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Decision Making as Constrained Optimization. Specification of Objective Function Decision Rule Identification of Constraints. Where do decision rules come from?. They are learned by experience “learning by getting hurt” by instruction “learning by being told” They are induced
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Decision Making as Constrained Optimization • Specification of Objective Function Decision Rule • Identification of Constraints
Where do decision rules come from? • They are learned • by experience • “learning by getting hurt” • by instruction • “learning by being told” • They are induced • using logic, mathematics
Historical Example:The St. Petersburg Paradox • Game: • You get to toss a fair coin for as many times as you need to score a “head” (H) (on toss n, n from 1 to infinity) • Payoff: • You get $2 n • If you score H on toss 1, you get $2 • If you score H on toss 2, you get $4 • If you score H on toss 3, you get $8 • If you score H on toss 4, you get $16, etc. • Question: • How much are you willing to pay me in order to play this game for one round? • How do you decide???
Expected Value of Game • How much do you think you can expect to win in this game? • EV(X) = Sum over all i {xi p(x i)} • Expected Utility of Game • Daniel Bernoulli (1739) • Utility of wealth is not linear, but logarithmic • EU(X) = Sum over all i {u(xi) p(x i)} • Other decision rules??? • Minimum return (pessimist) rule: • pay no more than you can expect to get back in the worst case • Expectation heuristic (Treisman, 1986): • Figure on what trial you can expect to get the first H and pay no more than you will get on that trial • Single vs. multiple games • Does it make a difference?
Expected Utility Theory • Generally considered best “objective function” since axiomatization by von Neumann & Morgenstern (1947)
Expected-Utility Axioms(Von Neumann & Morgenstern,1947) • Connectedness x>=y or y>=x • Transitivity If x>=y and y>=z, then x>=z • Substitution Axiom or Sure-thing principle If x>=y, then (x,p,z) >= (y,p,z) for all p and z • If you “buy into” all axioms, then you will choose X over Y • if and only if EU(X) > EU(Y), where EU(X) = Sum over all i {u(xi) p(x i)} and EU(Y) = Sum over all i {u(yi) p(y i)}
Violation of Connectedness • Sophie’s Choice • Trading money for human life/human organs • In general • there are some dimensions between which some people are uncomfortable making tradeoffs or for which they find tradeoffs unethical
Violations of Transitivity • Example A • Choice 1: rose soap ($2) vs. jasmine soap ($2.30) • Choice 2: jasmine soap ($2.30) vs. honeysuckle soap ($2.60) • Choice 3: rose soap ($2) vs. honeysuckle soap ($2.60) • Example B • Choice 1: large apple vs. orange • Choice 2: orange vs. small apple • Choice 3: large apple vs. small apple
Violation of Substitution • Allais’ paradoxDecision I: A: Sure gain of $3,000 B: .80 chance of $4,000Decision II: C: .25 chance of $3,000 D: .20 chance of $4,000
Examples of EV as a good decision rule • Pricing insurance premiums • Actuaries are experts at getting the relevant information that goes into calculating the expected value of a particular policy • Testing whether slot machines follow state laws about required payout • Bloodtesting • Test each sample individually or in batches of, say, 50? • Incidence of disease is 1/100 • If group test comes back negative, all 50 samples are negative • If group test comes back positive, all samples are tested individually • What is expected number of tests you will have to conduct if you test in groups of 50?
Another normative model • Choosing a spouse • What’s your decision rule for saying yes/no to a marriage proposal? • Tradeoff • Say yes too early, and you may miss the best person • Say no to a “good” one, you may be sorry later • “Optimal” algorithm • Estimate the number of offers you will get over your lifetime • Say “no” to the first 37 % • Then say “yes” to the first one who is better than all previous ones
Objective function • Maximize the probability of getting No.1 as a function of the cutoff percentage (i.e., % after which you start saying “yes”) • Example • Say n=4 suitors • Reject first 37% • Pass up first (25%) and pick the one after that who is better than all previous ones • Gets the “best” in 11 out of 24 cases: 47% • Suitors may come in all 24 rank orders: • 1234 1243 1342 1423 • 1432 2134(*) 2143(*) 2314(*) • 2341(*) 2413(*) 2431(*) 3124(*) • 3142 (*) 3214 3241 3412(*) • 3421 4123(*) 4132(*) 4213 • 4231 4312 4321 1324 • * means that she got the “best” one, with a rank of 1
Assumptions underlying normative model for spousal selection • You can estimate n • You have to “sample” sequentially • You have no second chances
A final normative model: Multi-Attribute Utility Theory (MAUT) • Model of riskless choice • Choice of consumer products, restaurants, etc. • Need to specify • Dimensions of choice alternatives that enter into decision • Value of each alternative on those dimensions • Importance weights of dimensions given ranges (acceptable tradeoff) • Tradeoffs • Willingness to interchange x units of dim1 for y units of dim2 • Computer programs can help you with utility assessment and tradeoff assessment
What do normative/prescriptive models provide? • Consistency in choices • Structure for decision making process • Transparency of reasons for choice • Justifiability • “Education” of other choice processes
