TY - GEN
T1 - Securing QR Codes Using a Hybrid Pseudo Baker's Mapped Cellular Automation
AU - Iliyasu, Abdullah M.
AU - Iliyasu, Abubakar M.
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Since their advent in 1994, Quick Response (QR) codes have grown to become ubiquitous in wide-ranging applications covering marketing, healthcare, commerce, and many other areas. Increasingly, commerce, QR codes are taking up roles where confidentiality, privacy, and integrity of the information they transmit or and/or the identities of parties involved in the communication is vital. Meanwhile, cellular automation (CA) is veritable tool for abstract dynamical information processing with finite number of discrete states space, and time that can be updated synchronously contents and is steered. By employing a pseudo baker's map, we design a template to scramble the QR code content whose evolution is steered using the dextral boundary condition (DBC) of cellular automation. The DBC combines a group of cells permeating contents of a QR code tile at state t to determine the left-most cell entry at state t+1. We evaluated our protocol by implementing both the encryption and recovery procedures on various QR codes, and our findings show that, our method can retain the physical appearance and heterogeneity of the QR code during both the encryption and decryption processes. This is manifest in 100% concordance between the original and recovered QR codes, which is better than what was reported in similar schemes.
AB - Since their advent in 1994, Quick Response (QR) codes have grown to become ubiquitous in wide-ranging applications covering marketing, healthcare, commerce, and many other areas. Increasingly, commerce, QR codes are taking up roles where confidentiality, privacy, and integrity of the information they transmit or and/or the identities of parties involved in the communication is vital. Meanwhile, cellular automation (CA) is veritable tool for abstract dynamical information processing with finite number of discrete states space, and time that can be updated synchronously contents and is steered. By employing a pseudo baker's map, we design a template to scramble the QR code content whose evolution is steered using the dextral boundary condition (DBC) of cellular automation. The DBC combines a group of cells permeating contents of a QR code tile at state t to determine the left-most cell entry at state t+1. We evaluated our protocol by implementing both the encryption and recovery procedures on various QR codes, and our findings show that, our method can retain the physical appearance and heterogeneity of the QR code during both the encryption and decryption processes. This is manifest in 100% concordance between the original and recovered QR codes, which is better than what was reported in similar schemes.
KW - baker's map
KW - cellular automation
KW - CIA triad
KW - Information security
KW - QR Codes
UR - http://www.scopus.com/inward/record.url?scp=85147710627&partnerID=8YFLogxK
U2 - 10.1109/CCIS57298.2022.10016396
DO - 10.1109/CCIS57298.2022.10016396
M3 - Conference contribution
AN - SCOPUS:85147710627
T3 - Proceedings of 2022 8th IEEE International Conference on Cloud Computing and Intelligence Systems, CCIS 2022
SP - 193
EP - 199
BT - Proceedings of 2022 8th IEEE International Conference on Cloud Computing and Intelligence Systems, CCIS 2022
A2 - Ren, Fuji
A2 - Pedrycz, Witold
A2 - Luo, Zhiquan
A2 - Yang, Dan
A2 - Li, Tianrui
A2 - Zhou, Mengqi
A2 - Wang, Weining
A2 - Li, Aijing
A2 - Dandan, Dandan
A2 - Zou, Liu Yaru
A2 - Liu, Yanna
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 8th IEEE International Conference on Cloud Computing and Intelligence Systems, CCIS 2022
Y2 - 26 November 2022 through 28 November 2022
ER -