Intel demonstrates ray tracing on ultra-mobile PCs
Subject: Graphics Cards | February 26, 2008 - 04:08 PM | Ryan Shrout
As frequent readers of PC Perspective know, we have been very interested in the work of on Daniel Pohl, now an employee at Intel, that developed some of the first modern ray tracing gaming engines. Daniel has written a couple of articles here on PC Perspective on the subject including Ray Tracing and Gaming - Quake 4: Ray Traced Project and Ray Tracing and Gaming - One Year Later. I have also covered a lot of the technology behind ray tracing such as the Terascale processing cores that will probably power it in the future and the first real-time showcase of ray tracing by Intel at IDF 2007.
One of the interesting points in that last article was on the premise of how ray tracing can scale with hardware very easily and thus allow ray tracing engines to run on the high-end PCs as well as hand held systems. At GDC last week Daniel showed off a version of the Quake 4 Ray Traced engine running on a 1.2 GHz single-core ultra-low power processor in a Sony VAIO micro-PC with a 512x256 resolution screen. The engine scales very well on this slower platform simply because the resolution deems there to be much less work for the processor to handle:
from the pixels on the screen, to the surfaces of objects in view. And
in the case of a UMPC, when one is viewing 3D space from the viewable
area of a 4.5” LCD screen, fewer rays are required, and hence, the CPU
requirements are substantially less. For example, you might prefer
viewing a high definition (1280x720 resolution) display on your PC, but
with the much smaller viewable area on a Sony* VAIO* UX Micro PC,
smaller resolutions may be quite acceptable (such as 480x272, for
example). Using this lower resolution, it would only require 8% of the
CPU requirements that had been needed to render in high definition."
The demo was running at 25-45 frames per second and was basically in the same detail level as the full screen demo shown last year.
Image courtesy Intel
the technology still needs to develop to the point where we can run
multiple rays per pixel within a sensible compute budget, because that
will allow us to add the kinds of lighting effects, per-pixel correct
shadows and reflections, and complex geometry that gamers expect in
leading edge games."
Intel claims that Moore's law will help them, as you would expect, giving more power and more cores to even the lowest power form factor. Since processing power continues to increase at a much higher rate that screen resolutions, the capability to ray trace on nearly any size screen should be a reality in the not-too-distant future.
The real strength with this demo at the Game Developer's Conference, as Intel sees it, is that games can be created and easily transported from form factor to form factor by utilizing the scaling ability of ray tracing:
to deliver more content in less time, because when you render things in
a physically correct environment, you can achieve high levels of
quality very quickly, and with an engine that is scalable from the
Ultra-Mobile to the Ultra-Powerful, Ray-Tracing may become a very
popular technology in the upcoming years."
Not everyone we have spoken to in the past few months sees ray tracing in such a positive light over existing rasterization rendering techniques - but we'll have more on that soon enough.
You can read more about Intel's ray tracing work here:
- Ray Tracing and Gaming - One Year Later
- Rendering Games with Raytracing Will Revolutionize Graphics
- Ray Tracing and Gaming - Quake 4: Ray Traced Project
- IDF Fall 2007: Terascale Computing Updates and more
- IDF Fall 2007 Keynote - Penryn, Nehalem, Larrabee
- IDF 2006: Terascale Processing Brings 80 Cores to your Desktop