scholarly journals A Multi-Depot Vehicle Routing Problem with Stochastic Road Capacity and Reduced Two-Stage Stochastic Integer Linear Programming Models for Rollout Algorithm

Mathematics ◽  
2021 ◽  
Vol 9 (13) ◽  
pp. 1572
Author(s):  
Wadi Khalid Anuar ◽  
Lai Soon Lee ◽  
Hsin-Vonn Seow ◽  
Stefan Pickl
Keyword(s):  
Linear Programming ◽  
Vehicle Routing ◽  
Integer Linear Programming ◽  
Vehicle Routing Problem ◽  
Programming Models ◽  
Dynamic Vehicle Routing ◽  
Two Stage ◽  
Routing Problem ◽  
Road Capacity ◽  
Rollout Algorithm

A matheuristic approach based on a reduced two-stage Stochastic Integer Linear Programming (SILP) model is presented. The proposed approach is suitable for obtaining a policy constructed dynamically on the go during the rollout algorithm. The rollout algorithm is part of the Approximate Dynamic Programming (ADP) lookahead solution approach for a Markov Decision Processes (MDP) framed Multi-Depot Dynamic Vehicle Routing Problem with Stochastic Road Capacity (MDDVRPSRC). First, a Deterministic Multi-Depot VRP with Road Capacity (D-MDVRPRC) is presented. Then an extension, MDVRPSRC-2S, is presented as an offline two-stage SILP model of the MDDVRPSRC. These models are validated using small simulated instances with CPLEX. Next, two reduced versions of the MDVRPSRC-2S model (MDVRPSRC-2S1 and MDVRPSRC-2S2) are derived. They have a specific task in routing: replenishment and delivering supplies. These reduced models are to be utilised interchangeably depending on the capacity of the vehicle, and repeatedly during the execution of rollout in reinforcement learning. As a result, it is shown that a base policy consisting of an exact optimal decision at each decision epoch can be obtained constructively through these reduced two-stage stochastic integer linear programming models. The results obtained from the resulting rollout policy with CPLEX execution during rollout are also presented to validate the reduced model and the matheuristic algorithm. This approach is proposed as a simple implementation when performing rollout for the lookahead approach in ADP.

scholarly journals Mixed Integer Linear Programming Models to Solve a Real-Life Vehicle Routing Problem with Pickup and Delivery

2021 ◽  
Vol 11 (20) ◽  
pp. 9551
Author(s):  
Ali Louati ◽  
Rahma Lahyani ◽  
Abdulaziz Aldaej ◽  
Racem Mellouli ◽  
Muneer Nusir
Keyword(s):  
Linear Programming ◽  
Vehicle Routing ◽  
Integer Linear Programming ◽  
Vehicle Routing Problem ◽  
Mixed Integer Linear Programming ◽  
Real Life ◽  
Mixed Integer ◽  
Pickup And Delivery ◽  
Routing Problem

This paper presents multiple readings to solve a vehicle routing problem with pickup and delivery (VRPPD) based on a real-life case study. Compared to theoretical problems, real-life ones are more difficult to address due to their richness and complexity. To handle multiple points of view in modeling our problem, we developed three different Mixed Integer Linear Programming (MILP) models, where each model covers particular constraints. The suggested models are designed for a mega poultry company in Tunisia, called CHAHIA. Our mission was to develop a prototype for CHAHIA that helps decision-makers find the best path for simultaneously delivering the company’s products and collecting the empty boxes. Based on data provided by CHAHIA, we conducted computational experiments, which have shown interesting and promising results.

scholarly journals Penentuan Rute Distribusi Menggunakan Model Integer Linear Programming dengan Metode Branch and Bound

2020 ◽  
Vol 1 (01) ◽  
pp. 69-79
Author(s):  
Gratia Melina Sari ◽  
Rainisa Maini Heryanto ◽  
Santoso Santoso
Keyword(s):  
Linear Programming ◽  
Vehicle Routing ◽  
Branch And Bound ◽  
Integer Linear Programming ◽  
Vehicle Routing Problem ◽  
Time Windows ◽  
Routing Problem ◽  
Capacitated Vehicle Routing Problem ◽  
Capacitated Vehicle

Biaya distribusi merupakan biaya yang dapat diminimalisasi perusahaan. Biaya distribusi dalam jaringan distribusi memiliki kontribusi 10% sampai 20% dari biaya akhir barang. Salah satu cara untuk meminimalisasi biaya distribusi adalah menentukan rute distribusi yang optimal yang memberikan total biaya minimum. Penelitian ini membahas penentuan rute distribusi menggunakan model Integer Linear Programming untuk menyelesaikan masalah Capacitated Vehicle Routing Problem with Time Windows (CVRPTW). Metode yang digunakan untuk memecahkan masalah adalah Branch and Bound dengan bantuan MATLAB. Model matematis yang digunakan adalah model matematis total biaya perjalanan. Studi kasus yang digunakan dalam perhitungan adalah PT XYZ, perusahaan manufaktur cat yang melakukanpendistribusian produk dari gudang ke konsumen. Saat ini, kebijakan pemesanan dan pengiriman perusahaan membuat biaya distribusi tidak efisien dan terjadi gagal pengiriman. Penelitian ini memberikan 2 skenario usulan pengiriman. Pada skenario 1, pengiriman dilakukan sesuai dengan kebijakan pada perusahaan saat ini dengan mencari biaya optimal.Pada skenario 2, permintaan akan dikumpulkan pada hari Jumat dan pengiriman akan dilakukan pada minggu berikutnya. Dari hasil perhitungan didapatkan total biaya per bulan pada rute aktual perusahaan adalah Rp. 1.349.053,49 sedangkan skenario 1 memberikan hasil Rp. 1.067.207,73 (penghematan 20,89%) dan skenario 2 memberikan hasil Rp. 602.105,21(penghematan 55,37%). Kata kunci: Biaya; Branch and Bound; CVRPTW; Distribusi; Integer Linear Programming;Rute

scholarly journals A mixed-integer linear programming model for the selective full-truckload multi-depot vehicle routing problem with time windows

2021 ◽  
Vol 10 (4) ◽  
pp. 471-486 ◽  
Author(s):  
Karim EL Bouyahyiouy ◽  
Adil Bellabdaoui
Keyword(s):  
Linear Programming ◽  
Vehicle Routing ◽  
Integer Linear Programming ◽  
Vehicle Routing Problem ◽  
Mixed Integer Linear Programming ◽  
Programming Model ◽  
Time Windows ◽  
Mixed Integer ◽  
Data Set ◽  
Routing Problem

This article has studied a full truckload transportation problem in the context of an empty return scenario, particularly an order selection and vehicle routing problem with full truckload, multiple depots and time windows (SFTMDVRPTW). The aim is to develop a solution where a set of truck routes serves a subset of selected transportation demands from a number of full truckload orders to maximize the total profit obtained from those orders. Each truck route is a chain of selected demands to serve, originating at a departure point and terminating at an arriving point of trucks in a way that respects the constraints of availability and time windows. It is not mandatory to serve all orders, and only the profitable ones are selected. In this study, we have formulated the SFTMDVRPTW as a mixed-integer linear programming (MILP) model. Finally, Computational results are conducted on a new data set that contains thirty randomly generated problem instances ranging from 16 to 30 orders using the CPLEX software. The findings prove that our model has provided good solutions in a reasonable time.

scholarly journals Analysis of Mixed-Integer Linear Programming Formulations for a Fuel-Constrained Multiple Vehicle Routing Problem

2017 ◽  
Vol 05 (04) ◽  
pp. 197-207 ◽  
Author(s):  
Kaarthik Sundar ◽  
Saravanan Venkatachalam ◽  
Sivakumar Rathinam
Keyword(s):  
Linear Programming ◽  
Vehicle Routing ◽  
Integer Linear Programming ◽  
Vehicle Routing Problem ◽  
Mixed Integer Linear Programming ◽  
Optimal Solution ◽  
Branch And Cut ◽  
Mixed Integer ◽  
Computational Results ◽  
Routing Problem

This paper addresses a fuel-constrained, multiple vehicle routing problem (FCMVRP) in the presence of multiple refueling stations. We are given a set of targets, a set of refueling stations, and a depot where [Formula: see text] vehicles are stationed. The vehicles are allowed to refuel at any refueling station, and the objective of the problem is to determine a route for each vehicle starting and terminating at the depot, such that each target is visited by at least one vehicle, the vehicles never run out of fuel while traversing their routes, and the total travel cost of all the routes is a minimum. We present four new mixed-integer linear programming (MILP) formulations for the problem. These formulations are compared both analytically and empirically, and a branch-and-cut algorithm is developed to compute an optimal solution. Extensive computational results on a large class of test instances that corroborate the effectiveness of the algorithm are also presented.

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