A Decomposition Algorithm for the Consistent Traveling Salesman Problem with Vehicle Idling

Subramanyam, Anirudh; Gounaris, Chrysanthos E.

doi:10.1287/trsc.2017.0741

Cited by 21 publications

(10 citation statements)

References 40 publications

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“…To the best of our knowledge, most of these approaches are heuristic in nature, and are based on the concept of generating a "template" routing plan that services only the most frequent customers; the daily routes are derived from the template by appropriately modifying it in a way that satisfies all service consistency requirements, in particular, driver and arrival-time consistency. With a focus on trying to address purely the requirement of arrival-time consistency, exact solution approaches for the ConTSP (the singlevehicle variant of the ConVRP) have been proposed in [34,35]. Given our result from later in this paper that establishes equivalence between the TWAVRP and arrival-time ConVRP, one can, in principle, adapt any of the aforementioned methods to obtain algorithms for the TWAVRP by ignoring aspects of driver consistency, whenever applicable.…”

Section: Related Literaturementioning

confidence: 99%

“…Given our result from later in this paper that establishes equivalence between the TWAVRP and arrival-time ConVRP, one can, in principle, adapt any of the aforementioned methods to obtain algorithms for the TWAVRP by ignoring aspects of driver consistency, whenever applicable. We, however, shall choose the decomposition algorithm of [35] for this purpose, due to a number of reasons. First, because of its decomposition principle, it solves the original problem by breaking it down into period-specific routing problems with time windows.…”

Section: Related Literaturementioning

confidence: 99%

“…The second consequence of the equivalence between the TWAVRP and the arrival-time ConVRP is that any algorithm developed for the latter can be used to obtain solutions for the former. In this paper, we adapt a decomposition algorithm proposed in [35] for the Consistent Traveling Salesman Problem (ConTSP), the single-vehicle variant of the ConVRP that focuses purely on the aspect of arrival-time consistency, to obtain a new algorithm for the TWAVRP. Our method can be viewed as a scenario decomposition algorithm in the language of stochastic programming, and is not based on branch(-price)-and-cut that has been the de facto approach for solving TWAVRP models.…”

Section: Introductionmentioning

confidence: 99%

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A scenario decomposition algorithm for strategic time window assignment vehicle routing problems

Subramanyam

Wang

Gounaris

2018

Transportation Research Part B: Methodological

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We study the strategic decision-making problem of assigning time windows to customers in the context of vehicle routing applications that are affected by operational uncertainty. This problem, known as the Time Window Assignment Vehicle Routing Problem, can be viewed as a two-stage stochastic optimization problem, where time window assignments constitute first-stage decisions, vehicle routes adhering to the assigned time windows constitute second-stage decisions, and the objective is to minimize the expected routing costs. To that end, we develop in this paper a new scenario decomposition algorithm to solve the sampled deterministic equivalent of this stochastic model. From a modeling viewpoint, our approach can accommodate both continuous and discrete sets of feasible time window assignments as well as general scenario-based models of uncertainty for several routing-specific parameters, including customer demands and travel times, among others. From an algorithmic viewpoint, our approach can be easily parallelized, can utilize any available vehicle routing solver as a black box, and can be readily modified as a heuristic for large-scale instances. We perform a comprehensive computational study to demonstrate that our algorithm strongly outperforms all existing solution methods, as well as to quantify the trade-off between computational tractability and expected cost savings when considering a larger number of future scenarios during strategic time window assignment.

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Section: Related Literaturementioning

confidence: 99%

Section: Related Literaturementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A scenario decomposition algorithm for strategic time window assignment vehicle routing problems

Subramanyam

Wang

Gounaris

2018

Transportation Research Part B: Methodological

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“…Considered the situation that time windows might be across periods for the same location, the multi periods MTSP with time window constraints was modeled by Yapicioglu [14]. Subramaniam and Gounaris extended the definition of the TSP with time windows to allow a waiting time at each customer location and to incorporate maximum route duration limits [15]. Then, the constraints on a minimal or maximum number of nodes that a traveler must visit are also common [16]- [18].…”

Section: Introductionmentioning

confidence: 99%

Region Division in Logistics Distribution With a Two-Stage Optimization Algorithm

Qian

Zhao

2020

IEEE Access

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When facing the problem of modern logistics distribution under the large-scale network, the reasonable delivery task allocation has become an important part. For this problem, this paper uses the idea of decentralized control to establish a region division model in logistics distribution and transforms it into the multiple traveling salesmen problem with constraints of the road network and task allocation. The optimization goal of the model is to minimize the sum of the distances for logistics transport agents traveling all demand points in the system, with the constraints on the equilibrium of commodity requirements in each sub region. Then, a two-stage algorithm is proposed to solve the model. In the first stage, the K-means clustering method is used to obtain a highly feasible initial solution; In the second stage, the initial solution is optimized by the algorithm which is combining swap algorithm and tabu search algorithm. In the two-stage solution evaluation, the TSP solution based on the Lin-Kernighan algorithm is applied to obtain the sets of demand points with ranking of the route and the corresponding shortest distances for each divided sub region. Finally, to verify the effectiveness of the proposed model and solving method, two cases are presented in this paper. The region division method in logistics distribution proposed in this paper not only helps to reduce the total distance, but also helps to balance the workload of the logistics transport agents, thereby making great potential to reduce logistics costs and improving the overall operational efficiency of logistics distribution.

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“…Subramanyam and Gounaris (2016) present three mixedinteger, linear-programming (MILP) formulations and several classes of valid inequalities that are embedded in a branch-and-cut framework; they are able to solve all instances with up to five planning periods and 25 customers to guaranteed optimality and also some instances with up to 50 customers. Subramanyam and Gounaris (2017) decompose the problem into a sequence of single-period TSPs with time windows and solve the consistent TSP via branch and bound; they are able to solve instances with up to five planning periods and 100 customers, outperforming the results of Subramanyam and Gounaris (2016), but a few instances with 33 customers remain open.…”

Section: Introductionmentioning

confidence: 99%

Exact and Heuristic Solution of the Consistent Vehicle-Routing Problem

Goeke

Roberti

Schneider

2019

Transportation Science

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Providing consistent service by satisfying customer demands with the same driver (driver consistency) at approximately the same time (arrival-time consistency) allows companies in last-mile distribution to stand out among competitors. The consistent vehicle-routing problem (ConVRP) is a multiday problem addressing such consistency requirements along with traditional constraints on vehicle capacity and route duration. The literature offers several heuristics but no exact method for this problem. The state-ofthe-art exact technique to solve VRPs-column generation (CG) applied to route-based formulations in which columns are generated via dynamic programming-cannot be successfully extended to the ConVRP because the linear relaxation of route-based formulations is weak. We propose the first exact method for the ConVRP, which can solve medium-sized instances with five days and 30 customers. The method solves, via CG, a formulation in which each variable represents the set of routes assigned to a vehicle over the planning horizon. As an upper bounding procedure, we develop a large neighborhood search (LNS) featuring a repair procedure specifically designed to improve the arrival-time consistency of solutions. Used as stand-alone heuristic, the LNS is able to significantly improve the solution quality on benchmark instances from the literature compared with state-of-the-art heuristics.

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A Decomposition Algorithm for the Consistent Traveling Salesman Problem with Vehicle Idling

Cited by 21 publications

References 40 publications

A scenario decomposition algorithm for strategic time window assignment vehicle routing problems

A scenario decomposition algorithm for strategic time window assignment vehicle routing problems

Region Division in Logistics Distribution With a Two-Stage Optimization Algorithm

Exact and Heuristic Solution of the Consistent Vehicle-Routing Problem

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