Large deviations for the one-dimensional Edwards model
Abstract
In this paper we prove a large deviation principle for the empirical drift of a one-dimensional Brownian motion with self-repellence called the Edwards model. Our results extend earlier work in which a law of large numbers, respectively, a central limit theorem were derived. In the Edwards model a path of length T receives a penalty e-β HT, where HT is the self-intersection local time of the path and β∈(0,∞) is a parameter called the strength of self-repellence. We identify the rate function in the large deviation principle for the endpoint of the path as β 23 I(β- 13·), with I(·) given in terms of the principal eigenvalues of a one-parameter family of Sturm-Liouville operators. We show that there exist numbers 0<b**<b*<∞ such that: (1) I is linearly decreasing on [0,b**]; (2) I is real-analytic and strictly convex on (b**,∞); (3) I is continuously differentiable at b**; (4) I has a unique zero at b*. (The latter fact identifies b* as the asymptotic drift of the endpoint.) The critical drift b** is associated with a crossover in the optimal strategy of the path: for b≥ b** the path assumes local drift b during the full time T, while for 0≤ b<b** it assumes local drift b** during time b**+b2b**T and local drift -b** during the remaining time b**-b2b**T. Thus, in the second regime the path makes an overshoot of size b**-b2T in order to reduce its intersection local time.
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