一类带机器准备时间的排序复杂性及算法

1引言文[2-4]中考虑了如下定义的一个排序模型：m台同型机器加工n个工件，每个工件在零时刻到达，第i个工件需加工时间pi,而各机器有各自的准备时间Tj≥0,怎样安排工件加工顺序，使机器总完工时间（makespan）尽可能早．这是一个强NP-完全问题．本文考虑增加这样一个约束，即每     

加工时间依赖于机器的自由作业排序问题

1992年M．Dror提出工件的加工时间依赖于机器的排序问题（schedulingwithmachinedependentprocessingtimes），并研究以最大完工时间（makespan）和以总的完工时间为优化目标的两种这类排序问题．然而，M．Dror对以总的完工时间为优化目标提出的“最优算法”是错误的．本文用算例表明他提出的算法不是最优的，并在机器连续加工的条件下，把这个排序问题转化成指派问题（assignmentproblem），从而可以用匈牙利算法得到最优解．最后，我们提出几个尚未解决的问题，以期引起国内外同行进一步研究．     

无限批量调度中最小化加权完工时间和问题的一个线性时间近似方案

本文考虑n个工件的无限批量机器调度问题．一台机器可以同时加工B≥n个工件．每个工件具有一个正权因子、一个释放时间和一个加工时间．一个批次的加工时间是该批次所包含所有工件的加工时间的最大者．在同一批次中加工的工件有相同的完工时间，即它们的共同开始时间加上该批次的加工时间．对于最小化加权完工时间和问题，本文给出了第一个多项式时间近似方案(PTAS)．对任意给定精度，该算法的运行时间为线性的．     

加工时间和尺寸成正比单机排序和工件运输的最小化最大完工时间问题

在单机排序和工件运输的最小化最大完工时间问题中,工件首先在一台机器上加工,然后被一辆有容量限制的汽车运送到一个顾客．当工件的加工时间和尺寸无关时, Chang和Lee已经证明该问题是强NP困难的．他们也给出了一个启发式算法,它的最差执行比为5／3,并且这个界是紧的．本文考虑工件的加工时间和尺寸成正比的情形,证明了Chang和Lee的算法有更好的最差执行比53／35,并提供了一个新的启发式算法,它的最差执行比是3／2,并且这个界是最好的．     

一个多项式时间可解的自由作业排序问题

一个多项式时间可解的自由作业排序问题俞国胜（上海大学理学院数学系，上海２０１８００）１引言和记号自由作业（ｏＰｅｒｌｓｈｏＰ）排序问题是：有ｎ个工件Ｊ一《ＪＩ，人，··，人｝和。台机器Ｍ一｛ＭＩ，ＭＺ，…；Ｍｔｎ｝，每个工件Ｊｊ需要在机器Ｍｉ上加工，...     

原始工件的完工时间限制下的最小化最大延误时间的重新排序

考虑由两个代理引起的重新排序问题,其中每个代理都在公共的加工资源下完成各自的不可中断加工的工件.每个代理要求在仅依赖工件的完工时间时最小化某一个特定的目标函数.考虑在原始工件的完工时间限制下的两个代理的单机最小化最大延误时间的重新排序问题.证明了该问题能在多项式时间或者拟多项式时间内解决.     

工件可自由下线最小化总完工时间的平行分批排序问题

考虑工件可自由下线最小化总完工时间的有界平行分批排序问题. 在该问题中, 一台平行批机器可以同时处理 b 个工件作为一个平行批, 这里b 是批容量, 一个批的加工时间等于分配给这个批的工件的最大加工时间. 关于可自由下线工件, 每一个工件的完工时间等于包含这个工件的批的开工时间与工件的加工时间的和. 也就是, 如果一个批B 有一个开工时间S, 那么包含在批B 中的每一个工件J_j 的开工时间定义为S, 而它的完工时间定义为S+p_j, 这里p_j 是工件J_j 的加工时间. 对此问题, 首先研究最优排序的一些性质. 然后, 基于这些性质, 给出一个运行时间为O(n^{b (b-1)})的动态规划算法.     

加工时间离散可控的分批配送排序问题

研究了工件的加工时间是离散可控的,并且工件加工完后需要分批配送到客户的单机排序问题.一个客户在初始时刻将一批工件交给一个制造商进行加工.每个工件有多种加工模式,分配给每个工件的加工资源越多,则其加工时间越短.工件生产完后需要分批配送到客户处,每一批需要花费一定的时间和费用.研究了排序理论中主要的四个目标函数,构建了单机情况下的具体模型,分析了问题的复杂性,对具体的问题给出了它们的最优算法.     

可拆分平行机排序问题研究

平行机排序问题是把n个产品安排到m台机器上加工，使其总费用最小．通常的平行机排序问题都假设（C1）：任何产品不能在不同机器上同时加工．但是，如果把产品的加工时间看成一个产品量的需求，就可以假设（C2）：允许同一产品拆分在不同机器上同时加工．本文首先回顾了C1假设下平行机排序问题已有的结果，然后基于假设C2，讨论了各种费用目标下问题的算法及其复杂性．在没有生产准备时间的情况下，给出了一些问题的多项式算法和线性规划方法．在有独立生产准备时间的情况下，给出了P／split／Cmax问题的启发式算法及其算法分析．     

加工时间可控和恶化的单机最大完工时间排序

本文研究加工时间可控并随开工时间简单线性增长的单机最大完工时间排序问题.该问题将加工时间可控排序和加工时间恶化排序两类研究连接到一起.通过比较技术证明了该问题存在满足以下性质的最优解:每个工件的加工时间或者完全压缩,或者完全不压缩;加工时间完全压缩的工件的顺序由一个工件参数和控制变量的函数的递增序给出,完全不压缩的工件在完全压缩的工件之后以任意序加工.通过将问题等价转换为0-1非线性整数规划问题,给出了单机排序问题的贪婪算法.     

Batch scheduling and common due-date assignment on a single machine

We consider the problem of scheduling n groups of jobs on a single machine where three types of decisions are combined: scheduling, batching and due-date assignment. Each group includes identical jobs and may be split into batches; jobs within each batch are processed jointly. A sequence independent machine set-up time is needed between each two consecutively scheduled batches of different groups. A due-date common to all jobs has to be assigned. A schedule specifies the size of each batch, i.e. the number of jobs it contains, and a processing order for the batches. The objective is to determine a value for the common due-date and a schedule so as to minimize the sum of the due date assignment penalty and the weighted number of tardy jobs. Several special cases of this problem are shown to be ordinary NP-hard. Some cases are solved in O(n log n) time. Two pseudopolynomial dynamic programming algorithms are presented for the general problem, as well as a fully polynomial approximation scheme.     

单位工件的平行机并行分批在线排序问题的算法

本文研究一类批容量有界的并行分批、平行机在线排序问题。模型中有n个相互独立的工件J={J₁,…,J_n}要在m台批处理机上加工。批处理机每次可同时加工至多B(Bj(1≤j≤n)的到达时间为r_j,加工时间为1,工件是否会到达事先未知,而只有等到工件的到达时间才能获知它的到达。目标为最小化工件的最大完工时间。针对该排序问题,本文设计了两个竞争比均达到最好可能的在线算法。     

极小化总完工时间的同时加工排序

讨论了并行工件同时加工排序问题,即n个同时到达的工件在m台批处理机上排序的问题.批处理机一次最多能加工B个工件.每批的加工时间等于该批中所含工件的加工时间的最大者.主要考虑B n的特殊情况,即每批可包含任意多个工件,目标函数是极小化总完工时间.首先对同型批处理机的情况给出了动态规划算法,算法的运行时间为O(m nm+1),并进一步将结论推广到同类批处理机的情况.     

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.     

Scheduling with batch setup times and earliness-tardiness penalties

We consider a scheduling model in which several batches of jobs need to be processed by a single machine. During processing, a setup time is incurred whenever there is a switch from processing a job in one batch to a job in another batch. All the jobs in the same batch have a common due date that is either externally given as an input data or internally determined as a decision variable. Two problems are investigated. One problem is to minimize the total earliness and tardiness penalties provided that each due date is externally given. We show that this problem is NP-hard even when there are only two batches of jobs and the two due dates are unrestrictively large. The other problem is to minimize the total earliness and tardiness penalties plus the total due date penalty provided that each due date is a decision variable. We give some optimality properties for this problem with the general case and propose a polynomial dynamic programming algorithm for solving this problem with two batches of jobs. We also consider a special case for both of the problems when the common due dates for different batches are all equal. Under this special case, we give a dynamic programming algorithm for solving the first problem with an unrestrictively large due date and for solving the second problem. This algorithm has a running time polynomial in the number of jobs but exponential in the number of batches.     

A constraint programming approach for a batch processing problem with non-identical job sizes

This paper presents a constraint programming approach for a batch processing machine on which a finite number of jobs of non-identical sizes must be scheduled. A parallel batch processing machine can process several jobs simultaneously and the objective is to minimize the maximal lateness. The constraint programming formulation proposed relies on the decomposition of the problem into finding an assignment of the jobs to the batches, and then minimizing the lateness of the batches on a single machine. This formulation is enhanced by a new optimization constraint which is based on a relaxed problem and applies cost-based domain filtering techniques. Experimental results demonstrate the efficiency of cost-based domain filtering techniques. Comparisons to other exact approaches clearly show the benefits of the proposed approach: it can optimally solve problems that are one order of magnitude greater than those solved by a mathematical formulation or by a branch-and-price.     

The unbounded parallel-batch scheduling with rejection

In this paper, we consider the unbounded parallel-batch scheduling with rejection. A job is either rejected, in which case a certain penalty has to be paid, or accepted and processed in batches on a machine. The processing time of a batch is defined as the longest processing time of the jobs contained in it. Four problems are considered: (1) to minimize the sum of the total completion time of the accepted jobs and the total rejection penalty of the rejected jobs; (2) to minimize the total completion time of the accepted jobs subject to an upper bound on the total rejection penalty of the rejected jobs; (3) to minimize the total rejection penalty of the rejected jobs subject to an upper bound on the total completion time of the accepted jobs; (4) to find the set of all the Pareto optimal schedules. We provide a polynomial-time algorithm for the first problem. Furthermore, we show that all the other three problems are binary NP-hard and present a pseudo-polynomial-time algorithm and a fully polynomial-time approximation scheme for them.     

工作有到达时间且拒绝工件总个数受限的单机平行分批排序问题的近似算法

考虑了工件有到达时间且拒绝工件总个数不超过某个给定值的单机平行分批排序问题.在该问题中,给定一个工件集和一台可以进行批处理加工的机器.每个工件有它的到达时间和加工时间;对于每个工件来说要么被拒绝要么被接受安排在机器的某一个批次里进行加工;一个工件如果被拒绝,则需支付该工件对应的拒绝费用.为了保证一定的服务水平,要求拒绝工件的总个数不超过给定值.目标是如何安排被接受工件的加工批次和加工次序使得其最大完工时间与被拒绝工件的总拒绝费用之和最小.该问题是NP-难的,对此给出了伪多项式时间动态规划精确算法,2-近似算法和完全多项式时间近似方案.     

Minimizing makespan on a single burn-in oven in semiconductor manufacturing

This paper considers a scheduling problem for a single burn-in oven in semiconductor manufacturing industry where the oven is a batch processing machine and each batch processing time is represented by the largest processing time among those of all the jobs contained in the batch. The objective measure of the problem is the maximum completion time (makespan) of all jobs. This paper investigates a static case in which all jobs are available to process at time zero, and also analyzes a dynamic case with different job-release times, for which a branch-and-bound algorithm and several heuristics are exploited. The worst case error performance ratios of the heuristics are also derived.     

极小化最大完工时间的单机分批加工问题

本文考虑极小化最大完工时间的单机分批加工问题．设有n个工件和一台批加工机器．每个工件有一个释放时间和一个加工时间．批加工机器可以同时加工b(b相似文献