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Elphel
imagej-elphel
Commits
5ef8f36f
Commit
5ef8f36f
authored
Nov 04, 2015
by
Oleg Dzhimiev
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new optical test pattern generation script
parent
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escher_pattern_invertedfisheye.py
src/main/resources/escher_pattern_invertedfisheye.py
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5ef8f36f
#!/usr/bin/env python3
'''
# Copyright (C) 2015, Elphel.inc.
# Usage: known
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http:#www.gnu.org/licenses/>.
@author: Oleg K Dzhimiev
@copyright: 2015 Elphel, Inc.
@license: GPLv3.0+
@contact: oleg@elphel.com
@deffield updated: unknown
'''
__author__
=
"Oleg K Dzhimiev"
__copyright__
=
"Copyright 2015, Elphel, Inc."
__license__
=
"GPL"
__version__
=
"3.0+"
__maintainer__
=
"Oleg K Dzhimiev"
__email__
=
"oleg@elphel.com"
__status__
=
"Silent Development"
import
argparse
from
argparse
import
RawTextHelpFormatter
parser
=
argparse
.
ArgumentParser
(
prog
=
"escher_pattern_invertedfisheye.py"
,
description
=
"* To change the parameters of the lens & pattern edit the source file.
\n\
* Python dependencies: numpy,scipy,pyx:
\n\
NumPy,SciPy - Ubuntu: sudo apt-get install python3-numpy python3-scipy
\n\
PyX - Download and install from: http://pyx.sourceforge.net/"
,
usage
=
"./escher_pattern_invertedfisheye.py or python3 escher_pattern_invertedfisheye.py"
,
formatter_class
=
RawTextHelpFormatter
)
args
=
parser
.
parse_args
()
import
numpy
as
np
from
pyx
import
*
import
math
import
scipy
as
sc
from
scipy.optimize
import
leastsq
#TODO:
# DONE 1. draw red arcs on cylinder pattern - don't break the filling - off/on
# DONE 2. approximate curves with more arcs thans just 1
# NOT CRITICAL 3. split floor pattern into 2 halves
# NOT CRITICAL 4. try creating horizontal/vertical lines
# DONE 5. Compare how extra points affect the calculations
#CONSTANTS
DEBUG
=
0
#PRIMARY
LENS_FOV
=
190
LENS_FOCAL_LENGTH
=
2.0
PATTERN_CYLINDER_HEIGHT_M
=
0.8
PATTERN_FLOOR_OVERLAP
=
0.01
#1cm
PATTERN_SCALE
=
unit
.
t_m
#PATTERN_SCALE = unit.t_cm
#lens
LENS_POLYNOME_COEFFICIENTS
=
[
LENS_FOCAL_LENGTH
,
0
,
0
,
0
,
0
]
#pattern (object plane side)
#PATTERN_CYLINDER_RADIUS_M = 1.5
#Black spot size on the sensor in pixels
PATTERN_PERIOD_IMG_PLANE_NPX
=
50
PATTERN_E
=
2
#some constant - affects the curves
PATTERN_ANGLE
=
0
#departure angle from vertical
#production values
PATTERN_NUMBER_OF_POINTS_FOR_CURVE_APPROXIMATION
=
50
PATTERN_NUMBER_OF_EXTRA_END_POINTS_APPROXIMATION
=
100
PATTERN_EPSILON_FOR_LEAST_SQUARE_APPROXIMATION
=
0.00001
#in scale parts
#debug values
#PATTERN_NUMBER_OF_POINTS_FOR_CURVE_APPROXIMATION = 20
#PATTERN_NUMBER_OF_EXTRA_END_POINTS_APPROXIMATION = 10
#PATTERN_EPSILON_FOR_LEAST_SQUARE_APPROXIMATION = 0.0001 #in scale parts
#LEAST IMPORTANT OR NOT USED
#sensor (image plane)
SENSOR_WIDTH_MM
=
5.70
SENSOR_HEIGHT_MM
=
4.28
SENSOR_PXSIZE_UM
=
2.2
#CLASSES
class
Lens
:
def
__init__
(
self
,
k
=
[
2
,
0
,
0
,
0
,
0
],
fov
=
180
):
try
:
#let the first coefficient be focal length
self
.
f
=
k
[
0
]
self
.
k
=
k
#field of view
self
.
fov
=
fov
except
IndexError
:
print
(
"ERROR: Lens init"
)
#forward translation
#theta - angle between principal axis and incoming ray, theta_max = fov/2
def
r_mm
(
self
,
theta_rad
):
result
=
0
for
i
in
range
(
len
(
self
.
k
)):
result
+=
self
.
k
[
i
]
*
(
theta_rad
**
(
2
*
i
+
1
))
return
result
#backward translation
def
theta_rad
(
self
,
r_mm
,
tolerance_rad
=
0.0001
):
theta1
=
0
theta2
=
2
*
math
.
pi
while
(
abs
(
theta2
-
theta1
)
>
tolerance_rad
):
r1
=
self
.
r_mm
(
theta1
)
-
r_mm
r2
=
self
.
r_mm
(
theta2
)
-
r_mm
theta
=
theta1
-
(
theta2
-
theta1
)
*
r1
/
(
r2
-
r1
)
theta1
=
theta2
theta2
=
theta
return
theta
def
theta_deg
(
self
,
r_mm
,
tolerance_rad
=
0.0001
):
return
(
self
.
theta_rad
(
r_mm
,
tolerance_rad
)
*
180
/
math
.
pi
)
class
Sensor
:
def
__init__
(
self
,
w_mm
=
5.70
,
h_mm
=
4.28
,
px_um
=
2.2
):
self
.
w_mm
=
w_mm
self
.
h_mm
=
h_mm
self
.
d_mm
=
math
.
sqrt
(
w_mm
**
2
+
h_mm
*
2
)
self
.
px_um
=
px_um
class
Pattern
:
def
__init__
(
self
,
H_m
,
lens_fov
,
period_n
=
40
,
e
=
2
,
angle
=
0
,
N
=
50
,
N_extra
=
10
,
epsilon
=
0.0001
,
scale
=
10
,
floor_overlap
=
0.01
):
self
.
H_m
=
H_m
self
.
lens_fov
=
lens_fov
tg
=
math
.
tan
(
lens_fov
/
2
*
math
.
pi
/
180
)
self
.
R_m
=
H_m
*
tg
/
(
tg
-
1
)
self
.
period_n
=
period_n
#pattern parameters
self
.
angle
=
angle
self
.
e
=
e
self
.
size
=
1
self
.
hsize
=
self
.
size
/
2
self
.
qsize
=
self
.
size
/
4
a
=
e
*
(
math
.
sqrt
(
2
)
-
1
)
self
.
a
=
a
self
.
r
=
(
a
*
a
+
1
)
/
(
2
*
a
)
*
self
.
qsize
self
.
h
=
math
.
sqrt
(
self
.
r
*
self
.
r
-
self
.
qsize
*
self
.
qsize
)
self
.
dc
=
2
*
self
.
qsize
-
self
.
h
self
.
halfangle
=
180
/
math
.
pi
*
math
.
atan
(
self
.
qsize
/
self
.
h
)
self
.
N
=
N
self
.
N_extra
=
N_extra
self
.
epsilon
=
epsilon
self
.
scale
=
scale
self
.
floor_overlap
=
floor_overlap
# init objects
L
=
Lens
(
LENS_POLYNOME_COEFFICIENTS
,
LENS_FOV
)
S
=
Sensor
(
SENSOR_WIDTH_MM
,
SENSOR_HEIGHT_MM
,
SENSOR_PXSIZE_UM
)
P
=
Pattern
(
PATTERN_CYLINDER_HEIGHT_M
,
L
.
fov
,
PATTERN_PERIOD_IMG_PLANE_NPX
,
PATTERN_E
,
PATTERN_ANGLE
,
PATTERN_NUMBER_OF_POINTS_FOR_CURVE_APPROXIMATION
,
PATTERN_NUMBER_OF_EXTRA_END_POINTS_APPROXIMATION
,
PATTERN_EPSILON_FOR_LEAST_SQUARE_APPROXIMATION
,
PATTERN_SCALE
,
PATTERN_FLOOR_OVERLAP
)
print
(
"CHECK 0: The pattern scale units are:"
)
print
(
P
.
scale
)
#FUNCTIONS
def
CircleCenterBy2PointsAndRadius
(
x1
,
y1
,
x2
,
y2
,
R
):
k
=
(
y2
-
y1
)
/
(
x2
-
x1
)
k
=
-
1
/
k
xm
=
(
x1
+
x2
)
/
2
ym
=
(
y1
+
y2
)
/
2
b
=
ym
-
k
*
xm
A
=
1
+
(
k
**
2
)
B
=
-
2
*
x1
-
2
*
k
*
(
y1
-
b
)
C
=
(
x1
**
2
)
+
(
y1
-
b
)
**
2
-
(
R
**
2
)
D
=
B
*
B
-
4
*
A
*
C
xc1
=
(
-
B
+
math
.
sqrt
(
D
))
/
(
2
*
A
)
xc2
=
(
-
B
-
math
.
sqrt
(
D
))
/
(
2
*
A
)
yc1
=
k
*
xc1
+
b
yc2
=
k
*
xc2
+
b
return
[[
xc1
,
yc1
],[
xc2
,
yc2
]]
def
MoveCircle
(
x1
,
y1
,
x2
,
y2
,
xc
,
yc
,
R
):
#move circle so the end points would lie to it
points
=
CircleCenterBy2PointsAndRadius
(
x1
,
y1
,
x2
,
y2
,
R
)
d1
=
math
.
sqrt
((
points
[
0
][
0
]
-
xc
)
*
(
points
[
0
][
0
]
-
xc
)
+
(
points
[
0
][
1
]
-
yc
)
*
(
points
[
0
][
1
]
-
yc
))
d2
=
math
.
sqrt
((
points
[
1
][
0
]
-
xc
)
*
(
points
[
1
][
0
]
-
xc
)
+
(
points
[
1
][
1
]
-
yc
)
*
(
points
[
1
][
1
]
-
yc
))
if
(
d1
<
d2
):
return
points
[
0
]
else
:
return
points
[
1
]
def
ArcsFit
(
points
,
spl
):
FunCircle
=
lambda
p
,
x
:
p
[
1
]
-
np
.
sqrt
((
p
[
2
])
*
(
p
[
2
])
-
(
x
-
p
[
0
])
*
(
x
-
p
[
0
]))
Fun
=
lambda
p
,
x
:
-
p
[
0
]
/
p
[
1
]
*
x
-
p
[
2
]
/
p
[
1
]
ErrorFun
=
lambda
p
,
x
,
y
:
(
y
*
y
+
x
*
x
)
-
(
p
[
0
]
*
x
+
p
[
1
]
*
y
+
p
[
2
])
result
=
[]
xdata
=
np
.
array
([])
ydata
=
np
.
array
([])
for
point
in
points
:
xdata
=
np
.
append
(
xdata
,
point
[
0
])
ydata
=
np
.
append
(
ydata
,
point
[
1
])
p0
=
(
1
,
1
,
1
)
x0w
=
np
.
array
([])
y0w
=
np
.
array
([])
xnw
=
np
.
array
([])
ynw
=
np
.
array
([])
#add weights like 1000x replicate end points
for
i
in
range
(
P
.
N_extra
):
x0w
=
np
.
append
(
x0w
,
xdata
[
0
])
y0w
=
np
.
append
(
y0w
,
ydata
[
0
])
xnw
=
np
.
append
(
xnw
,
xdata
[
len
(
xdata
)
-
1
])
ynw
=
np
.
append
(
ynw
,
ydata
[
len
(
xdata
)
-
1
])
xdata_leastsq
=
np
.
concatenate
((
x0w
,
xdata
,
xnw
),
axis
=
0
)
ydata_leastsq
=
np
.
concatenate
((
y0w
,
ydata
,
ynw
),
axis
=
0
)
if
(
DEBUG
==
1
):
print
(
"LEASTSQ RESULTS:"
)
abc
,
cov_x
=
leastsq
(
ErrorFun
,
p0
,
args
=
(
xdata
,
ydata
))
x0
=
abc
[
0
]
/
2
y0
=
abc
[
1
]
/
2
if
(
DEBUG
==
1
):
print
(
x0
,
y0
,
math
.
sqrt
(
abc
[
2
]
+
x0
*
x0
+
y0
*
y0
))
abc
,
cov_x
=
leastsq
(
ErrorFun
,
p0
,
args
=
(
xdata_leastsq
,
ydata_leastsq
))
x0
=
abc
[
0
]
/
2
y0
=
abc
[
1
]
/
2
if
(
DEBUG
==
1
):
print
(
x0
,
y0
,
math
.
sqrt
(
abc
[
2
]
+
x0
*
x0
+
y0
*
y0
))
x0
=
abc
[
0
]
/
2
y0
=
abc
[
1
]
/
2
r
=
math
.
sqrt
(
abc
[
2
]
+
x0
*
x0
+
y0
*
y0
)
#place circle through border points
# sometimes the distance between points is bigger than 2*r and this is ok
if
(
r
>=
(
math
.
sqrt
((
xdata
[
0
]
-
xdata
[
len
(
xdata
)
-
1
])
**
2
+
(
ydata
[
0
]
-
ydata
[
len
(
xdata
)
-
1
])
**
2
))
/
2
):
x0
,
y0
=
MoveCircle
(
xdata
[
0
],
ydata
[
0
],
xdata
[
len
(
xdata
)
-
1
],
ydata
[
len
(
xdata
)
-
1
],
x0
,
y0
,
r
)
if
(
DEBUG
==
1
):
print
(
x0
,
y0
,
r
)
s
=
np
.
sqrt
(
np
.
sum
((
np
.
sqrt
((
xdata
-
x0
)
**
2
+
(
ydata
-
y0
)
**
2
)
-
r
)
**
2
))
if
(
DEBUG
==
1
):
print
(
s
)
a0
=
180
/
math
.
pi
*
math
.
atan2
(
xdata
[
0
]
-
x0
,
ydata
[
0
]
-
y0
)
-
90
an
=
180
/
math
.
pi
*
math
.
atan2
(
xdata
[
len
(
xdata
)
-
1
]
-
x0
,
ydata
[
len
(
xdata
)
-
1
]
-
y0
)
-
90
if
(
s
>
P
.
epsilon
):
#print("Split=%d RMS=%f"%(spl,s))
#cut in half
if
(
len
(
points
)
>=
6
):
newpoints
=
np
.
array_split
(
points
,
2
)
#arrays should overlap
newpoints
[
0
]
=
np
.
append
(
newpoints
[
0
],[
newpoints
[
1
][
0
]],
axis
=
0
)
tmp1
=
ArcsFit
(
newpoints
[
0
],
spl
+
1
)
tmp2
=
ArcsFit
(
newpoints
[
1
],
spl
+
1
)
result
.
extend
(
tmp1
)
result
.
extend
(
tmp2
)
else
:
result
.
extend
([[
x0
,
y0
,
r
,
-
a0
,
-
an
]])
else
:
result
.
extend
([[
x0
,
y0
,
r
,
-
a0
,
-
an
]])
return
result
def
cylinder_curve_points
(
x
,
y
,
xc
,
yc
,
a0
,
an
,
n
,
delta
):
global
P
,
L
,
S
adata
=
np
.
linspace
(
a0
,
an
,
n
)
xdata
=
(
xc
)
+
P
.
r
*
np
.
cos
(
adata
*
math
.
pi
/
180
)
ydata
=
(
yc
)
+
P
.
r
*
np
.
sin
(
adata
*
math
.
pi
/
180
)
phidata
=
np
.
arctan2
(
ydata
,
xdata
)
#change pi to -pi for atan2
boundary_case1
=
(
phidata
[
0
]
>
0
)
and
(
phidata
[
len
(
adata
)
-
1
]
<
0
)
boundary_case2
=
(
phidata
[
0
]
<
0
)
and
(
phidata
[
len
(
adata
)
-
1
]
>
0
)
if
(
boundary_case1
):
phidata
[
0
]
=-
phidata
[
0
]
if
(
boundary_case2
):
phidata
[
len
(
adata
)
-
1
]
=-
phidata
[
len
(
adata
)
-
1
]
rdata
=
np
.
sqrt
(
xdata
**
2
+
ydata
**
2
)
*
img_pp_mm
tdata
=
np
.
fromiter
((
L
.
theta_rad
(
d
)
for
d
in
rdata
),
dtype
=
float
)
udata
=
[]
for
i
in
range
(
len
(
adata
)):
if
(
x
<
0
and
y
==
0
):
if
(
phidata
[
i
]
<
0
):
udata
.
append
(
P
.
R_m
*
(
-
(
phidata
[
i
]
+
math
.
pi
)
+
delta
))
else
:
udata
.
append
(
P
.
R_m
*
(
2
*
math
.
pi
-
(
phidata
[
i
]
+
math
.
pi
)
+
delta
))
else
:
udata
.
append
(
P
.
R_m
*
(
2
*
math
.
pi
-
(
phidata
[
i
]
+
math
.
pi
)))
vdata
=
P
.
H_m
+
P
.
R_m
*
np
.
tan
(
tdata
-
math
.
pi
/
2
)
pth
=
[]
for
j
in
range
(
len
(
udata
)):
pth
.
append
([
udata
[
j
],
vdata
[
j
]])
return
pth
def
floor_curve_points
(
xc
,
yc
,
a0
,
an
,
n
):
global
P
,
L
,
S
adata
=
np
.
linspace
(
a0
,
an
,
n
)
xdata
=
(
xc
)
+
P
.
r
*
np
.
cos
(
adata
*
math
.
pi
/
180
)
ydata
=
(
yc
)
+
P
.
r
*
np
.
sin
(
adata
*
math
.
pi
/
180
)
rdata
=
np
.
sqrt
(
xdata
**
2
+
ydata
**
2
)
*
img_pp_mm
cosdata
=
xdata
/
rdata
*
img_pp_mm
sindata
=
ydata
/
rdata
*
img_pp_mm
tdata
=
np
.
fromiter
((
L
.
theta_rad
(
d
)
for
d
in
rdata
),
dtype
=
float
)
R_m
=
P
.
H_m
*
np
.
tan
(
tdata
)
udata
=
R_m
*
cosdata
vdata
=
R_m
*
sindata
pth
=
[]
for
j
in
range
(
len
(
udata
)):
pth
.
append
([
udata
[
j
],
vdata
[
j
]])
return
pth
#MAIN
# Array for pattern check arcs - shifts and angles
D
=
[
[
-
P
.
size
+
P
.
dc
,
-
P
.
qsize
,
0
-
P
.
halfangle
,
0
+
P
.
halfangle
],
[
-
P
.
dc
,
P
.
qsize
,
180
+
P
.
halfangle
,
180
-
P
.
halfangle
],
[
-
P
.
qsize
,
P
.
size
-
P
.
dc
,
270
-
P
.
halfangle
,
270
+
P
.
halfangle
],
[
P
.
qsize
,
P
.
dc
,
90
+
P
.
halfangle
,
90
-
P
.
halfangle
],
[
P
.
size
-
P
.
dc
,
P
.
qsize
,
180
-
P
.
halfangle
,
180
+
P
.
halfangle
],
[
P
.
dc
,
-
P
.
qsize
,
0
+
P
.
halfangle
,
0
-
P
.
halfangle
],
[
P
.
qsize
,
-
P
.
size
+
P
.
dc
,
90
-
P
.
halfangle
,
90
+
P
.
halfangle
],
[
-
P
.
qsize
,
-
P
.
dc
,
270
+
P
.
halfangle
,
270
-
P
.
halfangle
]
]
# find max theta for the sensor
img_rmin_mm
=
S
.
h_mm
img_rmax_mm
=
S
.
d_mm
#print("CHECK 1: Min/Max radii on image plane: r_min = %0.2fmm, r_max = %0.2fmm"%(img_rmin_mm,img_rmax_mm))
img_pattern_period_mm
=
S
.
px_um
*
P
.
period_n
/
1000
img_pp_mm
=
img_pattern_period_mm
print
(
"CHECK 2: Pattern cell size on image plane:
%
fmm"
%
img_pattern_period_mm
)
# next... draw an ideal image plane filled with straight pattern - it's not needed - so, jus tt ocheck
#L.r_mm(L.fov/2*math.pi/180)
img_w_n
=
2
*
L
.
r_mm
(
L
.
fov
/
2
*
math
.
pi
/
180
)
/
img_pattern_period_mm
img_h_n
=
2
*
L
.
r_mm
(
L
.
fov
/
2
*
math
.
pi
/
180
)
/
img_pattern_period_mm
#thinking circles
img_r
=
L
.
r_mm
(
L
.
fov
/
2
*
math
.
pi
/
180
)
print
(
"CHECK 3: Image plane size in periods is:
%
d x
%
d"
%
(
img_w_n
,
img_h_n
))
print
(
"CHECK 4: Floor Pattern Radius is:
%
f m"
%
(
P
.
R_m
))
print
(
"CHECK 5: Cylinder Pattern Radius=
%
f m, Height=
%
f m"
%
(
P
.
R_m
,
P
.
H_m
))
# ip - Image Plane - the image of the pattern on the "image plane"
ip
=
canvas
.
canvas
()
# opf - Object Plane Floor - pattern wallpaper that will go to the floor
# Draw within a circle extended by "floor_overlap" for overlapping.
opf_clippath
=
path
.
circle
(
0
,
0
,(
P
.
R_m
+
P
.
floor_overlap
)
*
P
.
scale
)
opf
=
canvas
.
canvas
([
canvas
.
clip
(
opf_clippath
)])
# opc - Object Plane Cylinder - pattern wallpaper that will go to the cylinder wall
# Draw within a rectangle 2piR x H
opc_clippath
=
path
.
rect
(
0
*
P
.
scale
,
0
*
P
.
scale
,
2
*
math
.
pi
*
P
.
R_m
*
P
.
scale
,
P
.
H_m
*
P
.
scale
)
opc
=
canvas
.
canvas
([
canvas
.
clip
(
opc_clippath
)])
#add more periods to ends to compensate for tilt. do we need tilt at all? set tilt to 0 degrees for now
wn
=
img_w_n
+
img_h_n
*
math
.
sin
(
P
.
angle
*
math
.
pi
/
180
)
hn
=
img_h_n
+
img_w_n
*
math
.
sin
(
P
.
angle
*
math
.
pi
/
180
)
# the (optical) center is 0,0
for
y
in
range
(
int
(
-
hn
/
2
),
int
(
hn
/
2
),
2
):
for
x
in
range
(
int
(
-
wn
/
2
),
int
(
wn
/
2
),
2
):
# draw 2 black spots at once - top-left + bottom-right
for
i
in
range
(
2
):
tmp_x
=
x
+
i
tmp_y
=
y
+
i
# IMAGE PLANE BEGIN
# nothing to debug
# tmp_x & tmp_y - center of the spot, the spot is drawn within center +/- (r+dc) radius
# 8 paths, scaling to mm, draw a single black shape
# a tile of image plane
p
=
path
.
path
()
for
j
in
range
(
4
):
# D[][] is the array that contains shifts and angles for the base arcs
p
+=
path
.
path
(
path
.
arc
((
tmp_x
+
D
[
2
*
j
+
0
][
0
])
*
img_pp_mm
,(
tmp_y
+
D
[
2
*
j
+
0
][
1
])
*
img_pp_mm
,
P
.
r
*
img_pp_mm
,
D
[
2
*
j
+
0
][
2
],
D
[
2
*
j
+
0
][
3
]))
p
+=
path
.
path
(
path
.
arcn
((
tmp_x
+
D
[
2
*
j
+
1
][
0
])
*
img_pp_mm
,(
tmp_y
+
D
[
2
*
j
+
1
][
1
])
*
img_pp_mm
,
P
.
r
*
img_pp_mm
,
D
[
2
*
j
+
1
][
2
],
D
[
2
*
j
+
1
][
3
]))
#### drawing ###
ip
.
stroke
(
p
,[
style
.
linewidth
(
0.000
*
img_pp_mm
),
deco
.
filled
([
color
.
rgb
.
black
]),
trafo
.
rotate
(
-
P
.
angle
)])
# IMAGE PLANE END
# OBJECT PLANE: FLOOR & CYLINDER
# spot center distance from the pattern center @(0,0)
tmp_r
=
math
.
sqrt
(
tmp_x
**
2
+
tmp_y
**
2
)
*
img_pp_mm
# img_r is radius for the cylinder - anything closer is on the floor
# img_r is calculated long ago.
if
(
tmp_r
<
img_r
):
# tmp_r can be a zero
if
(
DEBUG
==
1
):
if
(
tmp_r
==
0
):
print
(
"tmp_r is 0"
)
# if tmp_r==0 - cos(phi) and sin(phi) do not matter - so, some previous ones can be safely taken
if
(
tmp_r
>
0
):
tmp_cos_phi
=
tmp_x
/
tmp_r
*
img_pp_mm
if
(
tmp_r
>
0
):
tmp_sin_phi
=
tmp_y
/
tmp_r
*
img_pp_mm
# max values are not used
# (P.r+P.dc) is pattern specific
tmp_r_min
=
tmp_r
-
(
P
.
r
+
P
.
dc
)
*
img_pp_mm
if
(
tmp_r_min
<
0
):
tmp_r_min
=
0
tmp_r_max
=
tmp_r
+
(
P
.
r
+
P
.
dc
)
*
img_pp_mm
# theta - angle between principal axis and incoming ray
tmp_theta_min
=
L
.
theta_rad
(
tmp_r_min
)
tmp_theta_max
=
L
.
theta_rad
(
tmp_r_max
)
tmp_theta_c
=
L
.
theta_rad
(
tmp_r
)
#tangent can go negative
R_min_m
=
P
.
H_m
*
math
.
tan
(
tmp_theta_min
)
R_max_m
=
P
.
H_m
*
math
.
tan
(
tmp_theta_max
)
# for floor
tmp_u_min
=
R_min_m
*
tmp_cos_phi
tmp_u_max
=
R_max_m
*
tmp_cos_phi
# for floor
tmp_v_min
=
R_min_m
*
tmp_sin_phi
tmp_v_max
=
R_max_m
*
tmp_sin_phi
# not used anymore?
R_c_m
=
P
.
H_m
*
math
.
tan
(
tmp_theta_c
)
tmp_u_c
=
R_c_m
*
tmp_cos_phi
tmp_v_c
=
R_c_m
*
tmp_sin_phi
#### FLOOR PATTERN CHECK ###
# ATTENTION: 3 chunks of code are basically the same - only some of the called functions are different
if
((
R_min_m
>=
0
)
and
(
abs
(
tmp_u_min
)
<=
P
.
R_m
)
and
(
abs
(
tmp_v_min
)
<=
P
.
R_m
)):
# reinitialize
pth_arcs
,
pth_lines
=
[],[]
# using 'arc' and 'arcn' - 8/2 = 4
for
j
in
range
(
4
):
# step 1 - using arc
pth_points_array
=
floor_curve_points
(
tmp_x
+
D
[
2
*
j
+
0
][
0
],
tmp_y
+
D
[
2
*
j
+
0
][
1
],
D
[
2
*
j
+
0
][
2
],
D
[
2
*
j
+
0
][
3
],
P
.
N
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arc
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
# step 2 - using arcn (the only difference)
pth_points_array
=
floor_curve_points
(
tmp_x
+
D
[
2
*
j
+
1
][
0
],
tmp_y
+
D
[
2
*
j
+
1
][
1
],
D
[
2
*
j
+
1
][
2
],
D
[
2
*
j
+
1
][
3
],
P
.
N
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arcn
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
p_sum_arcs
=
pth_arcs
[
0
]
for
k
in
range
(
1
,
len
(
pth_arcs
)):
p_sum_arcs
=
p_sum_arcs
+
pth_arcs
[
k
]
p_sum_arcs
.
append
(
path
.
closepath
())
#### drawing ###
opf
.
stroke
(
p_sum_arcs
,[
style
.
linewidth
(
0
*
P
.
scale
),
deco
.
filled
([
color
.
rgb
.
black
])])
if
(
DEBUG
==
1
):
p_sum_lines
=
path
.
path
(
path
.
moveto
(
pth_lines
[
0
][
0
]
*
P
.
scale
,
pth_lines
[
0
][
1
]
*
P
.
scale
))
for
k
in
range
(
1
,
len
(
pth_lines
)):
p_sum_lines
.
append
(
path
.
lineto
(
pth_lines
[
k
][
0
]
*
P
.
scale
,
pth_lines
[
k
][
1
]
*
P
.
scale
))
p_sum_lines
.
append
(
path
.
closepath
())
####
opf
.
stroke
(
p_sum_lines
,[
style
.
linewidth
(
0.000
*
P
.
scale
),
color
.
rgb
.
red
])
####
#### CYLINDER WALL PATTERN CHECK ###
if
(
tmp_theta_max
>=
math
.
atan
(
P
.
R_m
/
P
.
H_m
)):
#if the center of the spot is on the cylinder.
#take those 8 curves
delta
=
0
# reinitialize
pth_arcs
,
pth_lines
=
[],[]
for
j
in
range
(
4
):
# step 1 - using arc
pth_points_array
=
cylinder_curve_points
(
x
,
y
,
tmp_x
+
D
[
2
*
j
+
0
][
0
],
tmp_y
+
D
[
2
*
j
+
0
][
1
],
D
[
2
*
j
+
0
][
2
],
D
[
2
*
j
+
0
][
3
],
P
.
N
,
delta
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arc
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
# step 2 - using arcn (the only difference)
pth_points_array
=
cylinder_curve_points
(
x
,
y
,
tmp_x
+
D
[
2
*
j
+
1
][
0
],
tmp_y
+
D
[
2
*
j
+
1
][
1
],
D
[
2
*
j
+
1
][
2
],
D
[
2
*
j
+
1
][
3
],
P
.
N
,
delta
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arcn
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
p_sum_arcs
=
pth_arcs
[
0
]
for
k
in
range
(
1
,
len
(
pth_arcs
)):
p_sum_arcs
=
p_sum_arcs
+
pth_arcs
[
k
]
p_sum_arcs
.
append
(
path
.
closepath
())
#### drawing ###
opc
.
stroke
(
p_sum_arcs
,[
style
.
linewidth
(
0
*
P
.
scale
),
deco
.
filled
([
color
.
rgb
.
black
])])
if
(
DEBUG
==
1
):
p_sum
=
path
.
path
(
path
.
moveto
(
pth_lines
[
0
][
0
]
*
P
.
scale
,
pth_lines
[
0
][
1
]
*
P
.
scale
))
for
k
in
range
(
1
,
len
(
pth_lines
)):
p_sum
.
append
(
path
.
lineto
(
pth_lines
[
k
][
0
]
*
P
.
scale
,
pth_lines
[
k
][
1
]
*
P
.
scale
))
####
opc
.
stroke
(
p_sum
,[
style
.
linewidth
(
0.000
*
P
.
scale
),
color
.
rgb
.
red
])
####
#add extra point for 2piR
if
(
x
<
0
and
y
==
0
):
delta
=
2
*
math
.
pi
# reinitialize
pth_arcs
,
pth_lines
=
[],[]
for
j
in
range
(
4
):
# step 1 - using arc
pth_points_array
=
cylinder_curve_points
(
x
,
y
,
tmp_x
+
D
[
2
*
j
+
0
][
0
],
tmp_y
+
D
[
2
*
j
+
0
][
1
],
D
[
2
*
j
+
0
][
2
],
D
[
2
*
j
+
0
][
3
],
P
.
N
,
delta
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arc
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
# step 2 - using arcn (the only difference)
pth_points_array
=
cylinder_curve_points
(
x
,
y
,
tmp_x
+
D
[
2
*
j
+
1
][
0
],
tmp_y
+
D
[
2
*
j
+
1
][
1
],
D
[
2
*
j
+
1
][
2
],
D
[
2
*
j
+
1
][
3
],
P
.
N
,
delta
)
pth_lines
.
extend
(
pth_points_array
)
pth_arcs_array
=
ArcsFit
(
pth_points_array
,
0
)
for
pth_arc_single
in
pth_arcs_array
:
pth_arc
=
path
.
path
(
path
.
arcn
(
pth_arc_single
[
0
]
*
P
.
scale
,
pth_arc_single
[
1
]
*
P
.
scale
,
pth_arc_single
[
2
]
*
P
.
scale
,
pth_arc_single
[
3
],
pth_arc_single
[
4
]))
pth_arcs
.
append
(
pth_arc
)
p_sum_arcs
=
pth_arcs
[
0
]
for
k
in
range
(
1
,
len
(
pth_arcs
)):
p_sum_arcs
=
p_sum_arcs
+
pth_arcs
[
k
]
p_sum_arcs
.
append
(
path
.
closepath
())
#### drawing ###
opc
.
stroke
(
p_sum_arcs
,[
style
.
linewidth
(
0
*
P
.
scale
),
deco
.
filled
([
color
.
rgb
.
black
])])
if
(
DEBUG
==
1
):
p_sum
=
path
.
path
(
path
.
moveto
(
pth_lines
[
0
][
0
]
*
P
.
scale
,
pth_lines
[
0
][
1
]
*
P
.
scale
))
for
k
in
range
(
1
,
len
(
pth_lines
)):
p_sum
.
append
(
path
.
lineto
(
pth_lines
[
k
][
0
]
*
P
.
scale
,
pth_lines
[
k
][
1
]
*
P
.
scale
))
####
opc
.
stroke
(
p_sum
,[
style
.
linewidth
(
0.000
*
P
.
scale
),
color
.
rgb
.
red
])
####
# option #1 for creating pdf
#ip.writePDFfile("image_plane.pdf")
# option #2
d_ip
=
document
.
document
()
# centimeter scale for image/sensor plane
d_ip
.
append
(
document
.
page
(
ip
,
paperformat
=
document
.
paperformat
(
S
.
w_mm
*
unit
.
t_cm
,
S
.
h_mm
*
unit
.
t_cm
)))
d_ip
.
writePDFfile
(
"image_plane.pdf"
,
title
=
"
\"
Escher
\"
Pattern, Image Plane"
,
subject
=
"Lens calibration pattern"
,
keywords
=
"camera, lens, pattern, checker board, Escher"
,
author
=
"Fabian Gottlieb von Bellingshausen"
)
d_opf
=
document
.
document
()
d_opf
.
append
(
document
.
page
(
opf
,
paperformat
=
document
.
paperformat
(
2
*
(
P
.
R_m
+
P
.
floor_overlap
)
*
P
.
scale
,
2
*
(
P
.
R_m
+
P
.
floor_overlap
)
*
P
.
scale
)))
d_opf
.
writePDFfile
(
"object_plane_floor.pdf"
,
title
=
"
\"
Escher
\"
Pattern, Object Plane (Floor)"
,
subject
=
"Lens calibration pattern"
,
keywords
=
"camera, lens, pattern, checker board, Escher"
,
author
=
"Fabian Gottlieb von Bellingshausen"
)
d_opc
=
document
.
document
()
d_opc
.
append
(
document
.
page
(
opc
,
paperformat
=
document
.
paperformat
(
2
*
math
.
pi
*
P
.
R_m
*
P
.
scale
,
P
.
H_m
*
P
.
scale
)))
d_opc
.
writePDFfile
(
"object_plane_cylinder.pdf"
,
title
=
"
\"
Escher
\"
Pattern, Object Plane (Cylinder)"
,
subject
=
"Lens calibration pattern"
,
keywords
=
"camera, lens, pattern, checker board, Escher"
,
author
=
"Fabian Gottlieb von Bellingshausen"
)
# used to draw just a circle - not anymore
# ip.stroke(path.circle(tmp_x*img_pp_mm,tmp_y*img_pp_mm,0.5*img_pp_mm),[style.linewidth.Thin,deco.filled([color.rgb.black])])
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