Abstract: With the rapid development of hyperspectral reconnaissance technology, there is an increasing demand for materials which can spectrally simulate green vegetation as a counter-reconnaissance requirement. Green vegetation is one of the most widely used combat backgrounds with unique spectral characteristics in the 400—2 500 nm, with four main characteristic bands, namely ‘green peak’, ‘red edge’, ‘near-infrared plateau’, and ‘water absorption band’, derived from the chlorophyll, tissue structure and plant water content of leaves. Based on the characte-ristics of hyperspectral technology for reconnaissance, this paper reviews the current status of materials for spectrally simulating each characteristic reflection peak and the comprehensive application of existing materials in order to achieve the ‘same color and spectrum’ between the camouflage materials and the background. The paper introduces the weaknesses of the existing camouflage materials, such as poor weather resis-tance, despite the high accuracy in simulating green vegetation spectral curves. Moreover, it highlights the related work on improving spectral curve similarity and weather resistance by compounding, and discusses the future development of the simulative green vegetation spectral mate-rials.
通讯作者:
徐国跃,南京航空航天大学材料科学与技术学院教授、博士研究生导师。1986年华南理工大学特种陶瓷材料专业硕士毕业后到南京航空航天大学工作至今。目前主要从事隐身材料、光电功能材料、材料数据库等方面的研究工作。发表学术论文150余篇,其中Acta Materialia、Materials Science and Engineering C、Progress in Organic Coa-tings、Materials Chemistry and Physics等SCI、EI收录100多篇。xuguoy@nuaa.edu.cn
苗珊珊, 王业健, 李澄, 钱淇, 徐国跃. 基于同色同谱特征的模拟绿色植被光谱材料研究进展[J]. 材料导报, 2024, 38(7): 22080054-7.
MIAO Shanshan, WANG Yejian, LI Cheng, QIAN Qi, XU Guoyue. Research Progress on Materials Used for Spectrally Simulating Green Vegetation Based on Homochromatic and Homospectral Features. Materials Reports, 2024, 38(7): 22080054-7.
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