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REVIEW FOR EXAM 1

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REVIEW FOR EXAM 1 Chapters 3, 4, 5 & 6 – PowerPoint PPT presentation

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Title: REVIEW FOR EXAM 1


1
REVIEW FOR EXAM 1
  • Chapters 3, 4, 5 6

2
Why models?
  • Because all decisions are made, all actions are
    taken on the basis of models
  • We dont have a choice

3
Is model-building art or science?
  • A little of both

4
Three Decision Environments
  • Certainty
  • Risk Uncertainty
  • Change, complexity and causality

5
How do we determine which model paradigm to use?
  • Optimization models or simulation models
  • Deterministic models or probabilistic ones
  • Static models or dynamic ones
  • Linear models or nonlinear ones

6
How do we decide what to include in our model?
7
Methodology for Model Formulation
  • Problem Definition
  • Mathematical Modeling
  • Solution of the Model
  • Communication/Marketing of the Results

8
Chapter 3
  • Simple model formulation
  • Where solutions occur on the feasible region
    defined by the constraints
  • The optimal solution is always ______.
  • Sensitivity
  • Ranging reports
  • reduced costs
  • shadow prices
  • complementary slackness

9
Reduced cost
  • If a decision variable is in the basis, its
    reduced cost is ????
  • If a decision variable has an objective
    coefficient of 10 and a reduced cost of 5
  • Is the variable in solution?
  • If the obj. coeff is taken to 7, what happens?
  • If the obj. coeff is taken to 4, what happens?

10
Shadow price
  • Measures the degree of sensitivity of the Obj.
    Fcn. to a unit change in a constraint RHS
  • If a constraint has slack or surplus, then its
    shadow price is?
  • If a constraint has a shadow price of 5 and its
    RHS is increased by 10 (within the range of
    feasibility), then the obj. fcn. Will increase by?

11
Range of feasibility
  • Applies to obj fcn, constraints, technology
    coefficients, WHAT???
  • Remember these are ranges in which the solution
    is unchanged
  • However, when you change RHS, variables in
    solution may have their values change

12
Range of Optimality
  • Again, this is a range over which the same
    variables remain in solution
  • When within the range, do the basis variables
    (the variables in solution) change?
  • However, the objective function value may change,
    right?
  • Every time? For any coefficient?
  • Look at the Practice exam
  • Questions 55, 56

13
Chapter 4--Robust LP
  • More substantial models
  • Definitional variables
  • resulting in equality constraints that must be
    added
  • Interpretation of the output
  • Look at the exam
  • Questions 59, 60
  • Minimization models

14
Chapter 6--Network Optimization
  • Always an underlying network
  • a decision variable for each arc
  • a constraint for each node
  • fast solution algorithms can solve large models
    on small computers
  • Guaranteed integer solution values
  • Always an associated linear programming model

15
Frequency
  • 80 of math programming probs are networks
  • Concerned with the infrastructure that we.
  • drive on
  • ride on
  • talk on
  • telecommmunicate on
  • e-anything on

16
Network Model types
  • Transportation
  • Transhipment
  • Assignment
  • Production/Scheduling
  • Shortest route
  • Minimal spanning tree
  • Traveling salesman
  • Maximal flow

17
Transportation
  • 10 sources of supply, 15 destinations of demand
  • How many decision variables?
  • How many constraints?
  • Solution algorithm gives us sensitivity
    information

18
Transhipment
  • Essentially a transportation problem with
    intervening transhipment nodes
  • Solved using the out-of-kilter algorithm
    (generalized network model in WINQSB)

19
Assignment
  • A special case of the transportation problem with
    demand and supply numbers of 1
  • But solvable with its own Hungarian assignment
    algorithm

20
Production/Scheduling
  • Formulated as a Transportation problem
  • Tells you where and when to produce and when to
    ship so as to minimize costs, or maximize profits
    at the demand nodes
  • SEE THE EXAM

21
Shortest Route
  • Should be able to find it for small models
  • Use the node-labeling technique I showed you in
    class

22
Minimal spanning tree
  • To find what??
  • Use the greedy algorithm

23
Traveling salesman
  • Hard to solve algorithmically
  • Gives us the minimum distance or minimum cost
    tour
  • that takes us through each node (city) exactly
    once
  • 20 city problems have 500,000 constraints--to
    prevent subtours

24
Maximal flow
  • To find the bottleneck in an infrastructure

25
Chapter 5--Integer programming
  • Hardest to solve, algorithmically
  • Rounding??
  • Sensitivity data--NO

26
Problem types
  • Facility location
  • Fixed charge
  • Either/or
  • Go/no go
  • Discrete design--OPTIMIZED CURRICULUM
  • Capital budgeting

27
Model types
  • Pure
  • Mixed
  • Binary

28
Algorithm types
  • Cutting planes--for pure problems
  • Uses Simplex
  • Branch Bound--for everything else
  • Uses simplex

29
What else??
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