Deck 10: Distribution Network Models

If a transportation problem has four origins and five destinations,the LP formulation of the problem will have nine constraints.

Converting a transportation problem LP from cost minimization to profit maximization requires only changing the objective function;the conversion does not affect the constraints.

The direction of flow in the shortest-route problem is always out of the origin node and into the destination node.

When the number of agents exceeds the number of tasks in an assignment problem,one or more dummy tasks must be introduced in the LP formulation or else the LP will not have a feasible solution.

A transportation problem with 3 sources and 4 destinations will have 7 variables in the objective function.

The capacitated transportation problem includes constraints which reflect limited capacity on a route.

A transportation problem with 3 sources and 4 destinations will have 7 decision variables.

The shortest-route problem is a special case of the transshipment problem.

Flow in a transportation network is limited to one direction.

The assignment problem is a special case of the transportation problem in which all supply and demand values equal one.

The maximal flow problem can be formulated as a capacitated transshipment problem.

When a route in a transportation problem is unacceptable,the corresponding variable can be removed from the LP formulation.

Transshipment problem allows shipments both in and out of some nodes while transportation problems do not.

A transshipment problem is a generalization of the transportation problem in which certain nodes are neither supply nodes nor destination nodes.

In the general assignment problem,one agent can be assigned to several tasks.

Whenever total supply is less than total demand in a transportation problem,the LP model does not determine how the unsatisfied demand is handled.

In a transportation problem with total supply equal to total demand,if there are four origins and seven destinations,and there is a unique optimal solution,the optimal solution will utilize 11 shipping routes.

A transshipment constraint must contain a variable for every arc entering or leaving the node.

In the LP formulation of a maximal flow problem,a conservation-of-flow constraint ensures that an arc's flow capacity is not exceeded.

In a capacitated transshipment problem,some or all of the transfer points are subject to capacity restrictions.

Draw the network for this transportation problem.

Write the linear program for this transshipment problem.

A network of railway lines connects the main lines entering and leaving a city.Speed limits,track reconstruction,and train length restrictions lead to the flow diagram below,where the numbers represent how many cars can pass per hour.Formulate an LP to find the maximal flow in cars per hour from Node 1 to Node F.
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Write the LP formulation for this transportation problem.

Peaches are to be transported from three orchard regions to two canneries.Intermediate stops at a consolidation station are possible.
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Shipment costs are shown in the table below.Where no cost is given,shipments are not possible.Where costs are shown,shipments are possible in either direction.Draw the network model for this problem.

Show both the network and the linear programming formulation for this assignment problem.
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Find the maximal flow from node 1 to node 7 in the following network.

The following table shows the unit shipping cost between cities,the supply at each source city,and the demand at each destination city.The Management Scientist solution is shown.Report the optimal solution.
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TRANSPORTATION PROBLEM
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Fodak must schedule its production of camera film for the first four months of the year.Film demand (in 1,000s of rolls)in January,February,March and April is expected to be 300,500,650 and 400,respectively.Fodak's production capacity is 500 thousand rolls of film per month.The film business is highly competitive,so Fodak cannot afford to lose sales or keep its customers waiting.Meeting month i 's demand with month i +1's production is unacceptable.
Film produced in month i can be used to meet demand in month i or can be held in inventory to meet demand in month i +1 or month i +2 (but not later due to the film's limited shelflife).There is no film in inventory at the start of January.
The film's production and delivery cost per thousand rolls will be $500 in January and February.This cost will increase to $600 in March and April due to a new labor contract.Any film put in inventory requires additional transport costing $100 per thousand rolls.It costs $50 per thousand rolls to hold film in inventory from one month to the next.
a.Modeling this problem as a transshipment problem,draw the network representation.
b.Formulate and solve this problem as a linear program.

Consider the network below.Formulate the LP for finding the shortest-route path from node 1 to node 7.
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Draw the network for this assignment problem.

Consider the following shortest-route problem involving six cities with the distances given.Draw the network for this problem and formulate the LP for finding the shortest distance from City 1 to City 6.

A professor has been contacted by four not-for-profit agencies that are willing to work with student consulting teams.The agencies need help with such things as budgeting,information systems,coordinating volunteers,and forecasting.Although each of the four student teams could work with any of the agencies,the professor feels that there is a difference in the amount of time it would take each group to solve each problem.The professor's estimate of the time,in days,is given in the table below.Use the computer solution to see which team works with which project.
ASSIGNMENT PROBLEM
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The network below shows the flows possible between pairs of six locations.Formulate an LP to find the maximal flow possible from Node 1 to Node 6.
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A beer distributor needs to plan how to make deliveries from its warehouse (Node 1)to a supermarket (Node 7),as shown in the network below.Develop the LP formulation for finding the shortest route from the warehouse to the supermarket.
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Consider the following shortest-route problem involving seven cities.The distances between the cities are given below.Draw the network model for this problem and formulate the LP for finding the shortest route from City 1 to City 7.

After some special presentations,the employees of the AV Center have to move projectors back to classrooms.The table below indicates the buildings where the projectors are now (the sources),where they need to go (the destinations),and a measure of the distance between sites.
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Canning Transport is to move goods from three factories to three distribution centers.Information about the move is given below.Give the network model and the linear programming model for this problem.
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Shipping costs are:
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RVW (Restored Volkswagens)buys 15 used VW's at each of two car auctions each week held at different locations.It then transports the cars to repair shops it contracts with.When they are restored to RVW's specifications,RVW sells 10 each to three different used car lots.There are various costs associated with the average purchase and transportation prices from each auction to each repair shop.Also there are transportation costs from the repair shops to the used car lots.RVW is concerned with minimizing its total cost given the costs in the table below.

​Is it a coincidence to obtain integer solutions to network problems? Explain.

A foreman is trying to assign crews to produce the maximum number of parts per hour of a certain product.He has three crews and four possible work centers.The estimated number of parts per hour for each crew at each work center is summarized below.Solve for the optimal assignment of crews to work centers.

​How is the shortest-route problem like the transshipment problem?

​Explain how the general linear programming model of the assignment problem can be modified to handle problems
involving a maximization function,unacceptable assignments,and supply not equally demand.

​Define the variables and constraints necessary in the LP formulation of the transshipment problem.

​How is the assignment linear program different from the transportation model?

​Define the variables and constraints necessary in the LP formulation of the maximal flow problem.

​Explain what adjustments can be made to the transportation linear program when there are unacceptable routes.