Prove Inf Utility Function is Continuous
Abstract
Starting from an intuitive and constructive approach for countable domains, and combining this with elementary measure theory, we obtain an upper semi-continuous utility function based on outer measure. Whenever preferences over an arbitrary domain can at all be represented by a utility function, our function does the job. Moreover, whenever the preference domain is endowed with a topology that makes the preferences upper semi-continuous, so is our utility function. Although links between utility theory and measure theory have been pointed out before, to the best of our knowledge, this is the first time that the present intuitive and straight-forward route has been taken.
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Voorneveld, M. and Weibull, J. (2016) An Elementary Proof That Well-Behaved Utility Functions Exist. Theoretical Economics Letters, 6, 450-457. doi: 10.4236/tel.2016.63051.
Received 21 March 2016; accepted 3 June 2016; published 6 June 2016
1. Introduction
The purpose of this note is primarily pedagogical: it provides necessary and sufficient conditions for the existence of upper semi-continuous utility functions on arbitrary domains; see Theorem 2 and the text following it. Our approach is intuitive, constructive, and although it uses a measure-theoretic idea, it remains easily accessible to readers without any knowledge of measure theory.
Measure theory is the branch of mathematics that deals with the question of how to define the "size" (area/ volume) of sets. The main pedagogical point of our paper is to formalize a direct, intuitive link with utility theory: given a binary preference relation on a set of alternatives, the "better" an alternative is, the "larger" is its set of worse alternatives. So if one can measure the "size" of the set of worse elements, for each given alternative, one obtains a utility function.
To be a bit more precise, measure theory starts out by first defining the "size"―measure―of a class of "simple" sets, such as bounded intervals on the real line or rectangles in the plane, and then extends this definition to other sets by way of approximation in terms of simple sets. The outer measure is the best such approximation "from above". This is illustrated in Figure 1: having defined the size of rectangles in the plane, we can assign a size also to more general sets S in the plane by covering it with rectangles. That can be done in many ways, but to get a good approximation, one wants a covering that resembles S as closely as possible. Roughly speaking, the rectangles covering S should not stick out from S a lot. So the outer measure S is the infimum, over all coverings by a countable number of rectangles, of the sum of the rectangles' areas. In more general settings, the outer measure is defined likewise as the infimum over coverings whose sizes have been defined (see, for instance, Rudin [3] , p. 304; Royden [4] , Sec. 3.2; Billingsley [5] , Sec. 3; Ash [6] , p. 14).
Figure 1. A set S and an approximation of its size using a covering.
We follow this approach to define the utility of an alternative as the outer measure of its set of worse alternatives. We start by doing this for a countable set of alternatives, where this is relatively simple and then proceed to arbitrary sets.
The rest of the paper is organized as follows. Section 2 recalls definitions and provides notation. Section 3 contains the main results; one proof is in the Appendix.
2. Preliminaries
complete: for all
, or both;
transitive: for all
: if 
and
, then
.
As usual, 
means
, but not
, whereas 
means that both 
and
. The sets of elements strictly worse and strictly better than 
are denoted
For 
with
, the "open interval" of alternatives better than x but worse than y is denoted
A preference relation 
is represented by a function 
if
(1)
Any such function u is called a utility function for the preference relation in question.
3. Constructing the Utility Function
This section makes the intuitive argument from the introduction precise: given a binary preference relation on a set of alternatives, the "better" an alternative is, the "larger" is its set of worse alternatives. So if one can measure the "size" of the set of worse elements, for each given alternative, one obtains a utility function.
3.1. Existence
A complete, transitive binary relation 
on a set X can be represented by a utility function if and only if it is Jaffray order separable2 (Jaffray, [10] ): there is a countable set 
such that for all
:
(2)
Roughly speaking, countably many alternatives suffice to keep all pairs 
with 
apart: x lies on one side of d and
, whereas y lies on the other. To make our search for a (usc) utility representation at all meaningful, we will henceforth focus on preference relations that are Jaffray order separable.
Note that Jaffray order separability is satisfied automatically if the domain X itself is countable: you can simply take D equal to X. For uncountable domains, like commodity bundles in
, it is often―for instance under suitable continuity assumptions―the case that the countable subset that does the trick is the set D of commodity bundles with rational coordinates.
The set D in the definition of Jaffray order separability is countable, so let 
be an injection. Finding a utility function on D is easy. Give each element d of D a positive weight such that weights have a finite sum and use the total weight of the elements weakly worse than d as the utility of d. For instance, give
weight 
to the alternative d with label
, weight 
to the alternative d with label
, and inductively, weight 
to the alternative d with label
. In general, let 
be a summable sequence of positive weights; without loss of generality its sum 
is one. Assign to each 
weight
.3 Define 
for each 
by
. Clearly, (1) is satisfied.4
We can extend this procedure from D to X as follows. Let 
be the collection of subsets 
and define 
as follows:
, 
and for
:
(3)
Notice that 
is countable and that it is a covering of X. Extend 
to an outer measure 
on X in the usual way (recall Figure 1): for each set
, define 
as the smallest total size of sets in 
covering A. Formally, a countable collection 
of sets 
from 
covers A if
. Now define
where the infimum is taken over all countable collections 
that cover A.
Define 
for each 
as the outer measure of the set of elements worse than x:
(4)
It is easily seen that this gives the desired utility representation:
Theorem 1. Consider a complete, transitive, Jaffray order separable binary relation 
on an arbitrary set X. The function u in (4) is a utility function for
.
Proof. By definition,
(5)
and the outer measure 
is monotonic: if
, then
.
We prove that u represents
, i.e., we prove (1). Let
. If
, then 
by transitivity of
, so
. If
, there are 
with 
by (2). By monotonicity of 
and (5):
.
Perhaps a more important insight is that it automatically inherits a standard continuity property that is often imposed to guarantee the existence of most preferred elements; this part of the paper is a bit more technical and requires some further definitions.
3.2. Upper Semi-Continuity of the Outer-Measure Utility
continuous if for each
, 
and 
are open;
upper semi-continuous (usc) if for each
, 
is open.
Similarly, a function 
is usc if for each
, 
is open.
Three important topologies are, firstly, the order topology, generated by (i.e., the smallest topology containing) the collections 
and
; secondly, the lower order topology, generated by the collection
, and thirdly, for any subset
, the D-lower order topology, generated by the
collection
. By definition, the order topology is the coarsest topology in which 
is continuous; the lower order topology is the coarsest topology in which 
is usc.
As mentioned in the introduction, although one often appeals to continuity to establish existence of most preferred alternatives, the weaker requirement of upper semi-continuity suffices: consider a complete, transitive, usc binary relation 
over a compact set X. If X has no most preferred element, then for each
, there is a 
with
, i.e., the collection 
is a covering of X with (by usc) open sets. By
compactness, there are finitely many 
such that 
cover X. Let 
be the most preferred element of
. Then 
covers the entire set X, a contradiction.
Theorem 2. Consider a complete, transitive, Jaffray order separable binary relation 
on an arbitrary set X. The utility function u in (4) is usc in the D-lower order topology.
Corollary 1. If 
is a complete, transitive, usc binary relation over a topological space X with countable base, the utility function in (4) represents 
and is usc.
Also Rader [12] establishes existence of a usc utility function under the conditions of Corollary 1. However, we obtain the result as a special case of Theorem 2, which holds under weaker conditions and gives a specific usc utility function building upon basic measure-theoretic intuition.
Sondermann [8] calls a preference relation 
on a set X perfectly separable if there is a countable set 
such that for all
, with 
and 
for all
, the following holds:
Perfect separability implies Jaffray order separability (Jaffray, [10] ), so we obtain the following result, due to Sondermann [8] , as a special case:
Corollary 2. (Sondermann, [8] , Corollary 2) Consider a complete, transitive, perfectly separable binary relation 
on a set X. Then there is a utility function representing
, usc in any topology equal to or finer than the lower order topology.
Also here, the "value added" of Theorem 2 is that it provides a specific usc utility function building upon basic measure-theoretic intuition.
Acknowledgements
We are grateful to Avinash Dixit, Klaus Ritzberger, and Peter Wakker for comments and to the Knut and Alice Wallenberg Foundation and the Wallander-Hedelius Foundation for financial support.
Appendix: Proof of Theorem 2
Recall that
and that the outer measure 
is monotonic: if
, then
.
To establish upper semi-continuity, let
. We show that 
is open. To avoid trivialities, assume that 
equals neither 
nor X. Hence, there is a 
with
. Let 
have
. In particular,
. It suffices to show that there is an open neighborhood V of x with 
for each
.
Case 1: There is no 
with
. As D may be assumed to contain a worst element of X, if such exists (see footnote 1),
. By definition of
, there are 
with 
and
. As
, the set 
is nonempty. As 
and
, 
for each
. So for each 
there is a 
with
. We
show that 
for some
. Suppose, to the contrary, that 
for each
. For each
, the set 
is infinite: otherwise, it has a best element
, but then
is a proper subset of 
by Jaffray order separability, contradicting
. Let 
and let
. By the above, there are infinitely many 
with
, contradicting that
. We conclude that 
for some
. So
, an open set in the D-lower order topology, and for each
:
.
Case 2: There is a 
with
. Using (2) and
:
.
Case 2A: There is a 
with
. Then 
is open in the D-lower order topology, contains x, and for each
.
Case 2B: For each
,
. Then by (2), there is, for each
, a 
that is strictly worse:
. So 
is infinite. Since the sequence of weights
is summable, there is a 
such that
. Since there are only finitely many
with
, there is a 
such that 
for each 
with
.
Since
, 
, which is open in the D-lower order topology. Using 
and the construction of
:
and
Hence, for each
,
Whenever x is not a most preferred alternative in X, Jaffray order separability assures that there is a 
with
, so
: the most precise covering of 
does not use the entire set X. So in that case we can simplify the expression further and write
Jaffray ( [10] , p. 982) defines utility similar to the expression in the previous line, but, so to speak, from the opposite direction: he defines utility of an alternative x as the supremum of the utility of worse ones from a suitably chosen countable set.
NOTES
2See Fishburn ( [11] , Section 3.1) or Bridges and Mehta ( [9] , Section 1.4) for alternative necessary and sufficient separability conditions.
3If there is a worst element in X (an 
with 
for all
), one may assume without loss of generality that D contains one such element, say
. Its weight can be normalized to zero:
. This will assure that 
in (3).
4In class, we usually illustrate this common construction of utility functions on a countable domain D using chocolate bars: since D is countable, we may label its elements
. Now break a chocolate bar in two pieces and place the first piece on
. Then break the remaining piece in two and place one piece on
. Then break the remaining piece in two and place one piece on
, etc. Letting 
denote the weight of the chocolate placed on alternative
, with
, the aggregate weight of any subset is finite (at most one chocolate bar) and the utility function 
that we defined on the countable set D assigns to each alternative d the total weight of chocolate placed on pieces that are weakly worse than d.
Conflicts of Interest
The authors declare no conflicts of interest.
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