• DocumentCode
    631377
  • Title

    Adapting voltage ramp-up time for temperature noise reduction on memory-based PUFs

  • Author

    Cortez, Mafalda ; Hamdioui, Said ; van der Leest, Vincent ; Maes, Roel ; Schrijen, Geert-Jan

  • Author_Institution
    Fac. of EE, Math. & CS, Delft Univ. of Technol., Delft, Netherlands
  • fYear
    2013
  • fDate
    2-3 June 2013
  • Firstpage
    35
  • Lastpage
    40
  • Abstract
    The efficiency and cost of silicon PUF-based applications, and in particular key generators, are heavily impacted by the level of reproducibility of the bare PUF responses under varying operational circumstances. Error-correcting codes can be used to achieve near-perfect reliability, but come at a high implementation cost especially when the underlying PUF is very noisy. When designing a PUF-based key generator, a more reliable PUF will result in a less complex ECC decoder and a smaller PUF footprint, hence an overall more efficient implementation. This paper proposes a novel insight and resulting technique for reducing noise on memory-based PUF responses, based on adapting supply voltage ramp-up time to ambient temperature. Circuit simulations on 45nm Low-Power CMOS, as well as actual silicon measurements are presented to validate the proposed methods. Our results demonstrate that choosing an appropriate voltage ramp-up for enrollment and adapting it according to the ambient temperature at key-reconstruction is a powerful method which makes memory-based PUF response noise up to three times smaller.
  • Keywords
    CMOS memory circuits; error correction codes; integrated circuit reliability; ECC decoder; PUF footprint; PUF-based key generator; circuit simulations; error-correcting codes; low-power CMOS technology; memory-based PUF response noise; near-perfect reliability; size 45 nm; supply voltage ramp-up time; temperature noise reduction; Noise; Noise measurement; Optimization; Random access memory; Reliability; Silicon; Temperature measurement;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Hardware-Oriented Security and Trust (HOST), 2013 IEEE International Symposium on
  • Conference_Location
    Austin, TX
  • Print_ISBN
    978-1-4799-0559-1
  • Type

    conf

  • DOI
    10.1109/HST.2013.6581562
  • Filename
    6581562