based methods exist in the literature for feature selection but their performance is average at best. Similarly, many wrapper-based methods also exist but very few are specialized for textual features. In this study, a meta-heuristic based filter-wrapper approach to feature selection is proposed for fake news classification. The proposed algorithm combines three filter-based measures with Binary Dragonfly Algorithm. Moreover, a mechanism for dynamically adjusting the exploratory and exploitative behavior of the said algorithm is also proposed. The hybrid model is evaluated on three datasets of fake news. Additionally, it is also evaluated on the task of sentiment analysis of news. Both binary and multi-class classification tasks were used in our experiments. The proposed algorithm has been compared with several state-of-the-art wrapper-based and filter-based feature selection methods. For fake news detection, Macro F-1 Scores of 0.897, 0.782 and 0.667 were achieved on the three datasets. Moreover, for multi-class sentiment analysis task, Macro F-1 Scores of 0.553 and 0.597 were achieved. [ABSTRACT FROM AUTHOR]

Published

2024

36. Molecule discovery and optimization via evolutionary swarm intelligence.

Author

Liu, Hsin-Ping, Phoa, Frederick Kin Hing, and Dutta, Saykat

Subjects

*COMPUTER-assisted drug design, *DRUG discovery, *SWARM intelligence, *DRUG design, *EVOLUTIONARY algorithms

Abstract

Since the advent of computational analysis and visualization of chemical compounds, Computer-Aided Drug Design has made significant contributions to drug discovery. Recently, de novo drug design and molecular optimization have garnered considerable attention. Traditional optimization methods often struggle with the discrete nature of molecular space, but evolutionary computations have demonstrated their versatility across various optimization problems, regardless of the nature of the objective functions. This paper introduces a novel evolutionary algorithm, the Swarm Intelligence-Based Method for Single-Objective Molecular Optimization. Several experiments were conducted to showcase the efficiency of the proposed method, which identifies near-optimal solutions in a remarkably short time. The results were then compared with those of other state-of-the-art methods in the field. [ABSTRACT FROM AUTHOR]

Published

2024

37. Trainability maximization using estimation of distribution algorithms assisted by surrogate modelling for quantum architecture search.

Author

Soloviev, Vicente P., Dunjko, Vedran, Bielza, Concha, Larrañaga, Pedro, and Wang, Hao

Subjects

EVOLUTIONARY algorithms, DISTRIBUTION (Probability theory), COST functions, COST estimates, DESELECTION of library materials

Abstract

Quantum architecture search (QAS) involves optimizing both the quantum parametric circuit configuration but also its parameters for a variational quantum algorithm. Thus, the problem is known to be multi-level as the performance of a given architecture is unknown until its parameters are tuned using classical routines. Moreover, the task becomes even more complicated since well-known trainability issues, e.g., barren plateaus (BPs), can occur. In this paper, we aim to achieve two improvements in QAS: (1) to reduce the number of measurements by an online surrogate model of the evaluation process that aggressively discards architectures of poor performance; (2) to avoid training the circuits when BPs are present. To detect the presence of the BPs, we employed a recently developed metric, information content, which only requires measuring the energy values of a small set of parameters to estimate the magnitude of cost function's gradient. The main idea of this proposal is to leverage a recently developed metric which can be used to detect the onset of vanishing gradients to ensure the overall search avoids such unfavorable regions. We experimentally validate our proposal for the variational quantum eigensolver and showcase that our algorithm is able to find solutions that have been previously proposed in the literature for the Hamiltonians; but also to outperform the state of the art when initializing the method from the set of architectures proposed in the literature. The results suggest that the proposed methodology could be used in environments where it is desired to improve the trainability of known architectures while maintaining good performance. [ABSTRACT FROM AUTHOR]

Published

2024

38. Integrating Evolutionary Game-Theoretical Methods and Deep Reinforcement Learning for Adaptive Strategy Optimization in User-Side Electricity Markets: A Comprehensive Review.

Author

Cheng, Lefeng, Wei, Xin, Li, Manling, Tan, Can, Yin, Meng, Shen, Teng, and Zou, Tao

Subjects

*DEEP reinforcement learning, *REINFORCEMENT learning, *ELECTRICITY markets, *GAME theory, *MULTIAGENT systems, *EVOLUTIONARY algorithms

Abstract

With the rapid development of smart grids, the strategic behavior evolution in user-side electricity market transactions has become increasingly complex. To explore the dynamic evolution mechanisms in this area, this paper systematically reviews the application of evolutionary game theory in user-side electricity markets, focusing on its unique advantages in modeling multi-agent interactions and dynamic strategy optimization. While evolutionary game theory excels in explaining the formation of long-term stable strategies, it faces limitations when dealing with real-time dynamic changes and high-dimensional state spaces. Thus, this paper further investigates the integration of deep reinforcement learning, particularly the deep Q-learning network (DQN), with evolutionary game theory, aiming to enhance its adaptability in electricity market applications. The introduction of the DQN enables market participants to perform adaptive strategy optimization in rapidly changing environments, thereby more effectively responding to supply–demand fluctuations in electricity markets. Through simulations based on a multi-agent model, this study reveals the dynamic characteristics of strategy evolution under different market conditions, highlighting the changing interaction patterns among participants in complex market environments. In summary, this comprehensive review not only demonstrates the broad applicability of evolutionary game theory in user-side electricity markets but also extends its potential in real-time decision making through the integration of modern algorithms, providing new theoretical foundations and practical insights for future market optimization and policy formulation. [ABSTRACT FROM AUTHOR]

Published

2024

39. Identifying effective evolutionary strategies-based protocol for uncovering reaction kinetic parameters under the effect of measurement noises.

Author

Yeo, Hock Chuan, Vijay, Varsheni, and Selvarajoo, Kumar

Abstract

Background: The transition from explanative modeling of fitted data to the predictive modeling of unseen data for systems biology endeavors necessitates the effective recovery of reaction parameters. Yet, the relative efficacy of optimization algorithms in doing so remains under-studied, as to the specific reaction kinetics and the effect of measurement noises. To this end, we simulate the reactions of an artificial pathway using 4 kinetic formulations: generalized mass action (GMA), Michaelis–Menten, linear-logarithmic, and convenience kinetics. We then compare the effectiveness of 5 evolutionary algorithms (CMAES, DE, SRES, ISRES, G3PCX) for objective function optimization in kinetic parameter hyperspace to determine the corresponding estimated parameters. Results: We quickly dropped the DE algorithm due to its poor performance. Baring measurement noise, we find the CMAES algorithm to only require a fraction of the computational cost incurred by other EAs for both GMA and linear-logarithmic kinetics yet performing as well by other criteria. However, with increasing noise, SRES and ISRES perform more reliably for GMA kinetics, but at considerably higher computational cost. Conversely, G3PCX is among the most efficacious for estimating Michaelis–Menten parameters regardless of noise, while achieving numerous folds saving in computational cost. Cost aside, we find SRES to be versatilely applicable across GMA, Michaelis–Menten, and linear-logarithmic kinetics, with good resilience to noise. Nonetheless, we could not identify the parameters of convenience kinetics using any algorithm. Conclusions: Altogether, we identify a protocol for predicting reaction parameters under marked measurement noise, as a step towards predictive modeling for systems biology endeavors. [ABSTRACT FROM AUTHOR]

Published

2024

40. Combining Genetic Algorithm with Local Search Method in Solving Optimization Problems.

Author

Kralev, Velin and Kraleva, Radoslava

Subjects

EVOLUTIONARY algorithms, GRAPH theory, SEARCH algorithms, UNDIRECTED graphs, COMPLETE graphs

Abstract

This research is focused on evolutionary algorithms, with genetic and memetic algorithms discussed in more detail. A graph theory problem related to finding a minimal Hamiltonian cycle in a complete undirected graph (Travelling Salesman Problem—TSP) is considered. The implementations of two approximate algorithms for solving this problem, genetic and memetic, are presented. The main objective of this study is to determine the influence of the local search method versus the influence of the genetic crossover operator on the quality of the solutions generated by the memetic algorithm for the same input data. The results show that when the number of possible Hamiltonian cycles in a graph is increased, the memetic algorithm finds better solutions. The execution time of both algorithms is comparable. Also, the number of solutions that mutated during the execution of the genetic algorithm exceeds 50% of the total number of all solutions generated by the crossover operator. In the memetic algorithm, the number of solutions that mutate does not exceed 10% of the total number of all solutions generated by the crossover operator, summed with those of the local search method. [ABSTRACT FROM AUTHOR]

Published

2024

41. Optimizing the Scheduling of Teaching Activities in a Faculty.

Author

Diallo, Francis Patrick and Tudose, Cătălin

Subjects

EVOLUTIONARY algorithms, SCHEDULING, AUTOMATED planning & scheduling, SYSTEMS design, SATISFACTION

Abstract

To maximize resource usage, minimize disputes, and improve academic experience, professors must schedule teaching activities efficiently. This study provides an optimized automated schedule creation technique. The system generates schedules that aim to be conflict-free and efficient, utilizing evolutionary algorithms along with multi-objective optimization. Resource usage, scheduling problems, and faculty/student satisfaction are the goals of the research. The system optimizes scheduling based on room limitations, instructor availability, and student preferences. The project uses system design, model creation, algorithm implementation, and performance analysis to solve the difficult timetable-generating problem. This research should save administrators time, improve academic operations, and improve staff and student academic experiences. Scalability and flexibility allow the system to be used in multiple faculties and incorporate new limits and requirements. This paper presents a complete approach to faculty scheduling, including insights and recommendations for future study and application in educational institutions. [ABSTRACT FROM AUTHOR]

Published

2024

42. Parallel adaptive large neighborhood search based on spark to solve VRPTW.

Author

Liu, Songzuo, Sun, Jian, Duan, Xiaohong, and Liu, Guofang

Subjects

*EVOLUTIONARY algorithms, *SEARCH algorithms, *ARITHMETIC, *NEIGHBORHOODS, *SCHEDULING, *PARALLEL algorithms, *SIMULATED annealing

Abstract

Aiming at the multi-objective vehicle path planning problem with time windows (VRPTW), a Spark-based parallel Adaptive Large Neighborhood Search algorithm (Spark-ALNS) is proposed to solve it. The main design of the 4-point strategy: (1) Design a new simulated annealing algorithm cooling strategy to achieve a better jump out of the local optimal solution. (2) Adopt CW initialization to accelerate the convergence speed. (3) Use three destruction operators and three repair operators to implement local path optimization. (4) A new parallel strategy is proposed to improve the algorithm's accuracy and reduce the running time. To illustrate the algorithm's effectiveness, the arithmetic example in Solomon is used as an example. The experimental results show that the proposed Spark-ALNS can find better solutions, get the known optimal solutions for 41 out of 56 instances, and find new optimal solutions for 31 algorithms, which outperforms other evolutionary algorithms. The runtime is 3–5 times better than other parallel algorithms and is able to solve VRPTW effectively. [ABSTRACT FROM AUTHOR]

Published

2024

43. Multi‐population artificial bee colony algorithm for many‐objective cascade reservoir scheduling.

Author

Wang, Shuai, Wang, Hui, Liao, Futao, Wei, Zichen, and Hu, Min

Subjects

EVOLUTIONARY algorithms, BEES algorithm, BEES, SCHEDULING, PROBABILITY theory

Abstract

Summary: Artificial bee colony (ABC) is a popular intelligent algorithm that is widely applied to many optimization problems. However, it is challenging for ABC to solve many‐objective optimization problems (MaOPs). To tackle this issue, this article proposes a many‐objective ABC based on multi‐population (called MMaOABC) for MaOPs. In MMaOABC, the population is divided into multiple sub‐populations, and each sub‐population optimizes one objective. Three search strategies are constructed based on multiple sub‐populations to improve convergence and diversity. In the employed bee stage, some excellent solutions in multiple sub‐populations are used to guide the convergence. In the onlooker bee stage, new selection probabilities based on diversity metrics are designed to enhance the diversity. Dimensional learning is introduced in the scout bee stage to avoid falling into local minimum. In addition, environmental selection and external archives are utilized for communications among sub‐populations. To validate the performance of MMaOABC, two benchmark sets (DTLZ and MaF) with 3, 5, 8, and 15 objectives are tested. Computational results show that MMaOABC is competitive when compared with seven other many‐objective evolutionary algorithms (MaOEAs). Finally, MMaOABC is applied to many‐objective cascade reservoir scheduling. Simulation results show that MMaOABC still obtains promising performance. [ABSTRACT FROM AUTHOR]

Published

2024

44. Enhancing energy-efficient building design: a multi-agent-assisted MOEA/D approach for multi-objective optimization.

Author

Guo, Wei and Dong, Yaqiong

Subjects

EVOLUTIONARY algorithms, ENERGY conservation, GLOBAL optimization

Abstract

Energy-efficient building design is often challenged by multiple optimization problems due to contradictory objectives that are often hard to balance, so an effective optimization method should be thoroughly considered. Accordingly, a multi-objective evolutionary algorithm is then proposed. Firstly, the multi-agent auxiliary objective evolutionary algorithm for building energy efficiency model is established. According to model result analysis, the proposed algorithm runs fastest for 1640s with the average running time of 1710s in a single-room building, comparing to the least running time of 1680s for the multi-objective particle swarm optimization algorithm. In multi-room buildings, the proposed algorithm runs from 3350s to 3650s, with the average running time of 3500s. In conclusion, the model proposed in this study can comprehensively consider multiple objectives such as energy consumption, cost, comfort, etc. No matter in single-room or multi-room buildings, the model demonstrates superior performance and stability to realize comprehensive optimization of energy conservation design. [ABSTRACT FROM AUTHOR]

Published

2024

45. GFGDA: general framework for generating dungeons with atmosphere.

Author

Hojatoleslami, Mohammad Reza, Zamanifar, Kamran, and Zojaji, Zahra

Subjects

EVOLUTIONARY algorithms, GENETIC algorithms, PRISONS, EMOTIONS, VOLUNTEER service

Abstract

The atmosphere is one of the game elements that can significantly influence player's emotions. However, creating an immersive atmosphere that effectively influences player emotions poses several challenges, necessitating the utilization of various elements, such as audio-visual coordination and gameplay design. This paper introduces a general framework for procedurally generating dungeons with joyful and horror atmospheres in games, providing an abstract perspective to address these challenges. The proposed framework introduces a categorization system for game elements based on their role within the game. Leveraging this categorization, the Comprehensive Arrangement of Game Elements (CAGE) pattern is introduced, which facilitates the appropriate placement of elements within the dungeon environment. Subsequently, the General Framework for Generating Dungeons with Atmosphere (GFGDA) is employed to procedurally create the dungeon using the Feasible–Infeasible Two-Population (FI-2Pop) algorithm. To enhance gameplay experience, similar elements in the dungeon environment that impact gameplay are grouped and their coordination is evaluated by creating a graph based on the CAGE pattern. The transition and coordination of audio-visual elements along the path between these impactful elements are assessed in order to generate an immersive atmosphere within the dungeon. To ensure diversity, examining the variety of dungeons generated over 100 runs demonstrates that our method consistently produces distinct results in each iteration. Moreover, two comparative studies were conducted, one with 51 volunteers and another with 10 volunteers. In the first study, the Game Experience Questionnaire (GEQ) was utilized to assess the emotional impact of dungeons generated by our method. These were compared to dungeons created using a uniform random approach, alongside relevant research. The results suggest that our method significantly influences player emotions across the four components of the GEQ—sensory and imaginary immersion, flow, negative effects, and challenge—when compared to dungeons generated by the uniform random approach and another researched method. In another study, the emotional impact of two dungeons, one generated with joyful elements and the other with eerie elements, was evaluated using the GEQ. The findings indicate significant differences between the two components of the GEQ—tension and positive effects—when players interacted with the level containing joyful elements compared to the one with eerie elements. [ABSTRACT FROM AUTHOR]

Published

2024

46. Optimizing energy efficiency and routing in wireless sensor networks through genetic algorithm-based cluster head selection in a grid-based topology.

Author

Regilan, S. and Hema, L.K.

Subjects

*WIRELESS sensor networks, *ENERGY levels (Quantum mechanics), *EVOLUTIONARY algorithms, *NETWORK performance, *ENERGY consumption

Abstract

Wireless sensor networks (WSNs) struggle with energy efficiency because of limited node power. This paper presents an approach that uses evolutionary algorithms to choose the Cluster Head (CH) and optimize routing in wireless sensor networks (WSNs) using grid-based topologies. The proposed method repeatedly develops solutions based on criteria for node density, distance, and energy level by using the evolutionary capabilities of the genetic algorithm. A fitness function that considers latency, coverage, and energy efficiency is used to evaluate the solutions. The process selects CHs dynamically and uses GA-guided optimization to construct paths. Simulation results indicate improved network performance and energy efficiency over existing protocols. Evolutionary algorithm integration enables flexibility and optimization for energy-efficient CH selection and routing in WSNs with a grid-based design. [ABSTRACT FROM AUTHOR]

Published

2024

47. A Multimodal Multi-Objective Feature Selection Method for Intelligent Rating Models of Unmanned Highway Toll Stations.

Author

Gao, Zhaohui, Mo, Huan, Yan, Zicheng, and Fan, Qinqin

Subjects

*FEATURE selection, *CONTAINERIZATION, *EVOLUTIONARY computation, *INFORMATION superhighway, *EVOLUTIONARY algorithms

Abstract

To facilitate the intelligent classification of unmanned highway toll stations, selecting effective and useful features is pivotal. This process involves achieving a tradeoff between the number of features and the classification accuracy while also reducing the acquisition costs of features. To address these challenges, a multimodal multi-objective feature selection (MMOFS) method is proposed in the current study. In the MMOFS, we utilize a multimodal multi-objective evolutionary algorithm to choose features for the unmanned highway toll station classification model and use the random forest method for classification. The primary contribution of the current study is to propose a feature selection method specifically designed for the classification model of unmanned highway toll stations. Experimental results using actual data from highway toll stations demonstrate that the proposed MMOFS outperforms the other two competitors in terms of PSP, HV, and IGD. Furthermore, the proposed algorithm can provide decision-makers with multiple equivalent feature selection schemes. This approach achieves a harmonious balance between the model complexity and the classification accuracy based on actual scenarios, thereby providing guidance for the construction of unmanned highway toll stations. [ABSTRACT FROM AUTHOR]

Published

2024

48. Adaptive Bi-Operator Evolution for Multitasking Optimization Problems.

Author

Wang, Changlong, Wang, Zijia, and Kou, Zheng

Subjects

*EVOLUTIONARY computation, *BIOLOGICAL evolution, *KNOWLEDGE transfer, *PROBLEM solving, *ALGORITHMS, *EVOLUTIONARY algorithms

Abstract

The field of evolutionary multitasking optimization (EMTO) has been a highly anticipated research topic in recent years. EMTO aims to utilize evolutionary algorithms to concurrently solve complex problems involving multiple tasks. Despite considerable advancements in this field, numerous evolutionary multitasking algorithms continue to use a single evolutionary search operator (ESO) throughout the evolution process. This strategy struggles to completely adapt to different tasks, consequently hindering the algorithm's performance. To overcome this challenge, this paper proposes multitasking evolutionary algorithms via an adaptive bi-operator strategy (BOMTEA). BOMTEA adopts a bi-operator strategy and adaptively controls the selection probability of each ESO according to its performance, which can determine the most suitable ESO for various tasks. In an experiment, BOMTEA showed outstanding results on two well-known multitasking benchmark tests, CEC17 and CEC22, and significantly outperformed other comparative algorithms. [ABSTRACT FROM AUTHOR]

Published

2024

49. Set Packing Optimization by Evolutionary Algorithms with Theoretical Guarantees.

Author

Jin, Youzhen, Xia, Xiaoyun, Wang, Zijia, Peng, Xue, Zhang, Jun, and Liao, Weizhi

Subjects

*APPROXIMATION algorithms, *SEARCH algorithms, *GLOBAL optimization, *NP-hard problems, *COLLECTIONS

Abstract

The set packing problem is a core NP-complete combinatorial optimization problem which aims to find the maximum collection of disjoint sets from a given collection of sets, S, over a ground set, U. Evolutionary algorithms (EAs) have been widely used as general-purpose global optimization methods and have shown promising performance for the set packing problem. While most previous studies are mainly based on experimentation, there is little theoretical investigation available in this area. In this study, we analyze the approximation performance of simplified versions of EAs, specifically the (1+1) EA, for the set packing problem from a theoretical perspective. Our analysis demonstrates that the (1+1) EA can provide an approximation guarantee in solving the k-set packing problem. Additionally, we construct a problem instance and prove that the (1+1) EA beats the local search algorithm on this specific instance. This proof reveals that evolutionary algorithms can have theoretical guarantees for solving NP-hard optimization problems. [ABSTRACT FROM AUTHOR]

Published

2024

50. Analysis of green energy regeneration system for Electric Vehicles and Re estimation of carbon emissions in international trade based on evolutionary algorithms.

Author

Gao, Zhongpo and Yu, Ao

Subjects

*PARTICLE swarm optimization, *ELECTRIC motor buses, *EVOLUTIONARY algorithms, *CLEAN energy, *CARBON emissions, *ECONOMIC efficiency

Abstract

In order to achieve maximum carbon reduction during the operation of pure electric buses, the author proposes a re estimation of carbon emissions in international trade based on evolutionary algorithm analysis of electric vehicle green energy regeneration systems. On the basis of analyzing single line scheduling, the author focuses on studying the regional scheduling mode of pure electric buses, and establishes a multi-objective optimization model for pure electric bus regional scheduling considering carbon benefits with the goals of minimizing the number of operating vehicles, minimizing the empty distance, and maximizing carbon benefits. Based on the actual operation data of pure electric buses 146 and 149 in a certain city, the author used an improved particle swarm optimization algorithm to solve the regional scheduling problem of pure electric buses according to the characteristics of the model. The results indicate that assuming other conditions remain unchanged, when the price of diesel rises to around 7.9 yuan, its operating costs will exceed those of pure electric buses, and the cost advantage of diesel vehicles will gradually decrease. Other conditions remain unchanged, and when the battery price per vehicle drops to around 300,000 yuan, the operating cost of pure electric buses will be lower than that of diesel vehicles. Conclusion: Under the premise of considering carbon benefits, adopting regional dispatch mode for pure electric buses has better economic efficiency and is more conducive to the promotion of pure electric buses. [ABSTRACT FROM AUTHOR]

Published

2024