Direct linear transformation: Difference between revisions

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Line 5: where <math> \mathbf{x}_{k} </math> and <math> \mathbf{y}_{k} </math> are known vectors, <math> \, \propto </math> denotes equality up to an unknown scalar multiplication, and <math> \mathbf{A} </math> is a matrix (or linear transformation) which contains the unknowns to be solved. This type of relation appears frequently in [[projective geometry]]. Practical examples include the relation between 3D points in a scene and their projection onto the image plane of a [[Pinhole camera model\|pinhole camera]],<ref>{{cite journal \| last=Abdel-Aziz \| first=Y.I. \| last2=Karara \| first2=H.M. \| title=Direct Linear Transformation from Comparator Coordinates into Object Space Coordinates in Close-Range Photogrammetry \| journal=Photogrammetric Engineering & Remote Sensing \| publisher=American Society for Photogrammetry and Remote Sensing \| volume=81 \| issue=2 \| date=2015-02-01 \| issn=0099-1112 \| doi=10.14358/pers.81.2.103 \| pages=103–107\| doi-access=free }}</ref> and [[Homography (computer vision)\|homographies]]. == Introduction == Line 62: : <math> \mathbf{b}_{k} = \begin{pmatrix} x_{2k} \, y_{1k} \\ -x_{1k} \, y_{1k} \\ x_{2k} \, y_{2k} \\ -x_{1k} \, y_{2k} \\ x_{2k} \, y_{3k} \\ -x_{1k} \, y_{3k} \end{pmatrix} </math>   and   <math> \mathbf{a} = \begin{pmatrix} a_{11} \\ a_{21} \\ a_{12} \\ a_{22} \\ a_{13} \\ a_{23} \end{pmatrix}. </math> ~~This~~So far, we have 1 equation and 6 unknowns. A set of homogeneous ~~equation~~equations can ~~also~~ be written in the matrix form :<math> \mathbf{0} = \mathbf{B} \, \mathbf{a} </math> where <math> \mathbf{B} </math> is a <math> N \times 6 </math> matrix which holds the known vectors <math> \mathbf{b}_{k} </math> in its rows. The ~~This means that~~unknown <math> \mathbf{a} </math> ~~lies in the [[null space]] of <math> \mathbf{B} </math> and~~ can be determined, for example, by a [[singular value decomposition]] of <math> \mathbf{B} </math>; <math> \mathbf{a} </math> is a right singular vector of <math> \mathbf{B} </math> corresponding to a singular value that equals zero. Once <math> \mathbf{a} </math> has been determined, the elements of matrix <math> \mathbf{A} </math> can ~~be found by a simple rearrangement~~rearranged from ~~a 6-dimensional~~ vector ~~to a~~ <math> 2 \~~times 3~~ mathbf{a}</math> ~~matrix~~. Notice that the scaling of <math> \mathbf{a} </math> or <math> \mathbf{A} </math> is not important (except that it must be non-zero) since the defining equations already allow for unknown scaling. In practice the vectors <math> \mathbf{x}_{k} </math> and <math> \mathbf{y}_{k} </math> may contain noise which means that the similarity equations are only approximately valid. As a consequence, there may not be a vector <math> \mathbf{a} </math> which solves the homogeneous equation <math> \mathbf{0} = \mathbf{B} \, \mathbf{a} </math> exactly. In these cases, a [[total least squares]] solution can be used by choosing <math> \mathbf{a} </math> as a right singular vector corresponding to the smallest singular value of <math> \mathbf{B}. </math> Line 116: == External links == * [~~https~~http://~~www~~citeseerx.csist.~~ubc~~psu.caedu/~~grads~~viewdoc/~~resources/thesis/May09/Dubrofsky_Elan~~summary?doi=10.1.1.186.~~pdf~~4411 Homography Estimation] by Elan Dubrofsky (§2.1 sketches the "Basic DLT Algorithm") * [http://www.mathworks.com/matlabcentral/fileexchange/65030-direct-linear-transformation--dlt--solver A DLT Solver based on MATLAB] by Hsiang-Jen (Johnny) Chien