Related papers: Open-set Classification of Common Waveforms Using A Deep Feed-forward Network and Binary Isolation Forest Models

Open-set Classification of Common Waveforms Using A Deep Feed-forward Network and Binary Isolation Forest Models

URL: http://arxiv.org/abs/2110.00252v1
Date: Fri, 1 Oct 2021 08:15:26 GMT
Title: Open-set Classification of Common Waveforms Using A Deep Feed-forward Network and Binary Isolation Forest Models
Authors: C. Tanner Fredieu, Anthony Martone, R. Michael Buehrer
Abstract summary: We use a deep multi-layer perceptron architecture to classify received signals. The system can classify correctly in an open-set mode with 98% accuracy at SNR greater than 0 dB.
Score: 13.078132799573705
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In this paper, we examine the use of a deep multi-layer perceptron architecture to classify received signals as one of seven common waveforms, single carrier (SC), single-carrier frequency division multiple access (SC-FDMA), orthogonal frequency division multiplexing (OFDM), linear frequency modulation (LFM), amplitude modulation (AM), frequency modulation (FM), and phase-coded pulse modulation used in communication and radar networks. Synchronization of the signals is not needed as we assume there is an unknown and uncompensated time and frequency offset. The classifier is open-set meaning it assumes unknown waveforms may appear. Isolation forest (IF) models acting as binary classifiers are used for each known signal class to perform detection of possible unknown signals. This is accomplished using the 32-length feature vector from a dense layer as input to the IF models. The classifier and IF models work together to monitor the spectrum and identify waveforms along with detecting unknown waveforms. Results showed the classifier had 100% classification rate above 0 dB with an accuracy of 83.2% and 94.7% at -10 dB and -5 dB, respectively, with signal impairments present. Results for the IF models showed an overall accuracy of 98% when detecting known and unknown signals with signal impairments present. IF models were able to reject all unknown signals while signals similar to known signals were able to pass through 2% of the time due to the contamination rate used during training. Overall, the entire system can classify correctly in an open-set mode with 98% accuracy at SNR greater than 0 dB.

Related papers

MultiWave: Multiresolution Deep Architectures through Wavelet Decomposition for Multivariate Time Series Prediction [6.980076213134384]
MultiWave is a novel framework that enhances deep learning time series models by incorporating components that operate at the intrinsic frequencies of signals. We show that MultiWave consistently identifies critical features and their frequency components, thus providing valuable insights into the applications studied.
arXiv Detail & Related papers (2023-06-16T20:07:15Z)
Modulation Classification Through Deep Learning Using Resolution Transformed Spectrograms [3.9511559419116224]
We propose a scheme for Automatic Modulation Classification (AMC) using modern architectures of Convolutional Neural Networks (CNN) We perform resolution transformation of spectrograms that results up to 99.61% of computational load reduction and 8x faster conversion from the received I/Q data. The performance is evaluated on existing CNN models including SqueezeNet, Resnet-50, InceptionResnet-V2, Inception-V3, VGG-16 and Densenet-201.
arXiv Detail & Related papers (2023-06-06T16:14:15Z)
Time-to-Green predictions for fully-actuated signal control systems with supervised learning [56.66331540599836]
This paper proposes a time series prediction framework using aggregated traffic signal and loop detector data. We utilize state-of-the-art machine learning models to predict future signal phases' duration. Results based on an empirical data set from a fully-actuated signal control system in Zurich, Switzerland, show that machine learning models outperform conventional prediction methods.
arXiv Detail & Related papers (2022-08-24T07:50:43Z)
Decision Forest Based EMG Signal Classification with Low Volume Dataset Augmented with Random Variance Gaussian Noise [51.76329821186873]
We produce a model that can classify six different hand gestures with a limited number of samples that generalizes well to a wider audience. We appeal to a set of more elementary methods such as the use of random bounds on a signal, but desire to show the power these methods can carry in an online setting.
arXiv Detail & Related papers (2022-06-29T23:22:18Z)
Classification of Common Waveforms Including a Watchdog for Unknown Signals [9.928597392387186]
We examine the use of a deep multi-layer perceptron model architecture to classify received signal samples. An autoencoder with a deep CNN architecture is also examined to create a new fifth classification category of an unknown waveform type.
arXiv Detail & Related papers (2021-08-16T20:36:46Z)
Ensemble of Convolution Neural Networks on Heterogeneous Signals for Sleep Stage Scoring [63.30661835412352]
This paper explores and compares the convenience of using additional signals apart from electroencephalograms. The best overall model, an ensemble of Depth-wise Separational Convolutional Neural Networks, has achieved an accuracy of 86.06%.
arXiv Detail & Related papers (2021-07-23T06:37:38Z)
Deep Learning Radio Frequency Signal Classification with Hybrid Images [0.0]
We focus on the different pre-processing steps that can be used on the input training data, and test the results on a fixed Deep Learning architecture. We propose a hybrid image that takes advantage of both time and frequency domain information, and tackles the classification as a Computer Vision problem.
arXiv Detail & Related papers (2021-05-19T11:12:09Z)
Sampling-Frequency-Independent Audio Source Separation Using Convolution Layer Based on Impulse Invariant Method [67.24600975813419]
We propose a convolution layer capable of handling arbitrary sampling frequencies by a single deep neural network. We show that the introduction of the proposed layer enables a conventional audio source separation model to consistently work with even unseen sampling frequencies.
arXiv Detail & Related papers (2021-05-10T02:33:42Z)
Convolutional Neural Networks for Sleep Stage Scoring on a Two-Channel EEG Signal [63.18666008322476]
Sleep problems are one of the major diseases all over the world. Basic tool used by specialists is the Polysomnogram, which is a collection of different signals recorded during sleep. Specialists have to score the different signals according to one of the standard guidelines.
arXiv Detail & Related papers (2021-03-30T09:59:56Z)
Detection of gravitational-wave signals from binary neutron star mergers using machine learning [52.77024349608834]
We introduce a novel neural-network based machine learning algorithm that uses time series strain data from gravitational-wave detectors. We find an improvement by a factor of 6 in sensitivity to signals with signal-to-noise ratio below 25. A conservative estimate indicates that our algorithm introduces on average 10.2 s of latency between signal arrival and generating an alert.
arXiv Detail & Related papers (2020-06-02T10:20:11Z)
Time-Frequency Analysis based Blind Modulation Classification for Multiple-Antenna Systems [6.011027400738812]
Blind modulation classification is an important step to implement cognitive radio networks. The multiple-input multiple-output (MIMO) technique is widely used in military and civil communication systems. Traditional likelihood-based and feature-based approaches cannot be applied in these scenarios.
arXiv Detail & Related papers (2020-04-01T12:27:29Z)

This list is automatically generated from the titles and abstracts of the papers in this site.