Why are those demo's always done so ... well .... shit?
http://www.h265.net/

So that the manufacturers can continue to sell us some 4.2.0 8 bit codec.

@mozes: How could you possibly show that? Of course you could publish the same video encoded in H.264 and H.265, with the file size of the latter being half of the former, and ask people to download your decoder prototype to convince themselves that the quality is actually about the same.

But those not into the details of video encoding would either not bother to do that or doubt that the comparison was fair anyway (because of course, one could have chosen an unfavorable set of parameters for the H.264 version).

And those who are participating in the development of video encoders will probably measure their efficiency by other means than downloading one sample demo video somebody else prepared.

(There is actually a very old standard set of totally boring video clips that have been used as somewhat representative material to prove video encoders on for decades... just like there is that decades old picture of the lady with the large white hat that you can see in hundreds of papers on still image encoding... :-) )

http://en.wikipedia.org/wiki/High_Efficiency_Video_Coding#Coding_tools So, what does it take? 100x the processing power? I guess we won't see this in consumer encoding devices before 2020...

H.265 draft - http://phenix.it-sudparis.eu/jct/doc_end_user/current_document.php?id=6465

Do we still need this to be supported?

Why not?

It is widely used in satellite TV and DVB-C.

"Encoding it is very time-intensive. It takes amazingly long," said Homer Dowlat, a senior staff engineering manager at Qualcomm.

Time will tell, but an assessment like that doesn't sound promising for image capture applications. Lossy encoders achieve high compression ratios by eliminating redundant and imperceptible data. Spending significantly more processing time to eliminate even more image data than H.264 is not going to improve image quality, it will only make file sizes smaller. For real-time image capture, what's needed is a streamlined high-speed encoder rather than one that's even more sluggish and complex than H.264.

H.265 will be more focused on 4K things, I suppose :-)

Usually each resolution bump is accompanied by better compression :-)

4k 4:2:0 would suck...

Not good for caputring input... darn.

h265 will half the file size compared to h264. will this enable 1080p as default vimeo resolution for everybody?

Yep h265 (HEVC High Efficiency Video Coding) will be ratified by January 2013 and implemented in all new Cameras/camcorders/ and of course 4K devices by early 2014 - the codec wars begin again. Basically, HEVC achieves around avg 50% bit rate reduction while maintaining the same subjective video quality relative to its predecessor H.264/AVC (they're gonna need it for 4k). [source: fraunhofer]

What does it mean? Here's h265 v h264 test paper

See http://infoscience.epfl.ch/record/180494/files/hanhart_SPIE2012_1.pdf

At the moment trial-outs of h265 seem pretty scarce but people are beginning to announce things. Main Concept for example.

http://www.mainconcept.com/press/single-view/article/rovi-debuts-mainconcept-branded-codec-for-hevc-standard.html

x265 also has been rushed out by an unknown (x264 people will probably be unhappy with this?)

http://code.google.com/p/x265/

More good reading at;- http://www.hhi.fraunhofer.de/fields-of-competence/image-processing/research-groups/image-video-coding/high-efficiency-video-coding.html

@stonebat Actually, 4:2:2 doesn't require twice the bandwidth of 4:2:0. With 4:4:4 each pixel requires 3 bytes of data (8-bit uncompressed), 4:2:2 requires 2 bytes of data, and 4:2:0 requires 1.5 bytes of data. Thus 4:2:2 only requires 33% more bandwidth than 4:2:0 (or, 4:2:0 representing a 25% reduction from 4:2:2). The problem with 4:2:2 is that chroma channels use rectangular pixels instead of square ones. The result is that the horizontal resolution for chroma channels is cut in half, but the vertical resolution is not. With 4:2:0, both horizontal and vertical resolution are cut in half resulting in a more symmetrical appearance. Deblocking and filtering are used to smooth things out to make the subsampling less obvious; but nevertheless, with 4:2:2 subsampling there is a visible difference in how vertical and horizontal detail looks. I think camera manufacturers have opted for 4:2:0 over 4:2:2 because it is easier to produce a palatable image with it and there isn't enough to be gained by going with 4:2:2. I doubt that the relatively small reduction in bandwidth requirements was the main/only reason behind the decision.

@ stonebat Good question. The luma channel is still the same, though.