|
|
|
|
|
|
| Light and Small UAV Hyperspectral Image Mosaicking |
| YI Li-na1, XU Xiao1, ZHANG Gui-feng2,3*, MING Xing2, GUO Wen-ji2, LI Shao-cong1, SHA Ling-yu1 |
1. China University of Mining & Technology, Beijing, Beijing 100083, China
2. Academy of Opto-Electronics, Chinese Academy of Sciences, Beijing 100094, China
3. University of Chinese Academy of Sciences, Beijing 100049, China |
|
|
|
|
Abstract The rapid development of small and low-cost unmanned aerial imaging spectrometer has provided new means for water quality monitoring and precision agriculture. The ZK-VNIR-FPG480 airborne hyperspectral imager is a domestic development instrument with independent property right. The image has a total of 270 bands, the spectral range is 400~1 000 nm, the spectral resolution is 3 nm, and the spatial resolution is 0.9 m@1 km. The imaging method is motion push broom imaging, which is characterized by no overlap between the images and only overlapping. While providing high spectral and high spatial resolution images, it also has a series of problems:①the narrow field of unmanned aerial vehicle (UAV) restricts the coverage of the ground surface of each airstrip, and requires the splicing of flights; ②the positioning accuracy of its POS system is low; ③In order to improve operational efficiency, the overlap ratio between navigation bands is relatively low, which is generally set at about 30%, making it difficult to image splicing; ④Due to the influence of wind, light, and the instrument itself during flight, there is a difference in brightness between each band, and stitching occurs when stitching occurs. This paper proposes a method for splicing UAV hyperspectral images based on surface spline function and phase correlation, aiming at solving the above problems. The aim is to splice a single hyperspectral band taken by UAV into a complete panorama with geographic coordinates, and to achieve image geometry and spectral matching. The method includes the following steps: First, the hyperspectral flight is georeferenced using the surface spline function method with the orthophoto image as the reference, and the real geographic coordinates of each flight are assigned; second, the local variance method is used to calculate the signal-to-noise ratio of each band, and the highest value band is taken as the optimal band; and then the phase correlation algorithm based on the 2 power image is used to correct the existing geographic spatial mapping relations between flights and eliminate the dislocation of the flight. Finally, the weighted average fusion method is used to fuse the adjacent flights and eliminate the problem of the mosaic line caused by the illumination and the instrument itself. Through the above steps, we can get a hyperspectral panorama with absolute geographic coordinates. The experiment uses ZK-VNIR-FPG480 airborne hyperspectral imager to get the hyperspectral data of a region of Dali to splice. The results show that the splicing method has no dislocations in the panorama stitching, and the geometric position is accurate. The curve directions of the 4 typical objects before and after splicing are basically the same. The average value of the spectral cosine of the left and right images before and after the stitching image was calculated to be 0.965 2, the average value of the spectral correlation coefficient was 0.863 2, the average value of the spectral information divergence was 0.424 0, and the average value of the Euclidean distance was 0.494 1. The four kinds of spectral curve similarity measure indicators objectively showed the high similarity of the curves, indicating that the spectral matching degree of the same name point before and after splicing is high, which is suitable for the splicing of UAV hyperspectral data. The method not only improves the accuracy of the geographical coordinates of the spliced image, but also ensures the maximum spectrum fidelity on the basis of the elimination of the joint joint. The 2 power image is introduced to solve the problem of the registration algorithm failure under the low overlap of the image. However, there is a spectral difference between the same name points in adjacent bands before splicing, and the amount of hyperspectral data is large and the splicing takes more time. It is still a problem to figure out how to use the pixels of the overlapped region to correct the system error, to unify the measurement space of the image, to improve the spectral accuracy and stability and to improve the stitching speed.
|
|
Received: 2018-04-25
Accepted: 2018-09-08
|
|
|
|
Corresponding Authors:
ZHANG Gui-feng
E-mail: russhome@126.com
|
|
[1] Wang C,Guo Z,Wang S,et al. Journal of Spectroscopy,2015,2015:ID969185.
[2] Asadzadeh S, Roberto D S F C. International Journal of Applied Earth Observations & Geoinformation,2016,47: 69.
[3] XU Zhi-fang,WANG Shuang-ting,WANG Chun-yang,et al(许志方,王双亭,王春阳,等). Remote Sensing Information(遥感信息),2017, 32(1): 95.
[4] Kim J I,Kim T,Shin D,et al. International Journal of Remote Sensing,2017,38(8-10): 2557.
[5] CHENG Yuan-hang(程远航). Research on Aerial Remote Sensing Image Mosaic Technology for UAV(无人机航空遥感图像拼接技术研究). Beijing: Tsinghua University Press(北京:清华大学出版社),2016. 7.
[6] Ren X, Sun M, Zhang X, et al. Remote Sensing, 2017, 9(9): 962.
[7] GONG Sheng-sheng(龚声胜). Theoretical Research in Urban Construction(城市建设理论研究: 电子版), 2015, 5(15): 5284.
[8] ZHANG Lu,HUANG Wu-meng,ZHANG Yue,et al(张 璐,黄吴蒙,张 悦,等). Geospatial Information(地理空间信息),2013,11(3): 73.
[9] ZHOU Mei-li,BAI Zong-wen,YAN Xiao-jin(周美丽,白宗文,延小进). Foreign Electronic Measurement Technology(国外电子测量技术),2015,34(5): 31.
[10] Pant M, Ray K, Sharma T K, et al. Soft Computing: Theories and Applications, Proc. SoCTA 2016, Vol. 2 (Advances in Intelligent Systems and Computing 584). Springer,2017.
[11] ZHANG Jun-zhe,ZHU Wen-quan,ZHENG Zhou-tao,et al(张浚哲,朱文泉,郑周涛,等). Science of Surveying and Mapping(测绘科学),2013, 38(6): 33. |
| [1] |
YAN Xing-guang, LI Jing*, YAN Xiao-xiao, MA Tian-yue, SU Yi-ting, SHAO Jia-hao, ZHANG Rui. A Rapid Method for Stripe Chromatic Aberration Correction in
Landsat Images[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3483-3491. |
| [2] |
SONG Ruo-xi1, 3, FENG Yi-ning3, CHENG Wei2, WANG Xiang-hai2, 3*. Advance in Hyperspectral Images Change Detection[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2354-2362. |
| [3] |
ZHU Ling, QIN Kai*, SUN Yu, LI Ming, ZHAO Ying-jun. Hyperspectral Unmixing Based on Deep Stacked Autoencoders Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(05): 1508-1516. |
| [4] |
PAN Ke-yu1, 2, ZHU Ming-yao1, 2, WANG Yi-meng1, 2, XU Yang1, CHI Ming-bo1, 2*, WU Yi-hui1, 2*. Research on the Influence of Modulation Depth of Phase Sensitive
Detection on Stimulated Raman Signal Intensity and
Signal-to-Noise Ratio[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 1068-1074. |
| [5] |
LIU Ye-kun, HAO Xiao-jian*, YANG Yan-wei, HAO Wen-yuan, SUN Peng, PAN Bao-wu. Quantitative Analysis of Soil Heavy Metal Elements Based on Cavity
Confinement LIBS Combined With Machine Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(08): 2387-2391. |
| [6] |
WANG Yue1, 3, 4, CHEN Nan1, 2, 3, 4, WANG Bo-yu1, 5, LIU Tao1, 3, 4*, XIA Yang1, 2, 3, 4*. Fourier Transform Near-Infrared Spectral System Based on Laser-Driven Plasma Light Source[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1666-1673. |
| [7] |
YANG Yu-qing1, CAI Jiang-hui1, 2*, YANG Hai-feng1*, ZHAO Xu-jun1, YIN Xiao-na1. LAMOST Unknown Spectral Analysis Based on Influence Space and Data Field[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(04): 1186-1191. |
| [8] |
KONG Yu-ru1, 2, WANG Li-juan1*, FENG Hai-kuan2, XU Yi1, LIANG Liang1, XU Lu1, YANG Xiao-dong2*, ZHANG Qing-qi1. Leaf Area Index Estimation Based on UAV Hyperspectral Band Selection[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(03): 933-939. |
| [9] |
HU Li-hong1, ZHANG Jin-tong1, WANG Li-yun2, ZHOU Gang3, WANG Jiang-yong1*, XU Cong-kang1*. Optimization of Working Parameters of Glow Discharge Optical Emission Spectrometry of High Barrier Aluminum Plastic Film[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(03): 954-960. |
| [10] |
YANG Bao-hua, GAO Zhi-wei, QI Lin, ZHU Yue, GAO Yuan. Prediction Model of Soluble Solid Content in Peaches Based on Hyperspectral Images[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(11): 3559-3564. |
| [11] |
CUI Fang-xiao1, ZHAO Yue2, MA Feng-xiang2, WU Jun1*, WANG An-jing1, LI Da-cheng1, LI Yang-yu1. Optimization of FTIR Passive Remote Sensing Signal-to-Noise Ratio and Its Application in SF6 Leak Detection in Transform Substation[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(05): 1436-1440. |
| [12] |
WANG Jing-jing1, 2, TAN Tu1*, WANG Gui-shi1, ZHU Gong-dong1, XUE Zheng-yue1, 2, LI Jun1, 2, LIU Xiao-hai1, 2, GAO Xiao-ming1, 2. Research on All-Fiber Dual-Channel Atmospheric Greenhouse Gases Laser Heterodyne Detection Technology[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(02): 354-359. |
| [13] |
SUN Ran, HAO Xiao-jian*, YANG Yan-wei, REN Long. Effect of Cavity Confinement Materials on Laser-Induced Breakdown Cu Plasma Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(12): 3801-3805. |
| [14] |
ZHENG Guo-liang, ZHU Hong-qiu*, LI Yong-gang. Spectral Signal Denoising Algorithm Based on Improved LMS[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(02): 643-649. |
| [15] |
LI Zhi-wei1, 2, SHI Hai-liang1, 2, LUO Hai-yan1, 2, XIONG Wei1, 2*. Study on the Relationship Between Apodization Function and Signal-to-Noise Ratio of Hyperspectral Spatial Interferogram[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(01): 29-33. |
|
|
|
|
