Convex preferences

Last updated October 06, 2023

In economics, convex preferences are an individual's ordering of various outcomes, typically with regard to the amounts of various goods consumed, with the property that, roughly speaking, "averages are better than the extremes". The concept roughly corresponds to the concept of diminishing marginal utility without requiring utility functions.

Notation

Comparable to the greater-than-or-equal-to ordering relation $\geq$ for real numbers, the notation $\succeq$ below can be translated as: 'is at least as good as' (in preference satisfaction).

Similarly, $\succ$ can be translated as 'is strictly better than' (in preference satisfaction), and Similarly, $\sim$ can be translated as 'is equivalent to' (in preference satisfaction).

Definition

Use x, y, and z to denote three consumption bundles (combinations of various quantities of various goods). Formally, a preference relation $\succeq$ on the consumption set X is called convex if whenever

x,y,z\in X

where

y\succeq x

and

z\succeq x

,

then for every $\theta \in [0,1]$ :

\theta y+(1-\theta )z\succeq x

.

i.e., for any two bundles that are each viewed as being at least as good as a third bundle, a weighted average of the two bundles is viewed as being at least as good as the third bundle.

A preference relation $\succeq$ is called strictly convex if whenever

x,y,z\in X

where

y\succeq x

,

z\succeq x

, and

y\neq z

,

then for every $\theta \in (0,1)$ :

\theta y+(1-\theta )z\succ x

i.e., for any two distinct bundles that are each viewed as being at least as good as a third bundle, a weighted average of the two bundles (including a positive amount of each bundle) is viewed as being strictly better than the third bundle.^[1]^[2]

Alternative definition

Use x and y to denote two consumption bundles. A preference relation $\succeq$ is called convex if for any

x,y\in X

where

y\succeq x

then for every $\theta \in [0,1]$ :

\theta y+(1-\theta )x\succeq x

.

That is, if a bundle y is preferred over a bundle x, then any mix of y with x is still preferred over x.^[3]

A preference relation is called strictly convex if whenever

x,y\in X

where

y\sim x

, and

x\neq y

,

then for every $\theta \in (0,1)$ :

\theta y+(1-\theta )x\succ x

.

\theta y+(1-\theta )x\succ y

.

That is, for any two bundles that are viewed as being equivalent, a weighted average of the two bundles is better than each of these bundles.^[4]

Examples

1. If there is only a single commodity type, then any weakly-monotonically increasing preference relation is convex. This is because, if $y\geq x$ , then every weighted average of y and ס is also $\geq x$ .

2. Consider an economy with two commodity types, 1 and 2. Consider a preference relation represented by the following Leontief utility function:

u(x_{1},x_{2})=\min(x_{1},x_{2})

This preference relation is convex. Proof: suppose x and y are two equivalent bundles, i.e. $\min(x_{1},x_{2})=\min(y_{1},y_{2})$ . If the minimum-quantity commodity in both bundles is the same (e.g. commodity 1), then this implies $x_{1}=y_{1}\leq x_{2},y_{2}$ . Then, any weighted average also has the same amount of commodity 1, so any weighted average is equivalent to $x$ and $y$ . If the minimum commodity in each bundle is different (e.g. $x_{1}\leq x_{2}$ but $y_{1}\geq y_{2}$ ), then this implies $x_{1}=y_{2}\leq x_{2},y_{1}$ . Then $\theta x_{1}+(1-\theta )y_{1}\geq x_{1}$ and $\theta x_{2}+(1-\theta )y_{2}\geq y_{2}$ , so $\theta x+(1-\theta )y\succeq x,y$ . This preference relation is convex, but not strictly-convex.

3. A preference relation represented by linear utility functions is convex, but not strictly convex. Whenever $x\sim y$ , every convex combination of $x,y$ is equivalent to any of them.

4. Consider a preference relation represented by:

u(x_{1},x_{2})=\max(x_{1},x_{2})

This preference relation is not convex. Proof: let $x=(3,5)$ and $y=(5,3)$ . Then $x\sim y$ since both have utility 5. However, the convex combination $0.5x+0.5y=(4,4)$ is worse than both of them since its utility is 4.

Relation to indifference curves and utility functions

A set of convex-shaped indifference curves displays convex preferences: Given a convex indifference curve containing the set of all bundles (of two or more goods) that are all viewed as equally desired, the set of all goods bundles that are viewed as being at least as desired as those on the indifference curve is a convex set.

Convex preferences with their associated convex indifference mapping arise from quasi-concave utility functions, although these are not necessary for the analysis of preferences. For example, Constant Elasticity of Substitution (CES) utility functions describe convex, homothetic preferences. CES preferences are self-dual and both primal and dual CES preferences yield systems of indifference curves that may exhibit any degree of convexity.^[5]

Related Research Articles

In mathematics, a symmetric matrix $with real entries is positive-definite if the real number is positive for every nonzero real column vector where is the transpose of . More generally, a Hermitian matrix is positive-definite if the real number is positive for every nonzero complex column vector where denotes the conjugate transpose of$

As a topic of economics, utility is used to model worth or value. Its usage has evolved significantly over time. The term was introduced initially as a measure of pleasure or happiness as part of the theory of utilitarianism by moral philosophers such as Jeremy Bentham and John Stuart Mill. The term has been adapted and reapplied within neoclassical economics, which dominates modern economic theory, as a utility function that represents a consumer's ordinal preferences over a choice set, but is not necessarily comparable across consumers or possessing a cardinal interpretation. This concept of utility is personal and based on choice rather than on pleasure received, and so requires fewer behavioral assumptions than the original concept.

<span class="mw-page-title-main">Indifference curve</span> Concept in economics

In economics, an indifference curve connects points on a graph representing different quantities of two goods, points between which a consumer is indifferent. That is, any combinations of two products indicated by the curve will provide the consumer with equal levels of utility, and the consumer has no preference for one combination or bundle of goods over a different combination on the same curve. One can also refer to each point on the indifference curve as rendering the same level of utility (satisfaction) for the consumer. In other words, an indifference curve is the locus of various points showing different combinations of two goods providing equal utility to the consumer. Utility is then a device to represent preferences rather than something from which preferences come. The main use of indifference curves is in the representation of potentially observable demand patterns for individual consumers over commodity bundles.

The theory of consumer choice is the branch of microeconomics that relates preferences to consumption expenditures and to consumer demand curves. It analyzes how consumers maximize the desirability of their consumption, by maximizing utility subject to a consumer budget constraint. Factors influencing consumers' evaluation of the utility of goods include: income level, cultural factors, product information and physio-psychological factors.

Utility maximization was first developed by utilitarian philosophers Jeremy Bentham and John Stuart Mill. In microeconomics, the utility maximization problem is the problem consumers face: "How should I spend my money in order to maximize my utility?" It is a type of optimal decision problem. It consists of choosing how much of each available good or service to consume, taking into account a constraint on total spending (income), the prices of the goods and their preferences.

In mathematical economics, the Arrow–Debreu model is a theoretical general equilibrium model. It posits that under certain economic assumptions there must be a set of prices such that aggregate supplies will equal aggregate demands for every commodity in the economy.

In economics, an ordinal utility function is a function representing the preferences of an agent on an ordinal scale. Ordinal utility theory claims that it is only meaningful to ask which option is better than the other, but it is meaningless to ask how much better it is or how good it is. All of the theory of consumer decision-making under conditions of certainty can be, and typically is, expressed in terms of ordinal utility.

There are two fundamental theorems of welfare economics. The first states that in economic equilibrium, a set of complete markets, with complete information, and in perfect competition, will be Pareto optimal. The requirements for perfect competition are these:

There are no externalities and each actor has perfect information.
Firms and consumers take prices as given.

Stochastic dominance is a partial order between random variables. It is a form of stochastic ordering. The concept arises in decision theory and decision analysis in situations where one gamble can be ranked as superior to another gamble for a broad class of decision-makers. It is based on shared preferences regarding sets of possible outcomes and their associated probabilities. Only limited knowledge of preferences is required for determining dominance. Risk aversion is a factor only in second order stochastic dominance.

In economics, an agent's preferences are said to be weakly monotonic if, given a consumption bundle $, the agent prefers all consumption bundles that have more of all goods. That is, implies . An agent's preferences are said to be strongly monotonic if, given a consumption bundle, the agent prefers all consumption bundles that have more of at least one good, and not less in any other good. That is, and imply .$

Competitive equilibrium is a concept of economic equilibrium, introduced by Kenneth Arrow and Gérard Debreu in 1951, appropriate for the analysis of commodity markets with flexible prices and many traders, and serving as the benchmark of efficiency in economic analysis. It relies crucially on the assumption of a competitive environment where each trader decides upon a quantity that is so small compared to the total quantity traded in the market that their individual transactions have no influence on the prices. Competitive markets are an ideal standard by which other market structures are evaluated.

In mathematics, contour sets generalize and formalize the everyday notions of

In economics and consumer theory, quasilinear utility functions are linear in one argument, generally the numeraire. Quasilinear preferences can be represented by the utility function $where is strictly concave. A useful property of the quasilinear utility function is that the Marshallian/Walrasian demand for does not depend on wealth and is thus not subject to a wealth effect; The absence of a wealth effect simplifies analysis and makes quasilinear utility functions a common choice for modelling. Furthermore, when utility is quasilinear, compensating variation (CV), equivalent variation (EV), and consumer surplus are algebraically equivalent. In mechanism design, quasilinear utility ensures that agents can compensate each other with side payments.$

In economics and other social sciences, preference refers to the order in which an agent ranks alternatives based on their relative utility. The process results in an "optimal choice". Preferences are evaluations and concern matter of value, typically in relation to practical reasoning. An individual's preferences are determined purely by a person's tastes as opposed to the good's prices, personal income, and the availability of goods. However, people are still expected to act in their best (rational) interest. In this context, rationality would dictate that an individual will select the option that maximizes self-interest when given a choice. Moreover, in every set of alternatives, preferences arise.

Some branches of economics and game theory deal with indivisible goods, discrete items that can be traded only as a whole. For example, in combinatorial auctions there is a finite set of items, and every agent can buy a subset of the items, but an item cannot be divided among two or more agents.

In economics, the Debreu's theorems are preference representation theorems -- statements about the representation of a preference ordering by a real-valued utility function. The theorems were proved by Gerard Debreu during the 1950s.

Efficiency and fairness are two major goals of welfare economics. Given a set of resources and a set of agents, the goal is to divide the resources among the agents in a way that is both Pareto efficient (PE) and envy-free (EF). The goal was first defined by David Schmeidler and Menahem Yaari. Later, the existence of such allocations has been proved under various conditions.

In utility theory, the responsive set (RS) extension is an extension of a preference-relation on individual items, to a partial preference-relation of item-bundles.

In theoretical economics, an abstract economy is a model that generalizes both the standard model of an exchange economy in microeconomics, and the standard model of a game in game theory. An equilibrium in an abstract economy generalizes both a Walrasian equilibrium in microeconomics, and a Nash equilibrium in game-theory.

In economics, a utility representation theorem asserts that, under certain conditions, a preference ordering can be represented by a real-valued utility function, such that option A is preferred to option B if and only if the utility of A is larger than that of B.

References

↑ Hal R. Varian; Intermediate Microeconomics A Modern Approach. New York: W. W. Norton & Company. ISBN 0-393-92702-4
↑ Mas-Colell, Andreu; Whinston, Michael; & Green, Jerry (1995). Microeconomic Theory. Oxford: Oxford University Press. ISBN 978-0-19-507340-9
↑ Board, Simon (October 6, 2009). "Preferences and Utility" (PDF). Econ 11. Microeconomic Theory. Autumn 2009. University of California, Los Angeles.
↑ Sanders, Nicholas J. "Preference and Utility - Basic Review and Examples" (PDF). College of William & Mary. Archived from the original (PDF) on March 20, 2013.
↑ Baltas, George (2001). "Utility-consistent Brand Demand Systems with Endogenous Category Consumption: Principles and Marketing Applications". Decision Sciences. 32 (3): 399–422. doi:10.1111/j.1540-5915.2001.tb00965.x.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Varian-1] Hal R. Varian; Intermediate Microeconomics A Modern Approach. New York: W. W. Norton & Company. ISBN 0-393-92702-4

[Mas-2] Mas-Colell, Andreu; Whinston, Michael; & Green, Jerry (1995). Microeconomic Theory. Oxford: Oxford University Press. ISBN 978-0-19-507340-9

[Board-3] Board, Simon (October 6, 2009). "Preferences and Utility" (PDF). Econ 11. Microeconomic Theory. Autumn 2009. University of California, Los Angeles.

[Sanders-4] Sanders, Nicholas J. "Preference and Utility - Basic Review and Examples" (PDF). College of William & Mary. Archived from the original (PDF) on March 20, 2013.

[5] Baltas, George (2001). "Utility-consistent Brand Demand Systems with Endogenous Category Consumption: Principles and Marketing Applications". Decision Sciences. 32 (3): 399–422. doi:10.1111/j.1540-5915.2001.tb00965.x.

[1]

[2]

[3]

[4]

[5]

Convex preferences

Contents

Notation

Definition

Alternative definition

Examples

Relation to indifference curves and utility functions

See also

Related Research Articles

References