target/printtarg
Summary
Create a PostScript (PS), Embedded PostScript (EPS) or Tagged Image File
Format (TIFF) file containing profile test patch values, ready for printing.
Usage Summary
printtarg [options] basename
-v
Verbose mode
-i 20 | 22 | 41 | 51 | SS | i1 | p3 | CM Select
target instrument (default i1)
i1 = i1Pro, 3p = i1Pro3+, CM = ColorMunki
20
=
DTP20,
22
=
DTP22, 41 = DTP41, 51 = DTP51, SS = SpectroScan,
-a scale
Scale
patch
and
spacer
size
by factor (e.g. 0.857 or 1.5 etc.)
-A scale
Scale
spacer
size
by
additional
factor (e.g. 0.857 or 1.5 etc.)
-h
Use hexagon patches for SS, double density for CM
-r
Don't randomize patch location
-s
Create
a
scan
image
recognition
(.cht) file
-S
Same
as
-s,
but
don't
generate wide orientation strip.
-c
Force colored spacers
-b
Force B&W spacers
-n
Force no spacers
-f
Create
PostScript DeviceN Color fallback
-w g|r|s|n
White colorspace encoding DeviceGray (def), DeviceRGB, Separation or
DeviceN
-k g|c|s|n
Black colorspace encoding DeviceGray (def), DeviceCMYK, Separation or
DeviceN
-o k|n
CMY
colorspace encoding DefiveCMYK (def), inverted DeviceRGB or DeviceN
-e
Output EPS compatible file
-t [res]
Output
8
bit
TIFF
raster
file, optional res DPI (default 200)
-T [res]
Output
16
bit
TIFF
raster
file, optional res DPI (default 200)
-C
Don't
use TIFF compression
-N
Use
TIFF
alpha
N
channels
more than 4
-D
Dither 8 bit TIFF values down from 16 bit
-Q nbits
Quantize
test
values
to
fit
in nbits
-K file.cal Apply
printer calibration to patch values and include in .ti2
-I file.cal Include
calibration in .ti2 (but don't apply it)
-R rsnum
Use given random start number
-x pattern Use
given strip indexing pattern (Default = "A-Z, A-Z")
-y pattern Use
given patch indexing pattern (Default = "0-9,@-9,@-9;1-999")
-m margin
Set a page margin in mm (default 6.0 mm)
-M margin
Set a page margin in mm and include it in TIFF
-P
Don't limit strip length
-L
Suppress
any
left
paper
clip
border
-U
Suppress CUPS cupsJobTicket: cups-disable-cmm in PS & EPS files
-p size
Select page size from:
A4
[210.0 x 297.0 mm]
A4R
[297.0 x 210.0 mm]
A3
[297.0 x 420.0 mm] (default)
A2 [420.0 x 594.0 mm]
Letter
[215.9 x 279.4 mm]
LetterR [279.4 x 215.9 mm]
Legal [215.9 x 355.6 mm]
4x6 [101.6 x 152.4 mm]
11x17
[279.4 x 431.8 mm]
-p WWWxHHH
Custom size, WWW mm wide by HHH mm high
basename
Base name for input(.ti1),
output(.ti2) and
output(.ps/.eps/.tif)
Usage Details and Discussion
printtarg is used to generate a PostScript or TIFF print file from
device test values in a .ti1 file. It output both a PostScript/EPS/TIFF
file, and a .ti2 file containing the device test values together with the
layout information needed to identify the patch location. This module can
also generate the image recognition templates needed to read the print
targets in using a scanner.
The -v flag turns on verbose mode. Prints
information about how many patches there are in a row, how many patches in a
set, and how many pages will be generated. Good for figuring out what
the magic number of patches should be for a particular page size.
The -i parameter should be used to tell printtarg
which instrument it should lay the patches out for. Each instrument has a
slightly different requirement, and will lead to a different number of
patches ending up on a particular page size. For a generic type of chart,
try SS.
-a, -A: Normally,
printtarg prints test patches that are the minimum size that can be
reliably and accurately read by the instrument. For some media, it
might be desirable to use test patches that are larger than this minimum
(e.g. if the media has poor registration, gets physically distorted in the
print production process, or if it has a coarse screen, and there are few
samples per patch), and the -a flag
should be given an argument greater than 1.0 to increase the patch length,
patch width, and spacer size between patches, if it is appropriate for the
type of instrument. A value of 1.5 would make the patch 50% larger for
instance. For the strip reading instruments the patch is made longer, the
strip spacing remaining the same, while for XY scanning instruments, both
the width and height will be increased. If a value less than 1.0 is given as
an argument, then the patches will be made smaller. For instance, using the
SpectroScan instrument it is possible to reduce the test patches to 6mm
rather than the default 7mm by supplying an argument of 0.857. Note that
this make lining up of the scan head very critical, and increases the amount
of bleed through from adjacent squares. For an instrument that needs color
spacers between patches, -a scale
also scales the spacer length. For some situations, this may be
insufficient, and the -A scale
option can be used to additionally scale the spacer length.
Note that the for the DTP20 only -a values of 1.0, 1.08, 1.54, 1.92, 2.0
and that the patch width will be made no smaller than its length.
Normally, printtarg creates a regular grid of test
patches, but for instruments that support arbitrary X, Y addressing (such as
the SpectroScan). For the SpectroScan
it can also create a chart using regular hexagonal patches, allowing more
patches to be fitted into a single sheet if the -h
flag is used. For the ColorMunki
instrument, -h doubles the normal
number of patches is printed by halving the row width. The patches are also
staggered to improve the detection of a poor scan.
Normally, printtarg randomizes the patch locations,
which helps strip reading instruments detect patch boundaries and the
direction the strip was read in, as well as being able to detect incorrect
strips being fed into strip reading instruments, and also assists in
randomizing any systematic printing errors introduced into the test chart
due to print engine unevenness, inkjet banding, or printing press ink key
settings etc. The -r flag turns this off, and lays the test squares
out in the order the values appear in, in the .ti1 file. Note that if you
turn this off you probably want to disable
bi-directional strip reading in instruments such as the i1pro.
The -s flag does two things. One is that it causes
printtarg to output a chart recognition file (.cht)
so that scanin can recognize the chart, and
convert rasterized patches into patch values, and the second is that is
expands the size of the leading row of patches by 50%, to help make sure
that each sheet can be oriented correctly by scanin.
If -S is used rather than -s, then the
recognition chart will be created, but the leading row will be the same size
as all the other rows.
For strip reading instruments, the contrast with the
spacers is important in ensuring that a reading will be successful. Normally
printtarg ensures this by printing
optimally contrasting colored spacers between each measurement patch. The -c
flag is therefore the default behaviour. If the -b
flag is used, then contrasting neutral colored spacers will be used, but
these generally work less reliably than colored spacers. The
-n flag will cause spacers to be omitted, which may still work with
smaller numbers of test values when the patch selection is randomized, but
won't work successfully when a large number of test points is being used
(>200), or when the patches are not randomized in location.
-f: When creating a test chart for more than CMYK
inks, a PostScript file normally contains color settings that use the
PostScript level 3 "Device N" color specifications. Such color
specifications have a "fallback" color, for PostScript interpreters that
don't handle Device N specifications. Such fallback colors are normally set
to a grayscale estimate of the patch color, so that it is possible to tell
if the PostScript interpreter is not rendering the Device N values
correctly. The -f flag, causes the fallback color
to be a color estimate of the Device N test patch color, which is useful for
diagnostic purposes.
The -e flag gives EPS output, rather than
PostScript, allowing the charts to be included in other applications.
Because EPS disallows the showpage command, multiple EPS files will result
for a multi-page test chart, each one having a two digit number sequence in
it's name, so if the input file name is chart,
then file chart.ti1 will be read,
and file chart.ti2 written,
together with chart.eps if there is
only one page, or chart_01.eps, chart_02.eps, etc. if there is more than
one page.
-t [res],
-T [res] The -t flag gives TIFF raster output rather than
PostScript, allowing the charts to be printed to systems that do not accept
PostScript input. Because few systems understand multi-page TIFF files,
multiple TIFF files will result for a multi-page test chart, each one having
a two digit number sequence in it's name, so if the input file name is chart, then file chart.ti1
will be read, and file chart.ti2
written, together with chart.tif if
there is only one page, or chart_01.tif,
chart_02.tif, etc. if there is more
than one page. By default the resolution of the chart will be 100 Dots Per
Inch (DPI), but this can be changed by providing an optional DPI argument
after the -t or -T
flag. If the -t flag is used, then
an 8 bit per component TIFF file will be created. If the -T
flag is used, then a 16 bit per component TIFF file will be created. Note
that if 8 bit TIFF output is
selected (-t) without dithering (no
-D) then the values will by default
be quantized to 8 bits, and that if 16 bit TIFF
output is selected (-T) or 8 bit
TIFF with dithering (-D), then the
values will by default be quantized to 16 bits (see -Q
flag). The raster file will be the page size specified minus the -m
margin.
-C: Normally the
TIFF files created will be compressed using LZW compression to save space.
Some systems may not support this compression, so it can be disabled by
using the -C flag.
-N: When creating
TIFF files with more than 4 colorants, the normal Separated mode is used.
Some systems don't cope well with extra colorants presented in this manner,
and the -N flag causes all the
channels greater than 4 to be labelled as "Alpha" channels, which may be
more palatable.
-D: When creating
TIFF files with 8 bit output, dither the values to give effective 16 bit
precision. Note this is applied after any quantization of the test values
(see -Q). Note that this might interfere (i.e. give
alias/moire patterns) in printed output if the printer uses screening that
happens to clash. Note also that dithering is effectively linearly
interpolating between the 8 bit values using spatial averaging, and that
therefore the device response may also be a linear interpolation between its
8 bit output values, adding no effective extra precision to the device
measurement.
-Q: Normally the
target device values are floating point numbers that may get rounded and
quantized in the process of printing them or reproducing them on the
printing or display device. If some of this quantization can be accounted
for, it may improve the accuracy of the resulting profile, and the Q
parameter allows this quantization to be specified. The parameter is the
number of binary digits (bits) that the device values should be quantized
to. In many systems the right value would be 8 bits. Note that if 8 bit TIFF output is selected (-t)
without dithering (no -D) then the
values will by default be quantized to 8 bits, and that if 16 bit TIFF output is selected (-T)
or 8 bit TIFF with dithering (-D),
then the values will by default be quantized to 16 bits.
The -K file.cal parameter specifies a printer
calibration file created by printcal, and the
supplied calibration curves will be applied to the test patch values. This
allows profiling of a printing system that doesn't natively support
calibration. The calibration curves will also be included in the resulting
.ti2 file, so that they can be passed through to .ti3 file and ICC profile,
to allow accurate computation of ink limits.
The -I file.cal parameter specifies a printer
calibration file created by printcal, and the
calibration curves will be included in the included in the resulting .ti2
file, so that they can be passed through to .ti3 file and ICC profile, to
allow accurate computation of ink limits. The calibration is
not applied to the test patch values, but is assumed to be applied
somewhere else in the printing workflow when printing the profile test
chart.
The -R parameter allows setting the random layout
seed. Normally the seed is chosen at random, but sometimes it is useful to
be able to generate a chart with the same layout, so a specific seed can be
specified this way. The seed (ID) used to generate a chart is recorded in
the .ti2 file, and is also in the label printed on the right hand side of
each chart.
The -x parameter allows specifying the labeling
sequence used for strips (e.g. the X axis of the chart). By default this
will be a character sequence A, B, C .. Z. AA, AB, AC .. ZZ, but this can be
changed by specifying an alternate labeling sequence pattern. The pattern
specifies the labeling sequence as follows: First comes the definition of
the symbols for each digit location, least significant to most significant,
each digit separated by the ',' character. Note that space is a valid
character. The number of definitions declares the maximum number of digits.
For example, for a 2 digit numerical sequence: "0123456789, 123456789" would
define 0..99 with the most significant digit suppressed when it is 0
(because it uses a space rather than 0). Ranges can be used for brevity:
"0-9, 1-9". As a special case, the '@' character can be used to instead of
'0' to indicate suppression of the leading zero: "0-9,@-9". Leading ' '
characters in the resulting generated sequence are omitted. Optionally
following this and delimited by a ';' character, are the definitions of
valid segments of the index sequence. For instance, to define the index
range to be 1..19, 30..39 one could use the pattern "0-9, 1-9;1-19,30-39".
Of course most of the time an alphabetic sequence will be wanted, to
distinguish it from the numerical sequence used to number the patches in a
strip. For a sequence A, B, C .. AA, AB, AC etc. (the default used in
Argyll), the following patter would be used: "A-Z, A-Z". For a some ECI2002R
charts that skip columns Y and Z, and use a leading numeric digits for
addressing strips over 26, the following might be used: "A-Z,
2-9;A-X,2A-9Z".
The -y parameter allows specifying the labeling
sequence used for patches (e.g. the Y axis of the chart). By default this
will be a number sequence 1, 2, ..10, 11, ... 999, but this can be changed
by specifying an alternate labeling sequence pattern. See the above
description for the labeling sequence encoding.
NOTE that the pattern chosen for the
X and Y axes of the chart must be distinguishable, e.g. if they are both
numbers or both letters then reading the chart will fail.
The -w parameter changes how a white colorspace
test chart (ie. Additive Grey monochrome) will be represented in the
Postscript or TIFF output. The default is to use the DeviceGray
representation (-wg), but Device RGB
can also be used, where the R, G &B values are all set to the same value
(-wr), a White
separation color can be specified (-ws),
or a DeviceN White color can be
used (-wn).
The -k parameter changes how a black colorspace
test chart (ie. Subtractive Grey monochrome ) will be represented in the
Postscript or TIFF output. The default is to use the DeviceGray
representation (-kg), but Device
CMYK can also be used, where the CMY values are zero, and just the K channel
is used (-kc), a Black
separation color can be specified (-ks),
or a DeviceN Black color can be
used (-kn).
The -o parameter changes how a CMY colorspace test
chart will be represented in the Postscript or TIFF output. The default is
to use the DeviceCMYK representation (-ok)
where the K value is always zero, or inverted Device RGB (-or),
or as a 3 channel DeviceN colorsoace can be used (-on).
The -m parameter sets the page margin for all
sides. If the printer has print margins larger than the default assumed by printtarg, then critical parts of the
test chart may be cropped or scaled, and not printed properly.
Increasing the margin from the default of 6 mm to 10 or 15 mm, may alleviate
this problem. (Note that the number of patches per page may be reduced as a
consequence.) Decreasing the margin below 6 mm may be possible for printers
that have smaller or no margins, increasing the number of patches possible
on each page. A TIFF chart raster will be the size of the paper minus the
margin, so that it can be placed on a page that size without cropping or
inadvertent scaling.
The -M parameter sets the page margin for all sides
the same as -m,
but for a TIFF chart the margin will be included
in the raster, meaning that the TIFF will have to be printed right to the
edge of the paper, or on paper larger than the raster size. (Having the
raster be the full page size may be useful in certain situations.)
The -P flag disables any normal limiting of strip
length that would normally be imposed due to guide or instrument
limitations. There is still an upper limit of around 500 patches or 2 Meters
though. Note that if you generate a strip larger than the instrument can
cope with, it may be unable to read the strip.
The -L flag suppresses the left margin that is
added for instruments that have a paper holder that has a clip to hold the
chart in place, while it is being read. (Currently this is only the Eye-One
Pro).
The -U flag suppresses the CUPS %cupsJobTicket:
cups-disable-cmm in PS and EPS files. By default this ensures that the
resulting files doesn't have color management applied to it. If you are
creating a test chart that should be color managed (perhaps because you want
to use it to verify the overall operation of the printing system), then you
can use the -U flag to disable this.
The -p parameter specifies the paper size. The size
can either be one of the default sizes, or can be
specified in millimeters. Limitations of the instrument may limit the
maximum number of patches in a strip. For SpectroScan, a size of A4 or
Letter (or smaller) should be used. Useful combinations of number of patches
and paper size are listed here. The printed
parts of the chart will be the size of paper minus the page margin. A TIFF
chart will be the size of the paper minus the margin, so that it can be
placed on a page that size without cropping or inadvertent scaling, but also
see the -M flag.
basename is the base file name of the .ti1
file that contains the device values to be put on the test chart. printtarg
will output a basename.ps or one or more basename_NN.eps or
basename_NN.tif files files that should be printed on the devices,
as well as a basename.ti2 file that contains both the device test
point values, and the location of the corresponding patch on the test chart.
If the -s or -S flag was specified, then one or more basename_NN.cht
files will also be generated.
GSview or GhostView
are good programs to use to check what the PostScript or EPS file will look
like, without actually printing it out. Alternatively, use the TIFF raster
output for non-PostScript printers.