Non Fungible Gratings as Physical Unclonable Functions

被引:0
|
作者
Monet, Frederic [1 ]
Roberge, Anthony [1 ]
Kashyap, Raman [1 ,2 ]
机构
[1] Polytech Montreal, Engn Phys Dept, Fabulas Lab, Montreal, PQ H3T 1J4, Canada
[2] Polytech Montreal, Elect Engn Dept, Poly Grames, Montreal, PQ H3T 1J4, Canada
来源
IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS | 2023年 / 29卷 / 06期
关键词
Optical fiber polarization; Writing; Authentication; Optical reflection; Optical device fabrication; Hamming distances; Gratings; Optical fibers; optical fiber devices; gratings; electromagnetic scattering by random media; security; BRAGG GRATINGS; FIBER; SECURITY; ARRAYS;
D O I
10.1109/JSTQE.2023.3257741
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
Physical Unclonable Functions (PUFs) are physical devices exploiting intrinsic randomness through the fabrication process that can be used for authentication and secure key generation. In this article, we describe a novel weak PUF architecture based on the inscription of random gratings in an optical fiber, which can be easily interrogated by a commercial instrument due to the enhanced backscatter. With PUF lengths of only 40 mm, we show that the false positive and false negative probabilities can reach below 10(-27). We also describe a temperature and strain compensation algorithm to mitigate environmental fluctuations. Furthermore, we describe an alternative technique which increases the number of bits used for digitizing the PUF's signature, thus significantly decreasing the false identification probabilities by almost two orders of magnitude.
引用
收藏
页数:8
相关论文
共 50 条
  • [1] Secure Management of IoT Devices Based on Blockchain Non-fungible Tokens and Physical Unclonable Functions
    Arcenegui, Javier
    Arjona, Rosario
    Baturone, Iluminada
    APPLIED CRYPTOGRAPHY AND NETWORK SECURITY WORKSHOPS, ACNS 2020, 2020, 12418 : 24 - 40
  • [2] Physical unclonable functions
    Yansong Gao
    Said F. Al-Sarawi
    Derek Abbott
    Nature Electronics, 2020, 3 : 81 - 91
  • [3] Physical unclonable functions
    Gao, Yansong
    Al-Sarawi, Said F.
    Abbott, Derek
    NATURE ELECTRONICS, 2020, 3 (02) : 81 - 91
  • [4] Conformal assembly of plasmonic gratings on electrospun nanofiber membranes for holographic physical unclonable functions
    Yuan, Donglin
    Meng, Xianrui
    Liu, Ying
    Zhang, Manman
    Wang, Chiyu
    Yuan, Ke
    Qiang, Shunfei
    Zhang, Wenkai
    Liu, Dun
    OPTICAL MATERIALS, 2025, 162
  • [5] Physical Unclonable Functions: A Primer
    Bauer, Todd
    Hamlet, Jason
    IEEE SECURITY & PRIVACY, 2014, 12 (06) : 97 - 101
  • [6] Threshold Physical Unclonable Functions
    Marranghello, Felipe
    Yu, Yang
    Dubrova, Elena
    2019 IEEE 49TH INTERNATIONAL SYMPOSIUM ON MULTIPLE-VALUED LOGIC (ISMVL), 2019, : 55 - 60
  • [7] Public Physical Unclonable Functions
    Potkonjak, Miodrag
    Goudar, Vishwa
    PROCEEDINGS OF THE IEEE, 2014, 102 (08) : 1142 - 1156
  • [8] MEMS Gyroscopes as Physical Unclonable Functions
    Willers, Oliver
    Huth, Christopher
    Guajardo, Jorge
    Seidel, Helmut
    CCS'16: PROCEEDINGS OF THE 2016 ACM SIGSAC CONFERENCE ON COMPUTER AND COMMUNICATIONS SECURITY, 2016, : 591 - 602
  • [9] Modeling Attacks on Physical Unclonable Functions
    Ruehrmair, Ulrich
    Sehnke, Frank
    Soelter, Jan
    Dror, Gideon
    Devadas, Srinivas
    Schmidhuber, Juergen
    PROCEEDINGS OF THE 17TH ACM CONFERENCE ON COMPUTER AND COMMUNICATIONS SECURITY (CCS'10), 2010, : 237 - 249
  • [10] QUANTUM READOUT OF PHYSICAL UNCLONABLE FUNCTIONS
    Skoric, Boris
    INTERNATIONAL JOURNAL OF QUANTUM INFORMATION, 2012, 10 (01)
12345