Automatic Modulation Classification Research Articles

A Semantic-Consistent Few-Shot Modulation Recognition Framework for IoT Applications.

The rapid growth of the Internet of Things (IoT) has led to the widespread adoption of the IoT networks in numerous digital applications. To counter physical threats in these systems, automatic modulation classification (AMC) has emerged as an effective approach for identifying the modulation format of signals in noisy environments. However, identifying those threats can be particularly challenging due to the scarcity of labeled data, which is a common issue in various IoT applications, such as anomaly detection for unmanned aerial vehicles (UAVs) and intrusion detection in the IoT networks. Few-shot learning (FSL) offers a promising solution by enabling models to grasp the concepts of new classes using only a limited number of labeled samples. However, prevalent FSL techniques are primarily tailored for tasks in the computer vision domain and are not suitable for the wireless signal domain. Instead of designing a new FSL model, this work suggests a novel approach that enhances wireless signals to be more efficiently processed by the existing state-of-the-art (SOTA) FSL models. We present the semantic-consistent signal pretransformation (ScSP), a parameterized transformation architecture that ensures signals with identical semantics exhibit similar representations. ScSP is designed to integrate seamlessly with various SOTA FSL models for signal modulation recognition and supports commonly used deep learning backbones. Our evaluation indicates that ScSP boosts the performance of numerous SOTA FSL models, while preserving flexibility.

Learning Cross-Domain Features With Dual-Path Signal Transformer.

The past decade has witnessed the rapid development of deep neural networks (DNNs) for automatic modulation classification (AMC). However, most of the available works learn signal features from only a single domain via DNNs, which is not reliable enough to work in uncertain and complex electromagnetic environments. In this brief, a new cross-domain signal transformer (CDSiT) is proposed for AMC, to explore the latent association between different domains of signals. By constructing a signal fusion bottleneck (SFB), CDSiT can implicitly fuse and classify signal features with complementary structures in different domains. Extensive experiments are performed on RadioML2016.10A and RadioML2018.01A, and the results show that CDSiT outperforms its counterparts, particularly for some modulation modes that are difficult to classify before. Through ablation experiences, we also verify the effectiveness of each module in CDSiT.

Lightweight Automatic Modulation Classification Based on Efficient Convolution and Graph Sparse Attention in Low-Resource Scenarios

Lightweight Automatic Modulation Classification Based on Efficient Convolution and Graph Sparse Attention in Low-Resource Scenarios

Automatic Modulation Classification for OFDM Signals Based on CNN with α-Softmax Loss Function

Automatic Modulation Classification for OFDM Signals Based on CNN with α-Softmax Loss Function

Frequency-Constrained Iterative Adversarial Attacks for Automatic Modulation Classification

Frequency-Constrained Iterative Adversarial Attacks for Automatic Modulation Classification

Knowledge Embedding Networks based on Deep Learning for Automatic Modulation Classification in Cognitive Radio

Knowledge Embedding Networks based on Deep Learning for Automatic Modulation Classification in Cognitive Radio

VT-MCNet: High-Accuracy Automatic Modulation Classification Model Based on Vision Transformer

VT-MCNet: High-Accuracy Automatic Modulation Classification Model Based on Vision Transformer

Generalized Automatic Modulation Classification for OFDM Systems Under Unseen Synthetic Channels

Generalized Automatic Modulation Classification for OFDM Systems Under Unseen Synthetic Channels

Automatic Modulation Classification for MIMO System Based on the Mutual Information Feature Extraction

Automatic Modulation Classification for MIMO System Based on the Mutual Information Feature Extraction

Multi-Scale Feature Fusion and Distribution Similarity Network for Few-Shot Automatic Modulation Classification

Multi-Scale Feature Fusion and Distribution Similarity Network for Few-Shot Automatic Modulation Classification

MAMC - Optimal on Accuracy and Efficiency for Automatic Modulation Classification with Extended Signal Length

MAMC - Optimal on Accuracy and Efficiency for Automatic Modulation Classification with Extended Signal Length

Uncertainty-Aware Incremental Automatic Modulation Classification with Bayesian Neural Network

Uncertainty-Aware Incremental Automatic Modulation Classification with Bayesian Neural Network

Efficient Automatic Modulation Classification in Non-Terrestrial Networks With SNN-Based Transformer

Efficient Automatic Modulation Classification in Non-Terrestrial Networks With SNN-Based Transformer

Prototypical Network with Residual Attention for Modulation Classification of Wireless Communication Signals

Automatic modulation classification (AMC) based on data-driven deep learning (DL) can achieve excellent classification performance. However, in the field of electronic countermeasures, it is difficult to extract salient features from wireless communication signals under scarce samples. Aiming at the problem of modulation classification under scarce samples, this paper proposes a few-shot learning method using prototypical network (PN) with residual attention (RA), namely PNRA, to achieve the AMC. Firstly, the RA is utilized to extract the feature vector of wireless communication signals. Subsequently, the feature vector is mapped to a new feature space. Finally, the PN is utilized to measure the Euclidean distance between the feature vector of the query point and each prototype in this space, determining the type of the signals. In comparison to mainstream few-shot learning (FSL) methods, the proposed PNRA can achieve effective and robust AMC under the data-hungry condition.

A Fast Multi-Loss Learning Deep Neural Network for Automatic Modulation Classification

A Fast Multi-Loss Learning Deep Neural Network for Automatic Modulation Classification

Residual Stack-Aided Hybrid CNN-LSTM-Based Automatic Modulation Classification for Orthogonal Time-Frequency Space System

Residual Stack-Aided Hybrid CNN-LSTM-Based Automatic Modulation Classification for Orthogonal Time-Frequency Space System

Deep Learning-Based Automatic Modulation Classification Using Robust CNN Architecture for Cognitive Radio Networks

Automatic modulation classification (AMC) is an essential technique in intelligent receivers of non-cooperative communication systems such as cognitive radio networks and military applications. This article proposes a robust automatic modulation classification model based on a new architecture of a convolutional neural network (CNN). The basic building convolutional blocks of the proposed model include asymmetric kernels organized in parallel combinations to extract more meaningful and powerful features from the raw I/Q sequences of the received signals. These blocks are connected via skip connection to avoid vanishing gradient problems. The experimental results reveal that the proposed model performs well in classifying nine different modulation schemes simulated with different real wireless channel impairments, including AWGN, Rician multipath fading, and clock offset. The performance of the proposed system systems shows that it outperforms its best rivals from the literature in recognizing the modulation type. The proposed CNN architecture remarkably improves classification accuracy at low SNRs, which is appropriate in realistic scenarios. It achieves 86.1% accuracy at −2 dB SNR. Furthermore, it reaches an accuracy of 96.5% at 0 dB SNR and 99.8% at 10 dB SNR. The proposed architecture has strong feature extraction abilities that can effectively recognize 16QAM and 64QAM signals, the challenging modulation schemes of the same modulation family, with an overall average accuracy of 81.02%.

Dendrogram-based Heterogeneous Learners for Automatic Modulation Classification in DSTBC-OFDM Systems

Software-Defined Radios (SDRs) have a crucial role in dynamic spectrum sensing and sharing as they can quickly adapt to changes in their environment. Digital Modulation Recognition (DMR) enables this process by giving SDR the ability to recognize the received signal modulation format to make intelligent and autonomous decisions to switch on the optimal modulation scheme. However, with the deployment of the Distributed Space-Time Block Coding Orthogonal Frequency Division Multiplexing (DSTBC-OFDM) signals that support MIMO systems, that provides spatio-temporel multiplexing, new and challenging signal identification problems have emerged.This paper proposes a robust DMR method for relaying Space-Time Block Coding (STBC) Orthogonal Frequency Division Multiplexing (OFDM) systems. The proposed classifier is built using heterogeneous base classifiers namely, Support Vector Machine (SVM), K-Nearest Neighbors (KNN), and Random Forest (RFC), based on a Dendrogram or decision tree structure.The Dendrogram-based Heterogeneous Learners (DHL) classifier were obtained via Ascendant Hierarchical Clustering (AHC) and by employing Higher-Order Moment (HOMs) and Higher-Order Cumulants (HOCs) as features. Moreover, we propose a grid search-based hyperparameter tuning for DHL to produce the best structure and optimize the performance.

CrossTLNet: A Multitask-Learning-Empowered Neural Network with Temporal Convolutional Network–Long Short-Term Memory for Automatic Modulation Classification

Amidst the evolving landscape of non-cooperative communication, automatic modulation classification (AMC) stands as an essential pillar, enabling adaptive and reliable signal processing. Due to the advancement of deep learning (DL) technology, neural networks have found application in AMC. However, the previous DL models face the inter-class confusion problem in high-order modulations. To address this issue, we propose a multitask-learning-empowered hybrid neural network, named CrossTLNet. Specifically, after the signal enters the model, it is first transformed into two task components: in-phase/quadrature (I/Q) form and amplitude/phase (A/P) form. For each task, we design a method that combines a temporal convolutional network (TCN) with a long short-term memory (LSTM) network to effectively capture long-term dependency features in high-order modulations. To enable interaction between these two different dimensional features, we innovatively introduce a cross-attention method, thereby further enhancing the model’s ability to distinguish signal features. Moreover, we also design a simple and efficient knowledge distillation method to reduce the size of CrossTLNet, making it easier to deploy in real-time or resource-limited scenarios. The experimental results indicate that the suggested method exhibits exceptional performance in AMC on public benchmarks, especially in high-order modulations.

ShuffleFormer: An efficient shuffle meta framework for automatic modulation classification

Automatic modulation classification (AMC) plays an essential and fundamental part in wireless communication systems, which can greatly enhance the efficiency of spectrum utilization. With the rapid development of internet of things, it has been an urgent task to effectively deploy AMC method in edge devices which usually have limited computing power. Hence, there is a pressing need for a high-performance AMC method, especially in terms of high accuracy and low computation complexity in modulation recognition. Although numerous AMC methods have been proposed, it is still a challenge to develop a novel AMC method with both high recognition accuracy and limited parameters. Recently, MetaFormer, as the promising technology, has achieved outstanding performance in processing long sequences. Inspired by MetaFormer, in this paper, an efficient end-to-end deep ShuffleFormer AMC approach is proposed to realize high performance modulation recognition. In the proposed approach, firstly, the PreBlock is proposed to extract deep information from input signals, in which both the channel and temporal attention are utilized to enrich the useful features. Then, bidirectional gated recurrent unit (BiGRU) is employed to further refine the abundant information for feature extraction. Furthermore, ShuffleFormer module is proposed, which innovatively fuse shuffle blocks into MetaFormer to further enhance its both local and global feature extraction ability with less parameters. Experimental results demonstrate that the ShuffleFormer AMC approach has more superior recognition performance than other contrastive methods, i.e., at least 5.97% average accuracy improvement with almost the same number of parameters, and less 41.4% parameters with a competitive average accuracy.