A Theory of Privacy for Cyber-Physical Systems with Applications in Energy Systems

A Theory of Privacy for Cyber-Physical Systems with Applications in Energy Systems
Shuo Han

Citation
Shuo Han. "A Theory of Privacy for Cyber-Physical Systems with Applications in Energy Systems". Talk or presentation, 13, October, 2015.

Abstract
As many cyber-physical systems start to rely on collecting user data for more efficient operation, privacy has emerged as a concern among participating users. In this talk, I will discuss two frameworks that formalize the notion of privacy (differential privacy and information-theoretic privacy) from a unified point of view based on detection theory. I will demonstrate the applications of the two frameworks in energy systems through two case studies. (i) Private distributed charging of electric vehicles: It has been shown that the (non-private) distributed charging problem can be solved using distributed gradient descent. However, the messages exchanged between the center mediator and users may be exploited to breach the privacy of users. We show that differential privacy can be preserved by introducing additive noise to the gradients. We also quantify the trade-off between the level of privacy and the loss of utility using tools from optimization theory. (ii) Private smart metering with internal energy storage: We propose a new information-theoretic metric of privacy in order to handle the privacy of events (e.g., energy usage within any given time slot). The new metric is used to analyze the privacy of a smart metering system that uses internal energy storage as a buffer to hide distinctive energy usage patterns. The results quantify how the amount of energy storage helps improve the level of privacy.

Electronic downloads

seminar.2015-10-13.Shuo_Han.pdf · application/pdf · 2114 kbytes

Citation formats

HTML

Shuo Han. <a
href="http://chess.eecs.berkeley.edu/pubs/1143.html"
><i>A Theory of Privacy for Cyber-Physical Systems
with Applications in Energy Systems</i></a>,
Talk or presentation,  13, October, 2015.

Plain text

Shuo Han. "A Theory of Privacy for Cyber-Physical
Systems with Applications in Energy Systems". Talk or
presentation,  13, October, 2015.

BibTeX

@presentation{Han15_TheoryOfPrivacyForCyberPhysicalSystemsWithApplications,
    author = {Shuo Han},
    title = {A Theory of Privacy for Cyber-Physical Systems
              with Applications in Energy Systems},
    day = {13},
    month = {October},
    year = {2015},
    abstract = {As many cyber-physical systems start to rely on
              collecting user data for more efficient operation,
              privacy has emerged as a concern among
              participating users. In this talk, I will discuss
              two frameworks that formalize the notion of
              privacy (differential privacy and
              information-theoretic privacy) from a unified
              point of view based on detection theory. I will
              demonstrate the applications of the two frameworks
              in energy systems through two case studies. (i)
              Private distributed charging of electric vehicles:
              It has been shown that the (non-private)
              distributed charging problem can be solved using
              distributed gradient descent. However, the
              messages exchanged between the center mediator and
              users may be exploited to breach the privacy of
              users. We show that differential privacy can be
              preserved by introducing additive noise to the
              gradients. We also quantify the trade-off between
              the level of privacy and the loss of utility using
              tools from optimization theory. (ii) Private smart
              metering with internal energy storage: We propose
              a new information-theoretic metric of privacy in
              order to handle the privacy of events (e.g.,
              energy usage within any given time slot). The new
              metric is used to analyze the privacy of a smart
              metering system that uses internal energy storage
              as a buffer to hide distinctive energy usage
              patterns. The results quantify how the amount of
              energy storage helps improve the level of privacy.},
    URL = {http://chess.eecs.berkeley.edu/pubs/1143.html}
}

Posted by Sadigh Dorsa on 20 Oct 2015.
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