Difference between revisions of "Loury (1979) - Market Structure And Innovation"
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*There are <math>n\;</math> identical firms, indexed by <math>i\;</math> | *There are <math>n\;</math> identical firms, indexed by <math>i\;</math> | ||
*Each firm invests <math>x_i\;</math> to buy a random variable <math>\tau(x_i)\;</math> which gives a completion date | *Each firm invests <math>x_i\;</math> to buy a random variable <math>\tau(x_i)\;</math> which gives a completion date | ||
− | *The | + | *The firm with the earliest realised completion date wins <math>V\;</math> |
*<math>\tau \sim F_{\tau}(h(x_i))\;</math> where <math>F_{\tau}\;</math> is the CDF for the exponential distribution: <math>F_{\tau}(h(x_i)) = 1 - e^{-h(x_i)t}\;</math> | *<math>\tau \sim F_{\tau}(h(x_i))\;</math> where <math>F_{\tau}\;</math> is the CDF for the exponential distribution: <math>F_{\tau}(h(x_i)) = 1 - e^{-h(x_i)t}\;</math> | ||
*<math>h(x_i)\;</math> is the rate parameter, or the instantaneous probability of the innovation occuring. | *<math>h(x_i)\;</math> is the rate parameter, or the instantaneous probability of the innovation occuring. |
Revision as of 00:34, 17 November 2010
Reference(s)
- Loury G.C.(1979), "Market structure and innovation", Quarterly Journal of Economics, 93, pp. 395-410. (pdf)
Abstract
In the application of conventional economic theory to the regulation of industry, there often arises a conflict between two great traditions. Adam Smith's "invisible hand" doctrine formalized in the First Fundamental Theorem of Welfare Economics supports the prescription that monopoly should be restrained and competitive market structures should be promoted. On the other hand, Schumpeter, in his classic Capitalism, Socialism and Democracy, takes a dynamic view of the economy in which momentary monopoly power is functional and is naturally eroded over time through entry, imitation, and innovation. Indeed the possibility of acquiring monopoly power and associated quasi rents is necessary to provide entrepreneurs an incentive to pursue innovative activity. As Schumpeter put it, progress occurs through a process of "creative destruction." An antitrust policy that actively promotes static competition is not obviously superior to laissez faire in such a world. This leads one to ponder what degree of competition within an industry leads to performance that is in some sense optimal. This question has been extensively studied in the literature concerning the relationship between industrial concentration and firm investment in research and development.' Both theoretical and empirical studies have suggested the existence of a degree of concentration intermediate between pure monopoly and atomistic (perfect) competition that is best in terms of R & D performance...
The Model
Basic Setup and Assumptions
The basic setup is as follows:
- There are [math]n\;[/math] identical firms, indexed by [math]i\;[/math]
- Each firm invests [math]x_i\;[/math] to buy a random variable [math]\tau(x_i)\;[/math] which gives a completion date
- The firm with the earliest realised completion date wins [math]V\;[/math]
- [math]\tau \sim F_{\tau}(h(x_i))\;[/math] where [math]F_{\tau}\;[/math] is the CDF for the exponential distribution: [math]F_{\tau}(h(x_i)) = 1 - e^{-h(x_i)t}\;[/math]
- [math]h(x_i)\;[/math] is the rate parameter, or the instantaneous probability of the innovation occuring.
[math]h(x_i)\;[/math] is assumed to have the following properties:
- [math]h(0) = 0 = \lim_{x \to \infty} h'(x)\;[/math]
- For some [math]\overline{x} \ge 0\;[/math], [math]h''(x) \ge 0\;[/math] for [math]x \le \overline{x}\;[/math], and [math]h''(x) \le 0\;[/math] for [math]x \ge \overline{x}\;[/math]
- [math]\tilde{x}\;[/math] is defined as the point where [math]\frac{h(x)}{x}\;[/math] is greatest
Let [math]\hat{\tau_i}\;[/math] be an random variable giving the date of the earliest other firm:
[math]\hat{\tau_i} = \min_{j \ne i} \{ \tau(x_j) \}\;[/math]
Assuming iid tau's (no externalities in innovation!), then we can use a nice feature of the exponential distribution which is that if [math]X_1,\ldots,X_N\;[/math] are iid exponential with rates [math]\lambda_1,\ldots,\lambda_N\;[/math], then [math]\min(X_1,\ldots,X_N)\;[/math] is distributed exponential with rate [math]\sum_1^N \lambda_i\;[/math].
Therefore [math]\hat{\tau_i} \sim F_{\hat{\tau}}\;[/math], where
- [math]F_{\hat{\tau}} = 1 - e^{\left( \sum_{j\ne i} -h(x_j) \right) t}\;[/math].
For convenience we denote
- [math]a_i= \sum_{j\ne i} -h(x_j)\; [/math]