A Master-Slave Salp Swarm Algorithm Optimizer for Hybrid Energy Storage System Control Strategy in Electric Vehicles

Fabian Cheruiyot, D. Segera
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Abstract

Pure electric vehicles provide an enticing ecofriendly alternative to traditional fossil fuel combustion engine locomotives. Batteries have primarily been used to store energy in electric vehicles; however, peak load demand and transient power leading to decreased battery lifespan have bred interest in hybrid energy storage systems in electric vehicles. Management of energy drawn from a hybrid energy storage system (HESS) in electric vehicles is a real-time multistage optimization problem aimed at minimizing energy consumption while aptly distributing energy drawn from the battery and capacitor to enhance the battery life cycle. This paper explores the feasibility of a master-slave salp swarm optimization algorithm (MSSSA) (metaheuristic algorithm) in a HESS control strategy for electric vehicles. Introducing a master-slave learning approach to the salp swarm algorithm (SSA) improves its performance by increasing its convergence rate while maintaining a balance between exploration and exploitation phases of the algorithm. A comparison of the MSSSA results with the SSA (salp swarm algorithm), DA (dynamic algorithm), WOA (whale optimization algorithm), MFO (moth flame optimization algorithm), GA (genetic algorithm), and PSO (particle swarm optimization algorithm) on benchmark test functions and dynamic program simulation of an electric vehicle’s HESS control strategy and shows preeminence of the MSSSA control strategy for HESS.
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一种主从Salp群算法优化电动汽车混合储能系统控制策略
纯电动汽车为传统的化石燃料内燃机机车提供了一种诱人的环保替代品。电池主要用于电动汽车的储能;然而,峰值负载需求和导致电池寿命缩短的瞬态功率引起了人们对电动汽车混合储能系统的兴趣。电动汽车混合储能系统(HESS)的能量管理是一个实时的多阶段优化问题,旨在最大限度地降低能量消耗,同时合理分配来自电池和电容器的能量,以提高电池的寿命周期。本文探讨了一种主从salp群优化算法(MSSSA)(元启发式算法)在电动汽车HESS控制中的可行性。在salp群算法(SSA)中引入主从学习方法,提高了算法的收敛速度,同时保持了算法的探索和利用阶段之间的平衡,从而提高了算法的性能。将MSSSA算法与salp swarm algorithm、DA (dynamic algorithm)、WOA (whale optimization algorithm)、MFO (moth flame optimization algorithm)、GA (genetic algorithm)、PSO (particle swarm optimization algorithm)对某电动汽车HESS控制策略的基准测试函数和动态程序仿真结果进行了比较,表明MSSSA控制策略在HESS控制方面具有优越性。
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发文量
13
审稿时长
28 weeks
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