Exponentially equivalent measures

Definition

Summarize

Perspective

Let $(M,d)$ be a metric space and consider two one-parameter families of probability measures on $M$ , say $(\mu _{\varepsilon })_{\varepsilon >0}$ and $(\nu _{\varepsilon })_{\varepsilon >0}$ . These two families are said to be exponentially equivalent if there exist

a one-parameter family of probability spaces $(\Omega ,\Sigma _{\varepsilon },P_{\varepsilon })_{\varepsilon >0}$ ,
two families of $M$ -valued random variables $(Y_{\varepsilon })_{\varepsilon >0}$ and $(Z_{\varepsilon })_{\varepsilon >0}$ ,

such that

for each $\varepsilon >0$ , the $P_{\varepsilon }$ -law (i.e. the push-forward measure) of $Y_{\varepsilon }$ is $\mu _{\varepsilon }$ , and the $P_{\varepsilon }$ -law of $Z_{\varepsilon }$ is $\nu _{\varepsilon }$ ,
for each $\delta >0$ , " $Y_{\varepsilon }$ and $Z_{\varepsilon }$ are further than $\delta$ apart" is a $\Sigma _{\varepsilon }$ -measurable event, i.e.

{\big \{}\omega \in \Omega {\big |}d(Y_{\varepsilon }(\omega ),Z_{\varepsilon }(\omega ))>\delta {\big \}}\in \Sigma _{\varepsilon },

for each $\delta >0$ ,

\limsup _{\varepsilon \downarrow 0}\,\varepsilon \log P_{\varepsilon }{\big (}d(Y_{\varepsilon },Z_{\varepsilon })>\delta {\big )}=-\infty .

The two families of random variables $(Y_{\varepsilon })_{\varepsilon >0}$ and $(Z_{\varepsilon })_{\varepsilon >0}$ are also said to be exponentially equivalent.

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Properties

The main use of exponential equivalence is that as far as large deviations principles are concerned, exponentially equivalent families of measures are indistinguishable. More precisely, if a large deviations principle holds for $(\mu _{\varepsilon })_{\varepsilon >0}$ with good rate function $I$ , and $(\mu _{\varepsilon })_{\varepsilon >0}$ and $(\nu _{\varepsilon })_{\varepsilon >0}$ are exponentially equivalent, then the same large deviations principle holds for $(\nu _{\varepsilon })_{\varepsilon >0}$ with the same good rate function $I$ .

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References

Dembo, Amir; Zeitouni, Ofer (1998). Large deviations techniques and applications. Applications of Mathematics (New York) 38 (Second ed.). New York: Springer-Verlag. pp. xvi+396. ISBN 0-387-98406-2. MR 1619036. (See section 4.2.2)