Difference between revisions of "Baye Morgan Scholten (2006) - Information Search and Price Dispersion"
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imported>Ed (New page: *This page is part of a series under PHDBA279B ==Key Reference(s)== ==Introduction== Baye et al. (2006) provides a survey of models of search and clearing-house that exhibit price d...) |
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Baye et al. (2006) provides a survey of models of search and clearing-house that exhibit price dispersion. The survey is undertaken through two specializable frameworks, one for search and one for cleaning-houses, which are then adapted to show the key results from the literature. There are a number of equivalent results across the two frameworks. | Baye et al. (2006) provides a survey of models of search and clearing-house that exhibit price dispersion. The survey is undertaken through two specializable frameworks, one for search and one for cleaning-houses, which are then adapted to show the key results from the literature. There are a number of equivalent results across the two frameworks. | ||
+ | |||
+ | ==Search Theoretic Models of Price Dispersion== | ||
+ | |||
+ | The general framework used through-out is as follows: | ||
+ | |||
+ | A continuum of price-setting firms with unit measure compete selling an homogenous product | ||
+ | A mass <math>\mu</math> is interested in purchasing the product | ||
+ | Consumers have quasi-linear utility <math>u(q) + y</math> where <math>y\,</math> is a numeraire good | ||
+ | The indirect utility of consumers is <math>V(p,M) = v(p) + M\,</math> | ||
+ | where <math>v(\cdot)\,</math> in nonincreasing in <math>p\,</math>, and <math>M\,</math> is income. | ||
+ | By [http://en.wikipedia.org/wiki/Roy%27s_identity Roy's identity]: | ||
+ | <math>q(p) \equiv -v'(p)\,</math>. | ||
+ | There is a search cost <math>c\,</math> per price quote | ||
+ | The customer purchases after <math>n\,</math> price quotes | ||
+ | The final indirect utility of the customer is <math>V(p,M) = v(p) + M - cn\,</math> | ||
+ | |||
+ | '''A on the derivation of demand''' | ||
+ | Recall that <math>M=e(p,u)\,</math>, so that <math>v(e(p,u),p)=u\,</math> when the expenditure function is evaluated at <math>p\,</math> and <math>u\,</math>. | ||
+ | <math>d/dp(v(M,p)) = dv(M,p)/dm \cdot dM/dp + dv/dp = 0, where dM/dp = de(p,u)/dp\,</math>. | ||
+ | <math>\therefore q(m,p) = de(p,u)/dp = -frac{dv/dp}{dv(M,p)/dm}\,</math> | ||
+ | <math>\therefore q(m,p) = -d/dp(v(p))\,</math> | ||
+ | |||
+ | |||
+ | <math></math> | ||
+ | <math></math> | ||
+ | <math></math> | ||
+ | <math></math> |
Revision as of 20:25, 25 January 2010
- This page is part of a series under PHDBA279B
Key Reference(s)
Introduction
Baye et al. (2006) provides a survey of models of search and clearing-house that exhibit price dispersion. The survey is undertaken through two specializable frameworks, one for search and one for cleaning-houses, which are then adapted to show the key results from the literature. There are a number of equivalent results across the two frameworks.
Search Theoretic Models of Price Dispersion
The general framework used through-out is as follows:
A continuum of price-setting firms with unit measure compete selling an homogenous product A mass [math]\mu[/math] is interested in purchasing the product Consumers have quasi-linear utility [math]u(q) + y[/math] where [math]y\,[/math] is a numeraire good The indirect utility of consumers is [math]V(p,M) = v(p) + M\,[/math] where [math]v(\cdot)\,[/math] in nonincreasing in [math]p\,[/math], and [math]M\,[/math] is income. By Roy's identity: [math]q(p) \equiv -v'(p)\,[/math]. There is a search cost [math]c\,[/math] per price quote The customer purchases after [math]n\,[/math] price quotes The final indirect utility of the customer is [math]V(p,M) = v(p) + M - cn\,[/math]
A on the derivation of demand Recall that [math]M=e(p,u)\,[/math], so that [math]v(e(p,u),p)=u\,[/math] when the expenditure function is evaluated at [math]p\,[/math] and [math]u\,[/math]. [math]d/dp(v(M,p)) = dv(M,p)/dm \cdot dM/dp + dv/dp = 0, where dM/dp = de(p,u)/dp\,[/math]. [math]\therefore q(m,p) = de(p,u)/dp = -frac{dv/dp}{dv(M,p)/dm}\,[/math] [math]\therefore q(m,p) = -d/dp(v(p))\,[/math]
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