Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-10T15:51:00.328Z Has data issue: false hasContentIssue false
  • English
  • Français

A conditional limit theorem for high-dimensional ℓᵖ-spheres

Part of: Limit theorems General convexity Geometric probability and stochastic geometry

Published online by Cambridge University Press:  16 January 2019

Steven S. Kim  and
Kavita Ramanan
Steven S. Kim*
Affiliation:
Brown University
Kavita Ramanan*
Affiliation:
Brown University
*
* Postal address: Brown University, 182 George Street, Box F, Providence, RI 02912, USA.
* Postal address: Brown University, 182 George Street, Box F, Providence, RI 02912, USA.
Get access Rights & Permissions [Opens in a new window]

Abstract

The study of high-dimensional distributions is of interest in probability theory, statistics, and asymptotic convex geometry, where the object of interest is the uniform distribution on a convex set in high dimensions. The ℓp-spaces and norms are of particular interest in this setting. In this paper we establish a limit theorem for distributions on ℓp-spheres, conditioned on a rare event, in a high-dimensional geometric setting. As part of our proof, we establish a certain large deviation principle that is also relevant to the study of the tail behavior of random projections of ℓp-balls in a high-dimensional Euclidean space.

Keywords

Conditional limit theoremℓᵖ-spherelarge deviationGibbs conditioning principlecone measuresurface measurerelative entropyWasserstein topology

MSC classification

Primary: 60F10: Large deviations 52A20: Convex sets in $n$ dimensions (including convex hypersurfaces)
Secondary: 52A23: Asymptotic theory of convex bodies 60D05: Geometric probability and stochastic geometry
Type
Research Papers
Information
Journal of Applied Probability , Volume 55 , Issue 4 , December 2018 , pp. 1060 - 1077
Copyright
Copyright © Applied Probability Trust 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1]Alonso-Gutiérrez, D., Prochno, J. and Thäle, C. (2018). Large deviations for high-dimensional random projections of ℓpn balls. Adv. Appl. Math. 99, 135.Google Scholar
[2]Ambrosio, L., Gigli, N. and Savaré, G. (2008). Gradient flows in metric spaces and in the space of probability measures (Lectures Math. ETH Z\"urich), 2nd edn. Birkhäuser, Basel.Google Scholar
[3]Barthe, F., Guédon, O., Mendelson, S. and Naor, A. (2005). A probabilistic approach to the geometry of the ℓpn-ball. Ann. Prob. 33, 480513.Google Scholar
[4]Ben Arous, G., Dembo, A. and Guionnet, A. (2001). Aging of spherical spin glasses. Prob. Theory Relat. Fields 120, 167.Google Scholar
[5]Ben Arous, G. and Guionnet, A. (1997). Large deviations for Wigner’s law and Voiculescu’s non-commutative entropy. Prob. Theory Relat. Fields 108, 517542.Google Scholar
[6]Bertini, L.et al. (2015). Macroscopic fluctuation theory. Rev. Modern Phys. 87, 593636.Google Scholar
[7]Billingsley, P. (1999). Convergence of Probability Measures, 2nd edn. John Wiley, New York.Google Scholar
[8]Boyd, S. and Vandenberghe, L. (2004). Convex Optimization, Cambridge University Press.Google Scholar
[9]Cover, T. M. and Thomas, J. A. (2006). Elements of Information Theory, 2nd edn. John Wiley, Hoboken, NJ.Google Scholar
[10]Csiszár, I. (1984). Sanov property, generalized I-projection and a conditional limit theorem. Ann. Prob. 12, 768793.Google Scholar
[11]Dellacherie, C. and Meyer, P.-A. (2011). Probabilities and Potential, C (North-Holland Math. Studies 151). North-Holland, Amsterdam.Google Scholar
[12]Dembo, A. and Shao, Q.-M. (1998). Self-normalized large deviations in vector spaces. In High Dimensional Probability (Progr. Prob. 43). Birkhäuser, Basel, pp. 2732.Google Scholar
[13]Dembo, A. and Zeitouni, O. (1996). Refinements of the Gibbs conditioning principle. Prob. Theory Relat. Fields 104, 114.Google Scholar
[14]Dembo, A. and Zeitouni, O. (1998). Large Deviations Techniques and Applications (Appl. Math. 38), 2nd edn. Springer, Berlin.Google Scholar
[15]Diaconis, P. and Freedman, D. (1987). A dozen de Finetti-style results in search of a theory. Ann. Inst. H. Poincaré Statist. 23, 397423.Google Scholar
[16]Dupuis, P. and Ellis, R. S. (1997). A Weak Convergence Approach to the Theory of Large Deviations. John Wiley, New York.Google Scholar
[17]Ellis, R. S. (2006). Entropy, Large Deviations, and Statistical Mechanics. Springer, Berlin.Google Scholar
[18]Gantert, N., Kim, S. S. and Ramanan, K. (2006). Cramér's theorem is atypical. In Advances in the Mathematical Sciences (Assoc. Women Math. Ser. 6). Springer, Cham, pp. 253270.Google Scholar
[19]Gantert, N., Kim, S. S. and Ramanan, K. (2017). Large deviations for random projections of ℓp balls. Ann. Prob. 45, 44194476.Google Scholar
[20]Kabluchko, Z., Prochno, J. and Thäle, C. (2017). High-dimensional limit theorems for random vectors in $\ell_p^n$-balls. Commun. Contemp. Math. 1750092.Google Scholar
[21]Kim, S. S. (2017). Problems at the interface of probability and convex geometry: Random projections and constrained processes. Doctoral Thesis, Brown University.Google Scholar
[22]Kim, S. S. and Ramanan, K. (2018). Large deviations on the Stiefel manifold. Preprint.Google Scholar
[23]Klartag, B. (2007). A central limit theorem for convex sets. Invent. Math. 168, 91131.Google Scholar
[24]Léonard, C. (2010). Entropic projections and dominating points. ESAIM: Prob. Statist. 14, 343381.Google Scholar
[25]Léonard, C. and Najim, J. (2002). An extension of Sanov's theorem: application to the Gibbs conditioning principle. Bernoulli 8, 721743.Google Scholar
[26]Lynch, J. and Sethuraman, J. (1987). Large deviations for processes with independent increments. Ann. Prob. 15, 610627.Google Scholar
[27]Mogul′skii, A. A. (1991). De Finetti-type results for ℓp. Siberian Math. J. 32, 609619.Google Scholar
[28]Naor, A. (2007). The surface measure and cone measure on the sphere of ℓpn. Trans. Amer. Math. Soc. 359, 10451079.Google Scholar
[29]Naor, A.and Romik, D. (2003). Projecting the surface measure of the sphere of ℓpn. Ann. Inst. H. Poincaré Prob. Statist. 39, 241261.Google Scholar
[30]Rachev, S. T. and Rüschendorf, L. (1991). Approximate independence of distributions on spheres and their stability properties. Ann. Prob. 19, 13111337.Google Scholar
[31]Schechtman, G. and Zinn, J. (1990). On the volume of the intersection of two L pn balls. Proc. Amer. Math. Soc. 110, 217224.Google Scholar
[32]Spruill, M. C. (2007). Asymptotic distribution of coordinates on high dimensional spheres. Electron. Commun. Prob. 12, 234247.Google Scholar
[33]Stam, A. J. (1982). Limit theorems for uniform distributions on spheres in high-dimensional euclidean spaces. J. Appl. Prob. 19, 221228.Google Scholar
[34]Stroock, D. W.and Zeitouni, O. (1991). Microcanonical distributions, Gibbs states, and the equivalence of ensembles. In Random Walks, Brownian Motion, and Interacting Particle Systems (Progr. Prob. 28). Birkhäuser, Boston, MA.Google Scholar
[35]Sznitman, A.-S. (1991). Topics in propagation of chaos. In Ecole d’été de probabilités de Saint-Flour XIXXIX—1989 (Lecture Notes Math. 1464). Springer, Berlin, pp. 165251.Google Scholar
[36]Trashorras, J. (2002). Large deviations for a triangular array of exchangeable random variables. Ann. Inst. H. Poincaré Prob. Statist. 38, 649680.Google Scholar
[37]Villani, C. (2009). Optimal Transport: Old and New, 338, Springer, Berlin.Google Scholar
[38]Wang, R., Wang, X. and Wu, L. (2010). Sanov’s theorem in the Wasserstein distance: a necessary and sufficient condition. Statist. Prob. Lett. 80, 505512.Google Scholar