为了解决Min-Min调度算法中存在的负载不平衡问题,提高集群系统的负载均衡性,该文提出了一种基于Min-Min极限下压算法的负载模糊分类与局部重调度算法(Load fuzzy classification and local re-schedule algorithm,LFC-LRA)。引入模糊...为了解决Min-Min调度算法中存在的负载不平衡问题,提高集群系统的负载均衡性,该文提出了一种基于Min-Min极限下压算法的负载模糊分类与局部重调度算法(Load fuzzy classification and local re-schedule algorithm,LFC-LRA)。引入模糊分类的思想,根据各节点的负载大小,将节点分成三种类型:重负载、中负载和轻负载;对负载较重和较轻的节点进行重新调度,使用Min-Min极限下压算法压缩这些节点的任务完成时间,改善算法的负载失衡问题。实验结果表明:改进后的算法具有较好的负载均衡性,能有效地提高资源的利用率,降低系统的任务完成时间。展开更多
This paper addresses the single-machine scheduling problem with release times minimizing the total completion time. Under the circumstance of incomplete global information at each decision time, a two-level rolling sc...This paper addresses the single-machine scheduling problem with release times minimizing the total completion time. Under the circumstance of incomplete global information at each decision time, a two-level rolling scheduling strategy (TRSS) is presented to create the global schedule step by step. The estimated global schedules are established based on a dummy schedule of unknown jobs. The first level is the preliminary scheduling based on the predictive window and the second level is the local scheduling for sub-problems based on the rolling window. Performance analysis demonstrates that TRSS can improve the global schedules. Computational results show that the solution quality of TRSS outperforms that of the existing rolling procedure in most cases.展开更多
文摘为了解决Min-Min调度算法中存在的负载不平衡问题,提高集群系统的负载均衡性,该文提出了一种基于Min-Min极限下压算法的负载模糊分类与局部重调度算法(Load fuzzy classification and local re-schedule algorithm,LFC-LRA)。引入模糊分类的思想,根据各节点的负载大小,将节点分成三种类型:重负载、中负载和轻负载;对负载较重和较轻的节点进行重新调度,使用Min-Min极限下压算法压缩这些节点的任务完成时间,改善算法的负载失衡问题。实验结果表明:改进后的算法具有较好的负载均衡性,能有效地提高资源的利用率,降低系统的任务完成时间。
基金Supported by National Natural Science Foundation of P.R. China (60274013, 60474002)Shanghai Development Foundation for Science and Technology (04DZ11008)Science Research Foundation of Shandong University at Weihai (XZ2005001)
文摘This paper addresses the single-machine scheduling problem with release times minimizing the total completion time. Under the circumstance of incomplete global information at each decision time, a two-level rolling scheduling strategy (TRSS) is presented to create the global schedule step by step. The estimated global schedules are established based on a dummy schedule of unknown jobs. The first level is the preliminary scheduling based on the predictive window and the second level is the local scheduling for sub-problems based on the rolling window. Performance analysis demonstrates that TRSS can improve the global schedules. Computational results show that the solution quality of TRSS outperforms that of the existing rolling procedure in most cases.