1 / 13

IE 2030 Lecture 7 Decision Analysis

Dive into decision analysis and utility concepts like expected value, minimax criterion, and decision trees. Learn to navigate risk aversion, value of information, and sensitivity analysis. Explore scenarios of party planning and weather predictions to grasp practical applications. Enhance your decision-making skills and understand the impact of different forecasting probabilities. Gain insights on maximizing outcomes and managing uncertainties effectively.

robinsondonald
Download Presentation

IE 2030 Lecture 7 Decision Analysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. IE 2030 Lecture 7Decision Analysis Expected Value Utility Decision Trees

  2. Introduction to PERT Decision tree example: party planning Concepts: Uncertainty Minimax Criterion Expected Value Criterion Risk Aversion Risk Neutral, Risk Averse, Risk Seeking Utility Outcome and Decision Decision Tree Value of information Sensitivity analysis Topics Today IE 2030 Lecture 7

  3. 900 Clear .6 Party Example (R. Howard) Rain .4 100 OUT IN 600 Clear .6 Rain .4 500

  4. Decision Trees • Use different shapes for decisions and uncertain branchings • Compute from the leaves back to the root • Use expected values • When you make a decision, you know the history, the path from the root to the decision point

  5. Minimax or Maximin Criterion • Choice to make worst possible outcome as good as possible • Usually gives poor decisions because excessively risk averse • Fearful people use this criterion • Are you afraid of being judged badly afterwards? • Decisions vs. Outcomes Probability of regret

  6. Maximin and other Payoff Criteria • Who is your opponent? • An indifferent Nature… • use probability, consider expected value • A hostile or vengeful Fate... • Use Maximin, consider a psychiatrist • A self-interested person… • use game theory and economics • A hostile person who desires your failure... • use game theory, maximin, consider an intermediary or arbitrator

  7. Never attribute to malice, what can be adequately explained by stupidity Trust and Credibility

  8. Risk aversion • Choice of sure thing versus lottery • Size • Gain or loss • Expected value criterion • Utility

  9. It is expensive to be poor • Companies don’t like to risk going out of business • Wealthier people can afford to gamble • get higher average returns • We model this by setting very low utility values on outcomes below “danger” threshholds • Can cause problems in environmental decisions. Is going bankrupt as bad as destroying the world’s ecology?

  10. Decision Analysis: Value of Information (based on R. Howard’s notes) 900 out Clear .6 in 600 Rain .4 100 out in 500

  11. Value of Information • Expected value of a clairvoyant (perfect information) is an upper bound on the value of any forecast • Analysis assumes your probabilities are correct • Must use conditional probability to find probabilities of imperfect forecasts

  12. Forecast probabilities: simple example • Consistently 90% accurate forecast: whatever the forecast, it is correct w.p..9 • If it rains 50% of the time, forecast rain w.p. .5 • If it rains 90% of time, forecast rain w.p. 1 • If it rains 100% of time, consistent 90% accuracy is impossible • Many forecasts have inconsistent accuracy

  13. Forecast probabilities: party example • Consistently 90% accurate forecast: whatever the forecast, it is correct w.p..9 • If it rains 40% of time, forecast rain w.p. q. • .9q + .1(1-q) = 0.4 • LHS = Prob(rain), calculated over event partition: {predict rain, don’t predict rain} • You must decide what to do for each possible forecast • What if the forecast were 0% accurate?

More Related