| 19 |
19 |
jgamma= (Obsolete, ignored.) |
| 20 |
20 |
jq*uality= [95] JPEG quality factor (1 to 100) |
| 21 |
21 |
ext*name= Specify a single extension to extract, by its EXTNAME |
| 22 |
22 |
x0= Corner pixel x-coord of a cropping box. |
| 23 |
23 |
y0= Corner pixel y-coord of a cropping box. |
| 24 |
24 |
xs= Size in x of a region to crop. |
| 25 |
25 |
ys= Size in y of a region to crop. |
| 26 |
26 |
prescan= Override any row-prescan value in the FITS files |
| 27 |
27 |
bias*norm= [true] Normalize all overscan bias levels at 250 ADU |
| 28 |
28 |
fancy*bias= [false] Custom bias filter (not valid for science!) |
| 29 |
29 |
ped*sub= [true] Subtract pedestal if present (true/false) |
| 30 |
30 |
gaussian= [0.0] If >0, apply a blur of that FWHM (before scaling) |
| 31 |
31 |
cut*levels= [auto,auto] Force low and high ADU cut levels |
| 32 |
32 |
ramp*jpeg= [off] Just output a color-bar intensity ramp |
| 33 |
33 |
flip= [false] Flip image top-to-bottom |
| 34 |
34 |
comp*osite= [false] Convert from a MEF to a basic, composite FITS |
| 35 |
35 |
median= [false] Display median values of all cells |
| 36 |
36 |
stats= [false] Generate pedestal, bias, sky level and noise stats |
| 37 |
37 |
ponstats*file= Text input file with XRAY (gain) and LED (linearity) stats |
| 41 |
43 |
cplotccd= Name of the ccd, such as "ota34" |
| 42 |
44 |
cplotvar= [rmsov] Variable to color-plot |
| 43 |
45 |
(Do not type the *. Letters after the * are optional.) |
| 44 |
46 |
}}} |
| 45 |
47 |
== Dark Subtraction == |
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48 |
Some day, '''otatool''' is supposed to be able to do a scaled DARK subtraction from the image before generating JPEGs so they look nicer, but this is '''untested and probably not working correctly.''' |
| 47 |
49 |
||'''option'''||'''description''' |
| 48 |
50 |
||dark=darkmef.fits|| |
| 49 |
51 |
== True Color JPEG Generation == |
| 50 |
52 |
The '''otatool''' utility can generate a realistic JPEG image of a scene if provided with FITS files with neutral filter, red, and blue (without anything in the scene changing.) This functionality has '''not been used or tested recently and probably does not work correctly.''' This just documents the options that belong with this mode of operation. |
| 51 |
53 |
||'''option'''||'''description''' |
| 52 |
54 |
||open=mef0.fits|| |
| 53 |
55 |
||blue=mef1.fits|| |
| 54 |
56 |
||red=mef2.fits|| |
| 55 |
57 |
== False Color JPEG Generation == |
| 56 |
58 |
More commonly, we use '''otatool''' to generate a false color image of a single FITS frame. That mode of operation produces JPEG files with fixed names, so we run it in a separate subdirectory and then rename those output files. (In the future, we may add another command line option to control the output names.) Typical invocation for this mode of operation is: |
| 57 |
59 |
{{{ |
| 58 |
60 |
% otatool jpeg=true < mef.fits |
| 59 |
61 |
% ls |
| 60 |
62 |
< ... produces *.jpeg where "*" is the EXTNAME found in the FITS file. > |
| 61 |
63 |
}}} |
| 62 |
64 |
||'''option'''||'''description''' |
| 63 |
65 |
||jpeg=true ||Cause full 1:1 JPEGS to be generated for each image extension |
| 64 |
66 |
||jmosaic=true|| |
| 65 |
67 |
||jthumb=true || |
| 66 |
68 |
||jcmap= ||Choose between colormaps called '''gamma''' (the default) '''rainbow''', and '''terra'''. The '''gamma''' colormap is special because it modulates the brightness (using the '''rainbow''' colormap as a start) so that the steepest changes in brightness occur at the median of the image (see cutlevels=, below.) |
| 67 |
69 |
== Statistics Generation == |
| 68 |
70 |
You can use '''otatool''' to calculate the RMS of the overscan, or a part of the image in each extension and report the results to a "stats" text file. This can happen at the same time as JPEG generation, or instead. (Just specify all the relevant options and otatool will carry out the operations requested.) Options related to statistics calculation are: |
| 69 |
71 |
||'''option'''||'''description''' |
| 70 |
72 |
||stats=true ||Generate statistics |
| 71 |
73 |
||statsfile=foo.txt||Where to write the calculated numbers |
| 72 |
74 |
||prescan= ||Normally, our practice is to remove prescan with the controller (using clv prescan=3 or 4 for OTAs, or prescan=50 for e2v for example.) If the image still contains prescan pixels, you must tell otatool how many there are with this option so it can skip them. |
| 73 |
75 |
Here is a description of the statistics values calculated in the stats files: |
| 74 |
76 |
||'''stats var'''||'''description''' |
| 75 |
77 |
||ped= ||If a readout was performed with "bpp=32" and the FITS file was '''save'''d with "bpp=32" then otatool can report on the mean pedestal level in the pedestal image. Usually, the pedestal image is subtracted from the data before saving but this can be a good diagnostic. Pedestal levels should be within a few 100 ADU of 5000 (or whatever value you use for "readcal".) |
| 76 |
78 |
||bias= ||Measures the bias level, in ADU. '''This assumes otatool is looking in the right place for overscan. See "prescan=" above, and notes below.''' |
| 77 |
79 |
||back= ||Measures the mean level (above bias) in a portion of the image area. The portion used is currently hardcoded into otatool.c |
| 78 |
80 |
||rmsped= ||If you have a 32bpp STARGRASP FITS file (see ped= above) then this statistic reports the RMS in ADU of the pedestal. Expect this to be quite high in many applications. This is the uncorrelated sampling noise. |
| 79 |
81 |
||rmsvid= ||If you have a 32bpp STARGRASP FITS file (see ped= above) then this statistic reports the RMS in ADU of the uncorrelated video sample. Like rmsped=, it could also be quite high (100s of ADU sometimes) but should be similar to the rmsped value. |
| 80 |
82 |
||rmsov= ||This is the RMS of the subtraction of (vid-ped) which is the 16-bit value normally delivered as the image, for pixels in the serial overscan region. '''See notes below.''' |
| 81 |
83 |
Additional RMS values for image regions (intended to be used on BIAS readouts only) are available if otatool has been compiled with "-DDO_STREAKY" in the Makefile. These stats are: |
| 82 |
84 |
||'''stats var'''||'''description''' |
| 83 |
85 |
||rmsmask= ||The RMS in ADU of part of the image (region used is hardcoded in otatool.c) after masking out any bright chip defects. |
| 84 |
86 |
||rmsrow= ||The RMS in ADU of the same region, after applying a "row-by-row" bias correction to each pixel row individually. |
| 85 |
87 |
||rmsplane= ||The RMS in ADU after the above treatment by rmsrow, but after fitting a plane to the image to take out any overall horizontal slope. |
| 86 |
88 |
||rmstilt= ||The RMS in ADU after fitting a sloped bias correction to each individual row of pixels. |
| 87 |
89 |
'''NOTE:''' The region which '''otatool''' uses for "overscan" statistics and the window where the rmsmask/row/plane/tilt are taken are fragile, and hardcoded into the program! Most commonly, they can be confused by incorrect "prescan" setting. '''otatool''' is usually only used on data that contains no serial prescan pixels! The STARGRASP controller will read them and not transmit them if the '''clvset''' clocking pattern is set up with '''prescan=N'''. |
| |
90 |
|
| |
91 |
== Diagnostic Color Plot ("cplot") JPEG Generation == |
| |
92 |
|
| |
93 |
Fruity colored plots of OTAs and specific OTA-camera focal planes can also be generated by otatool. Instead of requiring a FITS for input, any file in the format of otatool's own "stats" file can be used. The following options are related to this function: |
| |
94 |
|
| |
95 |
||'''option'''||'''description'''|| |
| |
96 |
||cplotfile= ||This is the INPUT text file that otatool will read. It is expected to have a minimum of "ccd=otaXY ext=xyXY ..." on each line.|| |
| |
97 |
||cplotcam= ||Currently, only a value of "gpc1" is supported here. This generates plots in PS1-standard "camera coordinates" for a focalplane of 60 OTAs|| |
| |
98 |
||cplotccd= ||Omit this for entire focalplane plots. Set it to something like "cplotccd=ota43" to plot just one OTA|| |
| |
99 |
||cplotvar= ||Set this to the variable in the cplotfile you want to plot. If you were to plot bias levels, for example, use "cplotvar=bias" and make sure you feed otatool a cplotfile with (at least) ccd=... ext=... bias=... on every line.|| |
| |
100 |
||cut=X,X,Y ||The this to the lowest value, median value, and highest value of cplotvar you wish to be able to plot. Normally, set median value to the same as lowest value for these types of plots unless you really think it is useful for otatool to modulate the brightness of the colors in a way to create more contrast around the median. (Usually, that is only useful for rendering the image data itself, but you have to specify the median so set it to the same as the low cut level.)|| |
| |
101 |
||jcmap= ||See above. All the same colormaps are available as for image rendering. Try "jcmap=rainbow"|| |
| |
102 |
|
| |
103 |
Currently, there is no way to override the output file produced in this mode. It is always '''"cplot.jpeg"''' in the current directory. |
| |
104 |
|
| |
105 |
=== Example of "cplot" === |
| |
106 |
|
| |
107 |
Suppose there is a typical GPC1 stats file in /tmp/stats and we want to plot bias levels across the whole focalplane to see if there are any interesting trends. We notice that bias levels fall between 5000 and 10000 ADU, so we'll fix the color stretch to this. The command to produce a JPEG takes only about 1 second to execute, and looks like this: |
| |
108 |
|
| |
109 |
{{{ |
| |
110 |
otatool cplotfile=/tmp/stats cplotcam=gpc1 cplotvar=bias cut=5000,5000,10000 jcmap=rainbow |
| |
111 |
mv cplot.jpeg biasstats.jpeg |
| |
112 |
}}} |
| |
113 |
|
| |
114 |
The output is a binned-by-64 view of the GPC1 focalplane with every cell colored a particular color based on its bias level. As long as we use an appropriate scaling algorithm, such as !ImageMagick's Box filter, it can be reduced in size quite a bit and still convey the same information. This is accomplished with this command: |
| |
115 |
|
| |
116 |
{{{ |
| |
117 |
mogrify -filter Box -geometry 208x208 -quality 95 biasstats.jpeg |
| |
118 |
}}} |
| |
119 |
|
| |
120 |
208x208 is a magic size that causes the Box filter to place nicely with the cell spacing the otatool produces for gpc1. If you prefer a larger, sharp image, you can skip the scaling step, but it only takes a few milliseconds to execute. The resulting image looks like this: |
| |
121 |
|
| |
122 |
[[Image(biasstats.jpeg)]] |
| |
123 |
|
| |
124 |
To the uninitiated, all the pretty colors may not mean very much, so it might be handy to produce a legend or color scale to go with the image. You can use otatool for this as well: |
| |
125 |
|
| |
126 |
{{{ |
| |
127 |
otatool rampjpeg=biasramp.jpeg cut=5000,5000,10000 jcmap=rainbow |
| |
128 |
}}} |
| |
129 |
|
| |
130 |
and this produces the following image: |
| |
131 |
|
| |
132 |
[[Image(biasramp.jpeg)]] |
| |
133 |
|
| |
134 |
Finally, you can use !ImageMagick some more to apply text labels and tile the whole thing together. Here are example commands that can be modified to do just about anything that !ImageMagick supports. |
| |
135 |
|
| |
136 |
{{{ |
| |
137 |
mogrify -quality 95 -geometry '!208x16' biasramp.jpeg |
| |
138 |
montage -quality 95 -geometry 208x208+1+1 +frame +shadow +label -tile 3x3 -background '#226633' -gravity North NULL: NULL: NULL: NULL: biasstats.jpeg NULL: NULL: biasramp.jpeg NULL: biasplot.jpeg |
| |
139 |
mogrify -quality 95 -shave 208x190 biasplot.jpeg |
| |
140 |
mogrify -quality 95 -fill '#bbbbbb' -pointsize 17 -draw "text 6,18 \"Title: BIAS Levels\"" -fill '#ffffff' -pointsize 14 -draw "text 6,244 \"5000\"" -fill '#000000' -draw "text 168,244 \"10000\"" biasplot.jpeg |
| |
141 |
}}} |
| |
142 |
|
| |
143 |
This produces the resulting labelled map of the entire focal plane: |
| |
144 |
|
| |
145 |
[[Image(biasplot.jpeg)]] |
| |
146 |
|
