TY - JOUR
T1 - Roadmap on Optics and Photonics for Security and Encryption
AU - Javidi, Bahram
AU - Carnicer, Artur
AU - Ahmadi, Kavan
AU - Awatsuji, Yasuhiro
AU - Chen, Wen
AU - Fournel, Thierry
AU - Genevet, Patrice
AU - Guo, Jingying
AU - He, Wenqi
AU - Hebert, Mathieu
AU - Jana, Aloke
AU - Lam, Edmund Y.
AU - Long, Gui Lu
AU - Matoba, Osamu
AU - Mi, Zhaoke
AU - Moon, Inkyu
AU - Nishchal, Naveen K.
AU - Pan, Dong
AU - Peng, Xiang
AU - Pinkse, Pepijn W.H.
AU - Shi, Yishi
AU - Situ, Guohai
AU - Stern, Adrian
AU - Wang, Xiaogang
AU - Xia, Tian
AU - Xiao, Yin
AU - Zhenwei, Xie
AU - Zhu, Shuo
N1 - Publisher Copyright:
© 2013 IEEE.
PY - 2025/1/1
Y1 - 2025/1/1
N2 - In 1994, Javidi and Horner published a paper in Optical Engineering that highlighted the ability of free space optical systems to manipulate sensitive data for authentication purposes. The underlying idea was effective yet surprisingly simple: an optical nonlinear joint transform using a random phase mask in both the input and the reference could produce a correlation peak to indicate whether the input object is authentic or not. This seminal paper fueled the development of this new discipline. After three decades, optical encryption and security have matured into a field that plays a central role in the development of photonics techniques. While the pioneering work was mainly focused on the field of optical information processing, nowadays, a broad spectrum of disciplines are contributing to developing security solutions, including nanotechnology, materials science, quantum information, and deep learning, just to cite a few. The present roadmap paper gathers 28 leading authors in the field from 21 academic institutions across nine different countries. It is organized into 17 sections which discuss the present and future challenges, state-of-the-art technology, and real-world solutions to address the security challenges facing our society.
AB - In 1994, Javidi and Horner published a paper in Optical Engineering that highlighted the ability of free space optical systems to manipulate sensitive data for authentication purposes. The underlying idea was effective yet surprisingly simple: an optical nonlinear joint transform using a random phase mask in both the input and the reference could produce a correlation peak to indicate whether the input object is authentic or not. This seminal paper fueled the development of this new discipline. After three decades, optical encryption and security have matured into a field that plays a central role in the development of photonics techniques. While the pioneering work was mainly focused on the field of optical information processing, nowadays, a broad spectrum of disciplines are contributing to developing security solutions, including nanotechnology, materials science, quantum information, and deep learning, just to cite a few. The present roadmap paper gathers 28 leading authors in the field from 21 academic institutions across nine different countries. It is organized into 17 sections which discuss the present and future challenges, state-of-the-art technology, and real-world solutions to address the security challenges facing our society.
KW - Computational neuromorphic imaging
KW - compressive imaging and deep learning
KW - integrated photonics
KW - metasurfaces
KW - optical security and encryption
KW - physical unclonable functions and random number generators
KW - ptychography
KW - quantum secure direct communication
KW - scattering media and speckle
KW - structured light: polarization and orbital angular momentum
UR - https://www.scopus.com/pages/publications/105013126491
U2 - 10.1109/ACCESS.2025.3597226
DO - 10.1109/ACCESS.2025.3597226
M3 - Article
AN - SCOPUS:105013126491
SN - 2169-3536
VL - 13
SP - 140087
EP - 140117
JO - IEEE Access
JF - IEEE Access
ER -