Behavior of web safe colors with different print production profiles.
Zitinski Elias, Paula ; Poljicak, Ante ; Strgar Kurecic, Maja 等
Abstract: In the area of colour reproduction there is the
imperative of shifting between the monitor display colour model and the
one used in reproduction. Additionally, different printing substrates
have different printing capabilities, so their profiles change
accordingly. The goal is to be able to obtain the same image
independently of the media it is displayed in. For this purpose colour
profiles are used. In this paper we observe web safe colours under three
separate colour profiles in order to understand the limitations of each
of them. Results show that colours shift significantly between profiles.
Key words: web safe colours, colour profiles, CIE L *a*b*, [DELTA]E
value
1. INTRODUCTION
Web safe colours, also known as browser safe palette, are a set of
216 colours that are displayed exactly the same on all computer
monitors. Nevertheless, when wanting to achieve the same colour
reproduction on a printing substrate, a digital conversion must be made.
This digital conversion is referred to as colour management, and its
primary goal is to obtain a good match across colour devices by shifting
between colour profiles.
In this paper the sRGB colour space was observed and compared to
CMYK coated and uncoated paper colour space. The 216 web safe colours
were observed in their standardized values and under the three different
profiles mentioned.
Measurements in printing and colour space used in graphic
technologies in the context of colour definition, as well as the
tolerance between two colours, are defined by CIE L*a*b* colour space
(Zjakir, 2007). The value L* represents lightness, a* is the red-green
axis, and b* blue-yellow axis.
With the results of the CIE L*a*b* values, the [DELTA]E formula was
used to calculate the objective differences of the 216 safe colours
between the sRGB and the coated paper profile and the sRGB and the
uncoated paper profile. The [DELTA]E results show that colour management
produces differences when shifting between profiles. In addition, one
can observe that the changes in colours when printing onto an uncoated
printing substrate are greater than when printing onto a coated printing
substrate.
Future work goes in direction of additional input profile research,
pursuing the goal of finding an optimal profile which will recreate the
input colours as accurately as possible.
2. COLOUR MANAGEMENT
As the need of a close description of colours arises, abstract
colour models are used. A colour model can be explained as an abstract
mathematical model describing the way colours can be represented as
tuples of numbers, typically as three or four values or colour
components. When this model is associated with a precise description of
how the components are to be interpreted, the resulting set of colours
is called colour space (Ganesan et al., 2011). The most common colour
models are RGB, CMYK, YIQ and HSI.
In the RGB colour model the primary colours are red, green and
blue. This model is found in digital devices such as computer monitor
displays, cameras and television, where colour mixture is achieved
through photons of light, and colour synthesis is an additive, as white
colour is achieved through adding the three primary components.
The CMYK colour model is made out of cyan, magenta, yellow and
black and is suited for printing reproduction. It is a subtractive model, i.e. by primary component subtraction, white colour is obtained.
On the other hand, when mixing them, a dark shade is achieved, since
adding different pigments causes various colours not to be reflected and
thus not to be seen.
The YIQ model was designed to separate chrominance from luminance,
a requirement in the early days of colour television. The Y channel
represents the luminance information, while I and Q carry colour
information.
In the HSI colour model H stands for hue, S for saturation and I
for intensity (luminance). Hue and saturation of colours respond closely
to the way humans perceive it, thus this model is well suited for an
interactive manipulation of colour images where changes occur for each
variable shift that corresponds to what the operator expects (Ganesan et
al., 2011).
A complete subset of colours which can be represented in a given
space is called gamut. The larger the gamut, the larger is the colour
space.
CIE L*a*b* (CIELAB) is a generic, device independent colour space,
intended for equal perceptual differences in the L*, a* and b*
coordinates. It was specified by the International Commission on
Illumination. The three coordinates of CIE L*a*b* represent the
lightness of the colour (L* = 0 is black and L* = 100 indicates diffuse
white; specular white may be higher), its position between red/magenta
and green (a*, where negative values indicate green while positive
values indicate magenta) and its position between yellow and blue (b*,
where negative values indicate blue and positive values indicate
yellow). CIE L*a*b* is based on the concept that colours can be
considered as combinations of red and yellow, red and blue, green and
yellow, and green and blue (Ganesan, 2011). This colour space is shown
in figure 1.
[FIGURE 1 OMITTED]
Unlike RGB and CMYK colour models, CIE L*a*b* is designed to
approximate human vision. Another characteristic of the CIE L*a*b*
system is that the distance that can be calculated between two colours
is directly proportional to the difference between the two colours as
perceived by the human eye (Ganesan, 2011).
These differences can be measured as a mathematical distance
between two colours, and are referred to as [DELTA]E, as can be seen in
the equation (1).
[DELTA]E R [square root of ([eL.sub.2] - [L.sub.1] [f.sup.2] N
[ea.sub.2] - [a.sub.1] [f.sup.2] N [eb.sub.2] - [b.sub.1] [f.sup.2]] (1)
With the aid of [DELTA]E calculations differences between two
colours can be measured, which enables to quantify the difference of one
colour in two different colour profiles.
Colour profiles are numerical models of colour spaces. It is usual
for operating systems and programs to have a colour profile, as it
allows them to interpret the colour in their colour space (Anderson
& Krogh, 2011). Since most colour spaces are limited, i.e. their
gamut is smaller than a human-based, device independent colour space, a
conversion between colour spaces needs to be made in order to achieve
the best suited colour replacement in a given colour space. This is why
we employ the term "colour management", i.e. switching between
colour profiles.
Colour management can be defined as the "communication of the
associated data required for unambiguous interpretation of colour
content data, and application of colour data conversions as required to
produce the intended reproductions" (Green, 2010).
3. METHODOLOGY
A colour comparison between profiles was made for this research and
web safe colours in three colour profiles were observed.
Web safe colours were chosen in the first place because of their
uniformity in monitor displays. They are composed of three bytes, each
for a red, green and blue channel. Safe colours consist of 216 colours
that are displayed solid and consistent on any computer monitor screen
capable of displaying at least 8-bit colour. One can see these colours
in Adobe Photoshop, as shown in figure 2.
Since the safe colour values are often displayed in hexadecimal and/or RGB colour space, so a conversion to CIE L*a*b* was made using
MathWorks Matlab R2009b. This conversion was necessary, as CIE L*a*b*
colour space is designed to approximate human vision (Ganesan et al.,
2011).
A comparison was made when shifting from profile number 1 to
profile number 2 (suited for coated substrates), and when shifting from
profile number 1 to profile number 3 (suited for uncoated substrates).
The colour conversion intent used was relative colourimetric rendering.
[FIGURE 2 OMITTED]
This rendering maintains smooth colour gradation by compressing the
entire tonal range, not destroying colour information, but
redistributing it.
4. RESULTS AND DISCUSSION
A total of 216 web safe colours were observed in the three
different profiles described in section 3. The results for the chosen
representative 8 RGB and CMYK colours + white are displayed in table 1.
Results show a high level of discrepancy between profiles, shown in
high [DELTA]E values. The highest values show the green, blue and cyan
colours, the red and magenta colours show medium alterations, while
yellow shows low alterations. Black and white show no alteration in
[DELTA]E values in case of white or extremely low [DELTA]E values in
case of black, unnoticeable to the bare eye as it is below 1 (Zjakic,
2007).
In addition, one can notice a similarity between colour values in
the profiles suited for coated and uncoated paper. Profile 3 generally
shows the highest [DELTA]E values, while [DELTA]E values in profile 2
are usually somewhat lower.
The mean [DELTA]E value in profile 2 was calculated in 14.23;
whilst in profile 3 the value was greater (17.08).
In the case of possible printing reproduction, if the intention is
to get some similar colour impression, it must be noted that the safe
colours must be very carefully chosen, and the appropriate rendering
intent has to be selected.
5. CONCLUSION
Web safe colours were observed under three different colour
profiles--profile number 1 (sRGB IEC61966-2.1), profile number 2 (coated
Fogra27 1S0 12647-2:2004) and profile number 3 (uncoated Fogra29 ISO 12647-2:2004).
Some safe colours, like other special or custom colours, can be
precisely reproduced in all systems, for which reason they deserve
special attention.
6. REFERENCES
Anderson, R. & Krogh, P. (2011). Colour Space and Colour
Profiles, Available from:
http://dpbestflow.org/colour/colour-spaee-and-colour-profiles Accessed:
2011-07-12
Ganesan, P.; Rajini, V. & Rajkumar, R.I. (2010). Segmentation
and edge detection of colour images using CIELAB colour space and edge
detectors, Available from:
http://0-ieeexplore.ieee.org.cisne.sim.ucm.es/stamp/
stamp.jsp?tp=&arnumber=5706186 Accessed: 2011-08-25
Green, P. (2010). Colour Management, Understanding and Using ICC Profiles, John Wiley & sons, Ltd, ISBN: 978-0470-05825-1, West
Sussex, United Kingdom
Zjakic, I. (2007). Upravljanje kvalitetom ofsetnog tiska, Hrvatska
sveucilisna naklada, ISBN: 9531691452, Zagreb, Croatia
*** (2011) http://www.mathworks.com/--TheMathworks Accessed on:
2011-02-11
Tab. 1. Results of the AE values
[DELTA]E [DELTA]E
sRGB--coated sRGB--uncoated)
Red 10.61 9.89
Green 58.37 70.13
..lue 51.64 54.65
Cyan 42.59 47.07
a enta 27.43 28.50
Yellow 4.45 6.17
lack 0 0.74
White 0 0
