Asus Transformer Tablet Display Shoot-Out
Dr. Raymond M. Soneira
President, DisplayMate Technologies Corporation
Copyright © 1990-2011 by DisplayMate
Technologies Corporation. All Rights Reserved.
This article, or any part
thereof, may not be copied, reproduced, mirrored, distributed or incorporated
into any other work without
the prior written permission of DisplayMate Technologies Corporation
Series
Overview
This is part of a
comprehensive article series with in-depth measurements and analysis for the
LCD and OLED displays in state-of-the art Smartphones and Tablets. We will
show you the good, the bad, and also the ugly unfinished rough edges and
problems lurking below the surface of each of these displays and display
technologies, and then demonstrate how the displays can be improved by using
images that have been mathematically processed to correct color and imaging
errors on Tablets and Smartphones so you can compare them to the originals.
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Introduction
A key element in the success of all Tablets and Smartphones is
the quality and performance of their display. There have been lots of
articles comparing various smartphone LCD and OLED displays and
technologies, but almost all simply deliver imprecise off-the-cuff remarks
like “the display is gorgeous” with very little in the way of serious
attempts at objective or accurate display performance evaluations and
comparisons – and many just restate manufacturer claims and provide
inaccurate information, performance evaluations and conclusions. This article objectively
evaluates the display performance of the Asus Eee Pad Transformer LCD
Tablet Display based on extensive scientific lab measurements together with
extensive side-by-side visual tests.
The Asus Eee Pad Transformer has a high performance
In Plane Switching IPS LCD display with a White LED backlight. The screen
is 10.1 inches diagonally and has a high-resolution 1280x800 pixel display
with a screen Aspect Ratio of 1.60, which is significantly larger than the
iPad 2, which has an Aspect Ratio of 1.33, but less than a widescreen HDTV,
which has an Aspect Ratio of 1.78.
The
inner details of the display technologies are very interesting, but our
concern here is to evaluate the actual image and picture quality that they
deliver, so we don’t really care how they do it, as long as they do it
well. None-the-less with the measurements and analytical test patterns we
will learn quite a bit about how they work.
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FIGURE 1
Figure 1. Revealing Screen Shots for
the Asus Transformer.
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Asus Transformer: Intensity Scale Ramps
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Asus Transformer:
NASA Photo - Sunset on Mars
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Figure 1. Revealing Screen Shots for
the Asus Transformer.
The test patterns and photos are 24-bit color
bitmaps at the native resolution of each display.
Results and Conclusions
The Asus Transformer
display was evaluated by downloading 24-bit native resolution 1280x752 test patterns
and 24-bit HD resolution test photos to the tablet. Note that while the LCD
screen has 1280x800 pixels only 1280x752 are available for applications because
48 pixels are reserved for the Android 3.1 system bar with the navigation
buttons. Note that we are testing and evaluating the display on the Asus
Transformer with whatever hardware, firmware, OS and software are provided by
Asus and Google Android.
Color
Depth and Granularity: 18-bits with Dithering to Emulate 24-bits
The Asus Transformer uses 18-bit color, which provides 64
possible intensity levels for each of the Red, Green and Blue sub-pixels that
are used to mix and produce all of the on-screen image colors. That’s
relatively good but not great, and would produce visible false contouring in many
images and photos were the Transformer not also using dithering to emulate full
24-bit color, which is what is found on most monitors and HDTVs, and provides
256 intensity levels and a nice color and intensity scale with few visible
artifacts. The Android Gallery photo viewer and most
Apps on the Tablet deliver only 16-bit color processed up to 24-bits with
poorly implemented dithering. It’s about time that gets fixed… The Android
Browser does however deliver 24-bit color for images from the web. Figure 1
shows screen shots from the Android Gallery.
Display
Image Quality, Colors and Artifacts: Very Good except for Color Saturation
The image and picture quality on the Asus Transformer are
fairly good across the board, including text, icons, and menu graphics. In the
important category of images, pictures and photographs from external sources,
whether they be from digital cameras or web content, are rendered quite well,
except that the LCD panel is weak in color saturation – much more on that
below.
The Measurements with Explanations and
Interpretations:
The Measurements section
below has details of all of the lab measurements and tests with lots of
additional background information and explanations including the display’s
Maximum Brightness and Peak Luminance, Black Brightness, Contrast Ratio, Screen
Reflectance, Bright Ambient Light Contrast Rating, Dynamic Color and Contrast,
Color Temperature and White Chromaticity, Color Gamut, Intensity Scale and
Gamma, the variation of Brightness, Contrast Ratio and Color Shift with Viewing
Angle, Backlight Power Consumption, and Light Spectrum of the display.
The
Viewing Tests: Not Enough Color Saturation
We compared the Asus Transformer side-by-side to the
other Tablets and to a calibrated Professional Sony High Definition Studio
Monitor using a large set of DisplayMate Calibration and Test Photographs. All
of the photos on the Transformer had too little contrast and not enough color
saturation and were somewhat below the picture quality of the iPad 2 but much
better than the Motorola Xoom.
Factory
Calibration and Quality Control: Very Good
The
overall factory calibration and quality control for the Asus Transformer
display is fairly good. It was reasonably well calibrated, with slightly
irregular intensity scales than may introduce false contouring and other
artifacts. The color and gray-scale tracking are very good, which means that
the Red, Green and Blue primaries have been carefully calibrated and balanced.
The one major flaw in the factory calibration is the irregular Intensity Scale.
The display Look Up Tables should be changed to deliver a more constant Gamma
closer to the standard value of 2.2.
Suggestions for Asus:
The
Asus Transformer has a very good display, but here are some suggestions on how
to make it better: The major shortcoming is the reduced color gamut, due to
weak Red and Blue primaries. It’s worth trading some brightness and/or power
efficiency to get more accurate and saturated colors. The Intensity Scale (and
Gamma) are somewhat irregular. The accompanying iPad 2 and iPhone 4
LCD Shoot-Out includes some suggestions for the OS driver software to
further improve the Transformer image quality by using better sub-pixel
anti-aliasing. The Automatic
Brightness Controls and Light Sensors article includes
some important suggestions for correcting the Automatic Brightness control,
which is very important for screen readability, viewing comfort and preserving
battery power.
This
article is a lite version of our intensive scientific analysis of smartphone
and mobile displays – before the benefits of our advanced mathematical DisplayMate Display Optimization
Technology, which can correct or improve many of the deficiencies –
including higher calibrated brightness, power efficiency, effective screen
contrast, picture quality and color and gray scale accuracy under both bright
and dim ambient light, and much more. If you are a
manufacturer and want our expertise and technology to turn your display into a
spectacular one to surpass your competition then Contact DisplayMate Technologies
to learn more.
Asus
Transformer Conclusion: Very Good Mobile
Display
The
Asus Transformer has a very good IPS LCD like the iPad 2, and it delivered good
image and picture quality across the board. This is especially impressive
because it is $100 cheaper than the iPad 2 and $200 cheaper than the Motorola
Xoom. It’s not as bright or as well calibrated as the iPad 2 but it still
delivers very good performance including very good contrast, reasonably accurate
colors and very good Viewing Angle performance like the iPad 2. But the
Transformer screen has a 66 percent higher ambient light reflectance than the
iPad 2. It has an 18-bit color display, but produces 24-bit color by using
dithering.
The Measurements with Explanations and Interpretations
This
section explains all of the measurements incorporated in the article. The
display was evaluated by downloading 24-bit native resolution 1280x752 test
patterns and 24-bit HD resolution test photos to the Asus Transformer. Note
that while the LCD screen has 1280x800 pixels only 1280x752 are available for
applications because 48 pixels are reserved for the Android 3.1 system bar with
the navigation buttons. Note that we are testing and evaluating the display on
the Asus Transformer with whatever hardware, firmware, OS and software are
provided by Asus and Google Android. All measurements were made using DisplayMate Multimedia Edition
for Mobile Displays to generate the analytical test patterns together with
a Konica
Minolta CS-200 ChromaMeter, which is a Spectroradiometer. All measurements
were made in a perfectly dark lab to avoid light contamination. All devices
were tested with their Backlight set for maximum brightness with the Automatic
Brightness light sensor control turned off, and running on their AC power
adapter with a fully charged battery, so that the battery performance and state
was not a factor in the results. For further in-depth discussions and
explanations of the tests, measurements, and their interpretation refer to
earlier articles in the DisplayMate
Multimedia Display Technology Shoot-Out article series and the DisplayMate Mobile Display
Shoot-Out article series.
Konica Minolta CS-200
1. Peak Brightness: 325 cd/m2 –
Good for a Mobile Display
This is the maximum brightness that the display
can produce, called the Peak White Luminance. 325 cd/m2 is 20
percent dimmer than the other Tablets and lower than what we like to see for
mobile displays. It’s fine for just about everything except high ambient light,
although it may be too bright for comfortable viewing under dim ambient
lighting. If you find that to be the case, turn down on the Transformer’s
Automatic Brightness, which uses a light sensor to adjust the Peak Brightness
settings. Since that can be used to decrease the power used by the backlight it
will also increase the battery run time.
2. Black Level Brightness: 0.42 cd/m2
– Very Good for a Mobile Display
The Black Level is the
closest approximation to true black that the display can produce. Almost all
displays wind up producing a visible dark gray on-screen instead of true black.
This is a major problem for LCDs. The glow reduces image contrast and screen
readability and can be distracting or even annoying in dark environments. It
ruins the dark end of the display’s intensity/gray scale and washes out colors
in the image. But note that in bright ambient lighting the Black Level is
irrelevant because reflections off the screen dominate the screen background
brightness. The Asus Transformer’s value of 0.42 cd/m2 is reasonably
dark for a mobile display in typical ambient lighting. Note that if you
decrease the screen Brightness with the (Backlight) Brightness Control, the
Black Brightness will also decrease proportionally by the same amount, so in
dimmer ambient lighting the Black Brightness can be reduced significantly if
desired.
3. Contrast Ratio – Only Relevant for Low
Ambient Light:
769 –
Very Good for Mobile
The Contrast Ratio is a
measure of the full range of brightness that the display is capable of
producing. It is the ratio of Peak Brightness to Black Level Brightness. The
larger the Contrast Ratio the better, but it is only relevant for low ambient
lighting because reflections off the screen dominate the display’s Black Level
in bright ambient lighting. The very best LCDs now have (true) Contrast Ratios
of 1,500 to 2,000 so the 769 value for the Asus Transformer is very good for a
mobile device. Don’t confuse the true Contrast Ratio with the tremendously
inflated values that are published by many manufacturers.
4. Screen Reflectance of Ambient Light: 14.4 Percent – Relatively High
The often overlooked
Screen Reflectance is actually the most important parameter for a mobile
display, even more important than Peak Brightness. This is especially true for
the large 10.1 inch Asus Transformer display. The screen reflects a certain
percentage of the surrounding ambient light, which adds to the screen
background, washes out the image, and makes it harder to see what is on the
screen. In high ambient lighting the Screen Reflectance can significantly
reduce the visibility and readability of screen content. The lower the Screen
Reflectance the better. The value for the Asus Transformer is among the higher
values we have measured for mobile devices, and is approximately 66 percent
higher than the iPad 2. Lowering the Screen Reflectance increases the cost of a
display, but it’s the easiest and best way to improve screen readability under
bright ambient light. The Screen Reflectance measurements were done in
accordance with VESA FPDM 308-1, Reflectance with Diffuse Illumination, using
an integrating hemispherical dome and a calibrated diffuse white reflectance
standard.
5. Bright Ambient Light Contrast Rating: 23 – Good
In the same way that the
Contrast Ratio measures the screen contrast under low ambient lighting, the
Bright Contrast Rating specifies the relative screen contrast under high
ambient lighting. It is the ratio of Peak Brightness to Screen Reflectance. The
higher the value the better you’ll be able to see what’s on the screen when you
are in a bright location. The Contrast Rating for the Asus Transformer is 23,
at the lower end of Good. For all mobile devices the High Ambient Light Contrast
Rating is much more important than the Contrast Ratio.
6. Dynamic Color and Dynamic Contrast: No – Which is Good
Some displays dynamically adjust the color, gray
scale and contrast on every image that is displayed using an internal automatic
image processing algorithm. The goal is generally to jazz up and “enhance” the
picture by stretching and exaggerating the colors and intensity scale. It is
similar to the Vivid mode found in many digital cameras and HDTVs. Since it
alters and frequently distorts the image it is better left as an option for
people who aren’t concerned with picture accuracy and fidelity. Since the
Dynamic modes are generally triggered by changes in Average Picture Level, a
very simple test for Dynamic Contrast is to separately measure the brightness
of full screen Red, Green and Blue images and then compare them to White, which
should equal their sum. If they don’t agree then there is Dynamic Color and
Contrast processing. For the Asus Transformer, the measured Luminance for
Red=75, Green=209 and Blue=42 cd/m2. Their sum is 326 cd/m2,
which is virtually identical to the measured 325 cd/m2 White
Luminance.
7. Color Temperature and Chromaticity: 6570 degrees Kelvin –
Very Close to D6500, Excellent
White is not a single
color but rather falls within a range that is normally specified by a Color
Temperature. For accurate color reproduction of most content, including
photographs, images and web content it needs to be set to the industry standard
D6500, which is how most professional photo and video content is color
balanced. D6500 is the color of natural daylight and is similar to a Black Body
at 6500 degrees Kelvin. The Asus Transformer’s White Point is very close to
D6500 – see the White Points in Figure 2 below. The measured CIE Chromaticity
Coordinates of the Asus Transformer White Point are u’=0.1978 v’=0.4674.
8. Color Gamut:
Much Smaller than the Standard Color Gamut –
Colors are Inaccurate and Under Saturated
The Color Gamut of a
display is the range and set of colors that it can produce. The only way that a
display will deliver good color and gray scale accuracy is if it is accurately
calibrated to an industry standard specification, which for computers, digital
cameras, and HDTVs is sRGB or Rec.709. It’s the standard for most content and
necessary for accurate color reproduction. If the Color Gamut is smaller than
the standard then the image colors will appear too weak and under-saturated. If
the Color Gamut is greater than the standard then the image colors will appear
too strong and over-saturated. The important point here is that a Color Gamut
larger than the standard is also bad, not better. Wider gamuts will not show
you any colors or content that are not in the original images, which are almost
always color balanced for the sRGB / Rec.709 standard. Wider color gamuts
simply distort and decrease color accuracy and should be avoided, except for
some special applications.
Figure 2 shows the
measured Color Gamuts for the Tablets alongside the Standard sRGB / Rec.709
Color Gamut in a CIE 1976 Uniform Chromaticity Diagram. The dots in the center
are the measured White Points for the phones along with the D6500 Standard,
which is marked as a white circle. The outermost curve are the pure spectral
colors and the diagonal line on the bottom right is the line of purples. A
given display can only reproduce the colors that lie inside of the triangle
formed by its primary colors. Highly saturated colors seldom occur in nature so
the colors that are outside of the standard sRGB / Rec.709 triangle are seldom
needed and are unlikely to be noticed or missed in the overwhelming majority of
real images. When a camera or display can’t reproduce a given color it simply
produces the closest most saturated color that it can.
FIGURE 2
Figure 2. CIE 1976 Uniform
Chromaticity Diagram showing the Color Gamut and White Point for the Asus
Transformer
The LCD Tablets all perform poorly with reference to the
standard Color Gamut, which is the black triangle in Figure 2. They have much
too small a color Gamut. As a result they produce images that have
significantly too little color saturation. This applies to all external content
viewed on the displays, including web content, such as images, photos and
videos. This was easy to see in the viewing tests where we compared the
displays side-by-side to a calibrated Professional Sony High Definition Studio
Monitor using a large set of DisplayMate Calibration and Test Photographs. On
the LCD Tablets, all of the photos looked somewhat pale, flat, washed-out and
under-saturated. The Asus Transformer was much better than the Motorola Xoom
but not as good as the iPad 2 because of the Intensity Scale, which affects
color saturation. See below.
9. Intensity Scale, Image Contrast and Gamma: Slightly Irregular – Good
The display’s intensity
scale not only controls the contrast within an image but it also controls how
the Red, Green and Blue primary colors mix to produce all of the on-screen
colors. So if it doesn’t obey the industry standard intensity scale then the
colors and intensities will be wrong everywhere on-screen because virtually all
professional content and all digital cameras use the sRGB / Rec.709 standard,
so it’s necessary for accurate image, picture and color reproduction. The
standard intensity scale is not linear but rather follows a mathematical
power-law, so it is a straight line on a log-log graph. Its slope is called
Gamma, which is 2.2 in the standards. In order to deliver accurate color and
intensity scales a display must closely match the standard. Figure 3 shows the
measured (Transfer Function) Intensity Scale for the Apple iPad 2, Motorola
Xoom and Asus Transformer alongside the industry standard Gamma of 2.2, which
is a straight line.
FIGURE 3
Figure 3. Intensity Scale for the
Asus Transformer
The Asus Transformer has a slightly irregular Intensity
Scale with respect to the Standard intensity scale, which is needed in order to
accurately reproduce images and pictures for most content. Gamma is the slope
of the intensity scale, which should be a constant 2.2 like the straight line
in Figure 3. The Gamma for the Transformer ranges subtly between 2.10 and 2.23,
which is fairly good, especially near peak intensities which control the more
visible image elements..
10. Brightness Decrease with Viewing Angle: 58 percent Decrease in
30 degrees – Bad, Very Large
A major problem with many displays, especially
LCDs, is that the image changes with the viewing angle, sometimes dramatically.
The Peak Brightness, Black Luminance, Contrast Ratio and color generally change
with viewing angle (see below). Some display technologies are much better than
others. At a moderate 30 degree viewing angle the Peak Brightness of the Asus
Transformer fell by 58 percent to 135 cd/m2, which is an incredibly
large decrease. This behavior is typical for LCDs.
11. Black Level and Contrast Ratio Shift with
Viewing Angle:
At a moderate 30 degree viewing angle the Black
Level Brightness decreased somewhat to 0.31 cd/m2, but the Contrast
Ratio still fell considerably to 438. This behavior is typical for LCDs.
12. Color Shift with Viewing Angle: Excellent, Barely
Visible Shift
Colors generally shift
with viewing angle whenever the brightness shifts with viewing angle because
the Red, Green and Blue sub-pixels each shift independently and vary with
intensity level. At a moderate 30 degree viewing angle the primary colors
shifted by a maximum of Δ(u’v’) = 0.0110, which is 2.8 times the Just
Noticeable Color Difference. A much more challenging test is to use mixtures of
primary colors. Reference Brown (255, 128, 0) is a good indicator of color
shifts with angle because of the unequal drive levels and roughly equal
luminance contributions from Red and Green. For the Reference Brown color
mixture the color shift was Δ(u’v’) = 0.0056, which is just 1.4 times
JNCD. These values are so low that the Asus Transformer barely shows any
detectable color shift with angle.
13. RGB Display Power Consumption: Excellent, Relatively
Low
The power consumed by LCD
displays is independent of the brightness and color distribution of the images
– it only depends on the Brightness setting of the Backlight that illuminates
the LCD from behind. The Automatic Brightness option allows the ambient light
sensor on the Transformer to adjust the backlight brightness and power setting
as the ambient light changes. This not only improves visual comfort but can
also increase the battery run time. We turned off Automatic Brightness for the
tests. It is possible to indirectly determine the power used by the display by
measuring the AC power used by the Asus Transformer with different backlight
settings.
Table 1 lists the Measured
Relative Power, the Measured Luminance, and the Relative Luminous Efficiency,
which is just the Measured Luminance divided by the Measured Relative Power,
and normalized to 1.0 for White, which has the highest total efficiency.
Table 1. Asus
Transformer LCD Display Power Consumption
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Maximum Backlight
Full Screen
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Black
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Peak Red
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Peak Green
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Peak Blue
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Peak White
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Measured Relative Power
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2.1 watts
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2.1 watts
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2.1 watts
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2.1 watts
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2.1 watts
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Measured Luminance
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0.42 cd/m2
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75 cd/m2
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209 cd/m2
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42 cd/m2
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325 cd/m2
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Relative Luminous Efficiency
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0.0013
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0.23
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0.64
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0.13
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1.00
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14. OLED and LCD Spectra: Very Interesting
The spectra of an LCD display is just the
spectrum of the backlight filtered through the individual Red, Green and Blue
sub-pixel filters within the panel. OLEDs are emissive devices so their spectra
is just the sum of the individual Red, Green and Blue OLED spectra, modified slightly
by the touchscreen layer and anti-reflection absorption layer through which
their light must pass. We thought it would be very useful and interesting to
compare the spectra of the Galaxy S OLED with the spectra of the LCD Tablets.
The spectra for White, which is the sum of the Red, Green and Blue primaries is
shown in Figure 4 for the iPad 2, Motorola Xoom and Asus Transformer as well as
the Samsung Galaxy S OLED.
FIGURE 4
Figure 4. RGB Spectra for the LCD
Tablets and also for the Samsung Galaxy S OLED
As
expected the OLED RGB spectra are relatively narrow because of their high color
saturation. The LCD RGB spectra are a filtered broadband spectrum. The
backlights for the LCD Tablets are white LEDs, which consists of a Blue LED
with a yellow phosphor.
About the Author
Dr. Raymond Soneira is
President of DisplayMate Technologies Corporation of Amherst, New Hampshire,
which produces video calibration, evaluation, and diagnostic products for
consumers, technicians, and manufacturers. See www.displaymate.com. He is a research
scientist with a career that spans physics, computer science, and television
system design. Dr. Soneira obtained his Ph.D. in Theoretical Physics from
Princeton University, spent 5 years as a Long-Term Member of the world famous
Institute for Advanced Study in Princeton, another 5 years as a Principal
Investigator in the Computer Systems Research Laboratory at AT&T Bell
Laboratories, and has also designed, tested, and installed color television
broadcast equipment for the CBS Television Network Engineering and Development
Department. He has authored over 35 research articles in scientific journals in
physics and computer science, including Scientific American. If you have any
comments or questions about the article, you can contact him at dtso.info@displaymate.com.
About DisplayMate Technologies
DisplayMate Technologies
specializes in advanced mathematical display technology optimizations and
precision analytical scientific display diagnostics and calibrations to deliver
outstanding image and picture quality and accuracy – while increasing the
effective visual Contrast Ratio of the display and producing a higher
calibrated brightness than is achievable with traditional calibration methods.
This also decreases display power requirements and increases the battery run
time in mobile displays. This
article is a lite version of our intensive scientific analysis of smartphone
and mobile displays – before the benefits of our advanced mathematical DisplayMate Display Optimization
Technology, which can correct or improve many of the deficiencies –
including higher calibrated brightness, power efficiency, effective screen
contrast, picture quality and color and gray scale accuracy under both bright
and dim ambient light, and much more. Our advanced scientific
optimizations can make lower cost panels look as good or better than more
expensive higher performance displays. For more information on our technology
see the Summary description of our Adaptive Variable Metric Display
Optimizer AVDO. If you are a display or product
manufacturer and want our expertise and technology to turn your display into a
spectacular one to surpass your competition then Contact DisplayMate Technologies
to learn more.
Article Links: Display Technology Shoot-Out
Article Series Overview and Home Page
Copyright © 1990-2011 by DisplayMate
Technologies Corporation. All Rights Reserved.
This article, or any part
thereof, may not be copied, reproduced, mirrored, distributed or incorporated
into any other work without
the prior written permission of DisplayMate Technologies Corporation
