Research on Band Selection Method Based on Subspace Division and Visual Recognition
JIN Chun-bai1, YANG Guang1*, LU Shan2*, CHEN Qiang1, 3, ZHENG Nan1
1. Aviation University Air Force, Changchun 130022, China
2. School of Geographical Science, Northeast Normal University, Changchun 130024, China
3. Unit 93116 of PLA, Shenyang 110000, China
Abstract:In the face of the increasingly abundant airborne and spaceborne hyperspectral sensors and the accompanying increase in hyperspectral data, the problems of excessive data volume and band redundancy have always been the major difficulties in hyperspectral image processing and interpretation. At the same time, the use of hyperspectral remote sensing technology to reveal camouflaged targets has always been the key point of modern remote sensing application technology research. In detecting massive spectral data of ground objects and redundant spectral information, the design of appropriate data dimensionality reduction technology plays a vital role. The band selection method among the main methods of dimensionality reduction processing can not only reduce the spectral information of the image data without distortion but also accurately distinguish the camouflaged target and its background based on it. Today, hyperspectral technology is an important technical means for military applications, and it is also a research hotspot for many scholars at home and abroad.It is a commonly used research method to use various indicators to calculate the different performances between the bands and to select the most representative bands according to their parameters for feature identification or classification to test the pros and cons of the method. However, few experimental studies still exist on specific band selection methods for special features, such as vegetation camouflage targets. In the study, green steel plates, green camouflage nets, and green fake turf were selected and placed in a background environment containing healthy green vegetation, wet bare ground, and dry, bare ground. Band selection and classification experiments were carried out by simulating camouflage targets and background objects in the real environment. First, analyze the spectral curve, and select a significant feature band. Secondly, the band screening is performed based on the sub-space divided according to the phase relationship between the band. The visual model is then established according to the image brightness of the property target. Finally obtains a band selection collection with relative in dependence and optimal recognition. Next, using support vector machine classifier and Mahalanobis distance classifier, the proposed algorithm is compared with two common algorithms in band selection results and full band combination for classification experiments. The experiment shows that the band selection results of the proposed method are better than those of the common algorithms in band selection results and full band, and the classification accuracy and speed are improved. Among them, compared to using full band classification, the overall classification accuracy of the two types of classifiers has been improved by 4.559 2% and 2.364 8%, respectively. The Kappa coefficient has been improved by 0.059 4 and 0.031 2, and the classification time has been reduced by 6.83 seconds. Experiments show that this method can effectively classify vegetation camouflage targets and background objects and has great practical application value.
金椿柏,杨 桄,卢 珊,陈 强,郑 南. 基于子空间划分和视觉可识别度的波段选择方法研究[J]. 光谱学与光谱分析, 2023, 43(05): 1582-1588.
JIN Chun-bai, YANG Guang, LU Shan, CHEN Qiang, ZHENG Nan. Research on Band Selection Method Based on Subspace Division and Visual Recognition. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(05): 1582-1588.
[1] WANG Chong-chang, XUE Rong-rong, ZHAO Shi-hu, et al(王崇倡, 薛荣荣, 赵世湖, 等). Geography and Geo-information Science(地理与地理信息科学), 2021, 37(1): 33.
[2] LI Ai-min, XIA Guang-ping, QI Xin, et al(李爱民,夏光平,齐 鑫, 等). Journal of Geomatics Science and Technology (测绘科学技术学报), 2020, 37(4): 388.
[3] FANG Shuai, ZHANG Kun, ZHANG Jing, et al(方 帅, 张 坤, 张 晶, 等). Journal of Image and Graphics(中国图象图形学报), 2021, 26(8): 1940.
[4] Plaza A, Martinez P, Plaza J, et al. IEEE Transactions on Geoscience & Remote Sensing, 2005, 43(3): 466.
[5] Feng J, Li D, Gu J, et al. IEEE Transactions on Geoscience and Remote Sensing, 2022, 60: 5501719.
[6] LIU Yan-jun, ZHANG Gui, WANG Xiao, et al(刘彦君, 张 贵, 王 潇, 等). Bulletin of Surveying and Mapping(测绘通报), 2020,(4): 34.
[7] HUANG Hui, ZHANG De-jun, WANG Chao, et al(黄 慧, 张德钧, 王 超, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2019, 39(8): 2377.
[8] Zhao D, Liu S, Yang X, et al. Journal of Spectroscopy, 2021, 2021: 6629661.
[9] Xie L, Li G, Peng L, et al. Journal of Applied Remote Sensing, 2017, 11(2): 026018.
[10] Shang X, Song M, Wang Y, et al. IGARSS 2020-2020 IEEE International Geoscience and Remote Sensing Symposium. IEEE, 2020.
[11] Manoharan P, Boggavarapu P. Infrared Physics & Technology, 2021,119:103948.
[12] Chen Y, Zhou J, Chen X, et al. DEStech Transactions on Computer Science and Engineering, 2017,190:753.
[13] CAO Peng-fei, LI Hong-ning, LUO Yan-lin, et al(曹鹏飞, 李宏宁, 罗艳琳, 等). Laser & Optoelectronics Progress(激光与光电子学进展), 2014,(1): 011101.
[14] YAN Yang, HUA Wen-shen, LIU Xun, et al(严 阳, 华文深, 刘 恂, 等). Optical Technique(光学技术), 2018, 44(5): 634.
[15] WANG Xiao-ning, SONG Wei-dong(王小宁, 宋伟东). Remote Sensing Information(遥感信息), 2020, 35(6): 122.
