We present a new dominance rule by considering the time-dependent orderings between each pair of jobs for the single machine total weighted tardiness problem with release dates. The proposed dominance rule provides a sufficient condition for local optimality. Therefore, if any sequence violates the dominance rule then switching the violating jobs either lowers the total weighted tardiness or leaves it unchanged. We introduce an algorithm based on the dominance rule, which is compared to a number of competing heuristics for a set of randomly generated problems. Our computational results indicate that the proposed algorithm dominates the competing algorithms in all runs, therefore it can improve the upper bounding scheme in any enumerative al...
International audienceWe tackle precedence-constrained sequencing on a single machine in order to mi...
We address the problem of determining schedules for static, single-machine scheduling problems where...
This paper presents an exact algorithm for the single machine total tardiness problem (1//∑ T1). We ...
Cataloged from PDF version of article.We present a new dominance rule by considering the time-depend...
This is the author's version of the work. It is posted here by permission of Taylor & Francis for pe...
We address the parallel machine total weighted tardiness scheduling problem with release dates. We d...
We propose a new dominance rule that provides a sufficient condition for local optimality for the 1∥...
We present a neuro-dommance rule for single machine total weighted tardiness problem with unequal re...
A neuro-dominance rule (NDR) for single machine total weighted tardiness problem with unequal releas...
This paper deals with the parallel-machine scheduling problem with the aim of minimizing t...
AbstractThis paper surveys algorithms for the problem of scheduling jobs on a single machine to mini...
In this study, the single-machine total weighted tardiness scheduling problem with double due date h...
International audienceWe study the one-machine scheduling problem with release dates and we look at ...
Abstract The dominance test is a bounding operation in branch-and-bound algorithms, where each sub-p...
Earlier research by Kanet [11] has provided a number of new theorems for deciding precedence between...
International audienceWe tackle precedence-constrained sequencing on a single machine in order to mi...
We address the problem of determining schedules for static, single-machine scheduling problems where...
This paper presents an exact algorithm for the single machine total tardiness problem (1//∑ T1). We ...
Cataloged from PDF version of article.We present a new dominance rule by considering the time-depend...
This is the author's version of the work. It is posted here by permission of Taylor & Francis for pe...
We address the parallel machine total weighted tardiness scheduling problem with release dates. We d...
We propose a new dominance rule that provides a sufficient condition for local optimality for the 1∥...
We present a neuro-dommance rule for single machine total weighted tardiness problem with unequal re...
A neuro-dominance rule (NDR) for single machine total weighted tardiness problem with unequal releas...
This paper deals with the parallel-machine scheduling problem with the aim of minimizing t...
AbstractThis paper surveys algorithms for the problem of scheduling jobs on a single machine to mini...
In this study, the single-machine total weighted tardiness scheduling problem with double due date h...
International audienceWe study the one-machine scheduling problem with release dates and we look at ...
Abstract The dominance test is a bounding operation in branch-and-bound algorithms, where each sub-p...
Earlier research by Kanet [11] has provided a number of new theorems for deciding precedence between...
International audienceWe tackle precedence-constrained sequencing on a single machine in order to mi...
We address the problem of determining schedules for static, single-machine scheduling problems where...
This paper presents an exact algorithm for the single machine total tardiness problem (1//∑ T1). We ...