Abstract
The laser detection and ranging system (LADAR) is widely used in various fields that require 3D measurement, detection, and modeling. In order to improve the system stability and ranging accuracy, it is necessary to obtain the complete waveform of pulses that contain target information. Due to the inevitable noise, there are distinct deviations between the actual and expected waveforms, so noise suppression is essential. To achieve the best effect, the filters’ parameters that are usually set as empirical values should be adaptively adjusted according to the different noise levels. Therefore, we propose a novel noise suppression method for the LADAR system via eigenvalue-based adaptive filtering. Firstly, an efficient noise level estimation method is developed. The distributions of the eigenvalues of the sample covariance matrix are analyzed statistically after one-dimensional echo data are transformed into matrix format. Based on the boundedness and asymptotic properties of the noise eigenvalue spectrum, an estimation method for noise variances in high dimensional settings is proposed. Secondly, based on the estimated noise level, an adaptive guided filtering algorithm is designed within the gradient domain. The optimized parameters of the guided filtering are set according to an estimated noise level. Through simulation analysis and testing experiments on echo waves, it is proven that our algorithm can suppress the noise reliably and has advantages over the existing relevant methods.
Highlights
laser detection and ranging system (LADAR) is widely used in unmanned aerial vehicles (UAV), terrain mapping, robots, and automobile auxiliary driving
After one echo has been digitized into a one-dimensional signal, the image filtering algorithm can be used to suppress the noise of the LADAR signal
The system uses a multi-channel preamplifier circuit based on the variable gain amplifier (VGA) and implements full waveform sampling analysis based on a 2-GHz sampling rate analog-to-digital converter (ADC)
Summary
LADAR is widely used in unmanned aerial vehicles (UAV), terrain mapping, robots, and automobile auxiliary driving. The system emits a pulsed signal and receives the echo, which is a Gaussian pulse waveform, a Gaussian voltage is obtained after circuit transformation [2]. Background light noise mainly comes from natural and artificial light sources, such as the radiation from the Sun, ground, stars, atmosphere, clouds, and other sources of incidence or reflection to the detector. It includes the interfering signal caused by the atmosphere in the transmission process [13]. After one echo has been digitized into a one-dimensional signal, the image filtering algorithm can be used to suppress the noise of the LADAR signal. The practical usefulness of our method is illustrated by experiments
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