Lunar Cartography: Progress in the 2000s and Prospects for the 2010s

Kirk, R. L.; Archinal, B. A.; Gaddis, L. R.; Rosiek, M. R.

doi:10.5194/isprsarchives-xxxix-b4-489-2012

Cited by 17 publications

(12 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Obviously, a highly universal pushbroom sensor model can facilitate both the software development and the geometric processing of planetary remote sensing images. Researchers have pointed out that making geometric camera models available in various software packages is still a technically challenging task (Geng et al, 2019; Kirk et al, 2012). Furthermore, photogrammetric processing algorithms and software tools always lag behind the imaging instrument development.…”

Section: Introductionmentioning

confidence: 99%

A Generic Pushbroom Sensor Model for Planetary Photogrammetry

Geng

Xing

et al. 2020

Earth and Space Science

View full text Add to dashboard Cite

Different imaging instruments are designed in the planetary exploration missions, which require respective photogrammetric software modules to support the geometric processing of planetary remote sensing images. To decrease the cost of software development and maintenance, this paper presents a generic pushbroom sensor model for planetary photogrammetry. Thus, various coordinate transformations can be conducted in a unified and efficient way, without considering the specific camera and the optical distortion equations. In terms of implementation, the camera file and orientation data file designed for the airborne linear array camera ADS40 are used to manage the interior orientation and exterior orientation parameters of planetary images. The generic pushbroom sensor model supports the summing mode, varying exposure times within an image and image distortions, which are typical problems in need of a solution in planetary mapping. Furthermore, an alternative photogrammetric process based on extracting tie points on approximate orthophotos is developed. The geometric accuracy and computational efficiency of the generic pushbroom sensor model were compared with the popular planetary cartographic software-Integrated System for Imagers and Spectrometers (ISIS). The experimental results demonstrate that the proposed generic pushbroom sensor model can (1) deliver the same geometric accuracy as the ISIS pushbroom sensor model, (2) greatly improve the computational efficiency of orthophotos generation and tie points extraction, and (3) support various types of planetary remote sensing images. Moreover, the proposed generic pushbroom sensor model reduces the cost of software development because different types of planetary images share the same code base.Plain Language Summary The orbital photographs acquired by planetary imaging instruments need photogrammetric processing to be converted to cartographic products for planetary scientific research. It is noted that various types of imaging instruments are used in the planetary exploration missions, which increases the burden of photogrammetric software development and maintenance. Linear array cameras are widely adopted for planetary mapping, but the photogrammetric processing of linear pushbroom images is more complicated. In this paper, we present a generic pushbroom sensor model for photogrammetric processing of planetary images. Thus, various types of planetary pushbroom images can be processed in a unified and efficient way. In addition, a tie points extraction method based on approximate orthophotos is developed, which can decrease the search range and improve the computational efficiency of image matching. The feasibility of the proposed generic pushbroom sensor model is verified with both lunar and Martian images. Key Points: • We present a generic and efficient pushbroom sensor model for planetary photogrammetry. • The generic pushbroom sensor model greatly improves the computational efficiency of orthophotos generation and tie points extractions. • The generic push...

show abstract

Section: Introductionmentioning

confidence: 99%

A Generic Pushbroom Sensor Model for Planetary Photogrammetry

Geng

Xing

et al. 2020

Earth and Space Science

View full text Add to dashboard Cite

show abstract

“…During the 1990s, other countries or territories engaged in lunar scientific exploration work, including the Europe Union, India, Japan and China. In 1994, the US initiated the Clementine Lunar Mapping Project [12]. The captured data were used in a Clementine Lunar Imagery Atlas by Bussey and Spudis [13] The captured data were used to create an atlas of the global topographic map of the moon [15,16].…”

Section: Introductionmentioning

confidence: 99%

Setting Diverging Colors for a Large-Scale Hypsometric Lunar Map Based on Entropy

Zeng

et al. 2015

Entropy

View full text Add to dashboard Cite

Abstract:A hypsometric map is a type of map used to represent topographic characteristics by filling different map areas with diverging colors. The setting of appropriate diverging colors is essential for the map to reveal topographic details. When lunar real environmental exploration programs are performed, large-scale hypsometric maps with a high resolution and greater topographic detail are helpful. Compared to the situation on Earth, fewer lunar exploration objects are available, and the topographic waviness is smaller at a large scale, indicating that presenting the topographic details using traditional hypsometric map-making methods may be difficult. To solve this problem, we employed the Chang'E2 (CE2) topographic and imagery data with a resolution of 7 m and developed a new hypsometric map-making method by setting the diverging colors based on information entropy. The resulting map showed that this method is suitable for presenting the topographic details and might be useful for developing a better understanding of the environment of the lunar surface.

show abstract

“…Traditional 3D lunar mapping utilizes stereo image pairs acquired by one orbiter from the same orbit (along-track stereo) or from neighbouring orbit (cross-track stereo) (Radhadevi et al, 2011, Scholten et al, 2011, Kirk et al, 2012. With continual data acquisition by multiple lunar orbiter missions, many areas of the lunar surface have been covered many times by different orbiters or the same orbiter.…”

Section: Introductionmentioning

confidence: 99%

Geopositioning Precision Analysis of Multiple Image Triangulation Using Lro Nac Lunar Images

Liu

et al. 2016

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

View full text Add to dashboard Cite

ABSTRACT:This paper presents an empirical analysis of the geopositioning precision of multiple image triangulation using Lunar Reconnaissance Orbiter Camera (LROC) Narrow Angle Camera (NAC) images at the Chang'e-3(CE-3) landing site. Nine LROC NAC images are selected for comparative analysis of geopositioning precision. Rigorous sensor models of the images are established based on collinearity equations with interior and exterior orientation elements retrieved from the corresponding SPICE kernels. Rational polynomial coefficients (RPCs) of each image are derived by least squares fitting using vast number of virtual control points generated according to rigorous sensor models. Experiments of different combinations of images are performed for comparisons. The results demonstrate that the plane coordinates can achieve a precision of 0.54 m to 2.54 m, with a height precision of 0.71 m to 8.16 m when only two images are used for three-dimensional triangulation. There is a general trend that the geopositioning precision, especially the height precision, is improved with the convergent angle of the two images increasing from several degrees to about 50°. However, the image matching precision should also be taken into consideration when choosing image pairs for triangulation. The precisions of using all the 9 images are 0.60 m, 0.50 m, 1.23 m in along-track, cross-track, and height directions, which are better than most combinations of two or more images. However, triangulation with selected fewer images could produce better precision than that using all the images.

show abstract

Lunar Cartography: Progress in the 2000s and Prospects for the 2010s

Cited by 17 publications

References 21 publications

A Generic Pushbroom Sensor Model for Planetary Photogrammetry

A Generic Pushbroom Sensor Model for Planetary Photogrammetry

Setting Diverging Colors for a Large-Scale Hypsometric Lunar Map Based on Entropy

Geopositioning Precision Analysis of Multiple Image Triangulation Using Lro Nac Lunar Images

Contact Info

Product

Resources

About