Post on 05-Jan-2022
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Multiple Benchmarks and Portfolio Allocation:
Why Investors do not Diversify Enough
Anna Dodonova†
Visiting Assistant Professor in Finance
Henry B. Tippie College of Business
The University of Iowa
Iowa City, IA, 52242-1000
E-mail address: anna-dodonova@uiowa.edu
† I am extremely grateful to Richard Thaler for his support and invaluable comments. I also benefited a lot from discussions with Roger Gordon, Yuri Khoroshilov, Terrance Odean, and participants of the Berkeley Summer Institute in Behavioral Economics.
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ABSTRACT
This paper analyzes the behavior of loss-averse investors and its implications to
the portfolio choice, portfolio management, and asset pricing. The distinctive
feature of this paper is the recognition of investors’ ability to use several
benchmarks in evaluating their portfolio performances. Using the ideas of mental
accounting, the model shows that an investor who, in reality, has a number of
benchmarks to evaluate his portfolio performance will not want to completely
diversify his unsystematic risk. I show that even in the case when all investors are
identical they will not hold identical portfolios and, thus, their behavior cannot be
described by the behavior of a representative investor. A new approach developed
in this paper also helps to explain an observed time-series autocorrelation of stock
returns and the effect that a firm value and book-to-market ratio have on its
expected stock returns. Applied to the portfolio management, it implies that, in
order to maximize a client’s expected utility, a portfolio manager should follow
the contrarian strategy (buy past losers). The paper also has implications about the
design of the optimal incentive contract for the portfolio manager.
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1. Introduction
Even though the traditional finance paradigm that assumes that agents follow axioms of
the Expected Utility Theory (Von Neumann and Morgenstern [1947]) is extremely
simple and, therefore, very appealing, this framework along does not allow one to fully
understand individual trading behavior (e.g., the fact that investors do not diversify
enough) and the puzzling behavior of stock returns (e.g., high mean and volatility and the
time series correlation of stock returns1). Difficulties faced by the traditional paradigm
gave rise to a number of behavioral theories that try to explain “the natural order of
things” by assuming some kind of irrationality in people’s behavior. Overconfidence,
prospect theory, regret aversion, and mental accounting are just several examples of
behavioral theories that help to capture many of the known patterns of individual choice
under uncertainty2. And even though it is very difficult to rank behavioral theories in
their order of importance, some of them have very well documented empirical support
and, therefore, are very difficult to ignore. This paper deals with one of these well-
documented behavioral theories: prospect theory. The main idea behind prospect theory
is that people’s utility depends not on their wealth or their consumption but rather on
their gains and losses in comparison with some reference point. Prospect theory assumes
that people are loss averse, i.e., their utility from gains is lower than their disutility from
the same losses and that they are risk-averse over gains and risk-loving over losses. It
also assumes that people tend to overestimate small probabilities and underestimate large
1 See Mehra and Prescott [1985] (high mean and volatility of stock returns); Jegadesh and Titman [1993] and Conrad and Kaul [1988, 1989] (positive short run auto correlation of stock returns); De Bond and Thaler [1985, 1987] and Fama and French [1988] (negative long-run correlation of stock returns) 2 See Hirshleifer (2001) for an excellent review of existing behavioral theories and their applications to the Finance.
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ones. And a number of experimental evidences (see, e.g., Kahneman and Tversky (1979,
1991) and Kahneman, Knetsch and Thaler (1990)) leave no doubt that people are, indeed,
behaving as if they are loss-averse.
There are several papers (see e.g., Benartzi and Thaler [1995]; Barberis, Huang, and
Santos (1999); Barberis and Huang (2000); and Shumway (2002)) that apply ideas of
prospect theory to asset pricing.
In this paper I continue to investigate how the behavior of loss-averse investors affects
the stock market. Unlike all previous studies I am not trying to look only at the behavior
of asset prices but rather on the investment decisions of loss-averse investors and the
effects of these decisions on the investors’ portfolio allocation. The main question that I
am trying to answer is why people do not diversify enough. According to the mean-
variance frontier theory an optimal investment portfolio should be a combination only of
a risk-free asset and a market portfolio. If this is so, then how can we explain the
existence of different types of specialized mutual funds that only invest in some small
portions of the market (e.g., funds that invest only in growth firms, large cap firms, small
cap firms, etc.) in the semi-strong efficient market? Having these specialized mutual
funds means that people sometimes do not want to hold a market portfolio, i.e., they do
not want to diversify all their unsystematic risk. A new approach presented in this paper
shows that even in the world when all investors have the same preferences, none of them
wants to diversify completely and people’s investment portfolios will differ among
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people. This, in particular, implies that there is no representative investor even when all
investors are identical.
The fact that an investor’s utility depends on his gains and losses has a very important
implication to the portfolio management. Currently every portfolio manager has a
benchmark that he either tries to follow (as in the case of passive portfolio management)
or to beat (in the case of active portfolio management). So, when a client hires a portfolio
manager or invests his money into some mutual fund, he must choose the benchmark that
is appropriate for him.
How can the investor choose the unique benchmark? Is it possible for the investor to just
ignore bits of information that are available on the market and focus only on the
performance of his portfolio and the unique benchmark he uses? How a sophisticated
investor who knows the benefits of diversification and invests in S&P 500 (which more
or less tracks the market return) can resist the temptation to compare his return with
NASDAQ? The problem of benchmark choice is even more severe for ordinary investors
whose benchmarks are often influenced by different news sources (TV, Wall Street
Journal, friends, internet sites, etc.) So, it seems natural to assume that when a person
evaluates his portfolio performance he compares his return with the returns on each of his
several benchmarks (e.g., most popular market indices, some popular stock that is in the
news, portfolio of his sister, etc.) separately and his utility somehow depends on these
comparisons3. Thus, as soon as a person observes a return on one of his benchmarks he
3 An alternative assumption could be that a person constructs some “weighted average” benchmark (out of all his possible benchmarks) and then compares its return with the return on his portfolio. However, it is
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immediately compares it with his portfolio return and feels joy or disappointment
depending on how favorable this comparison is. If later on he gets news about the
performance of any other benchmark he uses, he makes his comparisons once again.
Every one of these comparisons is assigned to its own specific mental account (Thaler
[1985], [1990], [1999]). Mental accounts are evaluated with some frequency (Read,
Loewenstein, and Rabin [1998]). The person gets utility/disutility from every account
evaluation and uses them as the components of his aggregate utility function.
However, when the client with several different benchmarks on his mind comes to the
portfolio manager and says “I would like to have a return that is close to the return on the
high-tech companies but at the same time I do not want to have significant losses in
comparison with the average market return”, the natural response of the portfolio
manager is “You need to choose which one would you like me to follow. I cannot track
two indices simultaneously”. And the investor has to choose one of the benchmarks (or,
at best, a linear combination of them). So, the real problem is not that clients don’t know
what do they want but that portfolio managers don’t know how to deliver to them what
they want.
In this paper I provide a recommendation of how to deal with loss-averse investors who
want to use several benchmarks to evaluate their portfolio performance. I show that, in
order to maximize clients’ expected utility, the portfolio manager should not diversify
completely and should follow a contrarian strategy (invest in past losers). If we want to
hard to imagine that a person first gathers information about returns on his benchmarks, then calculates the “weighted average” return and only after that makes his comparison.
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make a simple incentive contract for a portfolio manager then we should force him to use
a benchmark that is a non-linear function of the benchmarks proposed by a client and is
biased toward the worst performing one (i.e., if the client uses portfolios A and B as his
benchmarks, the manager should try to invest so that the return will be close to min{rA,
rB}+some fixed premium).
This paper also shows that investors’ choice of the benchmarks may help to explain the
home-bias effect and the existing predictability (positive short-run and negative long-run
correlation) of stock returns. Investors’ choice of benchmarks may also explain why firm
value and the market/book ratio affect the expected return, why initial underpricing of
IPOs will partially disappear in several months of trading and why during the IPO waves
the IPO underpricing is not so severe.
The original version of prospect theory does not specify how people form their
benchmarks. In experimental studies it is assumed that people consider their current
wealth as their benchmark and an increase in their wealth is treated as a gain while a
decrease is treated as a loss. This assumption was used by Barberis, Huang, and Santos
(1999), and Barberis and Huang (2000) (who constructed the model of asset price
behavior that explains high risk premium and negative autocorrelation of returns) and by
Shumway (2002) (who shows that in the market populated by loss-averse investors the
pricing kernel is not a monotone function of the market return and that investors value the
upside and downside risks differently).
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The stock market, however, provides a number of other possible benchmarks for an
investor. For example, an investor may compare his portfolio return with the risk-free
rate of return4. He also may compare his return with the market rate of return. It is natural
to feel a gain if you overperformed the market and a loss if you underperformed it. An
investor who gets his information from watching CNN, reading his mutual fund reports,
and, occasionally, reading the Wall Street Journal or surfing investment-related sites on
the internet, may compare his return with returns on different market indices, with returns
on most known large companies, or with returns on the “hot” companies that are in the
news. Dodonova (2002) proposes that people may have regrets when they see that some
asset performs well but they did not invest much in it, i.e., the benchmark that investors
use when they evaluate their portfolio performance is not fixed ex ante but rather depends
on the ex post stock performance.
In this paper I make another step in the recognizing investors’ right to have different
benchmarks. Using the idea of mental accounting proposed by Thaler (1985, 1990, 1999),
I assume that investors may simultaneously use several benchmarks to evaluate their
portfolio performance. Namely, an investor separately compares his portfolio returns with
each of his benchmarks and his utility depends on each of these comparisons.
The main intuition behind my model is the following. At the time when the initial
investment is made investors do not expect to outperform all of their benchmarks. Since
investors are risk-loving over losses and since their disutility from the losses is higher
4 Barberis, Huang, and Santos (1999), Barberis and Huang (2000), and Shumway (2002) argue that their results will not change if investors use risk-free rate as a benchmark.
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than their utility from the same gains, investors want to have some risk exposure, so that,
they would be able to gamble over the losses relative to their benchmarks. Thus, investors
do not diversify enough. In the symmetric world when all investors and all assets are the
same, the exogenous supply of assets will lead to the situation in which identical
investors will allocate their portfolios differently. In the dynamic setting investors’ desire
to fix their relative gains and to gamble over their relative losses makes them more
willing to reallocate their portfolios toward the assets that their portfolios currently
overperform (i.e., toward the past losers). Such portfolio reallocation will lead to the
market underreaction on bad/good news and to the positive autocorrelation of stock
returns. So, when investors delegate their investment decisions to the portfolio manager
or put their money into a mutual fund, they want a portfolio manager to be biased toward
the worst performing asset, so that they will have a fixed gain over one of their
benchmarks and a gamble over the other.
The rest of the paper is organized as following. In part two I develop a basic 2-period
model of investors’ behavior, prove the existence of the equilibrium and analyze its basic
properties. In part three I discuss some of the empirical implications of the basic model.
In particular, I prove that investors never want to diversify all unsystematic risk and that
this economy does not have a representative investor even if all investors are identical. In
part four I generalize the basic model to a 3-period case and discuss its application to a
portfolio management. In part five I conclude.
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2. Basic Model
In this part of the paper I construct a basic 2-period model of investors’ behavior based
on the assumption that investors care not only about their final wealth but also about their
gains and losses relative to some benchmarks. The classic version of the prospect theory
(Kahneman and Tversky [1979, 1991]) assumes that investors care about changes in their
wealth. They are risk-averse over gains and risk-loving over losses and their utility from
gains is lower than their disutility from the same amount of losses. Kahneman and
Tversky (1992) proposed the following individual’s utility function:
( )
<−−≥=
0,0,)(
xxxxxv α
α
λ (1)
where x is the change in person’s wealth, 10 <<α and 1>λ are some parameters. Based
on the experimental data, Kahneman and Tversky (1992) estimate 88.0=α and
25.2=λ .
Even though a number of evidences confirm the loss-aversion assumption, it is still
unclear how people chose their benchmarks. Prospect theory assumes that people care
only about their gains and losses (i.e., their past wealth serves as their benchmarks) and
Barberis, Huang, and Santos (1999), Barberis and Huang (2000) and Shumway (2002)
use this assumption in their asset pricing models. There are, however, evidences that
people’s reference point may be influenced by aspiration, expectations, norms and social
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comparisons (see, e.g., Easterlin (1974), van Praag (1971), and van de Stadt, Kapteyn,
and van de Geer (1985))
The existing financial markets provide a wide range of possible benchmarks. Generally
speaking, an investor may compare his return with a return on any investment
opportunity that he considered in the past but decided not to pursue. Investment in T-bills
or T-bonds, which guarantees a risk-free rate of return, is one of these opportunities. A
more sophisticated investor, who is familiar with the concept of diversification, will be
interested in how his portfolio performed in comparison with the market rate of return
(this idea was used by Abel (1990) who assumes that a person’s utility depends on the
difference between his consumption and the aggregate consumption level in the
economy). A regret-averse investor who feels regret every time his assets turn out not to
be on the top of the market, compares his portfolio performance with the maximum
payoff he could have had if he, ex ante, invested in the best ex post portfolio (see
Dodonova [2002]).
Many times, however, it is hard for an investor to decide up-front which benchmark he
will use next year when he evaluates his portfolio performance. Consider, for example, an
investor who decides whether to invest in the high-tech industry (NASDAQ index) or in
more traditional businesses (Dow Jones). For simplicity, let us ignore the difference in
risks by assuming that investors adjust their risk exposure by investing in the money
market account. Next year, when he will get his mutual fund report, he may easily
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compare his return with returns on NASDAQ and Dow Jones indices and, depending on
which index he chooses as a benchmark, he may feel gain or loss.
Applying ideas of mental accounting (Thaler [1985], [1990], [1999]) one may argue that
nobody prevents the investor from comparing his return with both returns: on NASDAQ
and on the DJ. Thus, the investor’s utility must be some average of his utility from the
comparison of his return with the return on NASDAQ and his utility from the comparison
with the DJ, and not the utility from the comparison of his return with the average returns
on NASDAQ and DJ. So, an investor may use several different benchmarks
simultaneously.
In this paper I assume that investors care about both: their wealth and their financial gains
and losses, i.e. I assume that their utility function is given by
( ) ( ) ( )pRvwuU δδ +−= 1
where w is the investor’s wealth and Rp is his portfolio return.
I assume that an investor’s utility out of his wealth )(wu is an increasing and concave
function and, to prevent the possibility of negative wealth, I assume that −∞=)(wu for
w<0. Function )( pRv represents the investor’s utility from his portfolio performance and
depends on the benchmarks that the investor uses to evaluate his portfolio return.
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Following Kahneman and Tversky (1992) and allowing investors to have different
benchmarks, I assume that the investor’s utility from comparing his portfolio with
benchmark i is
( )( )
<−−−≥−−
=−0,0,
)(ippi
ipipipi RRRR
RRRRRRv α
α
λ (2)
and the total utility that he gets from comparing his portfolio return with different
benchmarks is given by:
( ) ( )∑=i
piip RvqRv (3)
where 1=∑i
iq and 0≥iq .
Assume that there are 2 assets in the economy: asset #1 and asset #2 (these assets may be
viewed as industry-specific indices) and that investors use these assets as their benchmark
portfolios. Assume there is a continuum of investors (numbered by c ) on the market with
the total wealth normalized to 2.
In the basic framework of the model I consider a 2-period case. At t=0 investors make
their investment decisions and invest cγ portion of their wealth in asset #1 and )1( cγ−
in asset #2, where cγ may be different for different investors. At t=1 both assets are
liquidated and investors consume the proceedings. The liquidation values of assets #1 and
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#2 are 1R and 2R and, to make things simple, I assume that 1R and 2R are independent
and identically distributed on ( )∞,0 random variables.
Thus, the problem of an investor with an initial wealth of $1 is to maximize
( )
−−+
−+−≡
2
2
1
1 )1()1()(maxpR
REvqpR
REvqREuU pcpccpccc
δδγγ
(4)
s.t.:
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1R
pR
pR cc
pγγ −
+= (5)
where 1p and 2p are the prices for the 1st and 2nd assets at t=0.
In general, I assume that the parameters of the utility function cδ (which measures how
important gains and losses are for the investor) and cq (which measures the relative
importance of the first asset as the benchmark) may be different for different investors,
but I will concentrate on the case in which they are equal, i.e., all investors have the same
preferences.
The equilibrium conditions for the stock market are given by
∫ =C
c pdc 1γ (6)
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and
∫ =−C
c pdc 2)1( γ (7)
where C is the set of investors.
Using the assumption that the total number of investors is 2, i.e., that 2=∫C
dc , we can
find
221 =+ pp (8)
and may use (8) instead of (7) in an equilibrium analysis.
The maximization problem (4) and (5) together with the market clearing conditions (6)
and (8) determine the equilibrium in the economy.
Before analyzing the properties of the equilibrium portfolio allocations and asset prices,
we need to check that the equilibrium, described by (4), (5), (6) and (8), exists. The
following theorem proves the existence of the equilibrium and describes the basic
properties of the equilibrium investment allocation.
Theorem 1
1) (Existence)
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There is an equilibrium portfolio allocation cγ and asset prices 1p and 2p that satisfy
(4), (5), (6) and (8). Moreover in any equilibrium [ ]1,0∈cγ
2) (Local monotonicity)
If )( 1pcγ is the solution to the investor’s problem (4) subject to (5) and (8), then
0)(
1
1 <dp
pd cγ at any point where )( 1pcγ is continuous and differentiable function of 1p
3) (Global monotonicity)
If 2/1≥cq , 11 ≤p , and at least one of these inequalities is strict, then in any equilibrium
2/1>cγ .
Proof: see appendix
The intuition behind the results of Theorem 1 is simple: an increase in the first asset price
1p (and, thus, a corresponding decrease in 2p ) makes investment in the first asset less
attractive, and, thus, decreases equilibrium cγ . When the investor is more concern about
his portfolio performance relative to the first benchmark ( 2/1>cq ) or when the expected
return on the first asset is higher than on the second ( 11 <p ), the investor wants to hold
more of the first asset, i.e., 2/1>cγ .
3. Empirical Implications
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To understand how loss-aversion affects investors’ behavior and asset prices, let us
assume that all investors are the same, i.e., that δδ =c and qqc = for c∀ . Moreover,
assume that investors do not have any preferences towards any particular asset and that
they value their gains and losses relative to the first asset in the same way as their gains
and losses relative to the second one, i.e., assume that 2/1=q . Thus, the investor’s
maximization problem becomes:
( )
−+
−+−≡
2
2
1
1
2)1()(max
pR
REvpR
REvREuU pppcc
δδγγ
(9)
s.t.
22
11
1R
pR
pR cc
pγγ −
+= (10)
Together with equilibrium conditions (6) and (8), investor’s problem (9) and (10)
determines an equilibrium in the economy. Note that, although )(xu is a concave
function, )(xv is concave for x>0 and convex for x<0. Thus, we cannot claim that the
solution to the investor’s problem (9) and (10) is unique, and, as I will show in
Proposition 1, investors do choose different portfolio allocations.
To get the intuition on how the equilibrium looks, note, that since investors treat both
assets in the same way, we may expect to have 121 == pp . Given that prices on both
assets are equal, there are two forces that affect an investor’s decision. First, his risk-
aversion over his final wealth (concavity of )(xu ), leads to the desire to diversify and to
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choose 2/1=cγ . Second, his loss-aversion together with his risk-loving over losses
makes him willing to gamble and, thus, unwilling to diversify. If the investor is
sufficiently loss-averse (δ is sufficiently large) than his desire to gamble may outweight
his desire to diversify and his optimal portfolio allocation cγ will be different from the
complete diversification ( 2/1≠cγ ). (In all that follows I assume that δ is sufficiently
large to make the loss-aversion effect important.) Because the investor treats both assets
in the same way, he is indifferent between the following two portfolios: 21 )1( RR γγ −+
and 21)1( RR γγ +− . Thus, to allow the stock market to clear, ½ of investors will invest γ
in asset #1 and )1( γ− in asset #2 while the remaining ½ of investors will invest )1( γ−
in asset #1 and γ in asset #2.
Figure 1 presents the investor’s expected utility function )(γU as a function of his
investment in the first asset.5 As it can be seen in this figure, )(γU has an M-shape: a
perfect diversification ( )2/1=γ is a local minimum of the expected utility function while
15.0=γ and 85.0=γ are two symmetric global maximums. Thus, in the equilibrium
nobody will perfectly diversify; ½ of the investors will invest 15% of their wealth in asset
#1 and 85% in asset #2 while the remaining ½ of the investors will invest 85% in asset #1
and 15% in asset #2. So, the total investment in both assets are the same.
The following proposition summarizes the discussion above.
5 For the expositional purposes I choose xxu ln4.0)( += , 88.0=α , 25.2=λ , 945.0=δ , and
{ }9.1,1.0=iR with equal probabilities.
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Proposition 1.
If all investors are the same ( δδ =c and qqc = ), and treat all assets in the same way
(q=1/2), then
1) In any equilibrium asset prices must be the same 121 == pp .
2) Nobody will diversify completely ( 2/1≠cγ ).
3) If some investors invest γ in asset #1 and )1( γ− in asset #2, then an equal number
of investors will invest )1( γ− in asset #1 and γ in asset #2.
Proof: see appendix.
As the discussion above indicates, the desire to diversify depends on how important the
“relative” component of the utility function is. Figures 2a and 2b present the expected
utility function )(γU for different values of δ . When δ increases, the relative part of
the utility function becomes increasingly important (Figure 2a). The maximums of the
expected utility function moves toward complete specialization and complete
diversification becomes more and more painful. If δ becomes too large, an M-shape of
the expected utility function transforms into a U-shape and complete specialization
becomes an optimal portfolio allocation. When δ decreases (Figure 2b), the “absolute”
part of the utility function becomes more important and the optimal portfolio allocation
moves toward perfect diversification. When δ becomes too small, an M-shape of the
expected utility function transforms into an arch-shape.
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Another important implication of the basic model may be received if we look at how
investment decisions depend on the volatility of assets returns. Standard asset-pricing
models with risk-averse investors predict that higher volatility makes the benefits of
diversification even higher and, thus, investors should diversify more in the more volatile
markets. If, however, investors are loss averse, then high volatility increases the possible
relative losses and makes an investor, who is risk-loving over losses, gamble more. Thus,
there are two different forces that affect investors’ decisions to diversify and higher risk
may increase or decrease this desire to diversify.
Now, let us relax the assumption that people treat all assets in the same way and, instead,
assume that people care about their portfolio performances relative to the first benchmark
more than relative to the second, i.e., assume that 2/1>q . Since people are loss-averse,
they will try to minimize their losses in comparison with the first benchmark. Thus, all
else equal, they will buy more of the first asset. Since the supply of assets is exogenous,
this behavior will lead to an excess demand on asset #1 and an excess supply of asset #2.
Thus, in the equilibrium prices should adjust so that 21 pp > and, as a result, the
expected return on the first asset must be lower than the return on the second
<
2
2
1
1
pR
EpR
E . Figure 3 presents how the expected utility function depends on the
first asset’s price6. When the first asset becomes more expensive, it becomes less
attractive for the investors. The M-shape of the expected utility function becomes
asymmetric: the left local maximum becomes more attractive and it moves to the left
6 An increase in the importance of the first asset in the “relative” component of utility function (i.e., an increase in q) has an opposite effect
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(more investment in second asset) while the right local maximum becomes less attractive.
And only the left local maximum will be the global maximum when 21 pp > and q=1/2.
An increase in q will have the opposite effect. Thus, if q>1/2 we should have 21 pp < in
order to have two local maximums such that 2,1, 2/1 cc γγ << . Note, that the optimal
portfolio allocation cγ is not a continuous function of 1p or q (Figure 4). For example,
when q=1, 21 pp < , the optimal solution 15.0<cγ while at 21 pp > we have 85.0>cγ .
This is so because at 21 pp = we have a symmetric M-shape expected utility with two
global maximums 15.0=cγ and 85.0=cγ . When 1p increases from 21 pp < to
21 pp > , the global maximum jumps from the left local maximum to the right local
maximum.
The following proposition summarizes the discussion above.
Proposition 2
If all investors are the same ( δδ =c and qqc = ) and care about their portfolio
performance relative to the first asset more than relative to the second asset (q>1/2), then
in the equilibrium asset #1 must be overpriced )1( 21 pp >> and must have a lower
expected return than asset #2
<
2
2
1
1
pR
EpR
E .
Proof: see appendix.
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Proposition 2 may have a number of empirical implications if we will understand how
investors form their benchmarks. For example, if they use market indices as benchmarks,
an inclusion of some stock in a market index will result in an abnormal positive return
and in lower future expected returns. If people more often compare their portfolio
performance with the performance of large firms than with the performance of small
firms then the firm market value should negatively affect the expected stock returns7. If
people pay more attention to the stocks that performed well in the past, then high past
return will increase the importance of these stocks in the relative component of the
investor’s utility function, and, thus, will lead to higher demand and higher (than
“fundamental”) equilibrium price on this stock. So, we should observe a market
overreaction and the negative long-run correlation of stock returns. Finally, if we are in
the situation of a stock market bubble and people pay attention to “hot” stocks that are in
the news (like amazon.com), then those stocks must also have abnormal returns and low
future expected returns. For example, if a high market-to-book ratio makes a firm “hot”
and draws an additional attention, then we should expect the market-to-book ratio to have
a negative effect on the firm’s expected returns8. Similarly, since any IPO draws
investors’ attention, we should expect abnormal returns on IPOs and we should expect
this return to partially disappear over time. Furthermore, one may argue that during stock
market booms or during stock bubbles a person will pay more attention to the stock
market and his benchmark returns will be more distinctive than when the stock market is
stable. So, the model described in this paper may have more power during stock market
booms or bubbles. Moreover, this model may also explain the existence of stock bubbles:
7 This result is consistent with Fama and French (1993). 8 This result is also consistent with Fama and French (1993).
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when some industry shows an abnormal return, investors start to compare their returns
with the return on this industry, and, thus, they will invest more into this industry which,
in turn, will lead to even higher stock prices.
Different people may have different utility functions, and, in particular, different
benchmarks to which they want to compare their returns. For example, people more often
compare their portfolio returns with home stock returns or with stock returns of firms
they work for. However, if different people have different benchmarks ( cq are different
among people) but, on average, all assets look the same ( )
=∫ 2/12/1
Cc dcq , we should
not expect to have any effect on the stock prices. We should, however, expect people to
invest more in their home country stock market (home-bias effect) or in the company
they work for. The following proposition summarizes the discussion above.
Proposition 3
If, for any [ ]1,0∈q , the number of investors with preferences q is the same as the number
of investors with preferences (1-q), then loss-aversion has no effect on stock prices
( 121 == pp ), but people, who care more about their portfolio performance relative to the
first asset than they do relative to the second one ( 2/1>cq ), invest more in the first asset
( 2/1>cγ ) while people who care more about their portfolio performance relative to the
second asset ( 2/1<cq ), invest more in the second asset ( 2/1<cγ ).
Proof: This result directly follows from Theorem 1.
24
4. Portfolio Management
In the basic set up of the model analyzed in parts 2 and 3, I assumed that investors do not
change their portfolio allocations during the whole period of investment (say, a year). If,
however, investors delegate their portfolio allocation decisions to a portfolio manager,
how would they like the manager to manage their portfolios? To get the intuition, assume
that at t=0 the manager invests γ in asset #1 and )1( γ− in asset #2 and sometime during
the year (at t=1/2) he sees that asset #1 is outperforming asset #2. Since there is a high
probability that asset #1 will overperform asset #2 over the year, investors’ returns most
likely will be higher than the return on asset #2 and lower that the return on asset #1.
Since people are risk averse over gains and risk-loving over losses, they want to fix their
relative gains relative to asset #2 and to gamble over losses relative to asset #1. Thus,
investors would want their portfolio manager to reallocate their portfolios toward asset #2
(past loser). In order to make the manager buy more of the past loser, investors need him
to be biased toward the minimum return, i.e., they want the manager to use a benchmark
that is close to the drr +},min{ 21 , where ir is the return on investors’ benchmarks and
d>0 is some positive premium. Moreover, such reallocation during the year will result in
the market underreaction and will lead to the positive short-run correlation of returns.
To see that this intuition works, let us generalize the basic 2-period model described in
part 2 to a 3-period model in which (1) at t=0 investors delegate their investment
decisions to the portfolio manager; (2) at t=1/2 the portfolio manager reallocates his
25
clients’ portfolios based on the information released at that time; and (3) at t=1 all assets
are liquidated, investors evaluate their portfolio performances and consume the
proceedings. Assume that the portfolio manager represents the interests of his clients and
wants to maximize their expected utility.
As in the basic 2-period model of part 3, assume that there are 2 securities that at t=1 will
pay 1R and 2R respectively. Assume that at time { }1,2/1∈t news ti,ξ about each asset
{ }2,1∈i is realized, and the final realized payoff is equal to 1,2/1,1 iiiR ξξ ++= . The
signals about assets’ final returns are independent across time, i.e., ( )1,21,1 ,ξξ is
independent on ( )2/1,22/1,1 ,ξξ . For tractability, assume that ti,ξ is equal to D or D− with
equal probabilities (where D<1/2) and that t,1ξ and t,2ξ are perfectly negatively
correlated. The latter assumption is needed only to simplify calculations: it allows us to
reduce the number of states of the world. To make things even more simple, assume that
at t=0 the portfolio manager does not take into account the fact that people’s utility
depends on the relative return on their portfolios, and he diversifies all the unsystematic
risk, i.e. he invests equally into assets #1 and #2.9
9 As was shown in the part 3 of the paper, an optimal portfolio allocation at t=0 should include an unequal amount of first and second assets and, thus, not all of unsystematic risk should be diversify. The model described here, however, do not allow one to solve analytically for an optimal portfolio allocation at t=0. To make things simple, I assume that at t=0 portfolio manager invests equally in both assets, but the intuition behind theorem 2 should work for any initial investment allocation.
26
The investors’ utility function is given by ( ) ( ) ( )pRvwuU δδ +−= 1 , where ( )pRv is
given by (3).10 Given that at t=0 the portfolio manager invests equally in assets #1 and
#2, at t=1/2 he wants to maximize the expected shareholder’s utility U , i.e. he wants to
solve the shareholder’s problem (4)-(5) given the information available at time t=1/2
( 2/1,1ξ and )2/1.2ξ . Assume that this portfolio manager is operating in an environment
where all other investors want to maximize their “absolute” expected utility ( )wu , i.e.,
they perfectly diversify. The following theorem shows that, in order to maximize their
clients’ expected utility, a portfolio manager should follow a contrarian strategy and
invest in past losers
Theorem 2
Assume that at t=1/2 asset #1 outperforms asset #2, i.e. assume that at t=1/2 we have
D=2/1,1ξ and D−=2/1.2ξ . Given that asset prices are formed by investors who
maximize their “absolute” expected utility ( )wu (and, thus, perfectly diversify), a
portfolio manager who wants to maximize his clients’ utility ( ) ( ) ( )pRvwuU δδ +−= 1
should reallocate his portfolio toward asset #2.
Proof: see appendix.
10 Here I assume that investors evaluate their portfolio performance only at the end of the year and compare their annual return with the annual return on each of the assets.
27
In the case when asset prices are formed by the people who want to diversify all of their
unsystematic risk, it is easy to show that the price on asset i at time t=1/2 will be11
2/1,1 iip ξ+= . Thus, an expected return between t=1/2 and t=1 will not depend on the
return between t=0 and t=1/2 and will be zero for both assets. If, however, portfolio
managers who maximize their clients’ expected utility ( ) ( ) ( )pRvwuU δδ +−= 1 affect
the price formation, they impose an excess demand on the past loser and will make the
price on the first asset (that performed good at t=1/2) to be below 2/1,11 ξ+=ip and the
price on the second asset (that performed poorly at t=1/2) to be above 2/1,11 ξ+=ip .
Thus, we should expect to have a positive return on past losers and a negative return on
past winners, i.e., we should expect a negative correlation of stock returns.
5. Conclusion
This paper presents a model of the behavior of loss-averse investors. Based on the ideas
of prospect theory (Kahneman and Tversky [1979], [1991]) and mental accounting
(Thaler [1985], [1990], [1999]), I assume that investors care not only about their final
wealth but also about their relative return in comparison with a number of different
benchmarks. Since the stock market provides investors a number of possible benchmarks,
I assume that investors’ utility depends on their gains and losses relative to every
benchmark they use.
11 See Dodonova (2002) who uses the similar setup and shows that the “rational” prices must be equal to the expected future payoff.
28
The model presented in this paper shows that even if investors are identical and do not
have any ex ante preferences toward any one particular benchmark, they will hold
different portfolios and none of them will diversify all of his unsystematic risk. The way
in which investors form their benchmark portfolios may explain a number of observed
anomalities in investors and stock price behavior, such as the predictability of stock
returns, the home-bias effect in investors’ portfolio allocation, and the fact that employee
invest an abnormal portion of their wealth into their own company stocks.
The model has an important implication that deals with portfolio management. It
proposes that portfolio managers should recognize investors’ desire to have several
benchmarks simultaneously: the benchmark that managers should follow must be biased
toward the minimum among the investors’ benchmarks’ returns, and, all else being equal,
should follow a contrarian strategy (buy past losers).
29
Appendix.
Proof of theorem 1
(1) Existence
By substituting (5) and (8) into (4), we can rewrite (4) as
( )
( ) ( )
−
−−+
−−
−−
+
−
−+−≡
1
2
1
1
1
2
1
1
1
2
1
1
1)1(
111
11
)1()(
max
pR
pR
Evqp
Rp
REvq
pR
pR
EuU
ccc
cccc
cccc
c γγγγδ
γγδγ
γ (A1)
Since ( ) −∞=pRu for 0<pR , any cγ that maximizes (A1) must satisfy
( )0
11
1
2
1
1 >−
−+
pR
pR cc γγ
for any 0, 21 >RR . Thus, [ ]1,0∈cγ . Since ( )cU γ is continuous
function of cγ and [ ]1,0∈cγ , equation (A1) has at leas one solution.
Denote the set of solutions to (A1) by ( )1* pγ . To complete the proof we need to show
that 11 : pdcpC
c =∃ ∫γ for some ( )1* pc γγ ∈ .
Denote
1
2
1
1
1 pR
pR
z−
−= (A2)
Using (2) and (A2), we can rewrite (A1) as
30
( )
( ) ( ) ( )( )
−+−−
+
−
−+−≡
zEvqzEvq
pR
pR
EuU
ccccc
cccc
cαα
γ
γγδ
γγδγ
)1(1
11
)1()(max 1
2
1
1
(A3)
Note that if 01 →p then ∞→z almost surely. Thus, for small enough 1p , ( ) 0>zEv
and ( ) 0<− zEv . Therefore, if 1p is small enough, then
( ) ( ) ( )( )0
)1(1>
∂−+−−∂
c
cccc zEvqzEvqγ
γγ αα
(A4)
Moreover, since u(.) is a concave increasing function, then in the case when one of the
assets’ price goes to zero, a person who maximizes ( )pREu will invest more into this
asset. In other words, [ ]1,0∈cγ P∃ such that for Pp <∀ 1 we have
( )
01
1
1
2
1
1
>∂
−
−+∂
c
cc
pR
pR
Eu
γ
γγ
(A5)
Combining (A4) and (A5) we have
( ) { }1lim 1*
01
=→
pp
γ (A6)
Similarly, one can show that
( ) { }0lim 1*
21
=→
pp
γ (A7)
Since ( )cU γ is continuous function of cγ and 1p , ( )1pµ∃ such that ( )⋅µ is continuous
and 1p∀ [ ]1,0∈∃ η such that ( ) ηγηγµ 2,1,1 ccp += , where ( )1*
2,1, , pcc γγγ ∈ . Note that if
31
( )1*
2,1, , pcc γγγ ∈ then ( )1pµ is a possible aggregate share of investment in asset 1, i.e.,
( ) ∫=C
c dcp γµ 1 for some ( )1* pc γγ ∈ . Using (A6) and (A7) we may claim that
( ) 2lim 101
=→
pp
µ and ( ) 0lim 121
=→
pp
µ . And, since ( )⋅µ is continuous there is 1p such that
1pdcC
c =∫γ where cγ is solution to (4) given (5) and (8). Q.E.D.
(2) Local monotonicity
Assume 11 ≤p (in the case when 11 ≥p the proof is the same)
( ) ( ) ( )( ) ( ) ( ) ( )( )zEvqzEvqzEvqzEvqV
ccccc
cccc 11 )1(1)1(1 −− −+−−−=
∂−+−−≡∂ αα
αα
γγαγ
γγ
Since 11 ≤p we have ( ) 0<− zEv . Since z is a decreasing function of 1p , and ( )zv is an
increasing function of z , we have ( ) ( ) ( )( )0
)1(1
1
2
<∂∂
−+−−∂p
zEvqzEvq
c
cccc
γγγ αα
.
Moreover, since u(.) is a concave increasing function, a person who maximizes ( )pREu
will invest more into an asset which price drops, i.e.,
( )
01
1
1
1
2
1
12
<∂∂
−
−+∂
pp
RpR
Eu
c
cc
γ
γγ
.
Therefore, ( )
01
2
<∂∂
∂p
U
c
c
γγ
. Moreover, if cγ is a solution to (A1), then ( )
02
2
<∂
∂
c
cUγ
γ at
cc γγ = . Thus, at cc γγ = we have
( )
( ) 0
2
21
2
1
<
∂∂
∂∂∂
−=
c
c
c
c
c
Up
U
dpd
γγ
γγ
γ. Q.E.D.
32
(3) Global monotonicity
A person wants to maximize his expected utility
( ) ( ) ( ) ( )( )zEvqzEvqp
RpR
EuU ccccccc
ccαα γγδγγδγ )1(1
11
)1()(1
2
1
1 −+−−+
−
−+−≡
Let us assume that 2/1≥cq and 11 ≤p , and at least one of this inequalities is strict. By
contradiction, assume that a solution to (A1) satisfy 2/1<cγ . Since 11 ≤p , we have
( ) ( )
−
+−
≤
−
−+
1
2
1
1
1
2
1
1
11
11
pR
pR
Eup
RpR
Eu cccc γγγγ.
Moreover, ( ) ( )zEvzEv ≤− , and, this inequality must be strict when 2/1=cq (because in
this case we must have 11 <p ) Thus,
( ) ( ) ( )( ) ( ) ( ) ( )( )zEvqzEvqzEvqzEvq ccccccccαααα γγγγ −−+−<−+−− 1)1()1(1
So, we have that ( ) ( )cc UU γγ −< 1 which contradict to the assumption that cγ is a
solution to (A1). Thus, it must be the case that 2/1≥cγ .
To complete the proof we need to show that 2/1≠cγ .
33
To do it, it is enough to show that ( )
0>∂
∂
c
cUγγ
at 2/1=cγ . And this is so because
( )
−
−+
1
2
1
1
11
pR
pR
Eu cc γγ has a unique maximum 2/1≥cγ and because
( ) ( ) ( )( ) ( ) ( )( ) .02/)1(2/)1(1
>−+−−=∂
−+−−∂zEvqzEvq
zEvqzEvqccc
c
cccc ααα
γαγ
γγ
The later is follows from the fact that ( ) 0<− zEv and ( ) ( )zEvzEv ≤− where the last
inequality is strict when 2/1=cq (because in this case we must have 11 <p ). Q.E.D.
Proof of proposition 1:
If 11 <p then, by theorem 1, any solution to (A1) must satisfy 2/1>cγ . Therefore,
∫ >>C
c pdc 11γ , i.e., condition (6) is violated. Thus, we must have 11 ≥p . Similarly, we
must have 12 ≥p , which means that 121 == pp .
To show that 2/1=cγ cannot be a solution to (A1), let us find
( )
( )( ) ( ) ( ) ( )
+−
−−+=
∂−+∂
−=
==∂
∂
−−
zEvzEvRREu
U
ccc
ccc
cc
c
1121
21
211
212/1
1)1(
2/1)(
αα
αδγγ
γγδ
γγγ
Since at 121 == pp we have ( ) ( )zEvzEv −= , and since
( )( ) ( ) 02/11 21 ==
∂−+∂
cc
cc RREu γγ
γγ
we can find
34
( ) 02/1)(
==∂
∂c
c
cU γγγ
(A8)
However,
( )
( )( ) ( )
( ) ( ) ( )
( )( ) ( ) ( ) ( )zEvRREu
zEvzEv
RREu
U
ccc
ccc
c
cc
ccc
cc
c
2
221
2
22
221
2
2
2
2112/1
1)1
21
211
211
2/11
)1(
2/1)(
−
−−
−+=
∂−+∂
−=
=
+−
−−+
+=∂
−+∂−=
==∂
∂
α
αα
ααδγγ
γγδ
ααδ
γγ
γγδ
γγ
γ
Since ( ) 0<zEv , we have that ( ) ( ) 0211
2
>
−
−
zEvc
α
ααδ . Thus, if cδ is large enough
we have that ( ) 02/1)(
2
2
>=∂
∂c
c
cU γγ
γ which means that 2/1=cγ is a local minimum of
)( cU γ and cannot be a solution to (A1).
Since in the equilibrium we must have ∫ =C
c dc 1γ , in the case when some investors invest
γ in asset #1 and )1( γ− in asset 2, an equal number of investors must invest )1( γ− in
asset #1 and γ in asset #2. Q.E.D.
35
Proof of proposition 2
By contradiction, assume that 11 ≤p . By theorem 1 (global monotonicity), we have
2/1>cγ . Thus, ∫ ≥>C
c pdc 11γ which contradicts equilibrium condition (6). Thus,
21 1 pp >> . This inequality immediately implies
( ) ( ) ( )
=<==
2
2
2
2
1
2
1
1
1
1
pR
EpRE
pRE
pRE
pR
E
Q.E.D.
Proof of theorem 2.
Assume that after observing the t=1/2 signals D=2/1,1ξ and D−=2/1,2ξ portfolio
manager decides to allocate $n into first asset. At t=1/2 stock prices will be 2
11
Dp +=
and 2
12
Dp −= . Since initially he invested $1/2 in asset #1 and $1/2 in asset #2, at t=1/2
he has a total of $1 to invest, and, thus, will invest $(1-n) in asset #2. We need to show
that he will want to reallocate his investment from asset #1 to asset #2, i.e., we want to
show that the optimal amount of investment in asset #1 is 2
1 Dn +< .
At time t=1/2 his objective function is to maximize
( ) ( ) ( ) ( )( )
( ) ( ) ( )( ) ( )
−+−−+⋅+
+
−−++−−+⋅=
−−−
+++
11211
21
)21()21(211
21
ppp
ppp
RvRvRu
DRvDRvRuEU
δδ
δδ (A9)
where
36
( ) ( )DDnD
DnR p 21
1121
1−
−−++
+=+ (A10)
and
Dn
DnR p −
−++
=−
11
1 (A11)
are the portfolio returns in the case when the “t=1” news are D=1,1ξ and D−=1.2ξ and
when they are D−=1,1ξ and D=1.2ξ respectively. Equations (A10) and (A11) can be
rewritten as
( )( ) ( )221211
1 DDnDDD
R p −−+−+
=+ (A12)
( )( ) ( )nDDDD
R p 2111
1 −+−+
=− (A13)
By contradiction, assume that 2
1 Dn +> and denote nD −+=1ζ . In this case
( ) ( )ζ−+ = pp RnR and ( ) ( )nRR pp−+ =ζ . To find a contradiction, it is enough to show that
( ) ( )ζEUnEU < . And, to show that, it is enough to show that (to simplify notation I will
use +pR for ( )nR p
+ )
37
( ) ( ) ( )( )( ) ( ) ( )( ) 012)21()21(
12)21()21(
<−+−−++−
−−+−−++−≡+−−
−++
ppp
ppp
RvDRvDRv
RvDRvDRvψ (A14)
Since D<1/2, we have DRRD pp 21121 −>>>>+ −+ . Thus, ψ can be rewritten as
( )( ) ( )( ) ( )( )( ) ( )( ) ( )ααα
ααα
λ
λλψ
122121
122121
−−−−−−++
+−−−−+−+−=++−
−++
ppp
ppp
RDRRD
RDRRD (A15)
Denote
( )( )DD
Dnm
−+
+−=
112
1
(A16)
Substituting (A16) into (A12) and (A13) gives us
mRp +=+ 1 (A17)
mR p −=− 1 (A18)
m positively depends on n and m=0 if and only if 2
1 Dn += . Thus, we need to show
that 0<ψ for 0>m . Using (A17) and (A18), we can rewrite (A15) as
( ) ( ) ( )( )αααλψ mmDmD 2221 −−−++= (A19)
Since ( ) αxxf = is concave, ( ) ( ) ( ) ( )αααα θθ mmmDmD −−+<−−+ 22 for any
D2<θ and 0>m . Take m=θ . Thus, ( ) ( ) ( ) αααα mmmDmD 2222 <<−−+ .
38
Therefore, ( ) 0<mψ for 0>m . This means that ( ) ( )ζEUnEU < which contradict to the
assumption that investing n$ into first asset is optimal. Thus, we should have 2
1 Dn +≤ .
To complete the proof we need to show that 2
1 Dn += is not an optimal allocation either.
To show that, it is enough to show that ( ) 0lim0
21
<
∂∂
−+
→ nnU
Dn
. Note that
( ) ( )( ) ( ) 0122)1(2
1 =−−⋅′=
+=
∂+∂ −+
DnDuDnn
RuRu pp (A20)
thus, we need to show that
( ) ( ) ( )( )( )0
12)21()21(lim
02
1<
∂−+−−++−∂ −++
−+
→ nRvDRvDRv ppp
Dn (A21)
Using (A16), (A17) and (A18), we can rewrite (A21) as
( ) ( ) ( )( ) 0222lim0
<
∂−+++−−∂
−→ nmmDmD
m
αααλ (A22)
which holds since ( )( )
∂−−∂
−→ nmD
m
αλ 2lim0
and ( )( )
∂+∂
−→ nmD
m
α2lim0
are finite and
( )( ) −∞=
∂−∂
−→ nm
m
α2lim0
. Q.E.D.
39
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42
Figure 1Expected utility in the symmetric case
-0.272
-0.2715
-0.271
-0.2705
-0.27
-0.2695
-0.269
-0.2685
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
gamma
expe
cted
util
ity
E(U)
43
Figure 2aThe effect of the importance of relative component in utility function on the expected utility
-0.275
-0.274
-0.273
-0.272
-0.271
-0.27
-0.269
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
gamma
expe
cted
util
ity
delta=0.945 delta=0.95 delta=0.96
44
Figure 2bThe effect of the importance of relative component in utility function on the expected utility
-0.274
-0.273
-0.272
-0.271
-0.27
-0.269
-0.268
-0.267
-0.266
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
gamma
expe
cted
util
ity
del=0.945055 del=0.94 del=0.932
45
Figure 3The effect of price differences on the expected utility
-0.275
-0.274
-0.273
-0.272
-0.271
-0.27
-0.269
-0.268
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
gamma
expe
cted
util
ity
p1=1 p1=1.0005 p1=1.001