Elasticity of substitution

Last updated March 27, 2024

Elasticity of substitution is the ratio of percentage change in capital-labour ratio with the percentage change in Marginal Rate of Technical Substitution.^[1] In a competitive market, it measures the percentage change in the two inputs used in response to a percentage change in their prices.^[2] It gives a measure of the curvature of an isoquant, and thus, the substitutability between inputs (or goods), i.e. how easy it is to substitute one input (or good) for the other.^[3]

History of the concept

John Hicks introduced the concept in 1932. Joan Robinson independently discovered it in 1933 using a mathematical formulation that was equivalent to Hicks's, though that was not implemented at the time.^[4]

Definition

The general definition of the elasticity of X with respect to Y is $E_{Y}^{X}={\frac {\%\ {\mbox{change in X}}}{\%\ {\mbox{change in Y}}}}$ , which reduces to $E_{Y}^{X}={\frac {dX}{dY}}{\frac {Y}{X}}$ for infinitesimal changes and differentiable variables. The elasticity of substitution is the change in the ratio of the use of two goods with respect to the ratio of their marginal values or prices. The most common application is to the ratio of capital (K) and labor (L) used with respect to the ratio of their marginal products $MP_{K}$ and $MP_{L}$ or of the rental price (r) and the wage (w). Another application is to the ratio of consumption goods 1 and 2 with respect to the ratio of their marginal utilities or their prices. We will start with the consumption application.

Let the utility over consumption be given by $U(c_{1},c_{2})$ and let $U_{c_{i}}=\partial U(c_{1},c_{2})/\partial {c_{i}}$ . Then the elasticity of substitution is:

E_{21}={\frac {d\ln(c_{2}/c_{1})}{d\ln(MRS_{12})}}={\frac {d\ln(c_{2}/c_{1})}{d\ln(U_{c_{1}}/U_{c_{2}})}}={\frac {\frac {d(c_{2}/c_{1})}{c_{2}/c_{1}}}{\frac {d(U_{c_{1}}/U_{c_{2}})}{U_{c_{1}}/U_{c_{2}}}}}={\frac {\frac {d(c_{2}/c_{1})}{c_{2}/c_{1}}}{\frac {d(p_{1}/p_{2})}{p_{1}/p_{2}}}}

where $MRS$ is the marginal rate of substitution. (These differentials are taken along the isoquant that passes through the base point. That is, the inputs $c_{1}$ and $c_{2}$ are not varied independently, but instead one input is varied freely while the other input is constrained to lie on the isoquant that passes through the base point. Because of this constraint, the MRS and the ratio of inputs are one-to-one functions of each other under suitable convexity assumptions.) The last equality presents $MRS_{12}=p_{1}/p_{2}$ , where $p_{1},p_{2}$ are the prices of goods 1 and 2. This is a relationship from the first order condition for a consumer utility maximization problem in Arrow–Debreu interior equilibrium, where the marginal utilities of two goods are proportional to prices. Intuitively we are looking at how a consumer's choices over consumption items change as their relative prices change.

Note also that $E_{21}=E_{12}$ :

E_{21}={\frac {d\ln(c_{2}/c_{1})}{d\ln(U_{c_{1}}/U_{c_{2}})}}={\frac {d\left(-\ln(c_{2}/c_{1})\right)}{d\left(-\ln(U_{c_{1}}/U_{c_{2}})\right)}}={\frac {d\ln(c_{1}/c_{2})}{d\ln(U_{c_{2}}/U_{c_{1}})}}=E_{12}

An equivalent characterization of the elasticity of substitution is:^[5]

E_{21}={\frac {d\ln(c_{2}/c_{1})}{d\ln(MRS_{12})}}=-{\frac {d\ln(c_{2}/c_{1})}{d\ln(MRS_{21})}}=-{\frac {d\ln(c_{2}/c_{1})}{d\ln(U_{c_{2}}/U_{c_{1}})}}=-{\frac {\frac {d(c_{2}/c_{1})}{c_{2}/c_{1}}}{\frac {d(U_{c_{2}}/U_{c_{1}})}{U_{c_{2}}/U_{c_{1}}}}}=-{\frac {\frac {d(c_{2}/c_{1})}{c_{2}/c_{1}}}{\frac {d(p_{2}/p_{1})}{p_{2}/p_{1}}}}

In discrete-time models, the elasticity of substitution of consumption in periods $t$ and $t+1$ is known as elasticity of intertemporal substitution.

Similarly, if the production function is $f(x_{1},x_{2})$ then the elasticity of substitution is:

\sigma _{21}={\frac {d\ln(x_{2}/x_{1})}{d\ln MRTS_{12}}}={\frac {d\ln(x_{2}/x_{1})}{d\ln({\frac {df}{dx_{1}}}/{\frac {df}{dx_{2}}})}}={\frac {\frac {d(x_{2}/x_{1})}{x_{2}/x_{1}}}{\frac {d({\frac {df}{dx_{1}}}/{\frac {df}{dx_{2}}})}{{\frac {df}{dx_{1}}}/{\frac {df}{dx_{2}}}}}}=-{\frac {\frac {d(x_{2}/x_{1})}{x_{2}/x_{1}}}{\frac {d({\frac {df}{dx_{2}}}/{\frac {df}{dx_{1}}})}{{\frac {df}{dx_{2}}}/{\frac {df}{dx_{1}}}}}}

where $MRTS$ is the marginal rate of technical substitution.

The inverse of elasticity of substitution is elasticity of complementarity.

Example

Consider Cobb–Douglas production function $f(x_{1},x_{2})=x_{1}^{a}x_{2}^{1-a}$ .

The marginal rate of technical substitution is

MRTS_{21}={\frac {1-a}{a}}{\frac {x_{1}}{x_{2}}}

It is convenient to change the notations. Denote

{\frac {1-a}{a}}{\frac {x_{1}}{x_{2}}}=\theta

Rewriting this we have

{\frac {x_{1}}{x_{2}}}={\frac {a}{1-a}}\theta

Then the elasticity of substitution is^[6]

\sigma _{21}={\frac {d\ln({\frac {x_{1}}{x_{2}}})}{d\ln(MRTS_{21})}}={\frac {d\ln({\frac {x_{1}}{x_{2}}})}{d\ln(\theta )}}={\frac {d{\frac {x_{1}}{x_{2}}}}{\frac {x_{1}}{x_{2}}}}{\frac {\theta }{d\theta }}={\frac {d{\frac {x_{1}}{x_{2}}}}{d\theta }}{\frac {\theta }{\frac {x_{1}}{x_{2}}}}={\frac {a}{1-a}}{\frac {1-a}{a}}{\frac {x_{1}}{x_{2}}}{\frac {x_{2}}{x_{1}}}=1

Economic interpretation

Given an original allocation/combination and a specific substitution on allocation/combination for the original one, the larger the magnitude of the elasticity of substitution (the marginal rate of substitution elasticity of the relative allocation) means the more likely to substitute. There are always 2 sides to the market; here we are talking about the receiver, since the elasticity of preference is that of the receiver.

The elasticity of substitution also governs how the relative expenditure on goods or factor inputs changes as relative prices change. Let $S_{21}$ denote expenditure on $c_{2}$ relative to that on $c_{1}$ . That is:

S_{21}\equiv {\frac {p_{2}c_{2}}{p_{1}c_{1}}}

As the relative price $p_{2}/p_{1}$ changes, relative expenditure changes according to:

{\frac {dS_{21}}{d\left(p_{2}/p_{1}\right)}}={\frac {c_{2}}{c_{1}}}+{\frac {p_{2}}{p_{1}}}\cdot {\frac {d\left(c_{2}/c_{1}\right)}{d\left(p_{2}/p_{1}\right)}}={\frac {c_{2}}{c_{1}}}\left[1+{\frac {d\left(c_{2}/c_{1}\right)}{d\left(p_{2}/p_{1}\right)}}\cdot {\frac {p_{2}/p_{1}}{c_{2}/c_{1}}}\right]={\frac {c_{2}}{c_{1}}}\left(1-E_{21}\right)

Thus, whether or not an increase in the relative price of $c_{2}$ leads to an increase or decrease in the relative expenditure on $c_{2}$ depends on whether the elasticity of substitution is less than or greater than one.

Intuitively, the direct effect of a rise in the relative price of $c_{2}$ is to increase expenditure on $c_{2}$ , since a given quantity of $c_{2}$ is more costly. On the other hand, assuming the goods in question are not Giffen goods, a rise in the relative price of $c_{2}$ leads to a fall in relative demand for $c_{2}$ , so that the quantity of $c_{2}$ purchased falls, which reduces expenditure on $c_{2}$ .

Which of these effects dominates depends on the magnitude of the elasticity of substitution. When the elasticity of substitution is less than one, the first effect dominates: relative demand for $c_{2}$ falls, but by proportionally less than the rise in its relative price, so that relative expenditure rises. In this case, the goods are gross complements.

Conversely, when the elasticity of substitution is greater than one, the second effect dominates: the reduction in relative quantity exceeds the increase in relative price, so that relative expenditure on $c_{2}$ falls. In this case, the goods are gross substitutes.

Note that when the elasticity of substitution is exactly one (as in the Cobb–Douglas case), expenditure on $c_{2}$ relative to $c_{1}$ is independent of the relative prices.

Notes

↑ Sydsaeter, Knut; Hammond, Peter (1995). Mathematics for Economic Analysis. Prentice Hall. pp. 561–562.
↑ Bergstrom, Ted (2015). Lecture Notes on Elasticity of Substitution, p. 5. Viewed June 17, 2016.
↑ de La Grandville, Olivier (1997). "Curvature and elasticity of substitution: Straightening it out". Journal of Economics. 66 (1): 23–34. doi:10.1007/BF01231465. S2CID 154023144.
↑ Chirinko, Robert (2006). Sigma: The Long and Short of It. Journal of Macroeconomics. 2: 671-86.
↑ Given that:
$\ {\frac {d(x_{2}/x_{1})}{x_{2}/x_{1}}}=d\log(x_{2}/x_{1})=d\log x_{2}-d\log x_{1}=-(d\log x_{1}-d\log x_{2})=-d\log(x_{1}/x_{2})=-{\frac {d(x_{1}/x_{2})}{x_{1}/x_{2}}}$
an equivalent way to define the elasticity of substitution is:
$\ \sigma =-{\frac {d(c_{1}/c_{2})}{dMRS}}{\frac {MRS}{c_{1}/c_{2}}}=-{\frac {d\log(c_{1}/c_{2})}{d\log MRS}}$ .
↑ "Elasticity of substitution". 11 July 2019.

Related Research Articles

In calculus, the chain rule is a formula that expresses the derivative of the composition of two differentiable functions $f$ and $g$ in terms of the derivatives of $f$ and $g$ . More precisely, if $is the function such that for every x, then the chain rule is, in Lagrange's notation,$

In calculus, integration by substitution, also known as u-substitution, reverse chain rule or change of variables, is a method for evaluating integrals and antiderivatives. It is the counterpart to the chain rule for differentiation, and can loosely be thought of as using the chain rule "backwards."

In non-Euclidean geometry, the Poincaré half-plane model is the upper half-plane, denoted below as H $, together with a metric, the Poincaré metric, that makes it a model of two-dimensional hyperbolic geometry.$

In geometry, a cissoid is a plane curve generated from two given curves $C 1$ , $C 2$ and a point $O$ . Let $L$ be a variable line passing through $O$ and intersecting $C 1$ at $P 1$ and $C 2$ at $P 2$ . Let $P$ be the point on $L$ so that $Then the locus of such points P is defined to be the cissoid of the curves C 1, C 2 relative to O .$

In microeconomics, a consumer's Marshallian demand function is the quantity they demand of a particular good as a function of its price, their income, and the prices of other goods, a more technical exposition of the standard demand function. It is a solution to the utility maximization problem of how the consumer can maximize their utility for given income and prices. A synonymous term is uncompensated demand function, because when the price rises the consumer is not compensated with higher nominal income for the fall in their real income, unlike in the Hicksian demand function. Thus the change in quantity demanded is a combination of a substitution effect and a wealth effect. Although Marshallian demand is in the context of partial equilibrium theory, it is sometimes called Walrasian demand as used in general equilibrium theory.

In mathematics and economics, the arc elasticity is the elasticity of one variable with respect to another between two given points. It is the ratio of the percentage change of one of the variables between the two points to the percentage change of the other variable. It contrasts with the point elasticity, which is the limit of the arc elasticity as the distance between the two points approaches zero and which hence is defined at a single point rather than for a pair of points.

In mathematics, matrix calculus is a specialized notation for doing multivariable calculus, especially over spaces of matrices. It collects the various partial derivatives of a single function with respect to many variables, and/or of a multivariate function with respect to a single variable, into vectors and matrices that can be treated as single entities. This greatly simplifies operations such as finding the maximum or minimum of a multivariate function and solving systems of differential equations. The notation used here is commonly used in statistics and engineering, while the tensor index notation is preferred in physics.

In microeconomics, the Slutsky equation, named after Eugen Slutsky, relates changes in Marshallian (uncompensated) demand to changes in Hicksian (compensated) demand, which is known as such since it compensates to maintain a fixed level of utility.

A shadow price is the monetary value assigned to an abstract or intangible commodity which is not traded in the marketplace. This often takes the form of an externality. Shadow prices are also known as the recalculation of known market prices in order to account for the presence of distortionary market instruments. Shadow prices are the real economic prices given to goods and services after they have been appropriately adjusted by removing distortionary market instruments and incorporating the societal impact of the respective good or service. A shadow price is often calculated based on a group of assumptions and estimates because it lacks reliable data, so it is subjective and somewhat inaccurate.

<span class="mw-page-title-main">Radical axis</span> All points whose relative distances to two circles are same

In Euclidean geometry, the radical axis of two non-concentric circles is the set of points whose power with respect to the circles are equal. For this reason the radical axis is also called the power line or power bisector of the two circles. In detail:

In mathematics, in the theory of ordinary differential equations in the complex plane $, the points of are classified into ordinary points, at which the equation's coefficients are analytic functions, and singular points, at which some coefficient has a singularity. Then amongst singular points, an important distinction is made between a regular singular point, where the growth of solutions is bounded by an algebraic function, and an irregular singular point, where the full solution set requires functions with higher growth rates. This distinction occurs, for example, between the hypergeometric equation, with three regular singular points, and the Bessel equation which is in a sense a limiting case, but where the analytic properties are substantially different.$

In mathematics, the elasticity or point elasticity of a positive differentiable function f of a positive variable at point a is defined as

Independent goods are goods that have a zero cross elasticity of demand. Changes in the price of one good will have no effect on the demand for an independent good. Thus independent goods are neither complements nor substitutes.

In statistics, the multivariate t-distribution is a multivariate probability distribution. It is a generalization to random vectors of the Student's t-distribution, which is a distribution applicable to univariate random variables. While the case of a random matrix could be treated within this structure, the matrix t-distribution is distinct and makes particular use of the matrix structure.

The PROPT MATLAB Optimal Control Software is a new generation platform for solving applied optimal control and parameters estimation problems.

Elasticity of complementarity is the percentage responsiveness of relative factor prices to a 1 percent change in relative inputs.

In economics, elasticity of intertemporal substitution is a measure of responsiveness of the growth rate of consumption to the real interest rate. If the real interest rate rises, current consumption may decrease due to increased return on savings; but current consumption may also increase as the household decides to consume more immediately, as it is feeling richer. The net effect on current consumption is the elasticity of intertemporal substitution.

<span class="mw-page-title-main">Edwards curve</span>

In mathematics, the Edwards curves are a family of elliptic curves studied by Harold Edwards in 2007. The concept of elliptic curves over finite fields is widely used in elliptic curve cryptography. Applications of Edwards curves to cryptography were developed by Daniel J. Bernstein and Tanja Lange: they pointed out several advantages of the Edwards form in comparison to the more well known Weierstrass form.

In mathematical economics, an isoelastic function, sometimes constant elasticity function, is a function that exhibits a constant elasticity, i.e. has a constant elasticity coefficient. The elasticity is the ratio of the percentage change in the dependent variable to the percentage causative change in the independent variable, in the limit as the changes approach zero in magnitude.

Hamiltonian optics and Lagrangian optics are two formulations of geometrical optics which share much of the mathematical formalism with Hamiltonian mechanics and Lagrangian mechanics.

References

Hicks, J. R. (1932). The Theory of Wages. Macmillan.
Mas-Colell, Andreu; Whinston; Green (2007). Microeconomic Theory. New York, NY: Oxford University Press. ISBN 978-0195073409.
Varian, Hal (1992). Microeconomic Analysis (3rd ed.). W.W. Norton & Company. ISBN 978-0-393-95735-8.
Klump, Rainer; McAdam, Peter; Willman, Alpo (2007). "Factor Substitution and Factor-Augmenting Technical Progress in the United States: A Normalized Supply-Side System Approach". Review of Economics and Statistics . 89 (1): 183–192. doi:10.1162/rest.89.1.183. S2CID 57570638.

External links

The Elasticity of Substitution, Gonçalo L. Fonsekca, essay, The New School for Social Research.

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.

[sydsaeter-1] Sydsaeter, Knut; Hammond, Peter (1995). Mathematics for Economic Analysis. Prentice Hall. pp. 561–562.

[bergstrom-2] Bergstrom, Ted (2015). Lecture Notes on Elasticity of Substitution, p. 5. Viewed June 17, 2016.

[grandville-3] La Grandville, Olivier (1997). "Curvature and elasticity of substitution: Straightening it out". Journal of Economics. 66 (1): 23–34. doi:10.1007/BF01231465. S2CID 154023144.

[chirinko-4] Chirinko, Robert (2006). Sigma: The Long and Short of It. Journal of Macroeconomics. 2: 671-86.

[5] Given that:
$\ {\frac {d(x_{2}/x_{1})}{x_{2}/x_{1}}}=d\log(x_{2}/x_{1})=d\log x_{2}-d\log x_{1}=-(d\log x_{1}-d\log x_{2})=-d\log(x_{1}/x_{2})=-{\frac {d(x_{1}/x_{2})}{x_{1}/x_{2}}}$
an equivalent way to define the elasticity of substitution is:
$\ \sigma =-{\frac {d(c_{1}/c_{2})}{dMRS}}{\frac {MRS}{c_{1}/c_{2}}}=-{\frac {d\log(c_{1}/c_{2})}{d\log MRS}}$ .

[6] "Elasticity of substitution". 11 July 2019.

[1]

[2]

[3]

[4]

[5]

[6]