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Structure from motion

August 21, 2023

Not to be confused with structure from motion (psychophysics).

Structure from motion (SfM)[1] is a photogrammetric range imaging technique for estimating three-dimensional structures from two-dimensional image sequences that may be coupled with local motion signals. It is studied in the fields of computer vision and visual perception. In biological vision, SfM refers to the phenomenon by which humans (and other living creatures) can recover 3D structure from the projected 2D (retinal) motion field of a moving object or scene.

Principle

 
Digital surface model of motorway interchange construction site
 
Real photo x SfM with texture color x SfM with simple shader. Made with Python Photogrammetry Toolbox GUI and rendered in Blender with Cycles.
 
Bezmiechowa airfield 3D digital surface model extracted from data collected during 30min flight of Pteryx UAV

Humans perceive a great deal of information about the three-dimensional structure in their environment by moving around it. When the observer moves, objects around them move different amounts depending on their distance from the observer. This is known as motion parallax, and from this depth information can be used to generate an accurate 3D representation of the world around them.[2]

Finding structure from motion presents a similar problem to finding structure from stereo vision. In both instances, the correspondence between images and the reconstruction of 3D object needs to be found.

To find correspondence between images, features such as corner points (edges with gradients in multiple directions) are tracked from one image to the next. One of the most widely used feature detectors is the scale-invariant feature transform (SIFT). It uses the maxima from a difference-of-Gaussians (DOG) pyramid as features. The first step in SIFT is finding a dominant gradient direction. To make it rotation-invariant, the descriptor is rotated to fit this orientation.[3] Another common feature detector is the SURF (speeded-up robust features).[4] In SURF, the DOG is replaced with a Hessian matrix-based blob detector. Also, instead of evaluating the gradient histograms, SURF computes for the sums of gradient components and the sums of their absolute values.[5] Its usage of integral images allows the features to be detected extremely quickly with high detection rate.[6] Therefore, comparing to SIFT, SURF is a faster feature detector with drawback of less accuracy in feature positions.[5] Another type of feature recently made practical for structure from motion are general curves (e.g., locally an edge with gradients in one direction), part of a technology known as pointless SfM,[7][8] useful when point features are insufficient, common in man-made environments.[9]

The features detected from all the images will then be matched. One of the matching algorithms that track features from one image to another is the Lucas–Kanade tracker.[10]

Sometimes some of the matched features are incorrectly matched. This is why the matches should also be filtered. RANSAC (random sample consensus) is the algorithm that is usually used to remove the outlier correspondences. In the paper of Fischler and Bolles, RANSAC is used to solve the location determination problem (LDP), where the objective is to determine the points in space that project onto an image into a set of landmarks with known locations.[11]

The feature trajectories over time are then used to reconstruct their 3D positions and the camera's motion.[12] An alternative is given by so-called direct approaches, where geometric information (3D structure and camera motion) is directly estimated from the images, without intermediate abstraction to features or corners.[13]

There are several approaches to structure from motion. In incremental SfM,[14] camera poses are solved for and added one by one to the collection. In global SfM,[15][16] the poses of all cameras are solved for at the same time. A somewhat intermediate approach is out-of-core SfM, where several partial reconstructions are computed that are then integrated into a global solution.

Applications

Geosciences

Structure-from-motion photogrammetry with multi-view stereo provides hyperscale landform models using images acquired from a range of digital cameras and optionally a network of ground control points. The technique is not limited in temporal frequency and can provide point cloud data comparable in density and accuracy to those generated by terrestrial and airborne laser scanning at a fraction of the cost.[17][18][19] Structure from motion is also useful in remote or rugged environments where terrestrial laser scanning is limited by equipment portability and airborne laser scanning is limited by terrain roughness causing loss of data and image foreshortening. The technique has been applied in many settings such as rivers,[20] badlands,[21] sandy coastlines,[22][23] fault zones,[24] landslides,[25] and coral reef settings.[26] SfM has been also successfully applied for the assessment of large wood accumulation volume[27] and porosity[28] in fluvial systems, as well as for the characterization of rock masses through the determination of some properties as the orientation, persistence, etc. of discontinuities.[29][30] A full range of digital cameras can be utilized, including digital SLR's, compact digital cameras and even smart phones. Generally though, higher accuracy data will be achieved with more expensive cameras, which include lenses of higher optical quality. The technique therefore offers exciting opportunities to characterize surface topography in unprecedented detail and, with multi-temporal data, to detect elevation, position and volumetric changes that are symptomatic of earth surface processes. Structure from motion can be placed in the context of other digital surveying methods.

Cultural heritage

Cultural heritage is present everywhere. Its structural control, documentation and conservation is one of humanity's main duties (UNESCO). Under this point of view, SfM is used in order to properly estimate situations as well as planning and maintenance efforts and costs, control and restoration. Because serious constraints often exist connected to the accessibility of the site and impossibility to install invasive surveying pillars that did not permit the use of traditional surveying routines (like total stations), SfM provides a non-invasive approach for the structure, without the direct interaction between the structure and any operator. The use is accurate as only qualitative considerations are needed. It is fast enough to respond to the monument’s immediate management needs.[31] The first operational phase is an accurate preparation of the photogrammetric surveying where is established the relation between best distance from the object, focal length, the ground sampling distance (GSD) and the sensor’s resolution. With this information the programmed photographic acquisitions must be made using vertical overlapping of at least 60% (figure 02).[32]

Furthermore, structure-from-motion photogrammetry represents a non-invasive, highly flexible and low-cost methodology to digitalize historical documents.[33]

See also

Further reading

  • Jonathan L. Carrivick, Mark W. Smith, Duncan J. Quincey (2016). Structure from Motion in the Geosciences. Wiley-Blackwell. 208 pages. ISBN 978-1-118-89584-9
  • Richard Hartley & Andrew Zisserman (2003). Multiple View Geometry in Computer Vision. Cambridge University Press. ISBN 978-0-521-54051-3.
  • Olivier Faugeras and Quang-Tuan Luong and Theodore Papadopoulo (2001). The Geometry of Multiple Images. MIT Press. ISBN 978-0-262-06220-6.
  • Yi Ma; S. Shankar Sastry; Jana Kosecka; Stefano Soatto (November 2003). An Invitation to 3-D Vision: From Images to Geometric Models. Interdisciplinary Applied Mathematics Series, #26. Springer-Verlag New York, LLC. ISBN 978-0-387-00893-6.

References

  1. ^ S. Ullman (1979). "The interpretation of structure from motion" (PDF). Proceedings of the Royal Society of London. 203 (1153): 405–426. Bibcode:1979RSPSB.203..405U. doi:10.1098/rspb.1979.0006. hdl:1721.1/6298. PMID 34162. S2CID 11995230.
  2. ^ Linda G. Shapiro; George C. Stockman (2001). Computer Vision. Prentice Hall. ISBN 978-0-13-030796-5.
  3. ^ D. G. Lowe (2004). "Distinctive image features from scale-invariant keypoints". International Journal of Computer Vision. 60 (2): 91–110. CiteSeerX 10.1.1.73.2924. doi:10.1023/b:visi.0000029664.99615.94. S2CID 221242327.
  4. ^ H. Bay; T. Tuytelaars & L. Van Gool (2006). "Surf: Speeded up robust features". 9th European Conference on Computer Vision.
  5. ^ a b K. Häming & G. Peters (2010). "The structure-from-motion reconstruction pipeline – a survey with focus on short image sequences". Kybernetika. 46 (5): 926–937.
  6. ^ Viola, P.; Jones, M. (2001). "Rapid object detection using a boosted cascade of simple features". Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition. CVPR 2001. Vol. 1. Kauai, HI, USA: IEEE Comput. Soc. pp. I–511–I-518. doi:10.1109/CVPR.2001.990517. ISBN 978-0-7695-1272-3. S2CID 2715202.
  7. ^ Nurutdinova, Andrew; Fitzgibbon, Andrew (2015). "Towards Pointless Structure from Motion: 3D Reconstruction and Camera Parameters from General 3D Curves" (PDF). 2015 IEEE International Conference on Computer Vision (ICCV). pp. 2363–2371. doi:10.1109/ICCV.2015.272. ISBN 978-1-4673-8391-2. S2CID 9120123.
  8. ^ Fabbri, Ricardo; Giblin, Peter; Kimia, Benjamin (2012). "Camera Pose Estimation Using First-Order Curve Differential Geometry" (PDF). Lecture Notes in Computer Science (ECCV 2012). Lecture Notes in Computer Science. 7575: 231–244. doi:10.1007/978-3-642-33765-9_17. ISBN 978-3-642-33764-2. S2CID 15402824.
  9. ^ Apple, ARKIT team (2018). "Understanding ARKit Tracking and Detection". WWDC.
  10. ^ B. D. Lucas & T. Kanade. "An iterative image registration technique with an application to stereo vision". Ijcai81.
  11. ^ M. A. Fischler & R. C. Bolles (1981). "Random sample consensus: a paradigm for model fitting with applications to image analysis and automated cartography". Commun. ACM. 24 (6): 381–395. doi:10.1145/358669.358692. S2CID 972888.
  12. ^ F. Dellaert; S. Seitz; C. Thorpe & S. Thrun (2000). "Structure from Motion without Correspondence" (PDF). IEEE Computer Society Conference on Computer Vision and Pattern Recognition.
  13. ^ Engel, Jakob; Schöps, Thomas; Cremers, Daniel (2014). "LSD-SLAM: Large-Scale Direct Monocular SLAM". European Conference on Computer Vision (ECCV) 2014 (PDF).
  14. ^ J.L. Schönberger & J.M. Frahm (2016). "Structure-from-Motion Revisited" (PDF). IEEE Computer Society Conference on Computer Vision and Pattern Recognition.
  15. ^ C. Tomasi & T. Kanade (1992). "Shape and motion from image streams under orthography: a factorization method". International Journal of Computer Vision. 9 (2): 137–154. CiteSeerX 10.1.1.131.9807. doi:10.1007/BF00129684. S2CID 2931825.
  16. ^ V.M. Govindu (2001). "Combining two-view constraints for motion estimation". Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition. CVPR 2001. Vol. 2. pp. II-218–II-225. doi:10.1109/CVPR.2001.990963. ISBN 0-7695-1272-0. S2CID 8252027.
  17. ^ Westoby, M. J.; Brasington, J.; Glasser, N. F.; Hambrey, M. J.; Reynolds, J. M. (2012-12-15). "'Structure-from-Motion' photogrammetry: A low-cost, effective tool for geoscience applications". Geomorphology. 179: 300–314. Bibcode:2012Geomo.179..300W. doi:10.1016/j.geomorph.2012.08.021. S2CID 33695861.
  18. ^ James, M. R.; Robson, S. (2012-09-01). "Straightforward reconstruction of 3D surfaces and topography with a camera: Accuracy and geoscience application" (PDF). Journal of Geophysical Research: Earth Surface. 117 (F3): F03017. Bibcode:2012JGRF..117.3017J. doi:10.1029/2011jf002289. ISSN 2156-2202.
  19. ^ Fonstad, Mark A.; Dietrich, James T.; Courville, Brittany C.; Jensen, Jennifer L.; Carbonneau, Patrice E. (2013-03-30). "Topographic structure from motion: a new development in photogrammetric measurement" (PDF). Earth Surface Processes and Landforms. 38 (4): 421–430. Bibcode:2013ESPL...38..421F. doi:10.1002/esp.3366. ISSN 1096-9837. S2CID 15601931.
  20. ^ Javernick, L.; Brasington, J.; Caruso, B. (2014). "Modeling the topography of shallow braided rivers using Structure-from-Motion photogrammetry". Geomorphology. 213: 166–182. Bibcode:2014Geomo.213..166J. doi:10.1016/j.geomorph.2014.01.006.
  21. ^ Smith, Mark William; Vericat, Damià (2015-09-30). "From experimental plots to experimental landscapes: topography, erosion and deposition in sub-humid badlands from Structure-from-Motion photogrammetry" (PDF). Earth Surface Processes and Landforms. 40 (12): 1656–1671. Bibcode:2015ESPL...40.1656S. doi:10.1002/esp.3747. ISSN 1096-9837. S2CID 128402144.
  22. ^ Goldstein, Evan B; Oliver, Amber R; deVries, Elsemarie; Moore, Laura J; Jass, Theo (2015-10-22). "Ground control point requirements for structure-from-motion derived topography in low-slope coastal environments". PeerJ PrePrints. doi:10.7287/peerj.preprints.1444v1. ISSN 2167-9843.
  23. ^ Mancini, Francesco; Dubbini, Marco; Gattelli, Mario; Stecchi, Francesco; Fabbri, Stefano; Gabbianelli, Giovanni (2013-12-09). "Using Unmanned Aerial Vehicles (UAV) for High-Resolution Reconstruction of Topography: The Structure from Motion Approach on Coastal Environments". Remote Sensing. 5 (12): 6880–6898. Bibcode:2013RemS....5.6880M. doi:10.3390/rs5126880.
  24. ^ Johnson, Kendra; Nissen, Edwin; Saripalli, Srikanth; Arrowsmith, J. Ramón; McGarey, Patrick; Scharer, Katherine; Williams, Patrick; Blisniuk, Kimberly (2014-10-01). "Rapid mapping of ultrafine fault zone topography with structure from motion". Geosphere. 10 (5): 969–986. Bibcode:2014Geosp..10..969J. doi:10.1130/GES01017.1.
  25. ^ Del Soldato, M.; Riquelme, A.; Bianchini, S.; Tomàs, R.; Di Martire, D.; De Vita, P.; Moretti, S.; Calcaterra, D. (2018-06-06). "Multisource data integration to investigate one century of evolution for the Agnone landslide (Molise, southern Italy)". Landslides. 15 (11): 2113–2128. doi:10.1007/s10346-018-1015-z. ISSN 1612-510X.
  26. ^ Bryson, Mitch; Duce, Stephanie; Harris, Dan; Webster, Jody M.; Thompson, Alisha; Vila-Concejo, Ana; Williams, Stefan B. (2016). "Geomorphic changes of a coral shingle cay measured using Kite Aerial Photography". Geomorphology. 270: 1–8. Bibcode:2016Geomo.270....1B. doi:10.1016/j.geomorph.2016.06.018.
  27. ^ Spreitzer, Gabriel; Tunnicliffe, Jon; Friedrich, Heide (2019-12-01). "Using Structure from Motion photogrammetry to assess large wood (LW) accumulations in the field". Geomorphology. 346: 106851. Bibcode:2019Geomo.34606851S. doi:10.1016/j.geomorph.2019.106851. S2CID 202908775.
  28. ^ Spreitzer, Gabriel; Tunnicliffe, Jon; Friedrich, Heide (2020). "Large wood (LW) 3D accumulation mapping and assessment using structure from Motion photogrammetry in the laboratory". Journal of Hydrology. 581: 124430. Bibcode:2020JHyd..58124430S. doi:10.1016/j.jhydrol.2019.124430. S2CID 209465940.
  29. ^ Riquelme, A.; Cano, M.; Tomás, R.; Abellán, A. (2017-01-01). "Identification of Rock Slope Discontinuity Sets from Laser Scanner and Photogrammetric Point Clouds: A Comparative Analysis". Procedia Engineering. 191: 838–845. doi:10.1016/j.proeng.2017.05.251. ISSN 1877-7058.
  30. ^ Jordá Bordehore, Luis; Riquelme, Adrian; Cano, Miguel; Tomás, Roberto (2017-09-01). "Comparing manual and remote sensing field discontinuity collection used in kinematic stability assessment of failed rock slopes" (PDF). International Journal of Rock Mechanics and Mining Sciences. 97: 24–32. Bibcode:2017IJRMM..97...24J. doi:10.1016/j.ijrmms.2017.06.004. hdl:10045/67528. ISSN 1365-1609.
  31. ^ Guidi. G.; Beraldin, J.A.; Atzeni, C. High accuracy 3D modelling of cultural heritage: The digitizing of Donatello. IEEE Trans. Image Process. 2004, 13, 370–380
  32. ^ Kraus, K., 2007. Photogrammetry: Geometry from Image and Laser Scans. Walter de Gruyter, 459 pp. ISBN 978-3-11-019007-6
  33. ^ Brandolini, Filippo; Patrucco, Giacomo (September 2019). "Structure-from-Motion (SFM) Photogrammetry as a Non-Invasive Methodology to Digitalize Historical Documents: A Highly Flexible and Low-Cost Approach?". Heritage. 2 (3): 2124–2136. doi:10.3390/heritage2030128.

August 21, 2023
structure, from, motion, confused, with, structure, from, motion, psychophysics, photogrammetric, range, imaging, technique, estimating, three, dimensional, structures, from, dimensional, image, sequences, that, coupled, with, local, motion, signals, studied, . Not to be confused with structure from motion psychophysics Structure from motion SfM 1 is a photogrammetric range imaging technique for estimating three dimensional structures from two dimensional image sequences that may be coupled with local motion signals It is studied in the fields of computer vision and visual perception In biological vision SfM refers to the phenomenon by which humans and other living creatures can recover 3D structure from the projected 2D retinal motion field of a moving object or scene Contents 1 Principle 2 Applications 2 1 Geosciences 2 2 Cultural heritage 3 See also 4 Further reading 5 ReferencesPrinciple Edit Digital surface model of motorway interchange construction site Real photo x SfM with texture color x SfM with simple shader Made with Python Photogrammetry Toolbox GUI and rendered in Blender with Cycles Bezmiechowa airfield 3D digital surface model extracted from data collected during 30min flight of Pteryx UAVHumans perceive a great deal of information about the three dimensional structure in their environment by moving around it When the observer moves objects around them move different amounts depending on their distance from the observer This is known as motion parallax and from this depth information can be used to generate an accurate 3D representation of the world around them 2 Finding structure from motion presents a similar problem to finding structure from stereo vision In both instances the correspondence between images and the reconstruction of 3D object needs to be found To find correspondence between images features such as corner points edges with gradients in multiple directions are tracked from one image to the next One of the most widely used feature detectors is the scale invariant feature transform SIFT It uses the maxima from a difference of Gaussians DOG pyramid as features The first step in SIFT is finding a dominant gradient direction To make it rotation invariant the descriptor is rotated to fit this orientation 3 Another common feature detector is the SURF speeded up robust features 4 In SURF the DOG is replaced with a Hessian matrix based blob detector Also instead of evaluating the gradient histograms SURF computes for the sums of gradient components and the sums of their absolute values 5 Its usage of integral images allows the features to be detected extremely quickly with high detection rate 6 Therefore comparing to SIFT SURF is a faster feature detector with drawback of less accuracy in feature positions 5 Another type of feature recently made practical for structure from motion are general curves e g locally an edge with gradients in one direction part of a technology known as pointless SfM 7 8 useful when point features are insufficient common in man made environments 9 The features detected from all the images will then be matched One of the matching algorithms that track features from one image to another is the Lucas Kanade tracker 10 Sometimes some of the matched features are incorrectly matched This is why the matches should also be filtered RANSAC random sample consensus is the algorithm that is usually used to remove the outlier correspondences In the paper of Fischler and Bolles RANSAC is used to solve the location determination problem LDP where the objective is to determine the points in space that project onto an image into a set of landmarks with known locations 11 The feature trajectories over time are then used to reconstruct their 3D positions and the camera s motion 12 An alternative is given by so called direct approaches where geometric information 3D structure and camera motion is directly estimated from the images without intermediate abstraction to features or corners 13 There are several approaches to structure from motion In incremental SfM 14 camera poses are solved for and added one by one to the collection In global SfM 15 16 the poses of all cameras are solved for at the same time A somewhat intermediate approach is out of core SfM where several partial reconstructions are computed that are then integrated into a global solution Applications EditGeosciences Edit Structure from motion photogrammetry with multi view stereo provides hyperscale landform models using images acquired from a range of digital cameras and optionally a network of ground control points The technique is not limited in temporal frequency and can provide point cloud data comparable in density and accuracy to those generated by terrestrial and airborne laser scanning at a fraction of the cost 17 18 19 Structure from motion is also useful in remote or rugged environments where terrestrial laser scanning is limited by equipment portability and airborne laser scanning is limited by terrain roughness causing loss of data and image foreshortening The technique has been applied in many settings such as rivers 20 badlands 21 sandy coastlines 22 23 fault zones 24 landslides 25 and coral reef settings 26 SfM has been also successfully applied for the assessment of large wood accumulation volume 27 and porosity 28 in fluvial systems as well as for the characterization of rock masses through the determination of some properties as the orientation persistence etc of discontinuities 29 30 A full range of digital cameras can be utilized including digital SLR s compact digital cameras and even smart phones Generally though higher accuracy data will be achieved with more expensive cameras which include lenses of higher optical quality The technique therefore offers exciting opportunities to characterize surface topography in unprecedented detail and with multi temporal data to detect elevation position and volumetric changes that are symptomatic of earth surface processes Structure from motion can be placed in the context of other digital surveying methods Cultural heritage Edit Cultural heritage is present everywhere Its structural control documentation and conservation is one of humanity s main duties UNESCO Under this point of view SfM is used in order to properly estimate situations as well as planning and maintenance efforts and costs control and restoration Because serious constraints often exist connected to the accessibility of the site and impossibility to install invasive surveying pillars that did not permit the use of traditional surveying routines like total stations SfM provides a non invasive approach for the structure without the direct interaction between the structure and any operator The use is accurate as only qualitative considerations are needed It is fast enough to respond to the monument s immediate management needs 31 The first operational phase is an accurate preparation of the photogrammetric surveying where is established the relation between best distance from the object focal length the ground sampling distance GSD and the sensor s resolution With this information the programmed photographic acquisitions must be made using vertical overlapping of at least 60 figure 02 32 Furthermore structure from motion photogrammetry represents a non invasive highly flexible and low cost methodology to digitalize historical documents 33 See also Edit3D reconstruction from multiple images Bundle adjustment Comparison of photogrammetry software Computer stereo vision Epipolar geometry Kinetic depth effect Match moving Motion field Motion parallax Semi global matching Simultaneous localization and mapping Stereophotogrammetry Tomasi Kanade factorization 2D to 3D conversionFurther reading EditJonathan L Carrivick Mark W Smith Duncan J Quincey 2016 Structure from Motion in the Geosciences Wiley Blackwell 208 pages ISBN 978 1 118 89584 9 Richard Hartley amp Andrew Zisserman 2003 Multiple View Geometry in Computer Vision Cambridge University Press ISBN 978 0 521 54051 3 Olivier Faugeras and Quang Tuan Luong and Theodore Papadopoulo 2001 The Geometry of Multiple Images MIT Press ISBN 978 0 262 06220 6 Yi Ma S Shankar Sastry Jana Kosecka Stefano Soatto November 2003 An Invitation to 3 D Vision From Images to Geometric Models Interdisciplinary Applied Mathematics Series 26 Springer Verlag New York LLC ISBN 978 0 387 00893 6 References Edit S Ullman 1979 The interpretation of structure from motion PDF Proceedings of the Royal Society of London 203 1153 405 426 Bibcode 1979RSPSB 203 405U doi 10 1098 rspb 1979 0006 hdl 1721 1 6298 PMID 34162 S2CID 11995230 Linda G Shapiro George C Stockman 2001 Computer Vision Prentice Hall ISBN 978 0 13 030796 5 D G Lowe 2004 Distinctive image features from scale invariant keypoints International Journal of Computer Vision 60 2 91 110 CiteSeerX 10 1 1 73 2924 doi 10 1023 b visi 0000029664 99615 94 S2CID 221242327 H Bay T Tuytelaars amp L Van Gool 2006 Surf Speeded up robust features 9th European Conference on Computer Vision a b K Haming amp G Peters 2010 The structure from motion reconstruction pipeline a survey with focus on short image sequences Kybernetika 46 5 926 937 Viola P Jones M 2001 Rapid object detection using a boosted cascade of simple features Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition CVPR 2001 Vol 1 Kauai HI USA IEEE Comput Soc pp I 511 I 518 doi 10 1109 CVPR 2001 990517 ISBN 978 0 7695 1272 3 S2CID 2715202 Nurutdinova Andrew Fitzgibbon Andrew 2015 Towards Pointless Structure from Motion 3D Reconstruction and Camera Parameters from General 3D Curves PDF 2015 IEEE International Conference on Computer Vision ICCV pp 2363 2371 doi 10 1109 ICCV 2015 272 ISBN 978 1 4673 8391 2 S2CID 9120123 Fabbri Ricardo Giblin Peter Kimia Benjamin 2012 Camera Pose Estimation Using First Order Curve Differential Geometry PDF Lecture Notes in Computer Science ECCV 2012 Lecture Notes in Computer Science 7575 231 244 doi 10 1007 978 3 642 33765 9 17 ISBN 978 3 642 33764 2 S2CID 15402824 Apple ARKIT team 2018 Understanding ARKit Tracking and Detection WWDC B D Lucas amp T Kanade An iterative image registration technique with an application to stereo vision Ijcai81 M A Fischler amp R C Bolles 1981 Random sample consensus a paradigm for model fitting with applications to image analysis and automated cartography Commun ACM 24 6 381 395 doi 10 1145 358669 358692 S2CID 972888 F Dellaert S Seitz C Thorpe amp S Thrun 2000 Structure from Motion without Correspondence PDF IEEE Computer Society Conference on Computer Vision and Pattern Recognition Engel Jakob Schops Thomas Cremers Daniel 2014 LSD SLAM Large Scale Direct Monocular SLAM European Conference on Computer Vision ECCV 2014 PDF J L Schonberger amp J M Frahm 2016 Structure from Motion Revisited PDF IEEE Computer Society Conference on Computer Vision and Pattern Recognition C Tomasi amp T Kanade 1992 Shape and motion from image streams under orthography a factorization method International Journal of Computer Vision 9 2 137 154 CiteSeerX 10 1 1 131 9807 doi 10 1007 BF00129684 S2CID 2931825 V M Govindu 2001 Combining two view constraints for motion estimation Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition CVPR 2001 Vol 2 pp II 218 II 225 doi 10 1109 CVPR 2001 990963 ISBN 0 7695 1272 0 S2CID 8252027 Westoby M J Brasington J Glasser N F Hambrey M J Reynolds J M 2012 12 15 Structure from Motion photogrammetry A low cost effective tool for geoscience applications Geomorphology 179 300 314 Bibcode 2012Geomo 179 300W doi 10 1016 j geomorph 2012 08 021 S2CID 33695861 James M R Robson S 2012 09 01 Straightforward reconstruction of 3D surfaces and topography with a camera Accuracy and geoscience application PDF Journal of Geophysical Research Earth Surface 117 F3 F03017 Bibcode 2012JGRF 117 3017J doi 10 1029 2011jf002289 ISSN 2156 2202 Fonstad Mark A Dietrich James T Courville Brittany C Jensen Jennifer L Carbonneau Patrice E 2013 03 30 Topographic structure from motion a new development in photogrammetric measurement PDF Earth Surface Processes and Landforms 38 4 421 430 Bibcode 2013ESPL 38 421F doi 10 1002 esp 3366 ISSN 1096 9837 S2CID 15601931 Javernick L Brasington J Caruso B 2014 Modeling the topography of shallow braided rivers using Structure from Motion photogrammetry Geomorphology 213 166 182 Bibcode 2014Geomo 213 166J doi 10 1016 j geomorph 2014 01 006 Smith Mark William Vericat Damia 2015 09 30 From experimental plots to experimental landscapes topography erosion and deposition in sub humid badlands from Structure from Motion photogrammetry PDF Earth Surface Processes and Landforms 40 12 1656 1671 Bibcode 2015ESPL 40 1656S doi 10 1002 esp 3747 ISSN 1096 9837 S2CID 128402144 Goldstein Evan B Oliver Amber R deVries Elsemarie Moore Laura J Jass Theo 2015 10 22 Ground control point requirements for structure from motion derived topography in low slope coastal environments PeerJ PrePrints doi 10 7287 peerj preprints 1444v1 ISSN 2167 9843 Mancini Francesco Dubbini Marco Gattelli Mario Stecchi Francesco Fabbri Stefano Gabbianelli Giovanni 2013 12 09 Using Unmanned Aerial Vehicles UAV for High Resolution Reconstruction of Topography The Structure from Motion Approach on Coastal Environments Remote Sensing 5 12 6880 6898 Bibcode 2013RemS 5 6880M doi 10 3390 rs5126880 Johnson Kendra Nissen Edwin Saripalli Srikanth Arrowsmith J Ramon McGarey Patrick Scharer Katherine Williams Patrick Blisniuk Kimberly 2014 10 01 Rapid mapping of ultrafine fault zone topography with structure from motion Geosphere 10 5 969 986 Bibcode 2014Geosp 10 969J doi 10 1130 GES01017 1 Del Soldato M Riquelme A Bianchini S Tomas R Di Martire D De Vita P Moretti S Calcaterra D 2018 06 06 Multisource data integration to investigate one century of evolution for the Agnone landslide Molise southern Italy Landslides 15 11 2113 2128 doi 10 1007 s10346 018 1015 z ISSN 1612 510X Bryson Mitch Duce Stephanie Harris Dan Webster Jody M Thompson Alisha Vila Concejo Ana Williams Stefan B 2016 Geomorphic changes of a coral shingle cay measured using Kite Aerial Photography Geomorphology 270 1 8 Bibcode 2016Geomo 270 1B doi 10 1016 j geomorph 2016 06 018 Spreitzer Gabriel Tunnicliffe Jon Friedrich Heide 2019 12 01 Using Structure from Motion photogrammetry to assess large wood LW accumulations in the field Geomorphology 346 106851 Bibcode 2019Geomo 34606851S doi 10 1016 j geomorph 2019 106851 S2CID 202908775 Spreitzer Gabriel Tunnicliffe Jon Friedrich Heide 2020 Large wood LW 3D accumulation mapping and assessment using structure from Motion photogrammetry in the laboratory Journal of Hydrology 581 124430 Bibcode 2020JHyd 58124430S doi 10 1016 j jhydrol 2019 124430 S2CID 209465940 Riquelme A Cano M Tomas R Abellan A 2017 01 01 Identification of Rock Slope Discontinuity Sets from Laser Scanner and Photogrammetric Point Clouds A Comparative Analysis Procedia Engineering 191 838 845 doi 10 1016 j proeng 2017 05 251 ISSN 1877 7058 Jorda Bordehore Luis Riquelme Adrian Cano Miguel Tomas Roberto 2017 09 01 Comparing manual and remote sensing field discontinuity collection used in kinematic stability assessment of failed rock slopes PDF International Journal of Rock Mechanics and Mining Sciences 97 24 32 Bibcode 2017IJRMM 97 24J doi 10 1016 j ijrmms 2017 06 004 hdl 10045 67528 ISSN 1365 1609 Guidi G Beraldin J A Atzeni C High accuracy 3D modelling of cultural heritage The digitizing of Donatello IEEE Trans Image Process 2004 13 370 380 Kraus K 2007 Photogrammetry Geometry from Image and Laser Scans Walter de Gruyter 459 pp ISBN 978 3 11 019007 6 Brandolini Filippo Patrucco Giacomo September 2019 Structure from Motion SFM Photogrammetry as a Non Invasive Methodology to Digitalize Historical Documents A Highly Flexible and Low Cost Approach Heritage 2 3 2124 2136 doi 10 3390 heritage2030128 Retrieved from https en wikipedia org w index php title Structure from motion amp oldid 1167112516, wikipedia, wiki, book, books, library,

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