基于自适应正态云模型的引力樽海鞘群算法

针对樽海鞘群算法(salp swarm algorithm,SSA)在求解复合问题时存在收敛速度慢和容易陷入局部最优等缺点,提出一种结合引力搜索技术与正态云发生器的樽海鞘群算法(cloud gravitational SSA,CGSSA).在更新樽海鞘领导者位置阶段引入引力搜索算法(gravitational sear...     

基于改进樽海鞘群算法的含瓦斯煤破裂过程信号特征识别

针对标准樽海鞘群算法存在的计算精度不足、易陷入局部停滞等缺陷,提出一种多策略融合的樽海鞘群算法。在初始化阶段,引入线性同余法随机发生器;利用野马算法优化樽海鞘领导者位置;采用金豺算法改进樽海鞘种群追随机制。通过测试函数寻优对比实验,证明多策略融合的樽海鞘群算法相比于其他智能算法在鲁棒性与稳定性方面均有显著提升。将多策略融合的樽海鞘群算法应用到含瓦斯煤破裂过程信号特征识别,实验结果表明：提出的含瓦斯煤破裂过程信号特征识别模型具有更好的表现,准确率可达93.33%,相比其他识别模型,识别率更高。     

双领导者樽海鞘群算法

为了提升樽海鞘群(Salp Swarm Algorithm,SSA)算法的求解精度和全局搜索能力,提出了一种基于正态过程搜索和差分进化(Differential Evolution,DE)算法的改进樽海鞘群算法——双领导者樽海鞘群算法(Two Types of Leaders Salp Swarm Algorithm,TTLSSA)。该算法设置了两类领导者和两种跟随群体,其中执行正态过程搜索的领导者需要进行正态过程游走、交叉、选择等操作,主要用于全局勘探;当前最优解附近的领导者在随迭代次数呈锯齿状变化的参数gap的影响下,兼顾了全局搜索和局部开发两种功能。用18个不同类型的标准测试函数检验所提算法的性能,并与DE、SSA、正弦余弦算法(Sines and Cosines Algorithm,SCA)、灰狼优化(Grey Wolf Optimizer,GWO)算法以及鲸鱼优化算法(Whale Optimization Algorithm,WOA)做对比,TTLSSA在16个测试函数上的平均精度排名第1或并列第1,在2个测试函数上的平均精度排名第2,在6种算法中平均耗时排名第2,说明了TTLSSA在没有增加SSA时间成本的前提下,显著提升了优化能力。     

融合信息反馈共享与蜉蝣搜索机制的樽海鞘群算法

针对樽海鞘群算法(SSA)收敛速度慢和易陷入局部最优的问题,提出了一种融合信息反馈共享与蜉蝣搜索机制的改进樽海鞘群算法。使用Piecewise映射的方法进行种群初始化,使初始樽海鞘种群更均匀的覆盖可行域空间;采用信息共享机制,提出辅助领导者策略,改进领导者位置更新公式,增强全局搜索能力;利用进化学说以及正负反馈调节的思想,通过变异操作和自然选择原则选取更优领导者,从而提高搜索精度;最后,提出蜉蝣搜索机制,选取蜉蝣算法的交配公式,优化追随者位置迭代公式,使算法在后期更快收敛。通过在12个基准测试函数的多个维度以及17个CEC测试函数的实验,证明了改进樽海鞘群算法的综合性能,并通过消融实验验证了改进策略的有效性,实验结果表明,改进算法在收敛速度以及搜索精度上具有明显的优势。     

一种多策略驱动的改进樽海鞘群算法

针对樽海鞘群算法(Salp Swarm Algorithm,SSA)求解精度不足、容易早熟收敛的缺点,提出了一种多策略协同作用的改进樽海鞘群算法(MSSSA).在领导者位置更新公式中引入指数衰减因子,改善算法的全局收敛速度;在跟随者位置更新公式中引入随机惯性权重算子,以协调并增强算法的局部开采和全局勘探能力;通过加权方...     

多策略融合的改进樽海鞘群算法

为解决传统樽海鞘群算法(SSA)收敛精度低、难以跳出局部最优等问题,提出了一种多策略融合的改进樽海鞘群算法(ISSA)。首先,提出了一种新的融合中垂线算法收敛策略的追随者位置更新方法,以解决传统SSA追随者位置更新方法的不足;为提升SSA跳出局部最优的能力,提出一种基于中垂线算法收敛策略的自扰动策略。其次,通过分析传统SSA领导者位置更新策略存在的不足,提出了一种新的领导者位置更新策略,并针对SSA的固定种群顺序,提出了以适应度为指标重构樽海鞘群体排列顺序的方法以提升算法性能。最后以仿真实验对ISSA的性能进行了验证,结果表明ISSA解决了SSA收敛精度低和难以跳出局部最优的问题,提升了SSA的收敛速度和稳定性。通过与其他改进SSA的对比实验,证明了ISSA的优越性。     

部分遮蔽下改进樽海鞘群算法的光伏系统最大功率跟踪

部分遮蔽条件(partial shading condition)会使光伏系统的功率–电压(P--V)特性曲线出现多个峰值,常规的最大功率跟踪(MPPT)算法易陷入局部最大功率点(LMPP)已不再适用.本文提出了一款新型启发式算法,即改进樽海鞘群算法(MSSA),用于部分遮蔽条件下光伏系统MPPT. MSSA在原有樽海鞘群算法(SSA)的基础上,引入了文化基因算法(memetic algorithm),以樽海鞘链为种群单位,采用多个樽海鞘链同时进行独立寻优,以提高算法全局搜索和局部探索的能力;同时,通过群落中所有樽海鞘间的信息交流,重组产生新的樽海鞘链,以提高算法的收敛稳定性.本文通过3个算例对MSSA的优化性能进行了研究,即恒温恒光照强度、恒温变光照强度和变温变光照强度.仿真结果表明,与增量电导法(INC)、遗传算法(GA)、粒子群算法(PSO)、灰狼算法(GWO)和樽海鞘群算法(SSA)相比,所提算法能在部分遮蔽条件下快速、稳定地获取最大光能.最后,基于d Space的硬件在环实验(HIL)验证了所提算法的硬件可行性.     

基于衰减因子和动态学习的改进樽海鞘群算法

樽海鞘群算法是一种新型的群智能优化算法.与其他智能优化算法相比,樽海鞘群算法的优化求解策略仍有待改进,以进一步提高该算法的求解精度和寻优效率.本文提出一种基于衰减因子和动态学习的改进樽海鞘群算法,通过在领导者更新阶段添加衰减因子,提高算法的局部开发能力,在跟随者更新阶段引入动态学习策略,提高算法的全局搜索能力.本文对16个测试函数进行实验,将提出的改进算法与其他智能优化算法比较,实验结果表明,本文提出的改进算法在收敛精度和收敛速度方面有较大提升,具有良好的优化性能.     

求解无人机航迹规划问题的精英引领自适应樽海鞘群算法

针对目前无人机航迹规划成本高、精度差和稳定性不足等问题,提出一种精英引领自适应樽海鞘群算法。首先,分别引入精英质心对立学习和精英引导惯性权重机制对樽海鞘领导者和跟随者更新方式进行改进,提升樽海鞘群算法的全局搜索能力和收敛速度,并设计种群个体角色自适应调整机制均衡算法的全局搜索和局部开发;然后建立无人机二维航迹空间模型和航迹成本模型,将航迹规划转换为多维函数优化问题,并利用精英引领自适应樽海鞘群算法求解无人机航迹规划问题,以综合考虑威胁成本和燃料成本的航迹目标函数评估个体位置适应度,对航迹规划最优方案迭代求解。在两个不同复杂性的威胁场景下进行的仿真实验结果表明,与人工势场(APF)、樽海鞘群算法(SSA)、人工蜂群算法(ABA)和改进樽海鞘群算法(ISSA)相比,所提算法的最优航迹平均成本分别可以降低78.68%、61.77%、42.76%和19.36%,验证了所提算法的有效性。     

多子群的共生非均匀高斯变异樽海鞘群算法

针对樽海鞘群算法求解精度不高和收敛速度慢等缺点, 提出一种多子群的共生非均匀高斯变异樽海鞘群算法. 根据不同适应度值将樽海鞘链群分为三个子种群, 各个子种群分别进行领导者位置更新、追随者共生策略和链尾者非均匀高斯变异等操作. 使用统计分析、收敛速度分析、Wilcoxon检验、经典基准函数和CEC 2014函数的标准差来评估改进樽海鞘群算法的效率. 结果表明, 改进算法具有更好的寻优精度和收敛速度. 尤其在求解高维和多峰测试函数上, 改进算法拥有更好性能.     

基于混沌映射的自适应樽海鞘群算法

针对樽海鞘群算法收敛速度慢、易陷入局部最优等问题,提出了一种基于混沌映射的自适应樽海鞘群算法。在种群初始化阶段引入混沌映射来增强种群的多样性,提高算法的收敛速度;改进领导者的更新方式,同时加入自适应权重,提高算法的探索和开发能力;改进追随者的位置更新方式,减少追随者的盲目性。通过对10个测试函数进行仿真实验,并与其他优化算法进行比较,实验结果表明,在不改变原有时间复杂度的前提下,提出的算法在收敛速度和寻优精度上有较大的提升,具有更好的优化性能。     

Improved salp swarm algorithm based on weight factor and adaptive mutation

Salp Swarm Algorithm (SSA) is a novel swarm intelligent algorithm with good performance. However, like other swarm-based algorithms, it has insufficiencies of low convergence precision and slow convergence speed when dealing with high-dimensional complex optimisation problems. In response to this concerning issue, in this paper, we propose an improved SSA named as WASSA. First of all, dynamic weight factor is added to the update formula of population position, aiming to balance global exploration and local exploitation. In addition, in order to avoid premature convergence and evolution stagnation, an adaptive mutation strategy is introduced during the evolution process. Disturbance to the global extremum promotes the population to jump out of local extremum and continue to search for an optimal solution. The experiments conducted on a set of 28 benchmark functions show that the improved algorithm presented in this paper displays obvious superiority in convergence performance, robustness as well as the ability to escape local optimum when compared with SSA.     

A novel chaotic salp swarm algorithm for global optimization and feature selection

Salp Swarm Algorithm (SSA) is one of the most recently proposed algorithms driven by the simulation behavior of salps. However, similar to most of the meta-heuristic algorithms, it suffered from stagnation in local optima and low convergence rate. Recently, chaos theory has been successfully applied to solve these problems. In this paper, a novel hybrid solution based on SSA and chaos theory is proposed. The proposed Chaotic Salp Swarm Algorithm (CSSA) is applied on 14 unimodal and multimodal benchmark optimization problems and 20 benchmark datasets. Ten different chaotic maps are employed to enhance the convergence rate and resulting precision. Simulation results showed that the proposed CSSA is a promising algorithm. Also, the results reveal the capability of CSSA in finding an optimal feature subset, which maximizes the classification accuracy, while minimizing the number of selected features. Moreover, the results showed that logistic chaotic map is the optimal map of the used ten, which can significantly boost the performance of original SSA.     

HMOSHSSA: a hybrid meta-heuristic approach for solving constrained optimization problems

This paper proposes a novel hybrid multi-objective optimization algorithm named HMOSHSSA by synthesizing the strengths of Multi-objective Spotted Hyena Optimizer (MOSHO) and Salp Swarm Algorithm (SSA). HMOSHSSA utilizes the exploration capability of MOSHO to explore the search space effectively and leader and follower selection mechanism of SSA to achieve global best solution with faster convergence. The proposed algorithm is evaluated on 24 benchmark test functions, and its performance is compared with seven well-known multi-objective optimization algorithms. The experimental results demonstrate that HMOSHSSA acquires very competitive results and outperforms other algorithms in terms of convergence speed, search-ability and accuracy. Additionally, HMOSHSSA is also applied on seven well-known engineering problems to further verify its efficacy. The results reveal the effectiveness of proposed algorithm toward solving real-life multi-objective optimization problems.

     

混沌精英质心拉伸机制的樽海鞘群算法

针对樽海鞘群算法求解精度不高的缺点,提出一种混沌精英质心拉伸机制的樽海鞘群算法。引入改进的Tent混沌序列生成初始种群,以增加初始个体的多样性;选择最优个体采用精英质心拉伸机制,可增强全局搜索能力。将改进算法在12个典型复杂函数和CEC2014函数优化问题上进行仿真实验,并同经典的遗传算法和粒子群算法进行对比。结果表明,混沌精英质心拉伸机制的樽海鞘群算法具有更好的全局搜索能力,寻优精度比标准算法有所增强。在求解高维和多峰测试函数上,改进算法拥有更好的性能。     

Harmonized salp chain-built optimization

As an optimization paradigm, Salp Swarm Algorithm (SSA) outperforms various population-based optimizers in the perspective of the accuracy of obtained solutions and convergence rate. However, SSA gets stuck into sub-optimal solutions and degrades accuracy while solving the complex optimization problems. To relieve these shortcomings, a modified version of the SSA is proposed in the present work, which tries to establish a more stable equilibrium between the exploration and exploitation cores. This method utilizes two different strategies called opposition-based learning and levy-flight (LVF) search. The algorithm is named m-SSA, and its validation is performed on a well-known set of 23 classical benchmark problems. To observe the strength of the proposed method on the scalability of the test problems, the dimension of these problems is varied from 50 to 1000. Furthermore, the proposed m-SSA is also used to solve some real engineering optimization problems. The analysis of results through various statistical measures, convergence rate, and statistical analysis ensures the effectiveness of the proposed strategies integrated with the m-SSA. The comparison of the m-SSA with the conventional SSA, variants of SSA and some other state-of-the-art algorithms illustrate its enhanced search efficiency.

     

基于鸡群优化算法的SAR图像快速分割

为提高SAR图像分割的速度和质量,利用鸡群优化算法,提出了一种SAR图像快速分割方法。该方法使用二维灰色Otsu模型作为鸡群优化算法的适应度函数,利用鸡群中公鸡、母鸡和小鸡的角色分工、协同工作快速逼近最佳阈值。实验结果表明,该方法在收敛速度和分割效果两方面均优于基于遗传算法、人工鱼群算法等群体智能优化算法的分割方法。     

基于SSA算法的飞行动作规则自动提取

针对空战知识获取问题展开研究，提出了一条从海量飞行参数中获取知识的途径。构建空战专家系统知识库；对于飞行动作规则知识的提取，提出了一种基于樽海鞘群优化算法的飞行动作规则知识提取方法，为了使提取的规则知识简洁有效，对算法的评价函数进行了设计。通过对水平右转弯机动动作和斤斗动作进行规则提取仿真与分析，验证了该方法的有效性和可行性。     

ESSAWOA: Enhanced Whale Optimization Algorithm integrated with Salp Swarm Algorithm for global optimization

In this paper, a novel hybrid meta-heuristic algorithm called ESSAWOA is proposed for solving global optimization problems. The main idea of ESSAWOA is to enhance Whale Optimization Algorithm (WOA) by combining the mechanism of Salp Swarm Algorithm (SSA) and Lens Opposition-based Learning strategy (LOBL). The hybridization process includes three parts: First, the leader mechanism with strong exploitation of SSA is applied to update the population position before the basic WOA operation. Second, the nonlinear parameter related to the convergence property in SSA is introduced to the two phases of encircling prey and bubble-net attacking in WOA. Third, LOBL strategy is used to increase the population diversity of the proposed optimizer. The hybrid design is expected to significantly enhance the exploitation and exploration capacity of the proposed algorithm. To investigate the effectiveness of ESSAWOA, twenty-three benchmark functions of different dimensions and three classical engineering design problems are performed. Furthermore, SSA, WOA and seven other well-known meta-heuristic algorithms are employed to compare with the proposed optimizer. Our results reveal that ESSAWOA can effectively and quickly obtain the promising solution of these optimization problems in the search space. The performance of ESSAWOA is significantly superior to the basic WOA, SSA and other meta-heuristic algorithms.