GPUs Keep Getting Faster, But Your Eyes Can't Tell

itwbennett writes "This brings to mind an earlier Slashdot discussion about whether we've hit the limit on screen resolution improvements on handheld devices. But this time, the question revolves around ever-faster graphics processing units (GPUs) and the resolution limits of desktop monitors. ITworld's Andy Patrizio frames the problem like this: 'Desktop monitors (I'm not talking laptops except for the high-end laptops) tend to vary in size from 20 to 24 inches for mainstream/standard monitors, and 27 to 30 inches for the high end. One thing they all have in common is the resolution. They have pretty much standardized on 1920x1080. That's because 1920x1080 is the resolution for HDTV, and it fits 20 to 24-inch monitors well. Here's the thing: at that resolution, these new GPUs are so powerful you get no major, appreciable gain over the older generation.' Or as Chris Angelini, editorial director for Tom's Hardware Guide, put it, 'The current high-end of GPUs gives you as much as you'd need for an enjoyable experience. Beyond that and it's not like you will get nothing, it's just that you will notice less benefit.'"

Lets not forget

[geekoid]

they need to handle more stuff happening on the screen.

Re:Lets not forget

[infogulch]

Exactly, the games themselves have been pared down to fewer objects because our older cards couldn't handle it. Now there are new cards and people expect games that can use that horsepower to be available instantly? Sounds unreasonable to me.

When your graphics card can handle 3x 4K monitors at 120Hz and 3D while playing a game with fully destructible and interactable environments (not this weak-ass pre-scripted 'destruction' they're hyping in BF4 & Ghosts) the size of new york city without breaking a sweat, the bank, or the power bill, THEN you can talk about the overabundance of gpu horsepower.

Err, wha?

One thing they all have in common is the resolution.

So 2560x1440 and 2560x1600 27"s only exist in my imagination?

Your eyes...

[blahplusplus]

... can certainly tell. The more onscreen objects there are the more slowdown there is. This is why I like sites like HardOCP that look at MIN and MAX framerates during a gameplay session. No one cares that a basic non-interactive timedemo gets 100's of frames a second, they are concerned with the framerate floor during actually playing the game.

Re:Your eyes...

[MatthiasF]

And don't forget about refresh rates. A 60hz refresh rate might be the standard but motion looks a lot better at 120 hz on better monitors.

Higher refresh requires more powerful GPU, no matter the resolution.

Re:Your eyes...

[faffod]

In your scenario the action started at exactly the same time. Then things diverge. The game state changing and reacting is driven by the game refresh rate (which may be independent of the video refresh rate). The latency between the game state change and the visual feedback is directly linked to the video refresh rate.
As an example if you have the same game running on two machines, one at 60Hz and the other at 1Hz. In both cases you press the button at exactly the same time. The game update will process that button press and start a muzzle flash, that took some period of time that we will assume is equal for both machines (i.e. I won't make the slow rendering machine also have a slow game update, even if typicaly the two are tightly coupled). So 1/nth of a second after the button press both machines are ready to show the muzzle flash. On the first machine you will see the muzzle flash 16.6 milliseconds later. On the 1Hz machine the muzzle flash will appear 1 second later.

Now, my example is a bit extreme (to make it obvious that there is a difference. Do not think that this is irrelevant in real word cases. I worked on one of the first fps games to win awards for jump puzzles that were not atrocious. Early on we spent a lot of time testing the game at 30Hz and at 60Hz. If we ran the game at 30 we could effectively double the quality of the graphics, which the art team obviously wanted so that they could do even greater stuff. But after blind testing we found that everyone noticed "something" was better about the game that ran at 60Hz. Reducing the latency between the button press and the jump allowed players to gage the jump point more accurately. Reducing the latency of the joystick movements allowed the player to guide their landings more accurately.

One final note, maintaining a consistent frame rate is even more critical, players have to know that when the press "x" they will get the same result.

Totally wrong

[brennz]

In cutting edge games, FPS still suffers even at low resolutions.

Many users are going to multi-monitor setups to increase their visualization and even cutting edge graphics cards cannot handle gaming at 1920x1080 x 3 display setups on taxing games or applications (e.g. Crysis).

Seriously?

[fragfoo]

For games, GPU's have to process 3D geometry, light, shadows, etc. Number of pixels is not the only factor. This is so lame.

Assumptions

[RogWilco]

That statement makes the rash assumption that GPUs will somehow continue to grow in speed and complexity while everything around them remains static. What about stereoscopic displays which would double the required number of pixels to be rendered for the equivalent of a 2d image? What about HMDs like the forthcoming Oculus Rift, which over time will need to continue pushing the boundaries of higher resolution displays? Who on earth is thinking that the display industry is thinking "whelp, that's it! we've hit 1080p! we can all go home now, there's nothing left to do!" ? 1080p on a 24 inch display is nowhere close to the maximum PPI we can perceive at a normal desktop viewing distance, why is that the boundary? Why are 24" displays the end? Yes, improving technology has diminishing returns. That's nothing groundbreaking, and using that to somehow suggest that we have peaked in terms of usable GPU performance is just downright silly.

Re:Now

[afidel]

They are, you can get very playable framerates @1080p using a nearly passively cooled card (the next shrink will probably make it possible using a completely passive card). Hell, my new gaming rig draws under 100W while playing most games, my previous rig used over 100W just for the graphics card.

Re:There are other applications

[exomondo]

These are often marketed as GPGPU products, nVidia's Tesla for example, rather than taking a bunch of Geforces and putting them together.

Re:There are other applications

Aren't there are other areas of science that a faster GPU benefits namely structural biology and the modeling proteins?

Even ignoring that, the guy is a fucking idiot.
He seems to be confused about the function of a GPU- they are doing far more than simply pushing pixels onto the screen. Wake up buddy, this isn't a VGA card from the 90's. A modern GPU is doing a holy shitload of processing and post-processing on the rendered scene before it ever gets around to showing the results to the user. Seriously man, there's a reason why our games don't look as awesomely smooth and detailed and complex as a big budget animated film- it's because in order to get that level of detail, yes on that SAME resolution display, you need a farm of servers crunching the scene data for hours, days, etc. Until I can get that level of quality out of my desktop GPU, there will always be room for VERY noticeable performance improvement.

Re:There are other applications

[Score+Whore]

Not to mention that the world hasn't standardized on 1920x1080. I've got half a dozen computers / tablets and the only one that is 1080p is the Surface Pro. The MacBook Pro with Retina Display is 2880x1880. Both of my 27" monitors are 2560x1440. I don't have any idea what this dipshit is thinking, but his assumptions are completely wrong.

Re:There are other applications

[TechyImmigrant]

I wouldn't let a 1920x1080 monitor grace my cheap Ikea desk.

Re:Author's poor interpretation of performance

[Anaerin]

And it depends on what part of the eye you're talking about. The Rods (The detail-oriented parts of the eye) see at around 30Hz. The Cones (The black-and-white but higher light sensitivity and faster responding parts) see at around 70Hz. This is why CRT monitors were recommended to be set at 72Hz or higher to avoid eyestrain - at 60Hz the Rods couldn't see the flickering of the display, but the Cones could, and the disparity caused headaches (You could also see the effect if you looked at a 60Hz monitor through your peripheral vision - it appears to shimmer).

You don't need a GPU.

[rew]

You don't need a GPU at all. A screen is 2Mpixels. Refreshing that about 60 times per second is enough to create the illusion of fluid motion for most humans. So that's only 120Mpixels per second. Any modern CPU can do that!

Why do you have a GPU? Because it's not enough to just refresh the pixels. You need (for some applications, e.g. gaming) complex 3D calculations to determine which pixels go where. And in complex scenes, it is not known in advance what objects will be visible and which ones (or part) will be obscured by other objecs. So instead of doing the complex calculations to determine what part of what object is visible, it has been shown to be faster to just draw all objects, but to check on drawing each pixel which object is closer, the already drawn object or the currently being drawn object.

Re:There are other applications

[lgw]

We only get good enough framerate at 1920x1200 (the One True Resolution) because of a lot of shortcuts. Improved computing power could allow games to make the transition to better lighting models (whatever they call the new ray0tracing stuff) that are both easier for artists/world builders and look better and more natural. It would also be nice to stop thinking of everything in polygons, but there's so much tooling there beyond the GPU (and if you push the poly-count high enough it doesn't matter visually).

Re:There are other applications

[hairyfeet]

But everyone here is missing the REAL advantagse of new GPUs....power consumption and price. My HD4850 uses over 110w and reaches nearly 190c under load, the HD7770 I'm getting for my BDay? It is nearly 60% faster while uses less than HALF of the power and creating less heat by nearly half. And while my HD4850 new cost nearly $300 the HD7770? Can be had for less than $100.

Now that CPUs have pretty much maxed out the big gains will be in GPUs, both on power and price. Sure the top 'o the line will be a giant wallet raper but those are really ePeens more than anything and the biggest sales will be the $75-$150 range and that is where we are seeing some really sweet cards.

Re:There are other applications

[im_thatoneguy]

I do some work on the side for a hardware raytracing company and you're mostly right. Shameless plug: http://caustic.com./ And speaking as a VFX artist ray tracing is way easier. When you aren't cheating everything it becomes much simpler to get to "realistic". Global Illumination also goes a long way to help. I can take a game asset with textures and geometry and normal maps etc and render it with a raytracing engine and it looks dramatically better.

The problem with current technology is that there is something of a divide in performance. Present ray tracing technology is about 5x too slow to match a good rasterized game. You could deliver 10-20 fps at decent resolution with ray tracing but wouldn't get any noticeable benefit. To really get that silky smooth GI you need another 20-30x faster or so (even with a dedicated ray tracing chip).

The challenge then is to improve ray tracing chips fast enough to catch up to GPUs. I think in 3-4 years you'll see a number of games which deliver exceptional ray traced images. Rivaling film renders in real-time. But 3-4 years in spite of this author's nonsense is a long time in GPU technology. In the last 3-4 years we've seen tessellation, the first instances of GI and dynamic light reflections. These make a huge difference. They're total hacks but game developers can't sit still and as much of a pain as they are--they work. It would be more of a paint to rewrite their engines from scratch to take advantage of a whole new rendering pipeline.

The other challenge is that the reason many films look so good is because of 2D cheats in the composite. If you look at a raw render out of Arnold, Brazil, Renderman or Vray it's not really like what shows up on screen. There is a lot of sweetening, a lot of one-off lighting tricks in post and in the render which only look great from the one angle. Games have to look good from every angle. I don't know that they'll ever achieve that. They'll look more photographic but the ultra polish of a film comes from lighting TDs, cinematographers and compositors all working in tandem to polish a shot for days or weeks. If things just looked good from every direction all the time--the VFX work on a feature film would be dramatically reduced. So in that regard game developers are going to have it way harder than film people. Not only does it have to render at 60 fps... but you can't cheat detail. You have to make it look good from 300 yards as you drive your car down main street... all the way to jumping out and walking up to 2" away and reading the headline.

Re:There are other applications

[Shadow+of+Eternity]

First off you're so wrong it hurts. Until very recently graphical framerates in the average FPS were relatively insulated from "physics framerates", in the days of TFC for example 100fps didn't make your rockets any more accurate because the SERVER calculated its trajectory.

Secondly it's been proven time and time again that humans are perfectly capable of detecting framerates well into the hundreds. Fighter pilots can not only detect a SINGLE frame from somewhere around 1/200th of a second but even tell you what enemy jet it was. Gamers are similar, until consolization forced a lower standard onto everyone and covered it up with a lower FOV filled with massive amounts of bloom and blur performance was judged by the gold standard of a solid 60fps minimum, 30 was choppy and 100 was idea.