自由作业的供应链排序研究

研究一类集成工件加工和发送的供应链排序模型,即研究如何安排工件在自由作业机器上加工,把加工完毕的工件分批发送给下游客户,使得含生产排序费用和发送费用的目标函数最优.这里,分别取工件最大送到时间和平均送到时间为生产排序费用;而发送费用是由固定费用和与运输路径有关的变化费用组成.利用排序理论和动态规划方法,构造了自由作业供应链排序问题的多项式时间近似算法,并分析算法的性能比.     

自由作业环境下的供应链排序问题

本文研究自由作业环境下的供应链排序问题,研究供应链的上游如何安排工件在自由作业机器上加工,把加工完毕的工件分批发送给下游,使得生产排序费用和发送费用总和最少.这里,生产排序费用是用工件送到时间的函数来表示;发送费用是由发送的固定费用和与运输路径有关的变化费用所组成.本文研究以工件最大送到时间为生产排序费用的自由作业供应链排序问题,在指出问题的NP困难性后,用动态规划算法构造多项式时间近似算法,并分析算法的性能比.本文最后还对特殊情形进行了讨论.     

一类自由作业供应链排序的研究

本文研究一类集成工件生产和发送的排序模型.在该模型中,供应链的上游首先将工件安排在自由作业机器上加工,然后把加工完毕的工件分批发送给下游.问题是寻找生产和发送相连的排序,使得生产排序费用和发送费用总和最少.这里,生产排序费用是以工件带权送到时间和表示;发送费用由固定费用和与运输路径有关的变化费用组成.在指出问题的NP困难性后,本文用动态规划算法构造了一致条件下的多项式时间近似算法,并分析算法的性能比.本文最后还讨论了该问题的其它情形.     

工件带就绪时间的单机供应链排序问题

研究工件带就绪时间的单机供应链排序问题,即工件到达后按何种顺序在机器上加工,并将完工工件如何由运输工具发送给客户,使得生产费用与发送费用总和最少.这里,每个工件的生产费用为工件的发送时刻,多个工件可组成一批一次发送给客户,发送费用与发送次数成正比.对于工件允许中断加工的问题,基于SRPT规则给出多项式时间的动态规划算法求解最优序；对于工件不允许中断加工的问题,证明问题是强NP难的,并提出了性能比为2的近似算法.     

自由作业环境下的供应链排序

本文研究了一类集成工件加工和发送的供应链排序模型.利用排序理论和动态规划方法,获得了两机器情形下的供应链排序问题的多项式时间近似算法,并证明算法的性能比为2.     

机器带不可用时间限制的简单线性恶化供应链排序问题

研究的单机供应链排序问题中, 机器有一个不可用时间限制, 工件的加工时间与恶化率及其开工时间有关, 且工件的加工不可恢复. 一个或多个完工工件可组成一个发送批由车辆发送给客户, 且在机器不可用时间限制之前完工的工件必须在限制开始之时或之前完成发送. 问题的目标是最小化总发送时间与总发送费用之和. 证明问题是NP-难的, 提出了伪多项式时间的动态规划算法. 进一步, 在确定问题目标函数值的上界及下界之后, 设计了一个完全多项式时间近似方案(FPTAS).     

平行机物流排序的近似算法

本文研究一个两阶段物流排序问题,即第一阶段工件在平行机上加工,在第二阶段这些被加工过的工件以某种运输方式分批运送到预先指定的目的地.优化的目标是使工件带权送到的时间与运输费用的总和为最小.应用动态规划及组合优化方法,分别研究“满足一致性条件”和一般情形下该问题的多项式时间近似算法,并分析算法的性能比.     

机器具有学习效应的供应链排序问题

研究了机器具有学习效应的供应链排序问题.有多个客户分布在不同位置,每个客户都有一定数量的工件需要在一台机器上进行加工.每个客户的工件在机器上加工时具有学习效应,即后面加工的工件实际加工时间是逐渐缩短的.工件生产完后需要运输到相应的客户处,每一批配送需要花费一定的时间和费用.这里研究了供应链排序理论中主要的四个目标函数,分析了这些问题的复杂性,对于一些情况给出了它们的最优算法.     

具有多个不可用时间段的单机供应链排序问题

在单机供应链排序问题中, 机器会有多个长度确定的不可用时间段,它仅可以在可用时间段内加工工件,且每个可用时间段的长度不大于给定的常数.多个完工工件可组成一批由一个容量无限制的运输工具发送给客户.问题的目标是如何 安排工件的加工、发送以及不可用时间段,以使总发送时间与总发送费用之和达到最小. 对于工件加工可恢复的情况,可在多项式时间 O(n^2) 内得到最优序. 对于工件加工不可恢复的情况,证明了问题是强NP-难的, 并提出了~2-近似算法.     

装配系统的供应链排序问题

在装配系统中,有多个供应商向同一个制造商提供零部件,仅当一个产品的所有零部件都送到后,制造商才进行最后的组装与发送.假设制造商为非瓶颈式生产.研究目标为工件带权完工时间和及最大延误的装配系统供应链排序问题,利用排序的理论和方法,分别设计多项式时间算法,并分析算法的性能比.     

基于多客户的工件可转包排序问题(英文)

In this paper, we study a new scheduling and outsourcing model with multiple customers in which jobs can be processed by either in-house machine or outsourcing machine.All processed jobs have to be delivered in batches to their respective customers and each shipment incurs a delivery cost as well as a fixed amount of time. We discuss three commonly used objective functions, analyze their complexity and solve them by dynamic programming algorithms.     

Complexity of flow shop scheduling problems with transportation constraints

In most manufacturing and distribution systems, semi-finished jobs are transferred from one processing facility to another by transporters such as Automated Guided Vehicles, robots and conveyors, and finished jobs are delivered to warehouses or customers by vehicles such as trucks.This paper investigates two-machine flow shop scheduling problems taking transportation into account. The finished jobs are transferred from the processing facility and delivered to customers by truck. Both transportation capacity and transportation times are explicitly taken into account in these models. We study the class of flow shop problems by analysing their complexity. For the makespan objective function, we prove that this problem is strongly NP-hard when the capacity of a truck is limited to two or three parts with an unlimited buffer at the output of the each machine. This problem with additional constraints, such as blocking, is also proven to be strongly NP-hard.     

带交货期的工件族生产与配送的排序问题

本文考虑了多个客户订购不同种类的工件,工件生产完后需要运输到客户的单机供应链排序问题.由于工件属于不同的种类,在加工不同种类工件前要有一个准备时间.每个客户分布在不同位置,客户的每个工件都有一个交货期,工件是分批配送的,每一批配送需要花费一定的时间及费用.考虑了两个与交货期有关的目标函数,分别给出了它们的最优算法.     

Minimizing the weighted number of tardy jobs with due date assignment and capacity-constrained deliveries for multiple customers in supply chains

In this paper, an integrated due date assignment and production and batch delivery scheduling problem for make-to-order production system and multiple customers is addressed. Consider a supply chain scheduling problem in which n orders (jobs) have to be scheduled on a single machine and delivered to K customers or to other machines for further processing in batches. A common due date is assigned to all the jobs of each customer and the number of jobs in delivery batches is constrained by the batch size. The objective is to minimize the sum of the total weighted number of tardy jobs, the total due date assignment costs and the total batch delivery costs. The problem is NP-hard. We formulate the problem as an Integer Programming (IP) model. Also, in this paper, a Heuristic Algorithm (HA) and a Branch and Bound (B&B) method for solving this problem are presented. Computational tests are used to demonstrate the efficiency of the developed methods.     

On-line integrated production–distribution scheduling problems with capacitated deliveries

In on-line integrated production–distribution problems, customers release jobs to a manufacturer that has to process the jobs and deliver them to the customers. The jobs are released on-line, that is, at any time there is no information about future jobs. Processed jobs are grouped into batches, which are delivered to the customers as single shipments. The total cost (to be minimized) is the sum of the total weighted flow time and the total delivery cost. Such on-line integrated production–distribution problems have been studied for the case of uncapacitated batches. We consider the capacitated case with an upper bound on the size of a batch. For several versions of the problem, we present efficient on-line algorithms, and use competitive analysis to study their worst-case performance.     

The Coordination of Scheduling and Batch Deliveries

This paper considers several scheduling problems where deliveries are made in batches with each batch delivered to the customer in a single shipment. Various scheduling costs, which are based on the delivery times of the jobs, are considered. The objective is to minimize the scheduling cost plus the delivery cost, and both single and parallel machine environments are considered. For many combinations of these, we either provide efficient algorithms that minimize total cost or show that the problem is intractable. Our work has implications for the coordination of scheduling with batch delivery decisions to improve customer service.     

On-line supply chain scheduling problems with preemption

We consider supply chain scheduling problems where customers release jobs to a manufacturer that has to process the jobs and deliver them to the customers. The jobs are released on-line, that is, at any time there is no information on the number, release and processing times of future jobs; the processing time of a job becomes known when the job is released. Preemption is allowed. To reduce the total costs, processed jobs are grouped into batches, which are delivered to customers as single shipments; we assume that the cost of delivering a batch does not depend on the number of jobs in the batch. The objective is to minimize the total cost, which is the sum of the total flow time and the total delivery cost. For the single-customer problem, we present an on-line two-competitive algorithm, and show that no other on-line algorithm can have a better competitive ratio. We also consider an extension of the algorithm for the case of m customers, and show that its competitive ratio is not greater than 2m if the delivery costs to different customers are equal.