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Modeling and Analysis Week 8 Modeling and Analysis Topics 2 Modeling for MSS (a critical component) Static and dynamic models Treating certainty, uncertainty, and risk Influence diagrams (in the posted PDF file) MSS modeling in spreadsheets Decision analysis of a few alternatives (with decision tables and decision trees) Optimization via mathematical programming Heuristic programming Simulation Model base management DSS Modeling A key element in most DSS Leads to reduced cost and increased revenue DuPont Simulates Rail Transportation System and Avoids Costly Capital Expenses Procter & Gamble uses several DSS models collectively to support strategic decisions 3 Locating distribution centers, assignment of DCs to warehouses/customers, forecasting demand, scheduling production per product type, etc. Fiat, Pillowtex (…operational efficiency)… P&G Used optimization models to redesign its distribution system Several models used: 4 Generating model (algorithm) to estimate transportation costs Demand forecasting model (statistics based) Distribution center location model Linear programming transportation model to determine best shipping Financial and risk simulation model that also considers some qualitative factors GIS for a user interface Some built in the DSS some external and some accessed as needed 500 employees involved over the course of a year AMR 5 Used models to optimize the altitude ascent and descent profile for planes Saved millions in fuel cost per week Part of SABRE system that used models extensively incremental revenues eventually exceeded $1 billion annually Major Modeling Issues Problem identification and environmental analysis (information collection) Variable identification Forecasting/predicting 6 More information leads to better prediction Multiple models: A DSS can include several models, each of which represents a different part of the decision-making problem Influence diagrams, cognitive maps Categories of models >>> Model management Knowledge based modeling Influence Diagrams Graphical representations of a model “Model of a model” A tool for visual communication Some influence diagram packages create and solve the mathematical model Framework for expressing DSS model relationships Rectangle = a decision variable Circle = uncontrollable or intermediate variable Oval = result (outcome) variable: intermediate or final Variables are connected with arrows indicates the direction of influence (relationship) 7 Influence Diagrams: Relationships CERTAINTY Amount in CDs Interest Collected UNCERTAINTY Price Sales The shape of the arrow indicates the type of relationship RANDOM (risk) variable: Place a tilde (~) above the variable’s name ~ Demand Sales 8 Influence Diagrams: Example An influence diagram for the profit model Unit Price ~ Amount used in Advertisement Income Units Sold Profit Profit = Income – Expense Unit Cost Income = UnitsSold * UnitPrice UnitsSold = 0.5 * Advertisement Expense Expenses = UnitsCost * UnitSold + FixedCost Fixed Cost 9 Expenses Influence Diagrams: Software Analytica, Lumina Decision Systems DecisionPro, Vanguard Software Co. Integrates influence diagrams and Excel, also supports Monte Carlo simulations PrecisionTree, Palisade Co. 10 Includes influence diagrams, decision trees and simulation Definitive Scenario, Definitive Software Supports hierarchical (tree structured) diagrams DATA Decision Analysis, TreeAge Software Supports hierarchical (multi-level) diagrams Creates influence diagrams and decision trees directly in an Excel spreadsheet Analytica Influence Diagram of a Marketing Problem: The Marketing Model 11 Analytica: The Price Submodel 12 Analytica: The Sales Submodel 13 Categories of Models Category 14 Objective Techniques Optimization of problems with few alternatives Find the best solution from a small number of alternatives Decision tables, decision trees Optimization via algorithm Find the best solution from a large number of alternatives using a step-by-step process Linear and other mathematical programming models Optimization via an analytic formula Find the best solution in one step using a formula Some inventory models Simulation Find a good enough solution by experimenting with a dynamic model of the system Several types of simulation Heuristics Find a good enough solution using “common-sense” rules Heuristic programming and expert systems Predictive and other models Predict future occurrences, what-if analysis, … Forecasting, Markov chains, financial, … Static and Dynamic Models Static Analysis Dynamic Analysis 15 Single snapshot of the situation Single interval Steady state Dynamic models Evaluate scenarios that change over time Time dependent Represents trends and patterns over time More realistic: Extends static models Mathematical Models 4 basic components Result variables Decision variables 16 constraints Intermediate result variables Alternative courses of action Uncontrollable variables Reflect the level of effectiveness of a system Intermediate outcomes Mathematical relationships link the components together Examples of the Components of Models 17 Area Decision variables Result variables Uncontrollable variables Financial investment Investment alternatives and amounts Total profit, risk, ROI, EPS, liquidity Inflation rate, prime rate, competition Marketing Ad budget, where to advertise Market share, Customer’s income, customer satisfaction competitor’s actions Manufacturing What and how much to produce, inventory levels Total cost, quality level Machine capacity, material prices Accounting Audit schedule Error rate Tax rates, legal requirements Transportation Shipments schedule, use of smart cards Total transportation cost Delivery distance, regulations Services Staffing levels Customer satisfaction Demand for services Certainty, Uncertainty and Risk 18 Decision Making: Treating Certainty, Uncertainty and Risk Certainty Models Uncertainty Several outcomes for each decision Probability of each outcome is unknown Knowledge would lead to less uncertainty Risk analysis (probabilistic decision making) 19 Assume complete knowledge All potential outcomes are known May yield optimal solution Probability of each of several outcomes occurring Level of uncertainty => Risk (expected value) DSS Modeling with Spreadsheets Spreadsheet: most popular end-user modeling tool Flexible and easy to use Powerful functions 20 Add-in functions and solvers Programmability (via macros) What-if analysis Goal seeking Simple database management Seamless integration of model and data Incorporates both static and dynamic models Examples: Microsoft Excel, Lotus 1-2-3 Excel spreadsheet - static model example: Simple loan calculation of monthly payments F P(1 i )n i (1 i )n A P n ( 1 i ) 1 21 Excel spreadsheet Dynamic model example: Simple loan calculation of monthly payments and effects of prepayment 22 Decision Analysis: A Few Alternatives Single Goal Situations Decision tables Decision trees 23 Multiple criteria decision analysis Features include decision variables (alternatives), uncontrollable variables, result variables Graphical representation of relationships Multiple criteria approach Demonstrates complex relationships Cumbersome, if many alternatives exists Decision Tables Investment example One goal: maximize the yield after one year Yield depends on the status of the economy (the state of nature) 24 Solid growth Stagnation Inflation Investment Example: Possible Situations 1. If solid growth in the economy, bonds yield 12%; stocks 15%; time deposits 6.5% 2. If stagnation, bonds yield 6%; stocks 3%; time deposits 6.5% 3. If inflation, bonds yield 3%; stocks lose 2%; time deposits yield 6.5% 25 Investment Example: Decision Table Payoff Decision variables (alternatives) Uncontrollable variables (states of economy) Result variables (projected yield) Tabular representation: 26 Investment Example: Treating Uncertainty Optimistic approach Pessimistic approach Treating Risk: 27 Use known probabilities Risk analysis: compute expected values Decision Analysis: A Few Alternatives Other methods of treating risk Multiple goals 28 Simulation, Certainty factors, Fuzzy logic Yield, safety, and liquidity DSS Mathematical Models Non-Quantitative Models (Qualitative) Captures symbolic relationships between decision variables, uncontrollable variables and result variables Quantitative Models: Mathematically links decision variables, uncontrollable variables, and result variables Decision variables describe alternative choices. Uncontrollable variables are outside decision-maker’s control Result variables are dependent on chosen combination of decision variables and uncontrollable variables Uncontrollable Variables Decision Variables Mathematical Relationships Intermediate Variables 29 Result Variables Optimization via Mathematical Programming Mathematical Programming A family of tools designed to help solve managerial problems in which the decision maker must allocate scarce resources among competing activities to optimize a measurable goal Optimal solution: The best possible solution to a modeled problem 30 Linear programming (LP): A mathematical model for the optimal solution of resource allocation problems. All the relationships are linear LP Problem Characteristics 1. Limited quantity of economic resources 2. Resources are used in the production of products or services 3. Two or more ways (solutions, programs) to use the resources 4. Each activity (product or service) yields a return in terms of the goal 5. Allocation is usually restricted by constraints 31 Linear Programming Steps 1. Identify the … Decision variables Objective function Objective function coefficients Constraints 2. Represent the model 32 Capacities / Demands LINDO: Write mathematical formulation EXCEL: Input data into specific cells in Excel 3. Run the model and observe the results Line LP Example The Product-Mix Linear Programming Model MBI Corporation Decision: How many computers to build next month? Two types of mainframe computers: CC7 and CC8 Constraints: Labor limits, Materials limit, Marketing lower limits CC7 CC8 Labor (days) 300 500 Materials ($) 10,000 15,000 Units 1 Units 1 Profit ($) 8,000 12,000 Rel <= <= >= >= Max Limit 200,000 /mo 8,000,000 /mo 100 200 Objective: Maximize Total Profit / Month 33 LP Solution 34 LP Solution 35 Decision Variables: X1: unit of CC-7 X2: unit of CC-8 Objective Function: Maximize Z (profit) Z=8000X1+12000X2 Subject To 300X1 + 500X2 200K 10000X1 + 15000X2 8000K X1 100 X2 200 Sensitivity, What-if, and Goal Seeking Analysis Sensitivity What-if Assesses solutions based on changes in variables or assumptions (scenario analysis) Goal seeking 36 Assesses impact of change in inputs on outputs Eliminates or reduces variables Can be automatic or trial and error Backwards approach, starts with goal Determines values of inputs needed to achieve goal Example is break-even point determination Heuristic Programming Cuts the search space Gets satisfactory solutions more quickly and less expensively Finds good enough feasible solutions to very complex problems Heuristics can be 37 Quantitative Qualitative (in ES) Traveling Salesman Problem >>> Heuristic Programming - SEARCH 38 Traveling Salesman Problem What is it? 39 A traveling salesman must visit customers in several cities, visiting each city only once, across the country. Goal: Find the shortest possible route Total number of unique routes (TNUR): TNUR = (1/2) (Number of Cities – 1)! Number of Cities TNUR 5 12 6 60 9 20,160 20 1.22 1018 When to Use Heuristics When to Use Heuristics Inexact or limited input data Complex reality Reliable, exact algorithm not available Computation time excessive For making quick decisions Limitations of Heuristics 40 Cannot guarantee an optimal solution Simulation 41 Technique for conducting experiments with a computer on a comprehensive model of the behavior of a system Frequently used in DSS tools Major Characteristics of Simulation ! 42 Imitates reality and capture its richness Technique for conducting experiments Descriptive, not normative tool Often to “solve” very complex problems Simulation is normally used only when a problem is too complex to be treated using numerical optimization techniques Advantages of Simulation 43 The theory is fairly straightforward Great deal of time compression Experiment with different alternatives The model reflects manager’s perspective Can handle wide variety of problem types Can include the real complexities of problems Produces important performance measures Often it is the only DSS modeling tool for non-structured problems Limitations of Simulation 44 Cannot guarantee an optimal solution Slow and costly construction process Cannot transfer solutions and inferences to solve other problems (problem specific) So easy to explain/sell to managers, may lead overlooking analytical solutions Software may require special skills Simulation Methodology Model real system and conduct repetitive experiments. Steps: 1. 2. 3. 4. 45 Define problem Construct simulation model Test and validate model Design experiments 5. Conduct experiments 6. Evaluate results 7. Implement solution Simulation Types Stochastic vs. Deterministic Simulation Time-dependent vs. Time-independent Simulation Time independent stochastic simulation via Monte Carlo technique (X = A + B) Discrete event vs. Continuous simulation Simulation Implementation 46 In stochastic simulations: We use distributions (Discrete or Continuous probability distributions) Visual simulation Visual Interactive Modeling (VIM) / Visual Interactive Simulation (VIS) Visual interactive modeling (VIM) Also called 47 Visual interactive problem solving Visual interactive modeling Visual interactive simulation Uses computer graphics to present the impact of different management decisions Often integrated with GIS Users perform sensitivity analysis Static or a dynamic (animation) systems Model Base Management MBMS: capabilities similar to that of DBMS But, there are no comprehensive model base management packages Each organization uses models somewhat differently There are many model classes 48 Within each class there are different solution approaches Relations MBMS Object-oriented MBMS