Abstract
High-Resolution Range Profile (HRRP) sequence has attracted academic attentions in the field of radar automatic target recognition (RATR) owing to its abundant spatial-temporal correlation between adjacent samples. However, it is difficult in the working state of radar to obtain complete HRRP sequence samples due to various internal and external factors such as ground clutter and systematic error, which poses an enormous challenge to radar target recognition. Therefore, it is crucial to repair the missing HRRPs based on the adjacent samples in the previous frames. In this paper, we discuss the extrapolate method of incomplete samples and propose an improved neural network algorithm named as Vanishing Gradient Mitigation Recurrent Neural Network (VGM-RNN). The lost samples in the sequence can be extrapolated by VGM-RNN, and the problem of vanishing gradient which is possessed in classical RNN can be effectively mitigated. The proposed method in this paper can be divided into two parts, as sample extrapolation and sequence recognition, in which sample extrapolation is the core method. Experimental results on Moving and Stationary Target Acquisition and Recognition (MSTAR) dataset show that our proposed model exhibits higher accuracy and efficiency, as well as excellent anti-noise performance, compared with traditional methods. It is suggested that our proposed model can be effectively applied to radar system.
Highlights
High resolution radar is widely used in more and more fields, especially in meteorological forecast [1], environmental monitoring [2], forest resources detection [3] and geological survey [4]
There are three kinds of data used for target recognition: one-dimensional High-Resolution Range Profile (HRRP) [5], [6], two-dimensional synthetic aperture radar (SAR) [7] and inverse synthetic aperture radar (ISAR) images [8], among which HRRP can effectively reflect energy and structure information of multiple scatters for a distributed target along the slant range direction with respect to a certain radar line-of-sight (RLOS) [9]
We creatively put forward the strategies to mitigate the vanishing gradient problem, to be specific, we improve the Exponential Linear Unit (ELU) function and Batch Normalization (BN) method based on the HRRP sequence recognition task, and creatively put forward the gradient lifting algorithm
Summary
High resolution radar is widely used in more and more fields, especially in meteorological forecast [1], environmental monitoring [2], forest resources detection [3] and geological survey [4]. Y. Zhang et al.: VGM-RNN: HRRP Sequence Extrapolation and Recognition Based on a Novel Optimized RNN value is filled by these methods, the correlation information between sequence samples are lacked. Long Short Term Memory Network (LSTM), an improved model of RNN, is the most popular RNN network at present, which has been widely used in the fields of Natural Language Processing (NLP) and speech recognition [19], [20] Considering their high computational complexity and insufficient processing capacity for high dimensional and long sequences, these methods are not selected to complete the HRRP sequence recognition task in this paper. We creatively put forward the strategies to mitigate the vanishing gradient problem, to be specific, we improve the ELU function and BN method based on the HRRP sequence recognition task, and creatively put forward the gradient lifting algorithm.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
