1Panotools::Script::LineU:s:eIrmaCgoen(t3r)ibuted Perl DoPcaunmoetnotoaltsi:o:nScript::Line::Image(3)
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NAME

6       Panotools::Script::Line::Image - Panotools input image
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SYNOPSIS

9       A single input image is described by an 'i' line
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DESCRIPTION

12       Basically the same format as an 'o' line.
13
14         w1000
15         h500     nona requires the width and height of input images wheras PTStitcher/mender don't
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17         f0           projection format,
18                          0 - rectilinear (normal lenses)
19                          1 - Panoramic (Scanning cameras like Noblex)
20                          2 - Circular fisheye
21                          3 - full-frame fisheye
22                          4 - PSphere, equirectangular
23                          7 - Mirror (a spherical mirror)
24                          8 - Orthographic fisheye
25                         10 - Stereographic fisheye
26                         21 - Equisolid fisheye
27
28         v82          horizontal field of view of image (required)
29         y0           yaw angle (required)
30         p43          pitch angle (required)
31         r0           roll angle (required)
32         a,b,c        lens correction coefficients (optional)
33                          (see http://www.fh-furtwangen.de/~dersch/barrel/barrel.html)
34         d,e          initial lens offset in pixels(defaults d0 e0, optional).
35                          Used to correct for offset from center of image
36                          d - horizontal offset,
37                          e - vertical offset
38         g,t          initial lens shear.  Use to remove slight misalignment
39                          of the line scanner relative to the film transport
40                          g - horizontal shear
41                          t - vertical shear
42         j            stack number
43
44         Eev          exposure of image in EV (exposure values)
45         Er           white balance factor for red channel
46         Eb           white balance factor for blue channel
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48         Ra           EMoR response model from the Computer Vision Lab at Columbia University
49         Rb           This models the camera response curve
50         Rc
51         Rd
52         Re
53
54         TiX,TiY,TiZ  Tilt on x axis, y axis, z axis
55         TiS           Scaling of field of view in the tilt transformation
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57         TrX,TrY,TrZ  Translation on x axis, y axis, z axis
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59         Tpy,Tpp      yaw and pitch of remapping plane for translation
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61         Te0,Te1,Te2,Te3  Test parameters
62
63         Vm           vignetting correction mode (default 0):
64                          0: no vignetting correction
65                          1: radial vignetting correction (see j,k,l,o options)
66                          2: flatfield vignetting correction (see p option)
67                          4: proportional correction: i_new = i / corr.
68                               This mode is recommended for use with linear data.
69                               If the input data is gamma corrected, try adding g2.2
70                               to the m line.
71
72                              default is additive correction: i_new = i + corr
73
74                            Both radial and flatfield correction can be combined with the
75                             proportional correction by adding 4.
76                         Examples: i1 - radial polynomial correction by addition.
77                                         The coefficients j,k,l,o must be specified.
78                                   i5 - radial polynomial correction by division.
79                                         The coefficients j,k,l,o must be specified.
80                                   i6 - flatfield correction by division.
81                                         The flatfield image should be specified with the p option
82
83         Va,Vb,Vc,Vd  vignetting correction coefficients. (defaults: 0,0,0,0)
84                       ( 0, 2, 4, 6 order polynomial coefficients):
85                        corr = ( i + j*r^2 + k*r^4 + l*r^6), where r is the distance from the image center
86                      The corrected pixel value is calculated with: i_new = i_old + corr
87                      if additive correction is used (default)
88                                  for proportional correction (h5): i_new = i_old / corr;
89
90         Vx,Vy        radial vignetting correction offset in pixels (defaults q0 w0, optional).
91                         Used to correct for offset from center of image
92                          Vx - horizontal offset
93                          Vy - vertical offset
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95         S100,600,100,800   Selection(l,r,t,b), Only pixels inside the rectangle will be used for conversion.
96                               Original image size is used for all image parameters
97                               (e.g. field-of-view) refer to the original image.
98                               Selection can be outside image dimension.
99                               The selection will be circular for circular fisheye images, and
100                               rectangular for all other projection formats
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102         nName        file name of the input image.
103
104         i f2 r0   p0    y0     v183    a0 b-0.1 c0  S100,600,100,800 n"photo1.jpg"
105         i f2 r0   p0    y180   v183    a0 b-0.1 c0  S100,600,100,800 n"photo1.jpg"
106
107       Rotate transform the image, angles in degrees:
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109         $i->Transform ($roll, $pitch, $yaw);
110
111       Each image attribute (v, a, b, c etc...) can be read like so:
112
113        $fov = $i->v;
114
115       Note that this will return either the value (56.7) or a reference to
116       another image (=0).  If you supply a Panotools::Script object as a
117       parameter then the reference will be resolved and you will always get
118       the value:
119
120        $fov = $i->v ($pto);
121
122       Get the absolute path to the image file
123
124       $i->Path ('/path/to/project.pto');
125
126       If a .pto project isn't specified then paths are assumed to be relatve
127       to cwd
128
129       For any given coordinate in this image (top left is 0,0), calculate an
130       x,y,z cartesian coordinate, accounting for lens distortion, projection
131       and rotation.
132
133         $coor = $i->To_Cartesian ($pto, [23,45]);
134         ($x, $y, $z) = @{$coor};
135
136       Query distance (radius) to photo in pixels:
137
138         $pix_radius = $i->Radius ($pto);
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142perl v5.34.0                      2021-07-22 Panotools::Script::Line::Image(3)
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