NVIDIA’s second GTC of 2020 is taking place this week, and as has quickly become a tradition, one of CEO Jensen Huang’s “kitchenside chats” kicks off the event. As the de facto replacement for GTC Europe, this fall virtual GTC is a bit of a lower-key event relative to the Spring edition, but it’s still one that is seeing some NVIDIA hardware introduced to the world.

Starting things off, we have a pair of new video cards from NVIDIA – and a launch that seemingly indicates that NVIDIA is getting ready to overhaul its professional visualization branding. Being announced today and set to ship at the end of the year is the NVIDIA RTX A6000, NVIDIA’s next-generation, Ampere-based professional visualization card. The successor to the Turing-based Quadro RTX 8000/6000, the A6000 will be NVIDIA’s flagship professional graphics card, offering everything under the sun as far as NVIDIA’s graphics features go, and chart-topping performance to back it up. The A6000 will be a Quadro card in everything but name; literally.

NVIDIA Professional Visualization Card
Specification Comparison
  A6000 A40 RTX 8000 GV100
CUDA Cores 10752 10752 4608 5120
Tensor Cores 336 336 576 640
Boost Clock ? ? 1770MHz ~1450MHz
Memory Clock 16Gbps GDDR6 14.5Gbps GDDR6 14Gbps GDDR6 1.7Gbps HBM2
Memory Bus Width 384-bit 384-bit 384-bit 4096-bit
VRAM 48GB 48GB 48GB 32GB
ECC Partial
(DRAM)
Partial
(DRAM)
Partial
(DRAM)
Full
Half Precision ? ? 32.6 TFLOPS 29.6 TFLOPS
Single Precision ? ? 16.3 TFLOPS 14.8 TFLOPS
Tensor Performance ? ? 130.5 TFLOPS 118.5 TFLOPs
(FP16)
TDP 300W 300W 295W 250W
Cooling Active Passive Active Active
NVLink 1x NVLink3
112.5GB/sec
1x NVLink3
112.5GB/sec
1x NVLInk2
50GB/sec
2x NVLInk2
100GB/sec
GPU GA102 GA102 TU102 GV100
Architecture Ampere Ampere Turing Volta
Manufacturing Process Samsung 8nm Samsung 8nm TSMC 12nm FFN TSMC 12nm FFN
Launch Price ? ? $10,000 $9,000
Launch Date 12/2020 Q1 2021 Q4 2018 March 2018

The first professional visualization card to be launched based on NVIDIA’s new Ampere architecture, the A6000 will have NVIDIA hitting the market with its best foot forward. The card uses a fully-enabled GA102 GPU – the same chip used in the GeForce RTX 3080 & 3090 – and with 48GB of memory, is packed with as much memory as NVIDIA can put on a single GA102 card today. Notably, the A6000 is using GDDR6 here and not the faster GDDR6X used in the GeForce cards, as 16Gb density RAM chips are not available for the latter memory at this time. As a result, despite being based on the same GPU, there are going to be some interesting performance differences between the A6000 and its GeForce siblings, as it has traded memory bandwidth for overall memory capacity.

In terms of performance, NVIDIA is promoting the A6000 as offering nearly twice the performance (or more) of the Quadro RTX 8000 in certain situations, particularly tasks taking advantage of the significant increase in FP32 CUDA cores or the similar performance increase in RT core throughput. Unfortunately NVIDIA has either yet to lock down the specifications for the card or is opting against announcing them at this time, so we don’t know what the clockspeeds and resulting performance in FLOPS will be. Notably, the A6000 only has a TDP of 300W, 50W lower than the GeForce RTX 3090, so I would expect this card to be clocked lower than the 3090.

Otherwise, as we saw with the GeForce cards launched last month, Ampere itself is not a major technological overhaul to the previous Turing architecture. So while newer and significantly more powerful, there are not many new marquee features to be found on the card. Along with the expanded number of data types supported in the tensor cores (particularly BFloat16), the other changes most likely to be noticed by professional visualization users is decode support for the new AV1 codec, as well as PCI-Express 4.0 support, which will give the cards twice the bus bandwidth when used with AMD’s recent platforms.

Like the current-generation Quadro, the upcoming card also gets ECC support. NVIDIA has never listed GA102 as offering ECC on its internal pathways – this is traditionally limited to their big, datacenter-class chips – so this is almost certainly partial support via “soft” ECC, which offers error correction against the DRAM and DRAM bus by setting aside some DRAM capacity and bandwidth to function as ECC. The cards also support a single NVLink connector – now up to NVLink 3 – allowing for a pair of A6000s to be bridged together for more performance and to share their memory pools for supported applications. The A6000 also supports NVIDIA’s standard frame lock and 3D Vision Pro features with their respective connectors.

For display outputs, the A6000 ships with a quad-DisplayPort configuration, which is typical for NVIDIA’s high-end professional visualization cards. Notably this generation, however, this means the A6000 is in a bit of an odd spot since DisplayPort 1.4 is slower than the HDMI 2.1 standard also supported by the GA102 GPU. I would expect that it’s possible for the card to drive an HDMI 2.1 display with a passive adapter, but this is going to be reliant on how NVIDIA has configured the card and if HDMI 2.1 signaling will tolerate such an adapter.

Finally, the A6000 will be the first of today’s video cards to ship. According to NVIDIA, the card will be available in the channel as an add-in card starting in mid-December – just in time to make a 2020 launch. The card will then start showing up in OEM systems in early 2021.

NVIDIA A40 – Passive ProViz

Joining the new A6000 is a very similar card designed for passive cooling, the NVIDIA A40. Based on the same GA102 GPU as the A6000, the A40 offers virtually all of the same features as the active-cooled A6000, just in a purely passive form factor suitable for use in high density servers.

By the numbers, the A40 is a similar flagship-level graphics card, using a fully enabled GA102 GPU. It’s not quite a twin to the A6000, but other than the cooling difference, the only other change under the hood is the memory configuration. Whereas the A6000 uses 16 Gbps GDDR6, A40 clocks it down to 14.5 Gbps. Otherwise NVIDIA has not disclosed expected GPU clockspeeds, but with a 300W TDP, we’d expect them to be similar to the A6000.

Overall NVIDIA is no stranger to offering passively cooled cards; however it’s been a while since we last saw a passively cooled high-end Quadro card. Most recently, NVIDIA’s passive cards have been aimed at the compute market, with parts like the Tesla T4 and P40. The A40, on the other hand, is a bit different and a bit more ambitious, and a reflection of the blurring lines between compute and graphics in at least some of NVIDIA’s markets.

The most notable impact here is the inclusion of display outputs, something that was never on NVIDIA’s compute cards for obvious reasons. The A40 includes three DisplayPort outputs (one fewer than the A6000), giving the server-focused card the ability to directly drive a display. In explaining the inclusion of display I/O in a server part, NVIDIA said that they’ve had requests from users in the media and broadcast industry, who have been using servers in places like video trucks, but still need display outputs.

Ultimately, this serves as something of an additional feature differentiator between the A40 and NVIDIA’s official PCIe compute card, the PCIe A100. As the A100 lacks any kind of video display functionality (the underlying A100 GPU was designed for pure compute tasks), the A40 is the counterpoint to that product, offering something with very explicit video output support both within and outside of the card. And while it’s not specifically aimed at the edge compute market, where the T4 still reigns supreme, make no mistake: the A40 is still capable of being used as a compute card. Though lacking in some of A100’s specialty features like Multi-Instance GPU (MIG), the A40 is fully capable of being provisioned as a compute card, including support for the Virtual Compute Server vGPU profile. So the card is a potential alternative of sorts to the A100, at least where FP32 throughput might be of concern.

Finally, like the A6000, the A40 will be hitting the streets in the near future. Designed to be sold primarily through OEMs, NVIDIA expects it to start showing up in servers in early 2021.

Quadro No More?

For long-time observers, perhaps the most interesting development from today’s launch is what’s not present: NVIDIA’s Quadro branding. Despite being aimed at their traditional professional visualization market, the A6000 is not being branded as a Quadro card, a change that was made at nearly the last minute.

Perhaps because of that last-minute change, NVIDIA hasn’t issued any official explanation for their decision. At face value it’s certainly an odd one, as the Quadro brand is one of NVIDIA’s longest-lived brands, second only to GeForce itself. NVIDIA still controls the lion’s share of the professional visualization market as well, so at face value there seems to be little reason for NVIDIA to shake-up a very stable market.

With all of that said, there are a couple of factors in play that may be driving NVIDIA’s decision. First and foremost is that the company has already retired one of its other product brands in the last couple of years: Tesla. Previously used for NVIDIA’s compute accelerators, Tesla was retired and never replaced, leaving us with the likes of the NVIDIA T4 and A100. Of course, Tesla is something of a special case, as the name has increasingly become synonymous with the electric car company, despite in both cases being selected as a reference to the famous scientist. Quadro, by comparison, has relatively little (but not zero) overlap with other business entities.

But perhaps more significant than that is the overall state of NVIDIA’s professional businesses. An important cornerstone of NVIDIA’s graphics products, professional visualization is a fairly stable market – which is to say it’s not a major growth market in the way that gaming and datacenter compute have been. As a result, professional visualization has been getting slowly subsumed by NVIDIA’s compute parts, especially in the server space where many products can be provisioned for either compute or graphics needs. In all these cases, both Quadro and NVIDIA’s former Tesla lineup have come to represent NVIDIA’s “premium” offerings: parts that get access to the full suite of NVIDIA’s hardware and software features, unlike the consumer GeForce products which have certain high-end features withheld.

So it may very well be that NVIDIA doesn’t see a need for a specific Quadro brand too much longer, because the market for Quadro (professional visualization) and Tesla (computing) are one in the same. Though the two differ in their specific needs, they still use the same NVIDIA hardware, and frequently pay the same high NVIDIA prices.

At any rate, it will be interesting to see where NVIDIA goes from here. Even with the overlap in audiences, branding segmentation has its advantages at times. And with NVIDIA now producing GPUs that lack critical display capabilities (GA100), it seems like making it clear what hardware can (and can’t) be used for graphics is going to remain important going forward.

Source: NVIDIA

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  • LauRoman - Monday, October 5, 2020 - link

    Still italian/latin Reply
  • MrVibrato - Monday, October 5, 2020 - link

    Yeah. Trying to market professional products to a commercial customer base by individual product brands is probably not that effective. Procurement/purchasing managers rarely care about product brands as much as they care about reputation of and past business with the vendors/manufacturers they are dealing with.

    For wooing commercial customers, a solutions-based marketing approach makes more sense. You can see this by just visiting Nvidia's website...

    That said, i was and still am curious about the origin of Nvidia's Quadro branding. Why "Quadro"? 4-way SLI? 4 monitors per graphics card? 4 times as expensive?
    Reply
  • Zagor Te Nay - Monday, October 5, 2020 - link

    Geforce makes sense as a consumer gaming card line only because we have associated term with gaming cards.

    It spells different, but it sounds like G-force... something that flying enthusiasts (oblivious to gaming) would associate with fighter and acrobatic pilots and airplanes.

    Just as well, Quadro is deeply associated with pro graphics, even if term doesn't naturally belong to that vocabulary. I don't see obvious reason to change that... curious to learn what motivated Nvidia.
    Reply
  • Operandi - Tuesday, October 6, 2020 - link

    Geforce make sense because it implies speed and high performance, its great branding. WTF does Quadro mean in terms of professional graphics???, oh yeah right, nothing. Reply
  • im.thatoneguy - Tuesday, October 6, 2020 - link

    Quadro in the pro graphics area usually means "If you like to spend way more money than you probably need to, by all means feel free to buy it for my workstation but I would rather take the cash." Reply
  • jabber - Thursday, October 8, 2020 - link

    Or "Thanks I'll take that low end $400 Quadro for $40 on Ebay that you had to swap out of that HP/Dell workstation!

    Thanks very much!
    Reply
  • euler007 - Friday, October 16, 2020 - link

    For me it meant Autodesk supported driver, tons of ram and four DP output. Reply
  • edzieba - Monday, October 5, 2020 - link

    "Notably this generation, however, this means the A6000 is in a bit of an odd spot since DisplayPort 1.4 is slower than the HDMI 2.1 standard also supported by the GA102 GPU. I would expect that it’s possible for the card to drive an HDMI 2.1 display with a passive adapter, but this is going to be reliant on how NVIDIA has configured the card and if HDMI 2.1 signaling will tolerate such an adapter."

    One would expect the not-Quadros to work the same way the Ampere GeForce cards and past GeForce and Quadros do: the Pd ports are DP++ ports, and are electrically both DP and HDMI (requiring only a passive adapter to change the port shape and pinout). There's no good reason to put anything other than physical DP ports on the rear of a card, other than regular consumers getting int a panic even if you include an adapter in the box.
    Reply
  • repoman27 - Monday, October 5, 2020 - link

    The latest version of the Dual-mode DisplayPort (DP++) standard, which is what enables passive DP to HDMI adapters, only supports up to HDMI 1.4b. HDMI 2.1 will require an adapter with an active Level Shifter/Protocol Converter (LSPCon), as did HDMI 2.0b.

    In the NVIDIA Ampere architecture whitepaper for the GA102, the maximum supported resolutions for both the DisplayPort and HDMI interfaces are the same (8K @ 60Hz + HDR or 4K @ 240Hz + HDR) and require DSC anyway. So once there's an LSPCon that can output an HDMI 2.1 Fixed Rate Link signal with DSC 1.2a and HDCP 2.3, there should be no problem with fully supporting HDMI 2.1 via an active adapter.
    Reply
  • Kevin G - Monday, October 5, 2020 - link

    Even active adapters will have a few issues. Thus far the HDMI 2.1 support of the Ampere line has been focused at a 40 Gbit/s link rate. Most 4320p displays seen to be circling around that data rate. The bad news is that DP 1.3/1.4 leverage 8/10 encoding which means a good chunk of their bandwidth is lost in overhead vs. HDMI 2.1's usage of more efficient 64/66 encoding. The effect is that HDMI 2.1 has roughly ~50% more usable bandwidth than DP 1.3/1.4.

    It seems the full 48 Gbit/s link rate will be reserved for the true 8192 x 4320 DCI resolution used in cinema and a few other niche applications. At the full 48 Gbit/s link rate, HDMI 2.1 has ~85% more bandwidth.

    Really curious if we'll just see DSC pass through for 4320p60 or if an active adapter will shift from 1:3 to 1:2 compression from DP 1.4- > HDMI 2.1.
    Reply

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