Mas-Colell, Whinton, Green - Solutions Manual[1]

Solutions Manual

! Microeconomic Theory Mas-Colell, Wbinston, and Green

Prepared by :

Chiaki Hara i Cambridge Universiry

Ilya Segal

Un iversity oj California, Berkeley • ,

Steve Tadelis

Harvard Un iverSity

I I , ,

New York Oxford OXFORD UNIVERSITY PRESS 1997

x - y a nd hence x ~ y. If, on the contrary. u(x) > u.(y), then X > y, and

hence x :: y. Thus, if u.(x) ~ u{y), then x ~ y. So u{·) represents r. -

l.B.S First, we shall pr-ove by induction on the number r..; of the elements of X

that, if there is no indifference between any two different elements of X,

then the:-e exists a utility function . If N =: 1, there is nothing t o prove: •

Just ass ign any number to the unique element. So let N > 1 and s uppose that ·

the above assertion is true for N - 1. We will show that it is st ill true for

N. Write X = {x1' ... . xN_l'xN}. By the induction hypothesis. :: can be

represented by a utility function u(·) on the subset {xl' ...• xN

_1}. Without

loss of generality we can assume that u(x11 > u{xZ) > ... > u(xN_1 1.

Consider the following three cases:

Case L For eve,y , < N. xN >- x .. , Case 2, For every , < N. x. ~ xN· ,

N such that x. >- xN

>- x, , 1 • ' J

Case 3, Tnere exist , < N and j <

Since there is no indifference between two different elements, these three

c ases are are exhaus~jve and mutually exclusive. We shall now show how the

value of u(xN

) should be detednined. in each of the three cases, fo:- u(· ) t o

r eor esent >- on the whole X. . -If Case 1 a pplies, t hen take U(X

N) to be larger than u (x

1). If Case 2

aoolies. • • ·a" " \,. "'-

applies. Le:

XN" ... I >-• • •

x .}. J

u {x.. ,) t o be smaller than N

I = {i e {l, ... , N - 1}: X. , Suppose now that Case 3

and J = {j EO, ... , r-.: - l}:

Campletene!Os and the assumption that there is no indifference

impli es that I v J = 0 •. .. • N - 1). The transitivity implies that both I and

J are " . ." I nT.e 'Y8!S , in the sense that if i E I and i' < i, then i' E l ; and if

J E J and j' > j, then j' E J. Let i- = max I, then j- + 1 = min J. Take

r r •

• •

the open interval (u(x .• I),U{X'.»' Then it is t o s~e 1 • 1

that u(· ) rep,eser.ts ?: on the whole X.

Suppose next that there may be indifference bet weer. som~ two elements of

x = { xl •... ' x " J. Fa. each n = 1 •. .. • N, define X ;: {x e X: x - x}. Then, 1', nm mn

bo" the reflex ivity of - (Proposition l.B.Hiill. v

N X = X. Also, by the

transitivity of - (Proposition l.8.Hiill, if X ~ . n x . m then n X

m = 0 . So

let M be a subset of O •... ,N} such that x = U MX and X ;: X fo:-mE m m n

any m E M

and any n E M with m ;: n. Define an relation >-* on {X : m e M} by letting X - m m

>-- X if and only if xm ~ x - n - n

In fact, by the definition of M, there is no

indifference between two different elements of {X : m EM}. m

Thus, bv the o

preceding result. there exists a utility function u*(') that represents ~ .. -= u·(X ) if m e M and x

m n EX .

m It is easy t.o

show t.hat, b y t.h~ tranS itivity, u(·J represents ?:.

I.e,! Ii y E C({x,Y,z}l. then the \VA would imply that Y E C({x,y}). B~t

contradicts the equality C({x,y}) = {x}. Hence Y E: C({x,y,z») . Th'JS

C« X,y ,Z}) E {{x},{z},{x, z}}.

I.C.2 The p:-ope .... t y in t he q uestion are equiva lent t o the f ollow ir.g prope:-ty ;

If B E ~ , B' E $ , X E B. 'i E 8, x E 8', Y E 8'. x E C(E ), and Y E C(S' ), t hen

X E C(E') and Y E G(E). We shall thus prove the equivalence betweer. this

property and the Weak Axiom.

. S up;lOse :~irs·. '-hat t he Weak Axiom IS sati sfied, Assume t ha', 8 e 2, S ' E

~ , X E 8. Y E B , XES' , Y E 8' . X E C(Sl , and y E G{E' ). If we app ly the

Weak Axiom t\ ... ·ice, we obtain x E e(B') and y E G(S ). Hence t he above Drooertv • • 0

.. ,- ".,- -,,_.. --.'"'

r Suppose conversely that the above property is satisfied. Let B E :8, x Ii:

B, Y E B, XES', and x E C(S). Furthermore, let 8' E 'E, x E 8', Y E B', and

Y E C(S'). Tnen the above condition implies that x E CIS' ) (and Y E em )). r Thus the Weak Axiom is satisfied.

l.C.3 (a) Suppose that x >-- y, then there is some E E :B such that x E 8, y E

r B, x. E C(B), and Y E CeB). Thus x ~. y. Suppose that y ~- x, then there

exists B E :a such that x E B, Y E B and x E C(B]' But the Weak Axiom implies

that Y E e(B), which is a contradiction. Hence if x. ).- y, then we cannot have ;

Y )-- x. He~ce x )-•• y . -Converseiy, SUppose that x )-•• Y. then x ~. y but not y Hence

• •

there is some B E 1l such that x E B, Y E B, x E erB) and if x E E' and YES'

fa, any E' E ~ , ther, Y E em' }. In particular, x E GtE) and y E e(E )' Thus •

x )-. y

The equality of the two relation is not guaranteed without the WA. As

car. be seen from the above proof, the WA is not necessary to guarantee tha: if"

x )-•• y, the:! x )- . y . But the converse need not be true, as shown by the

fcUo·.ving example. Define X· = {x·,Y.z}, :B = {{x,y},(x,y ,z}}, C({x ,y} ) = {x},

and C({x, y,z}) = {y}. Then x )-. y and Y )-. x. But neither x >- - y nor y >-- x .

(b) The re lation )- . need not be transitive, as shown by the following example.

Define X = {x,y,z}, ~ = {{x,Y},{y,z}}, C({x,y» = {x} and C({y,z} ) = {y}.

The:l. x >-* y and y )-- 2. But we do not have x )-- z (because neither of the tWO -sets m :B incl udes {x,z}} and hence we do not have x )-. z either.

(e) According to the proof of Proposition l.D.2, if 'B includes all three-

e:er.1er,t subset of X, then ::* is transitive. By Proposition l.B.Hil, F·· is

transit ive . Since)-·)s equal to )-•• , )-. is also transit ive.

An alternative proof is as foll ows; Let x e X. y e X, z e X. x }-W y, and

y )-- z. Then tx.,y,z} E. !B and. by (a). x )-.- y, a nd y )-•• z. Hence we have

nelthe:- y )-- x nor Z >-- y. Since >-- rationalizes (~,C(·)}, this imolies that - - - . y ~ C{(x ,Y.z}) and z f. C({x,y,z}). Since C«x,y.z}) ~ 0, C({x,y,Z} ) = {x}.

Thus x >-. z.

l.D.l The si!Iplest example is X = {x,y}, !8 =- {{xl, {y}}, C({x}} "" {x}, C({y})

= {y}. The!"! at]" rational preference relation of X rationa lizes C( · l.

1.0.2 By Ex~cise 1.B.S. let u{·) be a utility representation of >-. Since X -is finite. for any 8 c X with B ~ 0, there exists x E 8 such that u(x) ~ u(yl

for al l Y E B. Then x E CW(B.~) and h~ce C·(B.t1 ~ 0. (A direct p:-oof with

no use 0: utility representation is possible, but it is essentially the same

as the proof of Exercise 1.8.5.)

1.0.3 Su?pose that the Weak Axiom holds.· I f x E C(X ), then x E C({x ,z}), • •

which cor.tradlcts t he equality C({x,z} ) = {z}. If Y E C(X), then), e

C({X,y»), wn: d contradicts C({x,y}) =- {x}. If z e C(X ), ther.. z e C({y,z} )'

which comracrts C{{x.z}) = {y}. Thus (!B,C(')) must vio late the Weak Axiom.

1.0.4 Let ~ ntionali~ ct·) relative to 1l. Let x E C(Bl

) and Y E C(Bll

U C(E2

). t hec:l :1. ~ Y b~a~ B1 v Bz

:l e(E I) v C(S21. Tnus x E C(C(S I) v

Le: x € ~C(81) u C{B2)l and y E B1 v 82

, then there a,e f our cases:

Case 1. x e C(Bl), y e B

--_ . . .

r Case 2 . X'. e (SI). y e 8

Case 3. x E C(8zJ. y e B)"

x e CCB21. y • H2· r Case 4.

If either Case 1 or 4 is true, then x >- y follows directly fror:: -rationalizability . r If Case 2 is true, then pick any z e C(Bz l. Then z ).- y. -

Hence, -by the transitivity, x >- y. - If ~ z. -f .

Case 3 is true, then pick any Z E C(BI' and do the same argurne:1.t as for Case

2. , . ! •

1.D.5 (a) Assign probability 1/6 to each of the SIX possible p,eferences,

which are x >- y >- z, x >- z >- y, y >- x >- z, y >- z ,.. x. z >- x >- y. and z >- y >-

r X. ,

(b) If the gIven stochastic choice function were rationalizab!e , ther. the _. p robability that at least one of x >- y, y >- Z, and z >- x holds wou!c be at

mas: J x 0/4) = 3/4. But, in fact, at least one of the three relations

a lways hol ::is , because, if the first two do not. hold. t hen y >- x a:J.d z >- y.

Hence the transitivity implies the third. Thus. the given stccha.stic choice

function is not: rationalizable.

(c) T3e same argu ment as 10 (b ) can be used to sho w t hat a. ~ 1/3. Since

C(x.y}) = C({y,z}) - C({z.x}) :::: (a.. 1 - 0:) is equivalent to C{{y,x}) ::::

C({z.y}) = C({ x ,Z}) (I - 0'., 0'. ) , if we apply the same argumer.t as in (b) to y

)- x, z )- y. a :1d X )- z . t hen we can establish 1 - a ?! 1/3. that I S . 0'. -::: 2/3.

Thus, in order f o. the given stochastic choice function is rationalizable, it

is necessary that ex. e [1I3.2I3 J. Moreover . this condition 15 actuaIly

s ufficie:1t : Fo. anv 0:. E [1/3,2/3J. assign probability a. - 1/3 t o each of x )-•

-- ... , .. .

y ;- z, y ;- z >- x , and z >- x >- y; assign probability 2/3 - a: t o each of x ;- z >

y, y >- x >- z , and z >- y >- x. Then we obtain t he given stochastic choic~

functi on.

--------

CHAPTER 1

l.B.l S ince y >- z implies y >- Z, the transi tiv ity implies tha t x ;- z . - -Suppose that z >- x. - Since y ~ z , the transitivity t hen implies that y >- x. -But this contradicts x >- y. Thus we cannot have z >- x. - Hence x >- z.

1.B.2 By the completeness , x >- x f or - every x E X. Hence the,e IS no x e X

such that x >- x. Suppose that x >- y and y >- Z, then x >- y ;: z. By (jii) of

Proposition LB. 1, which was proved in Exercise L8.1, we have x >- z . Hence >-

IS trans itive. Property (jJ is now proved.

, As for ( ii), since x ~ x for every x e X, x - x for every x E X as welL

Thus - is reflexive. Suppose that x - y and y - z . Tnen x t y, Y t z. y = x,

and z >- y. - By t he transitivity, this implies that x t z and z >- x. - Thus x -

z . Hence - is t r ansitive. Suppose x that - y. Then x >- y and y >- x. - - Thus Y

?; x and x ~ y. Hence y - x . Thus - is symmetric Property Oil is now

prnved.

LB.3 Le;: x e X and Y E X. Since u(') r epresents >-, x }- v - -' . ," ""d o"lv ,'c l. _.. " . '

u( x } ~ u(yl. Since f { ' ) is strictly increasing, u (x) it u ( y) if and only if

v { x ) ~ v ( y ). Hence x ~ y if and only if vex) ::!: v(y). Theref 0:'1": v ( . )

represents ~.

1.BA Suppose first that x ?::' y. If. furthermore , y ?::' x , then x - y and hence

u tx ) u ty). If , on the contrary, we do not have y }- x, t h1":n x }- y. Hence -u{ x ) > u (y} . Thus , if x ?::' y, then u(x) ~ u(y).

Suppose conversely that u(x ) ~ u(y ). If , furthermore, u (x) = u (y), then