While this has always been an issue that’s been in the background since Android OEMs started releasing devices with display PPIs above the 300-400 “retina” range, recent events have sparked a broader discussion into the value of pursuing the PPI race that is happening between Android OEMs. Within this discussion, the key points of contention tend to center upon the various tradeoffs from increasing resolution, and whether an increase in pixels per inch (PPI) will actually have a perceivable increase.

If there is any single number that people point to for resolution, it is the 1 arcminute value that Apple uses to indicate a “Retina Display”. This number corresponds to around 300 PPI for a display that is at 10-12 inches from the eye. In other words, this is about 60 pixels per degree (PPD). Pixels per degree is a way accounting for both distance from the display and the resolution of the display, which means that all the information here is not limited to smartphone displays, and applies universally to any type of display. While this is a generally reasonable value to work with, the complexity of the human eye and the brain in regards to image perception makes such a number rather nebulous. For example, human vision systems are able to determine whether two lines are aligned extremely well, with a resolution around two arcseconds. This translates into an effective 1800 PPD. For reference, a 5” display with a 2560x1440 resolution would only have 123 PPD. Further muddying the waters, the theoretical ideal resolution of the eye is somewhere around .4 arcminutes, or 150 PPD. Finally, the minimal separable acuity, or the smallest separation at which two lines can be perceived as two distinct lines, is around .5 arcmin under ideal laboratory conditions, or 120 PPD. While all these values for resolution seem to contradict each other in one way or another, the explanation behind all of this is that the brain is responsible for interpretation of the received image. This means that while the difference in angular size may be far below what is possible to unambiguously interpret by the eye, the brain is able to do a level of interpolation to accurately determine the position of the object in question. This is self-evident, as the brain is constantly processing vision, which is illustrated most strikingly in cases such as using a flashlight to alter the shadowing of blood vessels that are on top of the retina. Such occlusions, along with various types of optical aberration and other defects present in the image formed on the retina are processed away by the brain to present a clean image as the end result.

Snellen chart used to test eyesight. The width of the lines determines the angle subtended.

While all of these resolution values are achievable by human vision, in practice, such values are highly unlikely. The Snellen eye test as seen above, is the well-known chart of various lines of high contrast text with increasingly small size, gives a reasonable value of around 1 arcminute, or 60 PPD for adults, and around .8 arcminutes for children, or 75 PPD. It's also well worth noting that these tests are all conducted under ideal conditions with high contrast, well-lit rooms.

So after going through these possible resolutions, the most reasonable upper bound for human vision is the .5 arcminutes value, as while there is a clear increase in detail going from ~300 PPI to ~400 PPI in mobile displays, it is highly unlikely that any display manufacturer can make a relatively large display with a resolution that corresponds to 1800 PPD at 12 inches away for mass production.  However, for the .5 arcminute value, at a distance 12 inches away from the eye, this would mean a pixel density of around 600 PPI. Of course, there would be no debate if it was that easy to reach an answer. Realistically, humans seem to only be able to have a practical resolution of around .8 to 1 arcminute. So while getting to 600 PPI would mean near zero noticeable pixelation for the vast majority of edge cases, the returns are diminishing after passing the 1 arcminute point. For smartphones around the display size of 4.7 to 5 inches in diagonal length, this effectively frames the argument around the choice of a few reasonable display resolutions with PPI ranging from 300 to 600. For both OLED and LCD displays, pushing higher pixel densities incurs a cost in the form of greater power consumption for a given luminance value. Going from around 330 PPI to 470 PPI for an LCD IPS display incurs around a 20% power draw increase on the display, which can be offset by more efficient SoC, larger batteries, improved RF subsystem power draw. Such power draw increases can also be offset by improvements in the panel technology used, which has consistently been the case with Samsung’s OLED development but regardless of these improvements, it is an increase to power draw compared to an equivalent technology display with lower pixel density. In the case of LCD displays, a stronger backlight must be used as the higher pixel density means the transistors around the liquid crystal become a larger proportion of the display, and the same is also true of OLED panels, but instead the issue becomes that smaller portions of organic phosphors on the display have to be driven at higher voltages in order to maintain the same level of luminance. An example of this can be seen below with the photo of the LCD display with its transistors, with the second showing a front-lit shot to illuminate the TFTs.

Example photo of the TFTs in a display, contrasted with the luminous area

Thus, there are multiple sets of tradeoffs that come with increased resolution. While getting closer to the 0.5 arcminute value means getting closer to nearly unperceivable pixels, there is a loss in power efficiency, and on the same note, a loss in peak luminance for a given level of power consumption which implies reduced outdoor visibility if an OEM artificially clamps the upper bound of display brightness. With the focus on resolution, it also means that the increased cost associated with producing higher resolution displays may be offset elsewhere as it’s much harder to market lower reflectance, higher color accuracy, and other aspects of display performance that require a more nuanced understanding of the underlying technology. Higher resolution also means a greater processing load to the SoC, and as a result, UI fluidity can be greatly affected by an insufficient GPU, and a greater need to leverage the GPU for drawing operations can also reduce battery life in the long run.

Of course, reaching 120 PPD may be completely doable with little sacrifice in any other aspect of a device, but the closer OEMs get to that value, the less likely it is that anyone will be able to distinguish a change in resolution between a higher pixel density and lower pixel density display, and diminishing returns definitely set in after the 60 PPD point. The real question is what point between 60 and 120 PPD is the right place to stop. Current 1080p smartphones are at the 90-100 PPD mark, and it seems likely that staying at that mark could be the right compromise to make.

An example of a display with RGB stripe, 468 PPI.

But all of this assumes that the display uses an RGB stripe as seen above, and with Samsung’s various subpixel layouts used to deal with the idiosyncrasies of the organic phosphors such as uneven aging of the different red, green and blue subpixels, as blue ages the fastest, followed by green and red. This is most obvious on well-used demo units, as the extensive runtime can show how white point drops dramatically if the display is used for the equivalent of the service lifetime of the smartphone. For an RGBG pixel layout as seen below, this means that a theoretical display of 2560x1440 resolution with a diagonal length of 5 inches would only give 415.4 SPPI for the red and blue subpixels, and only green subpixels would actually have the 587 SPPI value. While the higher number of green subpixels is a way of hiding the lower resolution due to the human eye’s greater sensitivity to wavelengths that correspond to a green color, it is without question that it is still possible to notice the different subpixel pattern, and the edge of high contrast detail is often where such issues are most visible. Therefore, in order to reach the 587 SPPI mark for the red and blue subpixels, a resolution of around 3616x2034 would be needed to actually get to the level of acuity required. This would mean a PPI of 881. Clearly, at such great resolutions, achieving the necessary SPPI with RGBG pixel layouts would effectively be untenable with any SoC that should be launching in 2014, possibly even 2015.

Example of a non-RGB layout. Note the larger area blue pixels due to their square shape.

While going as far as possible in PPD makes sense for applications where power is no object, the mobile space is strongly driven by power efficiency and a need to balance both performance and power efficiency, and when display is the single largest consumer of battery in any smartphone, it seems to be the most obvious place to focus on for battery life gains. While 1440p will undoubtedly make sense for certain cases, it seems hard to justify such a high resolution within the confines of a phone, and that’s before 4K displays come into the equation. While no one can really say that reaching 600 PPI is purely for the sake of marketing, going any further is almost guaranteed to be for marketing purposes.

Source: Capability of the Human Visual System

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  • willis936 - Sunday, February 9, 2014 - link

    While it's pointless to source higher than 44kHz it's important to appreciate the merits of upsampling during playback. Some receiver DACs do it on their own but most on board codecs in the past two years support 24 bit 192kHz. It does a more accurate interpolation before running it through the DAC and generally results in lower THD. You can go one step farther and do the upsampling in software with hefty algorithms like sinc in programs that support it. Two common ones that come to mind are foobar and mpc-hc. Granted doing it in software probably doesn't buy you much but I can't hear the difference and I don't have the equipment to test it either way.
  • extide - Sunday, February 9, 2014 - link

    For the most accurate* sound, you do NOT want to upsample.

    *Accurate meaning as close to the way it is supposed to be; or as close as possible to the artists intention.
  • fokka - Sunday, February 9, 2014 - link

    you are right and although you probably already know, what i've heard is that higher sampling rates are primarily used in production, so that after mixing and adding effects and distorting it an whatnot you still have a relatively "clean" signal you can just downsample to eg. 44.1khz and sell this way.

    even funnier is an article i read once on some site, where some alledged music professional physically explained why 192khz can even sound worse than your good ol' cd. but i guess we're getting ot ;)
  • speculatrix - Friday, February 14, 2014 - link

    not wanting to add to the o.t. conversation, but the filters required for using the Nyquist limit on lowest sample rate can be pretty harsh, and add to phase distortion too (even though the human ear isn't particularly sensitive to phase).. so sampling at a much higher rate with more bits makes the signal processing much easier so as to allow you to reproduce the original signal when fed through your DAC & final stage analogue filters.
  • speculatrix - Friday, February 14, 2014 - link

    p.s. my point is that you only want to accurately reproduce the 10Hz-20kHz spectrum, and drop everything that's not actually audible, but do it in a way that prevents aliassing and distortion, intermod etc.
  • errorr - Sunday, February 9, 2014 - link

    The problem is that human eyesight can exceed the theoretical physical limits through interpolation. It isn't as much as meeting the needs of the actual eye but the brain which has evolved the "software" to exceed the theoretical limits of the eye.
  • janderk - Sunday, February 9, 2014 - link

    What surprises me is that the assumption that a phone is always at 12 inches or 30cm, is accepted without any criticism. There are multiple reasons why printers go way beyond 300dpi. One of they is that paper is not always at 30cm distance.

    Forget phones and go back 10 years. When looking at a high quality print or photo on paper there was a very efficient way to zoom in: you bring the print closer to your eyes, like 10cm. It is quite a lot more efficient than pinching on a screen. And suddenly 1200dpi makes a lot of sense.

    Nobody with a low-res phone (say 300dpi or less) thinks of bringing a phone closer to zoom, because it is no use at all. But with high-dpi screens things look a lot clearer in close up.
  • haikuginger - Sunday, February 9, 2014 - link

    "There are multiple reasons why printers go way beyond 300dpi."

    Actually, professional-grade photo printing sits right at 300dpi.
  • Nick2000 - Sunday, February 9, 2014 - link

    Yes but they are only photos. They do not generaly need high resolution. It also depends on the technology. Actual chemical photo paper (developed, not printed) combines the dots in a different way than inkjet or laser printers. I work with high resolution printers and while most "pictures" come in at a relatively low resolution (200 or 300dpi) we print them at 1200x1200 because it makes the single pixels less visible when dithering. Also, diagonal lines really do not look great on a photo so that is out for precise maps for example... Anyway, there are a lot of factors to take into account past simply source resolution.
  • andy o - Sunday, February 9, 2014 - link

    The "dpi" or ppi in a digital picture is meaningless. "per inch" means something only in the context of physical size. In a digital picture it's just metadata that will tell layout programs at what size the picture should be laid out on the page. You can change these values without even touching the digital picture, it will be exactly the same. The DPI in printers' specs are the physical ink dots the printer will lay out in the paper. They're different things.

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