Target Recognition Technology Based on a New Joint Sensing Matrix for Compressed Learning

LI Feng; ZHAN Bang-cheng; XIN Lei; LIU Yang; LIU Zhi-jia; XIAO Hua-chao

doi:10.12263/DZXB.20200852

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Target Recognition Technology Based on a New Joint Sensing Matrix for Compressed Learning

PAPERS | 更新时间：2025-12-08

- Target Recognition Technology Based on a New Joint Sensing Matrix for Compressed Learning
- ACTA ELECTRONICA SINICA Vol. 49, Issue 11, Pages: 2108-2116(2021)
- 作者机构：
  
  1.钱学森空间技术实验室，北京 100094
  2.河南大学河南省大数据分析与处理重点实验室，河南开封 475004
  3.航天东方红卫星有限公司，北京 100094
  4.中国空间技术研究院西安分院，陕西西安 710100
- 作者简介：
- 基金信息：
- DOI：10.12263/DZXB.20200852
  CLC： TP391.4
- Received：05 August 2020，
  
  Revised：2021-04-20，
  
  Published：25 November 2021
- 稿件说明：
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李峰,詹邦成,辛蕾等.基于新型联合感知矩阵的压缩学习目标识别技术[J].电子学报,2021,49(11):2108-2116.

LI Feng,ZHAN Bang-cheng,XIN Lei,et al.Target Recognition Technology Based on a New Joint Sensing Matrix for Compressed Learning[J].ACTA ELECTRONICA SINICA,2021,49(11):2108-2116.
李峰,詹邦成,辛蕾等.基于新型联合感知矩阵的压缩学习目标识别技术[J].电子学报,2021,49(11):2108-2116. DOI： 10.12263/DZXB.20200852.

LI Feng,ZHAN Bang-cheng,XIN Lei,et al.Target Recognition Technology Based on a New Joint Sensing Matrix for Compressed Learning[J].ACTA ELECTRONICA SINICA,2021,49(11):2108-2116. DOI： 10.12263/DZXB.20200852.

摘要

目标识别正逐渐成为自动化领域中提供准确目标类别信息的一项重要技术，并且当前大多数目标识别方法都是基于深度学习框架实现.通常，深度学习框架的输入数据均为原始图像数据，而在实际应用中，探测器获取原始图像数据并作为深度学习框架的输入进而实现目标识别的方式并非是高效的，数据获取并识别的过程包含了大量的冗余信息，降低了识别效率.在本文中，通过深度学习与压缩感知技术的结合，提出了一种基于联合感知矩阵的压缩学习目标识别技术（Target recognition technology based on a new joint sensing matrix for compressed learning，TRNPCL），使得探测器可快速生成目标图像多维压缩数据，且压缩数据可直接作为深度学习目标识别框架的输入数据，而无需再进行解压缩步骤.该方法不仅大大减小了深度学习框架的数据输入量，在与同等压缩比下的单空间域数据压缩学习方式相比较，还保持了较高的识别准确率.在未来，该方法有望成为一种更有效、更灵活的目标识别方法，并特别适用于指纹识别、人脸识别等应用领域.

Abstract

Target recognition is gradually becoming an important technology to provide accurate target category information in the field of automation

and most current target recognition methods are based on machine learning frameworks. Generally

the input data of the machine learning framework is raw image data

but in practical applications

the way that the detector obtains the raw image data and uses it as the input of the deep learning framework to achieve target recognition is low efficient

contains a lot of redundant information

which reduces the recognition efficiency. In this paper

by combining machine learning and compressive sensing technology

a new target recognition method named as target recognition technology based on a new joint sensing matrix for compressed learning (TRNPCL) is proposed. Through the proposed method

the detector can quickly generate multi-dimensional compressed data of the target image

and the compressed data can be directly used as the input data of the deep learning target recognition framework without further decompression steps

which not only greatly reduces the amount of data input to the machine learning framework

but also maintains a higher recognition accuracy compared with the single-space domain data compression learning method under the same compression ratio. In the future

this method is expected to become a more effective and flexible target recognition method

and especially suitable for fingerprint recognition

face recognition and other application fields.

关键词

Keywords

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