Secure and robust error correction for physical unclonable functions

@article{Yu2010SecureAR,
  title={Secure and robust error correction for physical unclonable functions},
  author={M. Yu and S. Devadas},
  journal={IEEE Design & Test of Computers},
  year={2010},
  volume={27},
  pages={48-65}
}
  • M. Yu, S. Devadas
  • Published 2010
  • Computer Science
  • IEEE Design & Test of Computers
    • Physical unclonable functions (PUFs) offer a promising mechanism that can be used in many security, protection, and digital rights management applications. One key issue is the stability of PUF responses that is often addressed by error correction codes. The authors propose a new syndrome coding scheme that limits the amount of leaked information by the PUF error-correcting codes. 
    View on IEEE
    dspace.mit.edu
    301 Citations
    Highly Influential Citations
    20
    Background Citations
    107
    Methods Citations
    97
    Results Citations
    3

    Figures, Tables, and Topics from this paper

    Figures and Tables

    Explore Further: Topics Discussed in This Paper

    301 Citations
    Citation Type

    Citation Type

    Key Derivation with Physical Unclonable Functions
    • 3
    • PDF
    Error Correction for Physical Unclonable Functions Using Generalized Concatenated Codes
    • 15
    • PDF
    On Error Correction for Physical Unclonable Functions
    • 37
    • PDF
    Security and Reliability Properties of Syndrome Coding Techniques Used in PUF Key Generation
    • 10
    • PDF
    Attacking and protecting ring oscillator physical unclonable functions and code-offset fuzzy extractors
    • D. Merli
    • Computer Science, Engineering
    • 2013
    • 8
    A New Security Architecture for Smartcards Utilizing PUFs
    • 15
    Systematic Low Leakage Coding for Physical Unclonable Functions
    • 17
    Statistical Analysis of Arbiter Physical Unclonable Functions Using Reliable and Secure Transmission Gates
    • 2
    • PDF
    A novel way to authenticate untrusted Integrated Circuits
    • 22
    Application of LDPC codes on PUF error correction based on code-offset construction
    • 2

    References

    SHOWING 1-10 OF 14 REFERENCES
    Lightweight secure PUFs
    • 92
    • PDF
    Aegis: A Single-Chip Secure Processor
    • 144
    • PDF
    A soft decision helper data algorithm for SRAM PUFs
    • 154
    • PDF
    Physical random functions
    • 224
    • Highly Influential
    • PDF
    Silicon physical random functions
    • 1,268
    • PDF
    Extracting secret keys from integrated circuits
    • 785
    • PDF
    Efficient Helper Data Key Extractor on FPGAs
    • 263
    • PDF
    Intrinsic PUFs from Flip-flops on Reconfigurable Devices
    • 200
    • PDF
    Testing Techniques for Hardware Security
    • 175
    • PDF
    Initial SRAM State as a Fingerprint and Source of True Random Numbers for RFID Tags
    • 270
    • PDF