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Quantitative Correlation Inequalities via Semigroup Interpolation

Authors Anindya De, Shivam Nadimpalli, Rocco A. Servedio

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Author Details

Anindya De
  • University of Pennsylvania, Philadelphia, PA, USA
Shivam Nadimpalli
  • Columbia University, New York, NY, USA
Rocco A. Servedio
  • Columbia University, New York, NY, USA

Funding

  • De, Anindya: A.D. is supported by NSF grants CCF 1910534 and CCF 1926872.
  • Nadimpalli, Shivam: S.N. is supported by NSF grants CCF-1563155 and by CCF-1763970.
  • Servedio, Rocco A.: R.A.S. is supported by NSF grants CCF-1814873, IIS-1838154, CCF-1563155, and by the Simons Collaboration on Algorithms and Geometry.

Cite AsGet BibTex

Anindya De, Shivam Nadimpalli, and Rocco A. Servedio. Quantitative Correlation Inequalities via Semigroup Interpolation. In 12th Innovations in Theoretical Computer Science Conference (ITCS 2021). Leibniz International Proceedings in Informatics (LIPIcs), Volume 185, pp. 69:1-69:20, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2021)
https://doi.org/10.4230/LIPIcs.ITCS.2021.69

Abstract

Most correlation inequalities for high-dimensional functions in the literature, such as the Fortuin-Kasteleyn-Ginibre inequality and the celebrated Gaussian Correlation Inequality of Royen, are qualitative statements which establish that any two functions of a certain type have non-negative correlation. We give a general approach that can be used to bootstrap many qualitative correlation inequalities for functions over product spaces into quantitative statements. The approach combines a new extremal result about power series, proved using complex analysis, with harmonic analysis of functions over product spaces. We instantiate this general approach in several different concrete settings to obtain a range of new and near-optimal quantitative correlation inequalities, including: - A {quantitative} version of Royen’s celebrated Gaussian Correlation Inequality [Royen, 2014]. In [Royen, 2014] Royen confirmed a conjecture, open for 40 years, stating that any two symmetric convex sets must be non-negatively correlated under any centered Gaussian distribution. We give a lower bound on the correlation in terms of the vector of degree-2 Hermite coefficients of the two convex sets, conceptually similar to Talagrand’s quantitative correlation bound for monotone Boolean functions over {0,1}ⁿ [M. Talagrand, 1996]. We show that our quantitative version of Royen’s theorem is within a logarithmic factor of being optimal. - A quantitative version of the well-known FKG inequality for monotone functions over any finite product probability space. This is a broad generalization of Talagrand’s quantitative correlation bound for functions from {0,1}ⁿ to {0,1} under the uniform distribution [M. Talagrand, 1996]; the only prior generalization of which we are aware is due to Keller [Nathan Keller, 2012; Keller, 2008; Nathan Keller, 2009], which extended [M. Talagrand, 1996] to product distributions over {0,1}ⁿ. In the special case of p-biased distributions over {0,1}ⁿ that was considered by Keller, our new bound essentially saves a factor of p log(1/p) over the quantitative bounds given in [Nathan Keller, 2012; Keller, 2008; Nathan Keller, 2009]. We also give {a quantitative version of} the FKG inequality for monotone functions over the continuous domain [0,1]ⁿ, answering a question of Keller [Nathan Keller, 2009].

Subject Classification

ACM Subject Classification
  • Mathematics of computing
  • Mathematics of computing → Probability and statistics
Keywords
  • complex analysis
  • correlation inequality
  • FKG inequality
  • Gaussian correlation inequality
  • harmonic analysis
  • Markov semigroups

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References

  1. D. Bakry, I. Gentil, and M. LeDoux. Analysis and Geometry of Markov Diffusion Operators. Springer, 2013. URL: https://books.google.com/books?id=tf37sgEACAAJ.
  2. Andrew C. Berry. The accuracy of the Gaussian approximation to the sum of independent variates. Transactions of the American Mathematical Society, 49(1):122-136, 1941. Google Scholar
  3. Peter Borwein and Tamás Erdélyi. Littlewood-type polynomials on subarcs of the unit circle. Indiana University Mathematics Journal, 46(4):1323-1346, 1997. Google Scholar
  4. Peter Borwein, Tamás Erdélyi, and Géza Kós. Littlewood-type problems on [0,1]. Proceedings of the London Mathematical Society, 3(79):22-46, 1999. Google Scholar
  5. A. De, S. Nadimpalli, and R. Servedio. Influences for Centrally Symmetric, Convex Sets. In preparation, 2020. Google Scholar
  6. Carl-Gustav Esseen. On the Liapunoff limit of error in the theory of probability. Arkiv för matematik, astronomi och fysik, A:1-19, 1942. Google Scholar
  7. C. M. Fortuin, P. W. Kasteleyn, and J. Ginibre. Correlation inequalities on some partially ordered sets. Comm. Math. Phys., 22(2):89-103, 1971. URL: https://projecteuclid.org:443/euclid.cmp/1103857443.
  8. G. Gallavotti. A proof of the Griffiths inequalities for the XY model. Stud. Appl. Math, 50(1):89-92, 1971. Google Scholar
  9. R. Griffiths. Correlations in Ising ferromagnets. I. Journal of Mathematical Physics, 8(3):478-483, 1967. Google Scholar
  10. T.E. Harris. A lower bound for the critical probability in a certain percolation process. Proc. Camb. Phil. Soc., 56:13-20, 1960. Google Scholar
  11. Yaozhong Hu. Itô-wiener chaos expansion with exact residual and correlation, variance inequalities. Journal of Theoretical Probability, 10(4):835-848, 1997. Google Scholar
  12. G. Kalai, N. Keller, and E. Mossel. On the correlation of increasing families. Journal of Combinatorial Theory, Series A, 144, November 2015. URL: https://doi.org/10.1016/j.jcta.2016.06.012.
  13. N. Keller. Lower bound on the correlation between monotone families in the average case. Advances in Applied Mathematics, 43(1):31-45, 2009. Google Scholar
  14. N. Keller, E. Mossel, and A. Sen. Geometric Influences II: Correlation Inequalities and Noise Sensitivity. Ann. Inst. H. Poincaré Probab. Statist., 50(4):1121-1139, November 2014. URL: https://doi.org/10.1214/13-AIHP557.
  15. Nathan Keller. Improved FKG Inequality for product measures on the discrete cube, 2008. Google Scholar
  16. Nathan Keller. Influences of variables on Boolean functions. PhD thesis, Hebrew University of Jerusalem, 2009. Google Scholar
  17. Nathan Keller. A simple reduction from a biased measure on the discrete cube to the uniform measure. European Journal of Combinatorics, 33:1943-1957, 2012. Google Scholar
  18. D. Kelly and S. Sherman. General Griffiths' inequalities on correlations in Ising ferromagnets. Journal of Mathematical Physics, 9(3):466-484, 1968. Google Scholar
  19. Daniel J Kleitman. Families of non-disjoint subsets. Journal of Combinatorial Theory, 1(1):153-155, 1966. Google Scholar
  20. Rafał Latała and Dariusz Matlak. Royen’s Proof of the Gaussian Correlation Inequality. Geometric Aspects of Functional Analysis, pages 265-275, 2017. URL: https://doi.org/10.1007/978-3-319-45282-1_17.
  21. R. O'Donnell. Analysis of Boolean functions. Cambridge University Press, 2014. Google Scholar
  22. Christopher J. Preston. A generalization of the FKG inequalities. Communications in Mathematical Physics, 36(3):233-241, 1974. Google Scholar
  23. Thomas Royen. A simple proof of the Gaussian correlation conjecture extended to multivariate gamma distributions. arXiv preprint, 2014. URL: http://arxiv.org/abs/1408.1028.
  24. Walter Rudin. Real and Complex Analysis, 3rd Ed. McGraw-Hill, Inc., 1987. Google Scholar
  25. M. Suzuki. Correlation inequalities and phase transition in the generalized X-Y model. Journal of Mathematical Physics, 14(7):837-838, 1973. Google Scholar
  26. M. Talagrand. How much are increasing sets positively correlated? Combinatorica, 16(2):243-258, 1996. Google Scholar
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