Abstract
The wireless environment poses a significant challenge to the propagation of signals. Different effects such as multipath scattering, noise, degradation, distortion, attenuation, and fading affect the distribution of signals adversely. Deep learning techniques can be used to differentiate among different modulated signals for reliable detection in a communication system. This study aims at distinguishing COVID-19 disease images that have been modulated by different digital modulation schemes and are then passed through different noise channels and classified using deep learning models. We proposed a comprehensive evaluation of different 2D Convolutional Neural Network (CNN) architectures for the task of multiclass (24-classes) classification of modulated images in the presence of noise and fading. It is used to differentiate between images modulated through Binary Phase Shift Keying, Quadrature Phase Shift Keying, 16- and 64-Quadrature Amplitude Modulation and passed through Additive White Gaussian Noise, Rayleigh, and Rician channels. We obtained mixed results under different settings such as data augmentation, disharmony between batch normalization (BN), and dropout (DO), as well as lack of BN in the network. In this study, we found that the best performing model is a 2D-CNN model using disharmony between BN and DO techniques trained using 10-fold cross-validation (CV) with a small value of DO before softmax and after every convolution and fully connected layer along with BN layers in the presence of data augmentation, while the least performing model is the 2D-CNN model trained using 5-fold CV without augmentation.
Highlights
An important point to consider in modern wireless communication services is the ability to distinguish between different modulation schemes
We performed a total of 66 experiments. 60 experiments were done as part of 5- and 10-fold CV approaches to select the optimum set of hyperparameters, while 6 experiments were done on the testing dataset
We considered the following seven metrics for the evaluation and comparison of the performance of architectures for all classes of signal classification: Relative Classifier Information (RCI), Strength of Agreement Matthews’ benchmark (SOA-Matthews) for all categories, Matthews’ correlation coefficient (MCC), class-wise Index of Balanced Accuracy (IBA), class-wise Geometric Mean (GM), class-wise Confusion Entropy (CEN), and F2 Score
Summary
An important point to consider in modern wireless communication services is the ability to distinguish between different modulation schemes. The efficient propagation of signals through a wireless channel is of paramount importance to allow the signal energy to be carried optimally. Challenges such as the effects of channel depolarization, intersymbol and co-channel interferences [2], Rician fading [3], and Rayleigh fading channels [2] exist that makes it difficult for the signals to propagate smoothly. The wireless communication system needs to be able to operate in different environments (rural, urban, and suburban), including indoor and outdoor and in all kinds of multipath and time-varying fading channels. The multipath channel is used between the two sources, which is associated with data loss [4]
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