Transshipment problem

The Transshipment problem has a long and rich history. It has its origins in medieval times when trading started to become a mass phenomenon. Firstly, obtaining the minimum-cost transportational route had been the main priority, however technological development slowly gave place to minimum-durational transportation problems. Transshipment problems form a subgroup of transportational problems, where transshipment is allowed, namely transportation can, or in certain cases has to shipped through intermediate nodes.

Overview

Transshipment or Transhipment is the shipment of goods or containers to an intermediate destination, and then from there to yet another destination. One possible reason is to change the means of transport during the journey (for example from ship transport to road transport), known as transloading. Another reason is to combine small shipments into a large shipment (consolidation), dividing the large shipment at the other end (deconsolidation). Transshipment usually takes place in transport hubs. Much international transshipment also takes place in designated customs areas, thus avoiding the need for customs checks or duties, otherwise a major hindrance for efficient transport.

Formulation of the problem

A few initial assumptions are required in order to formulate the transshipment problem completely:

Notations

Mathematical formulation of the problem

The goal is to minimize \sum\limits_{i=1}^m \sum\limits_{j=1}^n t_{i,j} x_{i,j} subject to:

Solution

Since in most cases an explicit expression for the objective function does not exist, an alternative method is suggested by Rajeev and Satya. The method uses two consecutive phases to reveal the minimal durational route from the origins to the destinations. The first phase is willing to solve n\cdot m time-minimizing problem, in each case using the remained n+m-2 intermediate nodes as transshipment points. This also leads to the minimal-durational transportation between all sources and destinations. During the second phase a standard time-minimizing problem needs to be solved. The solution of the time-minimizing transshipment problem is the joint solution outcome of these two phases.

Phase 1

Since costs are independent from the shipped amount, in each individual problem one can normalize the shipped quantity to 1. The problem now is simplified to an assignment problem from i to m+j. Let x'_{r,s}=1 be 1 if the edge between nodes r and s is used during the optimization, and 0 otherwise. Now the goal is to determine all x'_{r,s} which minimize the objective function:

T_{i,m+j}=\sum_{r=1}^{m+n}\sum_{s=1}^{m+n}{t_{r,s}\cdot x'_{r,s}},

such that

Corollary

Phase 2

During the second phase, a time minimization problem is solved with m origins and n destinations without transshipment. This phase differs in two main aspects from the original setup:

In mathematical form

The goal is to find x_{i,m+j}\geq 0 which minimize

z=max\left\{t'_{i,m+j}: x_{i,m+j}>0\;\; (i=1\ldots m,\; j=1\ldots n)\right\},
such that

This problem is easy to be solved with the method developed by Prakash. The set \left\{t'_{i,m+j}, i=1\ldots m,\; j=1\ldots n\right\} needs to be partitioned into subgroups L_k, k=1\ldots q, where each L_k contain the t'_{i,m+j}-s with the same value. The sequence L_k is organized as L_1 contains the largest valued t'_{i,m+j}'s L_2 the second largest and so on. Furthermore, M_k positive priority factors are assigned to the subgroups \sum_{L_k}{x_{i,m+j}}, with the following rule:

\alpha M_k-\beta M_{k+1}=\left\{\begin{array}{cc}-ve, & if\; \alpha<0\\ ve, & if\; \alpha>0 \end{array}\right.

for all \beta. With this notation the goal is to find all x_{i,m+j} which minimize the goal function

z_1=\sum_{k=1}^{q}{M_k}\sum_{L_k}{x_{i,m+j}}

such that

Extension

Some authors such as Das et al (1999) and Malakooti (2013) have considered multi-objective Transshipment problem.

Sources

References

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