Deep Modulation (Deepmod): A Self-Taught PHY Layer for Resilient Digital Communications

• Published in: arXiv.org
• Main Authors: Anderson, Adam, Young, Steven R, Reed, F Kyle, Vann, Jason M
• Format: Paper
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 29.08.2019
• Subjects: Acoustic noise; Artificial intelligence; Channels; Machine learning; Optimization; Radio frequency; Signal processing; Wireless communications
• ISSN: 2331-8422

Traditional physical (PHY) layer protocols contain chains of signal processing blocks that have been mathematically optimized to transmit information bits efficiently over noisy channels. Unfortunately, this same optimality encourages ubiquity in wireless communication technology and enhances the potential for catastrophic cyber or physical attacks due to prolific knowledge of underlying physical layers. Additionally, optimal signal processing for one channel medium may not work for another without significant changes in the software protocol. Any truly resilient communications protocol must be capable of immediate redeployment to meet quality of service (QoS) demands in a wide variety of possible channel media. Contrary to many traditional approaches which use immutable man-made signal processing blocks, this work proposes generating real-time blocks {\it ad hoc} through a machine learning framework, so-called deepmod, that is only relevant to the particular channel medium being used. With this approach, traditional signal processing blocks are replaced with machine learning graphs which are trained, used, and discarded as needed. Our experiments show that deepmod, using the same machine intelligence, converges to viable communication links over vastly different channels including: radio frequency (RF), powerline communications (PLC), and acoustic channels.