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Ambiguity will concern Dow Jones & Nikkei indexes today: Peter P. Wakker & Enrico Diecidue & Marcel Zeelenberg Lecture + paper are on my homepage Domain:

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Presentation on theme: "Ambiguity will concern Dow Jones & Nikkei indexes today: Peter P. Wakker & Enrico Diecidue & Marcel Zeelenberg Lecture + paper are on my homepage Domain:"— Presentation transcript:

1 Ambiguity will concern Dow Jones & Nikkei indexes today: Peter P. Wakker & Enrico Diecidue & Marcel Zeelenberg Lecture + paper are on my homepage Domain: Quantitative measurement of beliefs under ambiguity. Question: How do people perceive of these uncertainties? How do they decide w.r.t. these? Concretely: A simple way to directly measure nonadditive beliefs/decision weights for ambiguity quantitatively. Measuring Decision Weights of Ambiguous Events by Adapting de Finetti's Betting-Odds Method to Prospect Theory U: both go Up (  ) D: both go Down (  ) R: Rest event (  =; one up other down, or at least one constant) We will analyze in terms of prospect theory.. Don’t forget to make yellow comments invisible ESA: The measurement of subjective beliefs is popular in game theory and experimental economics today (Andrew Schotter). The measurement methods used are based on classical theories. Subjects, however, deviate from classical models. This was pointed out by prospect theory. We show how subjective beliefs can be measured under prospect theory. We use our method and investigate if and how subjective beliefs deviate from the classical models. RUD: Many people have worked on nonadditive measures, or read about it. But few have actually “seen” them. Things such as “the capacity of rain tomorrow is 0.7 for \Mr. Jones. Hej, it is only 0.5 for Ms. Jones,” few if none have faced such information. Today you will see it! We will use our measurements to test properties of those decision weights. Prospect theory does not cause trouble for the classical economic concepts, but instead shows how to defend them against deviating biases, and how to correct for those biases. ESA: The measurement of subjective beliefs is popular in game theory and experimental economics today (Andrew Schotter). The measurement methods used are based on classical theories. Subjects, however, deviate from classical models. This was pointed out by prospect theory. We show how subjective beliefs can be measured under prospect theory. We use our method and investigate if and how subjective beliefs deviate from the classical models. RUD: Many people have worked on nonadditive measures, or read about it. But few have actually “seen” them. Things such as “the capacity of rain tomorrow is 0.7 for \Mr. Jones. Hej, it is only 0.5 for Ms. Jones,” few if none have faced such information. Today you will see it! We will use our measurements to test properties of those decision weights. Prospect theory does not cause trouble for the classical economic concepts, but instead shows how to defend them against deviating biases, and how to correct for those biases.

2 For gains only today. Then prospect theory = rank-dependent utility = Choquet expected utility. 1950-1980: nonEU desirable, nonlinear probability desirable. 1981 (only then): Quiggin introduced rank-dependence for risk (given probabilities). Greatest idea in decision theory since 1954!?!? 1989: Schmeidler did the same independently. Big thing: Schmeidler did it for uncertainty (no probabilities given). Up to that point, no implementable theory for uncertainty to deviate from SEU. (Multiple priors not yet implementable!?) Uncertainty before 1990: prehistorical times! Only after, Tversky & Kahneman (1992) could develop a sound prospect theory, thanks to Schmeidler. 2 Some History of Prospect Theory Multiple priors had existed long before. It is often used in theoretical studies. I am not aware of a study that empirically measured multiple priors, and do not know how to do that in a tractable manner. ESA’04: skip rest page

3 de Finetti’s betting-odds system assumes linear utility. Our analysis maintains this assumption. Reasonable? Outcomes between Dfl 10 (€4.5) and Dfl 100 (€45). Are moderate, and not very close to zero. Then utility is approximately linear. References supporting it: de Finetti 1937; Edwards 1955; Fox, Rogers, & Tversky 1996; Lopes & Oden 1999 p. 290; Luce 2000 p. 86; Rabin 2000; Ramsey 1931 p. 176; Samuelson 1959 p. 35; Savage 1954 p. 91. Special dangers of zero-outcome: Birnbaum. Modern view: Risk aversion for such amounts is due to other factors than utility curvature (Rabin 2000). Axiomatizations of prospect theory with linear utility: Chateauneuf (1991, JME), Diecidue & Wakker (2002, MSS). 3 Restrictive Assumption about Utility in Our Analysis Reasonable!? ESA’04: say rest page in one line

4 (Subjective) expected utility (linear utility): 4 UDRUDR 9 75 () evaluated through  U 9 +  D 7 +  R 5. UDRUDR 2 86 () evaluated through  U 2 +  D 8 +  R 6. A Reformulation of Prospect-Theory (= Rank-Dependent-Utility = Choquet-Expected-Utility) through Rank-Dependence of Decision Weights (Cumulative) prospect theory generalizes expected utility by rank-dependence (“decision-way” of expressing nonadditivity of belief). b b m m w w Properties of rank-dependent decision weights: For specialists, remark that there are two middle weights but for simplicity we ignore difference. For philosphers: You can claim that probabilities should be nonadditive, but for decision theory that as such doesn’t mean anything.

5 5 Pessimism: UU w > UU m UU b > (overweighting of bad outcomes) Optimism: UU w < m UU UU b < (overweighting of good outcomes) (Likelihood) insensitivity: (overweighting of extreme outcomes) Empirical findings: (Primarily insensitivity; also pessimism; Tversky & Fox, 1997; Gonzalez & Wu 1999 ) Uncertainty aversion UU w > m UU UU b > m UU UU w > UU b > m UU convex concave inverse-S inverse -S (lowered) p  linear Classical: UU w = m UU UU b = No rank-dependence (rational!) Economists usually want pessimism for equilibria etc. Note that we do unknown probs; figures only suggestive.

6 Our empirical predictions: 1. The decision weights depend on the ranking position. 2. The nature of rank-dependence: 6 UU w > UU b > UU m 3. Violations of prospect theory … see later. Those violations will come quite later. First I explain things within PT and explain and test those. Only after those results comes the test of the violations. But one violation will be strong, so, if you don’t like PT, keep on listening!

7 – Many studies in “probability triangle.” Unclear results; triangle is not suited for testing PT. –Other qualitative studies with three outcomes: Wakker, Erev, & Weber (‘94, JRU) Fennema & Wakker (‘96, JRU) Birnbaum & McIntosh (‘96, OBHDP) Birnbaum & Navarrete (‘98, JRU) Gonzalez & Wu (2004) –Lopes et al. on many outcomes, complex results. –Summarizing: no clear results! 7 Real test of (novelty of) rank-dependence needs at least 3-outcome prospects (e.g. for defining  m 's). Empirical studies of PT with 3 outcomes (mostly with known probs): Most here is for DUR. ESA’04: rest page in one sentence

8 Taking stock. We: 8 Shows how hard 3-outcome-prospect choices are. We developed special layout to make such choices transparent. –Tests the novelty of PT –by measuring decision weights of events in varying ranking positions –through choices between three-outcome prospects –that are transparent to the subjects by appealing to de Finetti’s betting-odds system (through stating “reference prospects”): see next slides. –This is how we want to make nonadditive measures/decision weights “visible.” ? UD R ( ) 1034712 UD R ( ) 9464 8 Which would you choose? ESA: skip this page.

9 9 + 13 + 46 + 65 + 13 + 46 + 65 i.e., UDR 334665 ()  U D R 16 49 68 () 20 3  U >. w Then we can conclude ¹· = 13 46 65 33 46 65 16 49 68   p p Choice + +++ U D R Layout of stimuli Classical method (de Finetti) to “check” if 3 20  U > : UDR 2000 () U D R 3 3 33 3 3 ().).  Check if this reveals that b U U 3 20 >. U U w 3 20 > ? How check if UDR 2000 ()  U D R 3 3 33 3 3 () Answer: add a “reference gamble” (side payment). Check if refer- ence gamble We: You can see de Finetti’s intuition “shine” through, embedded in rank-dependence. In explanation make clear that “check” means elicit from an individual from his choices. At Say that the very idea to verify from prefs, while well-known today, was an impressive step forward. Mention that we are finding out about fair price (CE-equivalent) of U. In explanation make clear that “check” means elicit from an individual from his choices. At Say that the very idea to verify from prefs, while well-known today, was an impressive step forward. Mention that we are finding out about fair price (CE-equivalent) of U. Before Figure-layout: So this is algebra. But, we also want it psychological, I.e., in the minds of our subjects. How can we let this take place in the minds of our subjects? This was the most difficult question in our research. We spent a year or so trying all kinds of stimuli, before we came to choose this figure. Then relate back to difficult choice on p. 8, that now it is clearer. Before Figure-layout: So this is algebra. But, we also want it psychological, I.e., in the minds of our subjects. How can we let this take place in the minds of our subjects? This was the most difficult question in our research. We spent a year or so trying all kinds of stimuli, before we came to choose this figure. Then relate back to difficult choice on p. 8, that now it is clearer. Explain in terms of how many utility units more than the reference gamble

10 + +++ Choice 13 46 65 33 46 65 37 70 89   ¹· = p p ¹· = 13 46 65 33 46 65 28 61 80   p p Choice + +++ U D R Choice 13 46 65 33 46 65 31 64 83   ¹· = p p + +++ Choice 13 46 65 33 46 65 34 67 86   ¹· = + +++ p p ¹· = 13 46 65 33 46 65 40 73 92   p p Choice + +++ U D R Choice 13 46 65 33 46 65 43 76 95   ¹· = p p + +++ 10 + +++ Choice 13 46 65 33 46 65 25 58 77   ¹· = p p Choice ¹· = 13 46 65 33 46 65 16 49 68   p p + +++ U D R Choice 13 46 65 33 46 65 19 52 71   ¹· = p p + +++ Choice 13 46 65 33 46 65 22 55 74   ¹· = + +++ p p xx xx Imagine the following choices: xx xx x x 9 more for sure  20 more under U  12 more for sure U U w < 9/20 < 12/20. This provides a tractable manner for quantitatively measuring decision weights under ambiguity. Combines de Finetti’s betting odds schemes with rank- dependence.

11 11 The Experiment Stimuli: explained before. N = 186 participants. Tilburg-students, NOT economics or medical. Classroom sessions, paper-&-pencil questionnaires; one of every 10 students got one random choice for real. Written instructions –brief verbal comment on likelihood of increases/decreases of Dow Jones & Nikkei. –graph of performance of stocks during last two months. ESA’04: rest page in one sentence

12 12 Performance of Dow Jones and Nikkei from March 16, 2001 till May 15, 2001

13 Order of questions –2 learning questions –questions about difficulty etc. –2 experimental questions –1 filler –6 experimental questions –1 filler –10 experimental questions –questions about emotions, e.g. regret order completely randomized 13 Skip most details of it.

14 1 st hypothesis (existence rank-dependence). ANOVA with repeated measures. Event U: F(2,328) = 9.44, p < 0.001; Event D: F(2,322) = 5.77, p = 0.003; Event R: F(2,334) = 2.80, p = 0.06. So, first hypothesis is confirmed: There is rank-dependence. 14 Results

15 .44 (.18) worst best middle worst Rest-event: RR.52 (.18).50 (.19).50 (.18) 2 nd hypothesis (nature of rank-dependence; t-tests) 15 * best middle worst suggests insensitivity DD.34 (.18).31 (.17).34 (.17) * * Up-event: best middle UU.48 (.20).46 (.18) * * Down-event: suggests pessimism suggests optimism Main effect is likelihood and is just fine. Bigger overestimation of unlikely events suggests likelihood insensitivity. The *’s are violations of SEU. Main effect is likelihood and is just fine. Bigger overestimation of unlikely events suggests likelihood insensitivity. The *’s are violations of SEU.

16 16 Third hypothesis (violations of prospect theory): Prospect theory accommodates the certainty effect. Are there factors beyond prospect theory (Loomes & Sugden, Luce, Humphrey, Birnbaum, etc.)? We call them degeneracy effects. If existing, do they reinforce or weaken the certainty effect? Prospect theory can explain more of the variance in choice than any other theory. But the total variance explained is still low. Degeneracy effects: working name, only for this paper.

17 13 46 65 33 46 65 19 52 71   ¹· = p p Choice + +++ + +++ Choice 13 46 65 33 46 65 22 55 74   ¹· = p p Choice ¹· = 13 46 65 33 46 65 16 49 68   p p + +++ U D R … + +++ 16 46 46 46 22 52 52   ¹· = p p Choice + +++ Choice 16 46 46 46 25 55 55   ¹· = p p + +++ ¹· = 16 46 46 46 19 49 49   p p Choice U D R … 17 UU w,n UU w,d Stimuli to test degeneracy effects:

18 .44 (.18) * worst degenerate.41 (.18).43 (.17) best middle worst degenerate.51 (.20).49 (.20) Rest-event: RR.52 (.18).50 (.19).50 (.18) nondeg.53 (.20).50 (.20) Results 18 * best middle worst.35 (.20).35 (.19) suggests insensitivity DD.34 (.18).31 (.17).34 (.17) degenerate nondeg..33 (.18).33 (.19) * * Up-event: best middle UU.48 (.20).46 (.18) nondeg.46 (.22).51 (.23) * * *** Down-event: suggests pessimism suggests optimism concerning factors beyond prospect theory

19 Conclusions For empirically measuring subjective beliefs, prospect theory has improvements to bring. De Finetti’s betting odds can be adapted to prospect theory/rank-dependence: easy way to directly measure nonadditive decision weights quantitatively. Using measurements, we investigated properties of rank- dependence. Rank-dependent violations of expected utility were found. Support for pessimism and likelihood insensitivity. Some degeneracy effects, violating prospect theory. 19


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