Abstract
Radiometric identification is the problem of attributing a signal to a specific source. In this work, a radiometric identification algorithm is developed using the whitening transformation. The approach stands out from the more established methods in that it works directly on the raw IQ data and hence is featureless. As such, the commonly used dimensionality reduction algorithms do not apply. The premise of the idea is that a data set is “most white” when projected on its own whitening matrix than on any other. In practice, transformed data are never strictly white since the training and the test data differ. The Förstner-Moonen measure that quantifies the similarity of covariance matrices is used to establish the degree of whiteness. The whitening transform that produces a data set with the minimum Förstner-Moonen distance to a white noise process is the source signal. The source is determined by the output of the mode function operated on the Majority Vote Classifier decisions. Using the Förstner-Moonen measure presents a different perspective compared to maximum likelihood and Euclidean distance metrics. The whitening transform is also contrasted with the more recent deep learning approaches that are still dependent on feature vectors with large dimensions and lengthy training phases. It is shown that the proposed method is simpler to implement, requires no features vectors, needs minimal training and because of its non-iterative structure is faster than existing approaches.
Highlights
Radiometric identification is the problem of attributing a signal to the source; often brand or model
Source identification is accomplished by radio frequency (RF) fingerprinting of devices by looking for signatures that may arise from manufacturing tolerances, imperfections or normal statistical variations in production
In [15], deep learning (DL) is implemented for RF device fingerprinting in the cognitive Zigbee networks using the time-domain complex baseband error signal as training and test data.The results show good accuracy (≈90%) but at high
Summary
Radiometric identification is the problem of attributing a signal to the source; often brand or model. Radiometric identification is a more difficult problem as signals originating from different sources may have similar characteristics such as modulation, bit rates, pulse shapes, etc. This fact makes subtle device variations the main signature for radiometric identification. Unintentional Modulation on Pulse (UMoP) is a method that exploits variations due to manufacturing differences of the transmitter hardware, including the power amplifiers UMoP is like a fingerprint of an emitter and can identify transmitters from the same model [41]. This metric is the input to a mode function followed by the Majority Vote Classifier
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