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In [[economics]], a '''complete market''' (or '''complete system of markets''') is one in which the complete set of possible gambles on future states-of-the-world can be constructed with existing [[asset]]s without [[Frictionless market|friction]]. Every agent is able to exchange every good, directly or indirectly, with every other agent without [[transaction costs]]. Here goods are state-contingent; that is, a good includes the time and state of the world in which it is consumed. So for instance, an umbrella tomorrow if it rains is a distinct good from an umbrella tomorrow if it is clear. The study of complete markets is central to state-preference theory. The theory can be traced to the work of [[Kenneth Arrow]] (1964), [[Gérard Debreu]] (1959), Arrow & Debreu (1954) and [[Lionel McKenzie]](1954). Arrow and Debreu were awarded the [[Nobel Memorial Prize in Economics]] (Arrow in 1972, Debreu in 1983), largely for their work in developing the theory of complete markets and applying it to the problem of general equilibrium.
 
A '''state of the world''' is a complete specification of the values of all relevant variables over the relevant time horizon. A '''state-contingent claim''', or '''state claim''', is a contract whose future payoffs depend on future states of the world. For example, suppose you can bet on the outcome of a coin toss. If you guess the outcome correctly, you will win one dollar, and otherwise you will lose one dollar. A bet on heads is a state claim, with payoff of one dollar if heads is the outcome, and payoff of negative one dollar if tails is the outcome. "Heads" and "tails" are the states of the world in this example. A state-contingent claim can be represented as a payoff vector with one element for each state of the world, e.g. (payoff if heads, payoff if tails). So a bet on heads can be represented as ($1, -$1) and a bet on tails can be represented as (-$1, $1). Notice that by placing one bet on heads and one bet on tails, you have a state-contingent claim of ($0, $0); that is, the payoff is the same regardless of which state of the world occurs.
 
The bet on a coin toss is a simplistic example but illustrates widely applicable concepts, especially in [[finance]]. If markets are complete, it is possible to arrange a portfolio with any conceivable payoff vector. That is, the state claims available for purchase, represented as payoff vectors, [[Linear span|span]] the payoff space. A ''pure security'' or simple [[contingent claims| contingent claim]] is a state claim that pays off in only one state. Any state-contingent claim can be regarded as a collection of pure securities. A system of markets is complete if and only if the number of attainable pure securities equals the number of possible states. Formally, a market is complete with respect to a [[trading strategy]], <math>s</math>, if there exists a [[self-financing trading strategy]], <math>s_0</math> such that at any time <math>t</math>, the returns of the two strategies, <math>s</math> and <math>s_0</math>  are equal. This is equivalent to stating that for a complete market, all cash flows for a trading strategy can be replicated using a similar synthetic trading strategy. Because a trading strategy can be simplified into a set of simple [[contingent claims]] (strategies paying 1 in one state and 0 in every other state), a complete market can be generalized as the ability to replicate cash flows of all simple contingent claims.
 
For example, consider the [[put–call parity]]:
 
:<math>\text{ Call } + \text{ Present Value of Strike Price } = \text{ Put } + \text{ Underlying security } \,</math>
 
A put option can be synthetically created by solving the parity for put:
 
:<math>\text{ Put } = \text{ Call } + \text{ Present Value of Strike Price } - \text{ Underlying security } \,</math>
 
A put is synthesized by buying the call, investing the strike at the risk free rate, and shorting the stock. If the calls on the stock are not traded in the market, the market is considered an incomplete market because it does not provide the ability to replicate the returns of a put option.
 
Often used to describe insurance markets the model of a complete market occurs if [[wiktionary:agent|agent]]s can buy insurance contracts to protect themselves against ''any'' future time and state-of-the-world.
 
For example, if a market is a finite state market with dimension ''N'', then a complete market would be one where there exist traded assets with payoffs that form a basis for&nbsp;'''R'''<sup>''N''</sup>.
 
== Dynamically complete market ==
 
In order for a market to be complete, it must be possible to ''instantaneously'' enter into any position  regarding any future state of the market.  In contrast, a market is called '''dynamically complete''' if it is possible to construct a self-financing trading strategy that will have the same cash-flow.  In other words, a complete market allows you to  place all of your bet at once, while a dynamically complete market may require that you execute subsequent trades after making your initial investment.  The requirement that the strategy be self-financing means that subsequent trades must be cash-flow neutral (you cannot contribute or withdraw any additional funds).  Any complete market is also dynamically complete.
 
== Further reading ==
 
* Mark D. Flood (1991), [http://research.stlouisfed.org/publications/review/91/03/Markets_Mar_Apr1991.pdf "An Introduction to Complete Markets"], [[Federal Reserve Bank of St. Louis]], Review, March/April 1991
 
== See also ==
*[[Incomplete markets]]
 
[[Category:Economics models]]

Revision as of 00:53, 12 February 2014

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