12.2.4.1 Spacecraft Pose, Space Object Pose

Shahid, K.[Kamran], Okouneva, G.[Galina],
Intelligent LIDAR scanning region selection for satellite pose estimation,
CVIU(107), No. 3, September 2007, pp. 203-209.
Elsevier DOI 0709
Pose estimation; Registration accuracy; Constraint analysis; Geometric features; LIDAR BibRef

Oumer, N.W.[Nassir W.], Kriegel, S.[Simon], Ali, H.[Haider], Reinartz, P.[Peter],
Appearance learning for 3D pose detection of a satellite at close-range,
PandRS(125), No. 1, 2017, pp. 1-15.
Elsevier DOI 1703
Satellite pose detection BibRef

Finance, A.[Adrien], Meftah, M.[Mustapha], Dufour, C.[Christophe], Boutéraon, T.[Thomas], Bekki, S.[Slimane], Hauchecorne, A.[Alain], Keckhut, P.[Philippe], Sarkissian, A.[Alain], Damé, L.[Luc], Mangin, A.[Antoine],
A New Method Based on a Multilayer Perceptron Network to Determine In-Orbit Satellite Attitude for Spacecrafts without Active ADCS Like UVSQ-SAT,
RS(13), No. 6, 2021, pp. xx-yy.
DOI Link 2104
BibRef

Zhang, J.H.[Jin-Hui], Zhao, W.[Weishuang], Shen, G.H.[Gang-Hui], Xia, Y.Q.[Yuan-Qing],
Disturbance Observer-Based Adaptive Finite-Time Attitude Tracking Control for Rigid Spacecraft,
SMCS(51), No. 11, November 2021, pp. 6606-6613.
IEEE DOI 2110
Attitude control, Space vehicles, Uncertainty, Quaternions, Angular velocity, Mathematical model, Observers, Adaptive control, sliding mode control (SMC) BibRef

Chen, Q.[Qiang], Xie, S.[Shuzong], He, X.X.[Xiong-Xiong],
Neural-Network-Based Adaptive Singularity-Free Fixed-Time Attitude Tracking Control for Spacecrafts,
Cyber(51), No. 10, October 2021, pp. 5032-5045.
IEEE DOI 2110
Space vehicles, Attitude control, Convergence, Materials requirements planning, Switches, Actuators, neural network (NN) BibRef

Yan, C.[Chuan], Long, H.F.[Hong-Feng], Cao, Z.[Zifei], Ma, Y.[Yuebo], Suo, J.Y.[Jia-Yu], Lu, X.Y.[Xiang-Ying], Zhao, R.[Rujin], Peng, Z.M.[Zhen-Ming],
Learning Structured Distance Mappings for Spacecraft Pose Estimation with Feature Degradation,
RS(18), No. 10, 2026, pp. 1647.
DOI Link 2605
BibRef

Price, A.[Andrew], Yoshida, K.[Kazuya],
A Monocular Pose Estimation Case Study: The Hayabusa2 Minerva-II2 Deployment,
AI4Space21(1992-2001)
IEEE DOI 2109
Space vehicles, Visualization, Pose estimation, Pipelines, Data acquisition, Trajectory, Convolutional neural networks BibRef

Liu, K.[Kun], Yu, Y.J.[Yong-Jun],
Revisiting the Domain Gap Issue in Non-cooperative Spacecraft Pose Tracking,
AI4Space24(6864-6873)
IEEE DOI 2410
Training, Space vehicles, Accuracy, Pose estimation, Object detection, Self-supervised learning, Prediction algorithms BibRef

Gallet, F.[Fabien], Marabotto, C.[Christophe], Chambon, T.[Thomas],
Exploring AI-Based Satellite Pose Estimation: from Novel Synthetic Dataset to In-Depth Performance Evaluation,
AI4Space24(6770-6778)
IEEE DOI Code:
WWW Link. 2410
Training, Space vehicles, Atmospheric modeling, Pose estimation, Satellite broadcasting, Robot vision systems, pose estimation, metrics BibRef

Legrand, A.[Antoine], Detry, R.[Renaud], de Vleeschouwer, C.[Christophe],
End-to-end Neural Estimation of Spacecraft Pose with Intermediate Detection of Keypoints,
AI4Space22(154-169).
Springer DOI 2304
BibRef

Pérez-Villar, J.I.B.[Juan Ignacio Bravo], García-Martín, Á.[Álvaro], Bescós, J.[Jesús],
Spacecraft Pose Estimation Based on Unsupervised Domain Adaptation and on a 3D-Guided Loss Combination,
AI4Space22(37-52).
Springer DOI 2304
BibRef

Carcagnì, P.[Pierluigi], Leo, M.[Marco], Spagnolo, P.[Paolo], Mazzeo, P.L.[Pier Luigi], Distante, C.[Cosimo],
A Lightweight Model for Satellite Pose Estimation,
CIAP22(I:3-14).
Springer DOI 2205
BibRef

Song, J.R.[Jing-Rui], Hao, S.[Shuling], Xu, K.[Kefeng],
Uncooperative Satellite 6D Pose Estimation with Relative Depth Information,
ISVC21(II:166-177).
Springer DOI 2112
BibRef

Hu, Y.L.[Yin-Lin], Speierer, S.[Sébastien], Jakob, W.[Wenzel], Fua, P.[Pascal], Salzmann, M.[Mathieu],
Wide-Depth-Range 6D Object Pose Estimation in Space,
CVPR21(15865-15874)
IEEE DOI 2111
Training, Solid modeling, Satellites, Pose estimation, Scattering, Benchmark testing BibRef

Zhi-Yu, C.[Chen], Po-Heng, C.[Chen], Kuan-Wen, C.[Chen], Chen-Yu, C.[Chan],
PA-FlowNet: Pose-Auxiliary Optical Flow Network for Spacecraft Relative Pose Estimation,
ICPR21(9703-9710)
IEEE DOI 2105
Space vehicles, Location awareness, Pose estimation, Moon, Cameras, Satellite navigation systems, Space Localization BibRef

Chen, B., Cao, J., Parra, A., Chin, T.,
Satellite Pose Estimation with Deep Landmark Regression and Nonlinear Pose Refinement,
R6D19(2816-2824)
IEEE DOI 2004
image reconstruction, learning (artificial intelligence), pose estimation, Satellite pose estimation BibRef

Wang, J.[Jie], Zhang, X.H.[Xiao-Hu], Chen, H.[Hao], Ding, S.W.[Shao-Wen],
Relative pose measurement of Satellite and rocket based on photogrammetry,
ICIVC17(1117-1122)
IEEE DOI 1708
Adaptation models, Calibration, Cameras, Measurement uncertainty, Position measurement, Rockets, EPnP (efficient perspective-n-point), orthogonal Iteration, position and attitude estimation, satellite-rocket, separation BibRef

Xu, W.F.[Wen-Fu], Xue, Q.A.[Qi-Ang], Liu, H.D.[Hou-De], Du, X.D.[Xiao-Dong], Liang, B.[Bin],
A pose measurement method of a non-cooperative GEO spacecraft based on stereo vision,
ICARCV12(966-971).
IEEE DOI 1304
BibRef

Chapter on Registration, Matching and Recognition Using Points, Lines, Regions, Areas, Surfaces continues in
Matching, Areas, Regions, Surfaces .