Deep-Learned Compression for Radio-Frequency Signal Classification
- URL: http://arxiv.org/abs/2403.03150v1
- Date: Tue, 5 Mar 2024 17:42:39 GMT
- Title: Deep-Learned Compression for Radio-Frequency Signal Classification
- Authors: Armani Rodriguez, Yagna Kaasaragadda, Silvija Kokalj-Filipovic
- Abstract summary: Next-generation cellular concepts rely on the processing of large quantities of radio-frequency (RF) samples.
We propose a deep learned compression model, HQARF, to compress the complex-valued samples of RF signals.
We are assessing the effects of HQARF on the performance of an AI model trained to infer the modulation class of the RF signal.
- Score: 0.49109372384514843
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Next-generation cellular concepts rely on the processing of large quantities
of radio-frequency (RF) samples. This includes Radio Access Networks (RAN)
connecting the cellular front-end based on software defined radios (SDRs) and a
framework for the AI processing of spectrum-related data. The RF data collected
by the dense RAN radio units and spectrum sensors may need to be jointly
processed for intelligent decision making. Moving large amounts of data to AI
agents may result in significant bandwidth and latency costs. We propose a deep
learned compression (DLC) model, HQARF, based on learned vector quantization
(VQ), to compress the complex-valued samples of RF signals comprised of 6
modulation classes. We are assessing the effects of HQARF on the performance of
an AI model trained to infer the modulation class of the RF signal. Compression
of narrow-band RF samples for the training and off-the-site inference will
allow for an efficient use of the bandwidth and storage for non-real-time
analytics, and for a decreased delay in real-time applications. While exploring
the effectiveness of the HQARF signal reconstructions in modulation
classification tasks, we highlight the DLC optimization space and some open
problems related to the training of the VQ embedded in HQARF.
Related papers
- Augmenting Training Data with Vector-Quantized Variational Autoencoder for Classifying RF Signals [9.99212997328053]
This paper proposes the use of a Vector-Quantized Variational Autoencoder (VQ-VAE) to augment training data.
The VQ-VAE model generates high-fidelity synthetic RF signals, increasing the diversity and fidelity of the training dataset.
Our experimental results show that incorporating VQ-VAE-generated data significantly improves the classification accuracy of the baseline model.
arXiv Detail & Related papers (2024-10-23T21:17:45Z) - RF Challenge: The Data-Driven Radio Frequency Signal Separation Challenge [66.33067693672696]
This paper addresses the critical problem of interference rejection in radio-frequency (RF) signals using a novel, data-driven approach.
First, we present an insightful signal model that serves as a foundation for developing and analyzing interference rejection algorithms.
Second, we introduce the RF Challenge, a publicly available dataset featuring diverse RF signals along with code templates.
Third, we propose novel AI-based rejection algorithms, specifically architectures like UNet and WaveNet, and evaluate their performance across eight different signal mixture types.
arXiv Detail & Related papers (2024-09-13T13:53:41Z) - Diffusion-Driven Semantic Communication for Generative Models with Bandwidth Constraints [27.049330099874396]
This paper introduces a diffusion-driven semantic communication framework with advanced VAE-based compression for bandwidth-constrained generative model.
Our experimental results demonstrate significant improvements in pixel-level metrics like peak signal to noise ratio (PSNR) and semantic metrics like learned perceptual image patch similarity (LPIPS)
arXiv Detail & Related papers (2024-07-26T02:34:25Z) - RF-Diffusion: Radio Signal Generation via Time-Frequency Diffusion [15.175370227353406]
We introduce a novel Time-Frequency Diffusion theory to enhance the original diffusion model, enabling it to tap into the information within the time, frequency, and complex-valued domains of RF signals.
RF-Diffusion is a versatile solution to generate diverse, high-quality, and time-series RF data.
We also showcase the versatility of RF-Diffusion in boosting Wi-Fi sensing systems and performing channel estimation in 5G networks.
arXiv Detail & Related papers (2024-04-14T04:56:05Z) - One-shot Generative Distribution Matching for Augmented RF-based UAV Identification [0.0]
This work addresses the challenge of identifying Unmanned Aerial Vehicles (UAV) using radiofrequency (RF) fingerprinting in limited RF environments.
The complexity and variability of RF signals, influenced by environmental interference and hardware imperfections, often render traditional RF-based identification methods ineffective.
One-shot generative methods for augmenting transformed RF signals offer a significant improvement in UAV identification.
arXiv Detail & Related papers (2023-01-20T02:35:43Z) - Deep Learning-Based Synchronization for Uplink NB-IoT [72.86843435313048]
We propose a neural network (NN)-based algorithm for device detection and time of arrival (ToA) estimation for the narrowband physical random-access channel (NPRACH) of narrowband internet of things (NB-IoT)
The introduced NN architecture leverages residual convolutional networks as well as knowledge of the preamble structure of the 5G New Radio (5G NR) specifications.
arXiv Detail & Related papers (2022-05-22T12:16:43Z) - Model-based Deep Learning Receiver Design for Rate-Splitting Multiple
Access [65.21117658030235]
This work proposes a novel design for a practical RSMA receiver based on model-based deep learning (MBDL) methods.
The MBDL receiver is evaluated in terms of uncoded Symbol Error Rate (SER), throughput performance through Link-Level Simulations (LLS) and average training overhead.
Results reveal that the MBDL outperforms by a significant margin the SIC receiver with imperfect CSIR.
arXiv Detail & Related papers (2022-05-02T12:23:55Z) - Three-Way Deep Neural Network for Radio Frequency Map Generation and
Source Localization [67.93423427193055]
Monitoring wireless spectrum over spatial, temporal, and frequency domains will become a critical feature in beyond-5G and 6G communication technologies.
In this paper, we present a Generative Adversarial Network (GAN) machine learning model to interpolate irregularly distributed measurements across the spatial domain.
arXiv Detail & Related papers (2021-11-23T22:25:10Z) - Spectro-Temporal RF Identification using Deep Learning [3.8137985834223507]
WRIST is a Wideband, Real-time RF Identification system with Spectro-Temporal detection, framework and system.
Our resulting deep learning model is capable to detect, classify, and precisely locate RF emissions in time and frequency.
WRIST detector achieves 90 mean Average Precision even in extremely congested environment in the wild.
arXiv Detail & Related papers (2021-07-11T19:02:07Z) - Conditioning Trick for Training Stable GANs [70.15099665710336]
We propose a conditioning trick, called difference departure from normality, applied on the generator network in response to instability issues during GAN training.
We force the generator to get closer to the departure from normality function of real samples computed in the spectral domain of Schur decomposition.
arXiv Detail & Related papers (2020-10-12T16:50:22Z) - A Compressive Sensing Approach for Federated Learning over Massive MIMO
Communication Systems [82.2513703281725]
Federated learning is a privacy-preserving approach to train a global model at a central server by collaborating with wireless devices.
We present a compressive sensing approach for federated learning over massive multiple-input multiple-output communication systems.
arXiv Detail & Related papers (2020-03-18T05:56:27Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.