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new iPad Display Technology Shoot-Out

iPad 2  –  new iPad  –  iPhone 4

 

Dr. Raymond M. Soneira

President, DisplayMate Technologies Corporation

 

Copyright © 1990-2012 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

 

 

To Scale

 

iPad 2

new iPad

iPhone 4

 

Introduction

The iPad has been a phenomenal runaway success – to a degree that may have even surprised Steve Jobs. At the new iPad launch Tim Cook remarked that people have been wondering who would improve upon the iPad. Amazingly, but to no one’s surprise, that would be Apple (again). Much to my delight the new Retina Display is its flagship and number one marketing feature. Tablets, after all, are essentially large portable displays so a top notch display is the key to a successful product – something most manufacturers haven’t figured out yet. Apple has from day 1 – and the new iPad Retina Display is impressive – Apple calls it “Resolutionary.” This article will be a combination of objective praise and critical analysis of the Retina Display on the new iPad.

 

First of all, the Apple Retina Display is pure marketing brilliance. While the enhanced screen resolution is getting most of the attention, the enhanced color saturation is equally responsible for its wow factor. These are the two wonders of the new iPad. Both are technically challenging because they require lots of additional battery power. In fact, the battery on the new iPad has 70 percent higher capacity than the iPad 2.

 

While the enhanced resolution is important, it’s also a technical overkill that parallels the Mega Pixel wars of digital cameras. More pixels are better up to a point, and then they wind up adversely affecting both performance and manufacturing costs. To a certain extent that is definitely the case for the new iPad as we explain below. Still Apple has managed to pull everything together nicely so that in the end it all performs quite well. Just as surprising is that Apple has managed to keep the retail price the same as the iPad 2. That’s the third wonder of the new iPad. We will show and tell you below a lot more than you’ll learn anywhere else about the iPad Retina Display…

 

A true “Retina Display” but not an actual Retina Display

The original Retina Display on the iPhone 4 has 326 pixels per inch (ppi). But to qualify as an Apple Retina Display the new iPad does not require the same ppi as the iPhone 4 Retina Display because it is typically held further away from the eye, whose visual sharpness is based on angular resolution rather than the linear ppi resolution on the display. The iPad is typically held 15-18 inches away as opposed to the iPhone 4’s 12-15 inches. As a result, to meet the 300 ppi Retina Display specification made by Steve Jobs at WWDC for the iPhone 4, an iPad Retina Display only needs 240 ppi – and it has 264 ppi. So according to Apple’s own definition, the new iPad is indeed a true “Retina Display.”

 

However, Apple’s definition of a “Retina Display” is actually for 20/20 Vision (defined as 1 arc-minute visual acuity). 20/20 Vision is just the legal definition of “Normal Vision,” which is at the lower end of true normal vision. There are in fact lots of people with much better than 20/20 Vision, and for almost everyone visual acuity is actually limited by blurring due to imperfections of the lens in the eye. The best human vision is about 20/10 Vision, twice as good as 20/20 Vision, and that is what corresponds to the true acuity of the Retina. So to be an actual “True Retina Display” a screen needs at least 573 ppi at 12 inches viewing distance or 458 ppi at 15 inches. The 326 ppi iPhone 4 is a 20/20 Vision display if it is viewed from 10.5 inches or more. Unfortunately, a “20/20 Vision Display” doesn’t sound anywhere near as enticing as a “Retina Display” so marketing and science don’t see eye-to-eye on this…

 

Do you really need all of that resolution and sharpness?

I am definitely not proposing a new display Mega Pixel war for 400+ ppi (but several manufacturers are working on it, so we’ll see). The new iPad display is incredibly sharp with 264 ppi and 3.1 million pixels on a 9.7 inch screen. The iPad 2 screen with 132 ppi, a resolution of 1024x768 and 0.8 million pixels is noticeably pixelated, but was it really necessary to double the resolution and therefore quadruple the number of pixels? Marketing considerations aside, the real reason for doubling the iPad’s resolution to 2048x1536 is for the convenience and ease in up-scaling the older 1024x768 Apps from the iPad 1 and iPad 2 – every older App pixel is simply replicated 2x2=4 times. Rescaling to lower resolutions like 1600x1200 would have required more complicated processing, but the high power A5X processor on the new iPad could have easily handled that.

 

Marketing considerations aside, do you really need all of that “Retina Display” resolution and sharpness? In many cases no, for these five reasons:  1. Most adults don’t actually have true corrected 20/20 Vision even with glasses or contact lenses.  2. If you view the display further away than the recommended viewing distance your eye can no longer fully resolve the sharpness of the display, so that high resolution is wasted.  3. Unlike computer graphics images, photographic images (including videos) are inherently fuzzy, with the sharpest image detail spread over multiple pixels. Similarly, you would be hard pressed to visually tell the difference between 640x480 and 2048x1536 photographic images of a (Granny Smith) Apple.  4. Sub-pixel rendering, rather than ordinary pixel rendering, will significantly improve the visual sharpness of any display, especially for computer generated text and graphics, so that is the most efficient approach to improving sharpness.  5. Most people don’t even have 1600x1200 resolution on the much larger 15-19 inch screens on their (Apple or Windows) laptops and desktop monitors and are happy with them (even the tech journalists that I asked).

 

So where will the 2048x1536 3.1 Mega Pixel Retina Display actually make a noticeable visual improvement over other displays? All (computer generated) text will appear much sharper, but it will make the most difference whenever there is tiny text and fine graphics, which you often see when surfing the web (like the front page of The New York Times) or in a complex spreadsheet. Then there is a tremendous visual difference between the new iPad and the iPad 2 or existing Android Tablets. You won’t have to zoom in as much or switch to Landscape mode as often when reading tiny web content. Full screen high quality photographs with lots of fine detail will also stand out and take full advantage of the new iPad’s High Definition screen. The larger Tablet format also makes the iPad appear visually sharper and more stunning than the much smaller (and higher ppi) iPhone 4. One final note on Retina Displays: your existing HDTV is already a Retina Display. For example, a 1080p 46 inch TV viewed from 6 feet or more and a 1080p 60 inch TV viewed from 8 feet or more (the typical TV viewing distance in the US is 9 feet) are already 20/20 Vision "Retina Displays" so don’t worry about upgrading them to get Retina Display resolution and sharpness…

 

IGZO and other Apple display Rumors explained

A high resolution display for the iPad 2 and then the “iPad 3” was the number one rumor in the tech world for all of 2011. In fact, it resulted in hundreds (possibly thousands) of rumors for if, when, where, and how it would be done. Actually, the question was not whether it could be done, but rather whether it could be done with satisfactory yields, production volumes, and costs. While Apple was rumored to have invested in production facilities for Sharp, essentially all of the advanced display technology for Apple displays comes from its three principal display suppliers: LG, Samsung and Sharp. Chimei Innolux and Au Optronics also supply displays. In many cases new Apple products launch with just a single supplier (rumored this time to be Samsung for the new iPad) and then expand to between 3 and 5 suppliers for high volume products like the iPad and iPhone. New teardown reports now indicate that there are actually 3 suppliers at launch: Samsung, LG, and possibly Sharp.

 

The iPad 2 uses amorphous Silicon for the LCD Active Matrix Thin Film Transistors (AM TFTs), the same display technology found in most Tablets, laptops, and desktop monitors. On the other hand, the iPhone 4 uses Low Temperature Poly Silicon (LTPS) because the much higher ppi requires smaller AM TFTs in order to maintain satisfactory brightness and efficiency. However, it’s more complex and costly to produce. One of the biggest rumors was that Apple was going to use Sharp’s IGZO (Indium Gallium Zinc Oxide), which is better at high ppi and lower cost than LTPS. But it’s a new technology and Sharp publicly announced in December that it was experiencing startup delays. LG and Samsung have also been working on IGZO technology. The question is when, not if, this technology will be coming to future Retina Displays (and non-Apple Tablets and Smartphones). It will also be coming to laptops, monitors, and televisions, possibly even Apple’s. Our lab measurements show that IGZO is desperately needed for the new iPad high ppi display because of the high power and large batteries it currently needs. And, counter to the rumor mill, IGZO can do IPS (in Plane Switching) technology that is found on the iPad 2 and iPhone 4 displays, see below.

 

So what display technology is in the new iPad? According to DisplaySearch it is still amorphous Silicon that has been pushed to its extreme upper ppi limit. Apple has a nice video on their website that discusses advanced dual plane LCD technology that they say is there to reduce sub-pixel crosstalk in the new iPad. It’s actually technology originally developed by Sharp and other companies to increase the aperture ratio and brightness efficiency of these very high ppi LCDs. Another interesting display technology mystery: while Apple’s official website Tech Specs and Features list IPS (In Plane Switching) as the LCD technology used in both the iPads and iPhone 4/4S (which provides wide viewing angles) the displays from all suppliers actually come with FFS (Fringe Field Switching) licensed from Hydis, which is related to IPS technology. This is also the case for many Android Tablets, including the Amazon Kindle Fire, Barnes & Noble Nook Tablet, and even the Samsung Galaxy Tab 10.1.

 

The Shoot-Out

To compare the performance of the new iPad we ran our in-depth series of Display Technology Shoot-Out tests on the new iPad. We take display quality very seriously and provide in-depth objective analysis side-by-side comparisons with the iPad 2 and iPhone 4 based on detailed laboratory measurements and extensive viewing tests with both test patterns and test images. We used the iPhone 4 rather than 4S because it performs slightly better. For comparisons with other “popular” Tablets see our 10 Inch Tablet Display Technology Shoot-Out and our IPS Tablet Display Technology Shoot-Out for comparisons with the Amazon Kindle Fire and Barnes & Noble Nook Tablet.

 

To Scale

 

iPad 2

new iPad

iPhone 4

 

 

Results Highlights

In this Results section we provide Highlights of the comprehensive lab measurements and extensive side-by-side visual comparisons using test photos, test images and test patterns that are presented in later sections. The Comparison Table in the following section summarizes the lab measurements in the following categories:  Screen ReflectionsBrightness and ContrastColors and IntensitiesViewing AnglesDisplay Backlight Power ConsumptionRunning Time on Battery, and Battery Charging Issues.

 

Comparison with the iPad 2 and current Android Tablets:  The display on the new iPad decisively beats (blows away) all of the Tablets we have previously tested including the iPad 2 (below), the Samsung Galaxy Tab 10.1, the Barnes & Noble Nook Tablet, and the Amazon Kindle Fire at the back of the pack. The articles also show that the iPad 2 display has recently slipped behind the Galaxy Tab and Nook Tablet. See the Conclusion section below for the evaluation and the article links for other tested Tablets.

 

Display Sharpness:  As expected, all of the images, especially the text and graphics, were incredibly and impressively razor sharp. In some photographs, that extra sharpness made a significant difference, especially in close-ups and when fine detail like text was photographed.

 

Improved Color Saturation and Color Accuracy:  A major shortcoming of the iPad 2 and iPhone 4 is their reduced Color Gamut, they only have 61-64 percent of the sRGB-Rec.709 Standard Color Gamut needed for accurate color reproduction. That produces images with noticeably under saturated colors, particularly reds, blues and purples. This is due to efficiency issues from the Backlight LEDs. Apple claims “44 percent greater color saturation.” Technically it’s not clear what that means in this context, but the new iPad has a virtually perfect 99 percent of the Standard Color Gamut (a 38 percent improvement over the iPad 2). The colors are beautiful and accurate due to very good factory calibration – they are also “more vibrant” but not excessively so or gaudy like some existing OLED displays. See the Conclusion below for our overall assessment and the screen shots for a side-by-side screen comparison.

 

Viewing Tests:  What makes the new iPad really shine is its very accurate colors and picture quality. It’s most likely better and more accurate than any display you own (unless it’s a calibrated professional display). In fact with some minor calibration tweaks the new iPad would qualify as a studio reference monitor. See our detailed Color and Intensity Scale measurements below.

 

The new iPad as a Camera:  The main (rear) camera on the iPad 2 was awful but the camera on the new iPad appears to be the same as the camera on the iPhone 4, and it does take very good photos, but no where near as nice as a DSLR camera. Many reviewers have commented that it’s awkward and dorky to hold up a Tablet to take a photo. But the real advantage of the new iPad over any other camera is that you immediately see your photo on a beautiful and color accurate 9.7 inch display. Even $2,000 DSLRs have only 3 inch low resolution screens, which are less than one tenth the area of the iPad screen, so you really don’t know how good your photo is until you download it later on after the opportunity to take a better shot is gone (the same problem that film cameras had). Fortunately, DSLR cameras are beginning to offer WiFi.

 

Screen Reflectance:  The screens on almost all Tablets and Smartphones are mirrors good enough to use for personal grooming. Even in moderate ambient lighting the sharpness and colors can noticeably degrade from light reflected by the screen, especially objects like your face and any bright lighting behind you. Screen Reflectance on the new iPad is 7.7 percent, in the middle of the range that we have seen for Tablets and Smartphones. The best we have ever measured in our lab tests are the Samsung Galaxy S and the Nokia Lumia 900 with its ClearBlack display, with about half of the Reflectance of the new iPad, and the current worst is the Amazon Kindle Fire, with about double the Reflectance of the new iPad. This article shows how screen images degrade in bright ambient light.

 

Viewing Angle Performance:  According to Apple the new iPad has an IPS LCD like the iPad 2 and iPhone 4, and our lab measurements confirmed excellent Viewing Angle performance, with no noticeable color shifts. However, all LCDs, including IPS LCDs, do have a strong decrease in brightness with Viewing Angle, and the new iPad performed as expected, with a 57 percent decrease in brightness at just 30 degrees Viewing Angle. The Viewing Angle performance for the new iPad, iPad 2 and iPhone 4 are all virtually identical.

 

Much Lower Display Power Efficiency:  The new iPad uses 2.5 times the Backlight power of the iPad 2 for the same screen Brightness. As discussed above that results from the TFT transistors in the LCD blocking much more of the light at higher ppi. On the other hand, the highest ppi iPhone 4 is the most power efficient display of all because it uses Low Temperature Poly Silicon LTPS, which is much more efficient than amorphous Silicon in the iPads. All of this points to the need for the IGZO display technology discussed above, which is lower cost than LTPS, and more efficient so it can use smaller batteries. IGZO should be in production shortly, and is the first in a whole series of enhanced Metal Oxide semiconductors for LCD and OLED displays.

 

Much more Power and Battery but not Thickness or Weight:  There are 4 times as many pixels in the display that need to be kept powered. Also 4 times as much memory and processing power is needed for the images. In addition, the light transmission of the LCD decreases as the pixel density increases, so a brighter Backlight is necessary. In fact, the number of Backlight LEDs has roughly doubled (from 36 to an estimated 72 to 82), so the Backlight power has approximately doubled. Since the display normally consumes about 50-60 percent of the total Tablet power, the new iPad needs at least a 50 percent larger battery. In fact, the battery increased from 25 to 42.5 watt hours, a 70 percent increase. Our measured Backlight power for the new iPad is 2.5 times the iPad 2 for the same screen brightness. In spite of the larger battery the running time at Maximum brightness in our tests was 5.8 hours, 20 percent less than the iPad 2’s 7.2 hours. But at the Middle brightness slider setting, which is closer to typical user settings, the running time was 11.6 hours, which is almost identical to the iPad 2, indicating that Apple has used an appropriately larger battery (and confirms Apple’s 10 hour claim). Surprisingly the overall iPad thickness increased by only 0.6mm (0.03 inches) and the weight increased by only 1.8 ounces (8 percent). That small increase in weight in spite of 70 percent more battery capacity indicates that the case and cover glass are significantly lighter.

 

new iPad Conclusion:   Impressive… but Lots of Room for Improvement

Apple has taken the very good display on the iPad 2 and dramatically improved two of its major weak points: sharpness and color saturation – they are now state-of-the-art. Our lab tests and visual tests agree with Apple’s claim that the new iPad has “the best display ever on a mobile device” so we have awarded the new iPad the Best Mobile Display Award in DisplayMate’s Best Video Hardware Guide. But there’s more… the new iPad’s picture quality, color accuracy, and gray scale are not only much better than any other Tablet or Smartphone, it’s also much better than most HDTVs, laptops, and monitors. In fact with some minor calibration tweaks the new iPad would qualify as a studio reference monitor. So we have also awarded the new iPad the Best Mobile Picture Quality Award, which was previously held by the original Motorola Droid (not the more recent Droids, which all have poor picture quality). Finally, almost as impressive is that Apple has maintained the base price of $499. Who says Apple doesn’t compete aggressively on price!

 

Many New Professional Level Applications:

With this degree of picture quality and accuracy the iPad is now qualified for many interesting professional level applications. If you are a professional (or serious amateur) photographer the new iPad will show your photographs more accurately than any other display you have (unless it’s a calibrated professional display). More importantly, for medical imaging – every MD should have one for both mobile and office use. It will also be great for anyone that needs to refer to detailed documents and manuals – like field service technicians (millions of them), warehouse workers, and pilots just to name a few. Tens of millions of sales people often need a portable device that displays very sharp and accurate color representations of their products and sales information. For this the new iPad beats every laptop, Tablet, and mobile projector I have seen. It’s impressive, but there is still…

 

Lots of Room for Improvement by Apple and Other Manufacturers:

If you read our earlier Mobile Display Shoot-Outs for the iPhone 3GS, iPhone 4, and iPad 2, it certainly appears that Apple has been following our display advice (see Figure 3 on the evolution of the iPhone and iPad gray scale). So what’s next… While Apple has zeroed in on sharpness and done an excellent job of it, and improved the color saturation and color accuracy to an impressive level, there are still plenty of other very important display issues that need to be addressed by all of the Tablet and Smartphone manufacturers, including Apple. Here are just a few:  1. Screen Reflectance:  The typically large screen reflections can make the screen much harder to read even in moderate ambient light levels, requiring ever higher brightness settings that waste precious battery power. Manufacturers need to significantly reduce the mirror reflections with anti-reflection coatings and haze surface finishes. This article shows how Tablet and Smartphone screens degrade as the Ambient Light increases from 0 to 40,000 lux.   2. Ambient Light Sensor:  The forward facing Ambient Light Sensor on virtually all Tablets and Smartphones measures the brightness of your face instead of the surrounding ambient light, which is what is needed to accurately set the screen’s Automatic Brightness.  3. Automatic Brightness:  The Automatic Brightness controls on all Tablets and Smartphones that we have measured are positively awful and close to functionally useless. As a result they often get turned off, which reduces battery run time and increases eye strain. This article explains how to do it properly.  4. Display User Interface:  The User Interface for most Tablet and Smartphone displays consists of a Brightness slider and an Automatic Brightness checkbox. People have very different visual preferences that should be accommodated with a display Pizzazz control that is similar to the functionality provided by the audio Equalizers found on most Tablets and Smartphones.  5. RGB LED Backlights:  Using separate red, green and blue Backlight LEDs instead of just white LEDs will allow more accurate calibration, allow the image color saturation to be increased under high ambient lighting, and also accommodate people that like extra vibrant rather than accurate colors on-screen.  6. OLED Displays:  Once their cost significantly decreases and their power efficiency and production volumes significantly increase we’ll start to see lots of Tablets with OLED displays. Until then, IPS LCDs can’t be beat.  7. Size:  Tablets are so useful that there is plenty of room for 7 inch, 10 inch, and even 12+ inch screens – the first for extra portability and the latter for professional and office applications… and there are lots of people that would own more than one size based on their varying needs. One of the more credible rumors flying around is that Apple will introduce a 7-8 inch 1024x768 iPad in 2012. I hope so… and so does my daughter, saying it will then fit in her handbag.

 

 

DisplayMate Display Optimization Technology

All Tablet and Smartphone displays can be significantly improved using DisplayMate’s advanced scientific analysis and mathematical display modeling and optimization of the display hardware, factory calibration, and driver parameters. We can improve the performance of any specified set of display parameters. This article is a lite version of our intensive scientific analysis – before the benefits of our DisplayMate Display Optimization Technology, which can correct or improve all of these issues. If you are a display or product manufacturer and want to significantly improve display performance for a competitive advantage then Contact DisplayMate Technologies.

 

To Scale

 

iPad 2

new iPad

iPhone 4

 

 

 

Display Shoot-Out Comparison Table

Below we compare the displays on the iPad 2, new iPad, and iPhone 4 based on objective measurement data and criteria. For additional background, context, and information see the Tablet Display Technology Shoot-Out article that compares the larger Motorola Xoom, Asus Transformer, Acer Iconia A500, and Samsung Galaxy Tab 10.1 Tablets with the Apple iPad 2, and the IPS Tablet Display Technology Shoot-Out that compares the Amazon Kindle Fire, Barnes & Noble Nook Tablet with the iPad 2.

 

Categories

Apple

iPad 2

Apple

new iPad

Apple

iPhone 4

Comments

Display Technology

9.7 inch IPS LCD

Amorphous Silicon

9.7 inch IPS LCD

Amorphous Silicon

3.5 inch IPS LCD

Low Temperature

Poly Silicon

Liquid Crystal Display

In Plane Switching

Screen Shape

4:3  =  1.33

Aspect Ratio

4:3  =  1.33

Aspect Ratio

3:2 = 1.50

Aspect Ratio

The iPad screen has the same shape as 8.5x11 paper.

Display Resolution

1024 x 768 pixels

2048 x 1536 pixels

960 x 640 pixels

The more Pixels and Sub-Pixels the better.

Typical Viewing Distance

15 to 18 inches

15 to 18 inches

12 to 15 inches

Typical Ranges for Normal Viewing

Pixels Per Inch

132 ppi

Noticeably Less Sharp

264 ppi

Excellent

326 ppi

Excellent

At 12 inches from the screen 20/20 vision is 286 ppi.

Best human vision is about 20/10 vision or 573 ppi.

See this on the visual acuity for a true Retina Display

Retina Display at Viewing Distance

No

Yes

Exceeds 240 PPI

at Viewing Distance

Yes

Exceeds 300 PPI

at Viewing Distance

300 PPI for the iPhone 4 is Apple’s own definition

of a Retina Display at its Viewing Distance..

On-Screen Displayed Color Depth

Full 24-bit color

256 Intensity Levels

Full 24-bit color

256 Intensity Levels

Full 24-bit color

256 Intensity Levels

24-bit displays produce images with relatively

smooth and artifact free colors and intensities.

Gallery / Photo Viewer Color Depth

Full 24-bit color

256 Intensity Levels

Very Good Calibration

Full 24-bit color

256 Intensity Levels

Very Good Calibration

Full 24-bit color

256 Intensity Levels

Very Good Calibration

Most Android Tablets and Smartphones still have

only 16-bit color depth in the Gallery Photo Viewer.

 

iPad 2

new iPad

iPhone 4

 

 

Overall Assessments

This section summarizes the results of all of the extensive Lab measurements and viewing tests performed on all of the displays.

 

Viewing Tests

Good Images

Photos and Videos

have too little color

and too much contrast

 

Small Color Shifts

with Viewing Angle

Very Good Images

Photos and Videos

have accurate color

and accurate contrast

 

Small Color Shifts

with Viewing Angle

Good Images

Photos and Videos

have too little color

and too much contrast

 

Small Color Shifts

with Viewing Angle

The Viewing Tests examined the accuracy of

photographic images by comparing the displays

to a calibrated studio monitor and HDTV.

Overall Display Assessment

Lab Tests and Viewing Tests

Very Good Display

For Second Generation

Excellent Display

Excellent Display

The iPad 2 was a Very Good Display for its time.

Current Overall Display Grade

B

A

A–

The new iPad is decisively better than the competition

but not close to A+ as discussed in the Conclusion.

 

iPad 2

new iPad

iPhone 4

 

 

 

 

Screen Reflections

Figure 1.  Screen Reflection Photos

Click to Enlarge

All of these screens are large mirrors good enough to use for personal grooming – but it’s actually a very bad feature…

We measured the light reflected from all directions and also direct mirror (specular) reflections, which are much more

distracting and cause more eye strain. The 10 – 15 percent reflections can make the screen much harder to read even

in moderate ambient light levels, requiring ever higher brightness settings that waste precious battery power. Hopefully

manufacturers will reduce the mirror reflections with anti-reflection coatings and haze surface finishes.

Average Screen Reflection

Light From All Directions

8.7 percent

Good

Reflects 7.7 percent

Very Good

Reflects 7.0 percent

Very Good

Measured using an Integrating Hemisphere.

The best value we have measured is 4.4 percent

and the current worst is 14.8 percent.

Mirror Reflections

Percentage of Light Reflected

10.8 percent

Poor

9.9 percent

Good

8.1 percent

Good

These are the most annoying types of reflections.

Measured using a narrow collimated pencil beam of

light reflected off the screen.

 

iPad 2

new iPad

iPhone 4

 

 

Brightness and Contrast

The Contrast Ratio is the specification that gets the most attention, but it only applies for low ambient light, which is seldom

the case for mobile displays. Much more important is the Contrast Rating, which indicates how easy it is to read the screen

under high ambient lighting and depends on both the Maximum Brightness and the Screen Reflectance.

Measured Maximum Brightness

is the Peak Luminance for White

Brightness 410 cd/m2

Very Good

Brightness 421 cd/m2

Very Good

Brightness 541 cd/m2

Excellent

Maximum Brightness is very important for mobile

because of the typically high ambient light levels.

Black Level

at Maximum Brightness

Black is 0.43 cd/m2

Very Good for Mobile

Black is 0.48 cd/m2

Very Good for Mobile

Black 0.48 cd/m2

Very Good for Mobile

Black brightness is important for low ambient light,

which is seldom the case for mobile devices.

Contrast Ratio

Relevant for Low Ambient Light

962

Very Good for Mobile

877

Very Good for Mobile

1,117

Very Good for Mobile

Only relevant for low ambient light,

which is seldom the case for mobile devices.

Defined as Maximum Brightness / Black Brightness.

Contrast Rating

for High Ambient Light

47

Good

55

Good

77

Very Good

Defined as Maximum Brightness / Average Reflectance.

Screen Readability in Bright Light

Good    B

Good    B+

Very Good    A

Indicates how easy it is to read the screen

under high ambient lighting. Very Important!

See High Ambient Light Screen Shots

 

iPad 2

new iPad

iPhone 4

 

 

 

Figure 2.  Color Gamuts

Click to Enlarge

Figure 3.  Intensity Scales

Click to Enlarge

Figure 4.  Screen Shots

Click to Enlarge

Colors and Intensities    

 

 

 

 

 

 

 

The Color Gamut, Intensity Scale, and White Point determine the quality and accuracy of all displayed images and all

the image colors. Bigger is definitely Not Better because the display needs to match all the standards that were used

when the content was produced. For LCDs a wider Color Gamut reduces the power efficiency and the Intensity Scale

affects both image brightness and color mixture accuracy.

White Color Temperature

6,991 degrees Kelvin

Slightly Too Blue

7,085 degrees Kelvin

Slightly Too Blue

7,781 degrees Kelvin

Somewhat Too Blue

D6500 is the standard color of White for most content

and necessary for accurate color reproduction.

Color Gamut

See Figure 2

Color Gamut Too Small

61 percent of Std

See Figure 2

Excellent

99 percent of Std

See Figure 2

Gamut Too Small

64 percent

See Figure 2

sRGB / Rec.709 is the color standard for most

content and needed for accurate color reproduction.

Note that Too Large a Color Gamut is visually

worse than Too Small.

Dynamic Contrast  or Backlight

No

Excellent

No

Excellent

No

Excellent

Many manufacturers manipulate the Intensity Scale

and Backlight based on image content. That results

in inaccurate colors and images.

Intensity Scale and Image Contrast

See Figure 3

Very Smooth But

Contrast Too High

Very Smooth

Contrast is Perfect

Very Smooth But

Contrast Too High

The Intensity Scale controls image contrast needed

for accurate image reproduction. See Figure 3

Gamma for the Intensity Scale

Larger means more Image Contrast

See Figure 3

Good 2.66

Gamma Too High

Outstanding  2.20

Gamma is Perfect

Good 2.68

Gamma Too High

Gamma is the slope of the Intensity Scale.

Gamma of 2.2 is the standard and needed for

accurate image reproduction. See Figure 3

 

iPad 2

new iPad

iPhone 4

 

 

Viewing Angles

The variation of Brightness, Contrast, and Color with viewing angle is especially important for Tablets because of

their large screen and multiple viewers. The typical manufacturer 176+ degree specification for LCD Viewing Angle

is nonsense because that is where the Contrast Ratio falls to a miniscule 10. For most LCDs there are substantial

degradations at less than ±30 degrees, which is not an atypical viewing angle for Tablets

Brightness Decrease

at a 30 degree Viewing Angle

58 percent Decrease

Falls to 171 cd/m2

 

Very Large Decrease

57 percent Decrease

Falls to 182 cd/m2

 

Very Large Decrease

57 percent decrease

to 235 cd/m2

 

Very Large Decrease

Screens become less bright when tilted.

 

LCD brightness variation is generally very large.

Contrast Ratio

at a 30 degree Viewing Angle

564

Very Good for Mobile

526

Very Good for Mobile

556

Very Good for Mobile

A measure of screen readability when the screen

is tilted under low ambient lighting.

Primary Color Shifts

at a 30 degree Viewing Angle

Small Color Shift

Δ(u’v’) = 0.0100

2.5 times JNCD

Small Color Shift

Δ(u’v’) = 0.0046

1.2 times JNCD

Small Color Shift

Δ(u’v’) = 0.0096

2.4 times JNCD

JNCD is a Just Noticeable Color Difference.

IPS LCDs have smaller color shifts with angle.

Color Shifts for Color Mixtures

at a 30 degree Viewing Angle

Reference Brown (255, 128, 0)

Small Color Shift

Δ(u’v’) = 0.0047

1.2 times JNCD

Small Color Shift

Δ(u’v’) = 0.0073

1.8 times JNCD

Small Color Shift

Δ(u’v’) = 0.0097

2.4 times JNCD

JNCD is a Just Noticeable Color Difference.

 

Reference Brown is a good indicator of color shifts

with angle because of unequal drive levels and

roughly equal luminance contributions from

Red and Green.

 

Color Shifts for non-IPS displays are about 10 JNCD.

 

iPad 2

new iPad

iPhone 4

 

 

Display Backlight Power Consumption

Figure 5.  LED Backlight Spectrum

Click to Enlarge

  

The Display Backlight power does not include the power used by the LCD itself or by the display electronics.

Since the displays have different screen sizes and maximum brightness, the values were also scaled to the

same screen brightness (Luminance) and screen area in order to compare their relative power efficiencies.

The new iPad uses 2.5 times the Backlight power of the iPad 2 for the same screen brightness.

The highest ppi iPhone 4 is the most efficient of all because it uses Low Temperature Poly Silicon LTPS (see above).

Display Backlight Power

at Maximum Brightness

2.7 watts

7.0 watts

0.42 watts

Lower power consumption is important for energy

efficiency and improving running time on battery.

Display Backlight Power Efficiency

same Peak Luminance 421 cd/m2

same 9.7 inch screen size area

2.8 watts

7.0 watts

2.6 watts

This compares the Relative Power Efficiency

by looking at the same screen brightness and

screen area.

 

iPad 2

new iPad

iPhone 4

 

 

Running Time on Battery

The running time on battery was determined with the Brightness sliders at the Maximum and Middle (center) settings,

in Airplane Mode, with no running applications, and with Auto Brightness turned off. Note that the batteries do not

actually reach full charge when 100% is shown and need up to an extra hour before the charging actually stops.

Note that Auto Brightness can have a considerable impact on running time but we found abysmal performance for

both the iPhone and Android Smartphones in our BrightnessGate analysis of Ambient Light Sensors and Automatic

Brightness. They all need a more convenient Manual Brightness Control as described in the BrightnessGate article.

Running Time

At the Maximum Brightness Setting

7.2 hours

5.8 hours

7.8 hours

Display always On at the Maximum setting with

Airplane Mode and no running applications.

Running Time

At the Middle Brightness Setting

11.8 hours

11.6 hours

12.2 hours

Display always On at the Middle slider setting with

Airplane Mode and no running applications.

Categories

iPad 2

new iPad

iPhone 4

Comments

 

 

Battery Charging and Running Time Issues

The outstanding very high performance Retina Display on the new iPad requires a lot more power than the iPad 2 because it is pushing the upper limits of amorphous Silicon LCD technology. In fact, it has a rather large 42.5 watt hour battery that is 70 percent larger than the battery on the iPad 2. Because of both power and heat limitations the monstrous battery takes a lot longer to charge, and if you don’t fully charge it you will get shorter running times. Below we explain these issues, measure the actual battery charging and running time performance, and also discuss Apple’s shocking comment that the extended charging time could “harm the longevity of the battery.”

 

Recharging the new iPad battery

It takes a relatively long time to recharge the massive battery in the new iPad – over 5˝ hours when it is fully discharged. That’s only if the new iPad is off or in sleep mode – if you try recharging while using the new iPad I estimate that it will take about 20 hours if the display is set to Maximum Brightness. But when is the battery fully charged?

 

While preparing to measure the battery running time to evaluate the Retina Display’s load on the iPad battery I noticed that the power meter indicated that the iPad AC charger was still continuing to deliver close to the full 10 watt recharging power long after the screen indicator showed that the battery was 100% charged – the additional time is slightly over 1 hour if the new iPad is off or in sleep mode, and slightly over 2 hours if it is on. Since I wanted to measure the proper maximum running time for a fully charged battery I waited until the recharging power dropped, indicating that the battery was actually full and the charging cycle was completed.

 

But if you stop charging the iPad when the battery indicator says 100% you won’t get the maximum running time – something that is very important to many people. Let’s see how much less…

 

new iPad running time based on a fully charged battery is 11.6 hours

Starting with a truly fully charged battery as described above, the battery running time for the new iPad at the Middle Brightness Slider setting is 11.6 hours. That is in Airplane Mode with no WiFi, with no activity or running Apps of any sort, and with Auto Brightness Off – the same running conditions specified on the Apple website. Note that you’ll get only about half that running time at the Maximum Brightness Slider setting, but it delivers 2.8 times the Brightness (Luminance) of the Middle Brightness Slider setting – see the Running Time on Battery measurement results above.

 

new iPad running time based on the 100% battery indicator is 10.4 hours

If you stop charging the iPad when the battery indicator says 100% you won’t get the maximum running time – something that is very important to many people. I repeated the Battery Running Time measurements exactly as above, but stopped the battery charging when the battery indicator reached 100%. For the new iPad at the Middle Brightness Slider setting the Running Time decreased by 1.2 hours to 10.4 hours (10 percent). While at first sight this appears consistent with Apple’s own “up to 10 hours running time” my tests were in Airplane Mode with no WiFi and no activity or running Apps of any sort – just a static display. The 11.6 hour running time above for a fully charged battery would most likely deliver a real use running time of over 10 hours as indicated by Apple, but the 10.4 hour time would most likely not.

 

What’s the matter with the battery indicator?

The battery charge indicator on all mobile devices is based on a mathematical model of the charge rates, discharge rates, and recent discharge history of the battery. It uses this information to estimate how much running time is left. It's actually rather difficult to do because most batteries degrade slowly as they discharge and then tend to surprise with a precipitous decline near the end. Note that batteries are based on complex chemistry so there is no practical way to measure the charge level “in hardware.” So there is something wrong with the battery charge mathematical model on the iPad. It should not say 100% until it actually stops recharging and goes from the full recharging rate of about 10 watts to a trickle charging rate of about 1 watt. Otherwise the user will not get the maximum running time that the iPad is capable of delivering.

 

Conclusion – the battery is only 90% charged when it says 100%

So, when the battery indicator first says 100% the battery is actually only 90% charged and you get 1.2 hours less running time. It takes an additional 1 to 2 hours to fully charge the battery as explained above. However, anyone that recharges their iPad unattended (and off or in sleep mode), especially overnight, will get the necessary extra charging time and get the full running time indicated above.

 

Apple has subsequently released a statement saying that this is by design and as they intended. Maybe so, but why? ALL of our results are technically correct EXACTLY as stated above. So what’s the REAL reason – it isn’t the one mentioned in Apple’s statement. The battery charging rate gets slower and slower as it approaches full charge, so Apple decided to show 100% sooner so that people didn’t notice or get annoyed by the long and slow final creep up to the true 100% charge level. The last hour in the long 6˝ charging cycle is painfully slow, so that becomes invisible if the battery indicator is accelerated up to 100% for that final hour. It’s all done to improve the quality of the user experience...

 

Could the new iPad be damaging its own battery?

Apple’s most recent statement also corrects their earlier unfortunate and incorrect remark that keeping the battery charging after the battery indicator reaches 100% could damage the battery. I am keeping this section intact for the record because of the incredible firestorm that ensued.

 

While my interpretation is that this is just simply an issue of correcting the on-screen battery indicator so that it matches and agrees with what the battery charging hardware and software actually do, Apple PR originally put forth a rather shocking reverse perspective that the on-screen battery indicator is instead the correct one. As reported by Jon Fortt of CNBC: "Apple is saying... if you charge it more than [when the battery indicator reads 100%], you could actually harm the longevity of the battery." This statement was made by an official Apple PR representative directly to Jon Fortt. How do I know this? Because Jon Fortt called me immediately after he spoke to Apple PR and we discussed Apple’s statement together. As I indicate below, it is my feeling that this was a misguided off-the-cuff remark by an Apple representative to make everything sound just fine, but they really didn’t know or understand the repercussions of what they were saying. But if we take their statement at face value, it unfortunately implies that the new iPad is damaging its own battery. I logically explore the repercussions of this remark next.

 

If the Apple PR remark made to Jon Fortt of CNBC was in fact correct –  then damaging the longevity of the battery is exactly what the new iPad’s internal battery charging hardware and software are doing since it is their responsibility to properly control and manage the battery recharging process. It’s pretty obvious that if the new iPad knows that it is fully charged then it should automatically stop the charging! So according to Apple PR the new iPad is then configured to damage the longevity of its own battery if it isn’t manually disconnected from the AC charger when the 100% indicator appears. Anyone that recharges their iPad unattended, especially overnight, would then be doing this.

 

While Apple’s remark might apply to recharging dumb battery operated toys, the new iPad is a very sophisticated and expensive computer device that is fully capable of properly controlling and managing its own (rudimentary) battery charging process. Perhaps Apple should instead retract the remark and graciously accept my interpretation and rescind their own remarks, which sound like very poorly thought out PR damage control. On the other hand, if the Apple PR remark is correct, then Apple needs to immediately fix the iPad battery charging algorithm or they may be held responsible for replacing all iPad batteries. Which one will it be?

 

Apple’s most recent statement corrects their earlier unfortunate and incorrect remark. It’s perfectly fine to leave the battery charging all day or all night. As Gilda Radner of Saturday Night Live used to say… Never Mind!

 

A Reminder – the new iPad Retina Display is Impressive

While the battery charging issue has taken on a life of its own, the true subject of this article is the new iPad’s outstanding Retina Display. To read about that start at the Introduction, the Highlights, or the Conclusion.

 

 

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 proprietary sophisticated scientific display calibration and mathematical display optimization to deliver unsurpassed objective performance, picture quality and accuracy for all types of displays including video and computer monitors, projectors, HDTVs, mobile displays such as smartphones and tablets, and all display technologies including LCD, OLED, 3D, LED, LCoS, Plasma, DLP and CRT. This article is a lite version of our intensive scientific analysis of Tablet and Smartphone mobile displays – before the benefits of our advanced mathematical DisplayMate Display Optimization Technology, which can correct or improve many of the display deficiencies. We offer DisplayMate display calibration software for consumers and advanced DisplayMate display diagnostic and calibration software for technicians and test labs.

 

For manufacturers we offer Consulting Services that include advanced Lab testing and evaluations, confidential Shoot-Outs with competing products, calibration and optimization for displays, cameras and their User Interface, plus on-site and factory visits. See our world renown Display Technology Shoot-Out public article series for an introduction and preview. DisplayMate’s 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 to turn your display into a spectacular one to surpass your competition then Contact DisplayMate Technologies to learn more.

 

Article Links:  10 Inch Tablet Display Technology Shoot-Out

Article Links:  IPS Tablet Display Technology Shoot-Out

 

Article Links:  Smartphone "Super" LCD-OLED Display Technology Shoot-Out

Article Links:  Tablet Displays Under High Ambient Lighting Shoot-Out

Article Links:  Automatic Brightness Controls and Light Sensors

 

Article Links:  Mobile Display Shoot-Out Article Series Overview and Home Page

Article Links:  Display Technology Shoot-Out Article Series Overview and Home Page

 

 

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