• DocumentCode
    2867746
  • Title

    Information-Theoretic Bounds for Differentially Private Mechanisms

  • Author

    Barthe, Gilles ; Köpf, Boris

  • fYear
    2011
  • fDate
    27-29 June 2011
  • Firstpage
    191
  • Lastpage
    204
  • Abstract
    There are two active and independent lines of research that aim at quantifying the amount of information that is disclosed by computing on confidential data. Each line of research has developed its own notion of confidentiality: on the one hand, differential privacy is the emerging consensus guarantee used for privacy-preserving data analysis. On the other hand, information-theoretic notions of leakage are used for characterizing the confidentiality properties of programs in language-based settings. The purpose of this article is to establish formal connections between both notions of confidentiality, and to compare them in terms of the security guarantees they deliver. We obtain the following results. First, we establish upper bounds for the leakage of every ϵ-differentially private mechanism in terms of eps and the size of the mechanism´s input domain. We achieve this by identifying and leveraging a connection to coding theory. Second, we construct a class of ϵ-differentially private channels whose leakage grows with the size of their input domains. Using these channels, we show that there cannot be domain-size-independent bounds for the leakage of all ϵ-differentially private mechanisms. Moreover, we perform an empirical evaluation that shows that the leakage of these channels almost matches our theoretical upper bounds, demonstrating the accuracy of these bounds. Finally, we show that the question of providing optimal upper bounds for the leakage of ϵ-differentially private mechanisms in terms of rational functions of ϵ is in fact decidable.
  • Keywords
    channel coding; cryptography; data analysis; data privacy; formal verification; ϵ-differentially private channels; coding theory; confidential data; differential privacy; formal connections; information-theoretic bounds; language-based settings; leakage; privacy-preserving data analysis; security guarantees; Data privacy; Entropy; Noise; Privacy; Probabilistic logic; Security; Upper bound; Differential Privacy; Information Theory; Quantitative Information-Flow;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Computer Security Foundations Symposium (CSF), 2011 IEEE 24th
  • Conference_Location
    Cernay-la-Ville
  • ISSN
    1940-1434
  • Print_ISBN
    978-1-61284-644-6
  • Type

    conf

  • DOI
    10.1109/CSF.2011.20
  • Filename
    5992163