Conversion from Nonstandard to Standard Measure Spaces and Applications in Probability Theory

Loeb, Peter A.

doi:10.2307/1997222

Cited by 101 publications

(101 citation statements)

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“…Below, we show that the existence of a pure-strategy Nash equilibrium can still be obtained when the nowhere equivalence condition is imposed on the agent space; such a result extends the theorem of Rauh (2007). 35 Such probability spaces were introduced by Loeb (1975). For the construction, see Loeb and Wolff (2015).…”

Section: Hyperfinite Agent Spacementioning

confidence: 72%

Modeling infinitely many agents

Sun

2017

Theoretical Economics

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This paper offers a resolution to an extensively studied question in theoretical economics: which measure spaces are suitable for modeling many economic agents? We propose the condition of "nowhere equivalence" to characterize those measure spaces that can be effectively used to model the space of many agents. In particular, this condition is shown to be more general than various approaches that have been proposed to handle the shortcoming of the Lebesgue unit interval as an agent space. We illustrate the minimality of the nowhere equivalence condition by showing its necessity in deriving the determinateness property, the existence of equilibria, and the closed graph property for equilibrium correspondences in general equilibrium theory and game theory.

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Section: Hyperfinite Agent Spacementioning

confidence: 72%

Modeling infinitely many agents

Sun

2017

Theoretical Economics

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“…Let (Ω F L(μ)) be the (complete) Loeb measure generated by (Ω F μ) (Loeb (1975)). Although (Ω F L(μ)) is generated by a nonstandard construction, Loeb showed that it is a probability space in the usual standard sense.…”

Section: Appendix C: Nonstandard Stochastic Integrationmentioning

confidence: 99%

“…We then use nonstandard analysis to produce a candidate equilibrium in the continuous-time model, show that the equilibrium in the hyperfinite model is infinitely close to the candidate equilibrium in the continuous-time model, verify that the candidate prices are dynamically complete, and are in fact equilibrium prices. Anderson (1976) provided a construction for Brownian motion and Brownian stochastic integration using Loeb (1975) measure-a measure in the usual standard sense produced by a nonstandard construction. Anderson's Brownian motion is a hyperfinite random walk which can simultaneously be viewed as being a standard Brownian motion in the usual sense of probability theory.…”

Section: Introductionmentioning

confidence: 99%

Equilibrium in Continuous-Time Financial Markets: Endogenously Dynamically Complete Markets

2008

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We prove existence of equilibrium in a continuous-time securities market in which the securities are potentially dynamically complete: the number of securities is at least one more than the number of independent sources of uncertainty. We prove that dynamic completeness of the candidate equilibrium price process follows from mild exogenous assumptions on the economic primitives of the model. Our result is universal, rather than generic: dynamic completeness of the candidate equilibrium price process and existence of equilibrium follow from the way information is revealed in a Brownian filtration, and of a mild exogenous nondegeneracy condition on the terminal security dividends. The nondegeneracy condition, which requires that finding one point at which a determinant of a Jacobian matrix of dividends is nonzero, is very easy to check. We find that the equilibrium prices, consumptions, and trading strategies are well-behaved functions of the stochastic process describing the evolution of information. We prove that equilibria of discrete approximations converge to equilibria of the continuous-time economy.

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“…" eN Fix H 6 * N \ N ; it will be convenient to assume that H = 4 L for some L. Let At = H~l and let T = {0, At, 2At,..., HAt = 1}. We assume familiarity with the uniform Loeb measure P on T (see [11] or [9]). Now P is a standard probability measure on the <r-algebra <y({B : B £ T, B internal}), whose P-completion is denoted by L(T).…”

Section: Preliminariesmentioning

confidence: 99%

“…In this paper we show that under fairly general conditions on / , internal controls U correspond exactly to relaxed (or generalised) controls (see below for definition) in the following sense: given an internal control U there is a (unique) relaxed control v producing the same trajectory as U, and vice versa. The proof uses hyperfinite Loeb measure [11]. Relaxed controls were introduced by J. Warga [14] and a comprehensive account of them is provided in [15].…”

Section: Introductionmentioning

confidence: 99%

Internal Controls and Relaxed Controls

Cutland

1983

Journal of the London Mathematical Society

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Conversion from Nonstandard to Standard Measure Spaces and Applications in Probability Theory

Cited by 101 publications

References 0 publications

Modeling infinitely many agents

Modeling infinitely many agents

Equilibrium in Continuous-Time Financial Markets: Endogenously Dynamically Complete Markets

Internal Controls and Relaxed Controls

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