Enhancing Secrecy Capacity With Non-Orthogonal Artificial Noise Based on Pilot Information Codebook

• Published in: IEEE wireless communications letters Vol. 13; no. 4; pp. 1019 - 1023
• Main Authors: Gu, Yebo, Shen, Tao, Song, Jian, Wang, Qingbo
• Format: Journal Article
• Language: English
• Published: Piscataway IEEE 01.04.2024; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Channel state information; imperfect channel state information; Mathematical analysis; MIMO communication; Non-orthogonal artificial noise; Optimization; perfect channel state information; pilot-based codebook non-orthogonal artificial noise; Receivers; Reconfigurable intelligent surfaces; secrecy capacity; Signal to noise ratio; Unmanned aerial vehicles; White noise; Wireless communication; Wireless communication systems
• ISSN: 2162-2337; 2162-2345
• DOI: 10.1109/LWC.2024.3357652

Contemporary research has highlighted that the design possibilities for Orthogonal Artificial Noise (AN) are circumscribed by the inherent limitations in channel degrees of freedom, yielding a scant assortment of design alternatives. In this letter, Non-Orthogonal Artificial Noise (NORAN) emerges as a viable substitute. Its applications have been recognized in relay communication systems such as those involving Unmanned Aerial Vehicles (UAVs) and Intelligent Reflecting Surfaces (IRS). Despite this, the mathematical exploration of the Secrecy Capacity (SC) function within wireless communication systems incorporating NORAN has been scant. This letter pioneers the examination of the concave-convex nature of the SC function in such systems. The findings reveal that, subject to certain transmit power conditions, the SC function for NORAN is inherently convex, implying a decrement in SC upon NORAN's deployment, which negates its intended effect. In response to this conundrum, this discourse introduces Pilot-based Codebook Non-Orthogonal Artificial Noise (PCAN), wherein the codebook capitalizes on pilot signals exchanged between the receiver and sender as an encryption key. The receiver, with the aid of the pilot signals, retrieves the forthcoming PCAN from the codebook, thereby neutralizing the PCAN's influence during the reception of information. This innovation equates the SC functions of PCAN and AN within the same channel framework. Additionally, this letter delves into the optimization conundrum of PCAN, considering scenarios of both perfect and imperfect Channel State Information (CSI). Through theoretical analysis, it is established that with an ideal CSI and an signal-to-noise ratio (SNR) surpassing zero, the quintessential power allocation for PCAN equates to half of the total transmission power. Contrariwise, under imperfect CSI parameters, PCAN fails to deliver efficacy.