Abstract
Radar technology has evolved considerably in the last few decades. There are many areas where radar systems are applied, including air traffic control in airports, ocean surveillance, and research systems, to cite a few. Other types of sensors have recently appeared, which allow tracking sub-millimeter motion with high speed and accuracy rates. These millimeter-wave radars are giving rise to myriad new applications, from the recognition of the material close objects are made, to the recognition of hand gestures. They have also been recently used to identify how a person interacts with digital devices through the physical environment (Tangible User Interfaces, TUIs). In this case, the radar is used to detect the orientation, movement, or distance from the objects to the user’s hands or the digital device. This paper presents a thoughtful comparative analysis of different feature extraction techniques and classification strategies applied on a series of datasets that cover problems such as the identification of materials, element counting, or determining the orientation and distance of objects to the sensor. The results outperform previous works using these datasets, especially when the accuracy was lowest, showing the benefits feature extraction techniques have on classification performance.
Highlights
Radar sensing has been classically used in an extensive range of applications, due to its ability to operate under all-weather and scene illumination geometry independence acquisition conditions
This paper presents a comparative analysis of different types of classification methodologies, applied on a series of datasets of raw signals acquired by a portable radar sensor, for different types of materials
Twelve different types of feature vectors obtained from the original raw dataset were obtained, applying different types of feature extraction strategies
Summary
Radar sensing has been classically used in an extensive range of applications, due to its ability to operate under all-weather and scene illumination geometry independence acquisition conditions This would be a critical advantage, under specific circumstances, when compared, for instance, to optical sensing. Advances in radar hardware and software technology have made it possible to reliably detect and track objects, under competitive classification accuracy conditions, in underwater, air, and ground environments [1,2]. This framework seems to have been applied only to relatively big objects in specific scenarios, i.e., airplanes, ships, or submarines [3,4]. Gestures [7] and more complex actions are aimed at by the new radar acquisition technology and classification strategies [8]
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