Wikipedia says it’s 16,000x16,000 (which is way less than I thought). The way the math works, that’s 16x as big as a 4k monitor, so 16 GPUs would make sense. And there’s a screen inside and one outside, so double that. But I also can’t figure out why it needs five times that. Redundancy? Poor optimization? I dunno.
I work for a digital display company, and it is definitely redundancy. There will be at least two redundant display systems that go to the modules separately so they can switch between them to solve issues. If a component fails on one side they just switch to the other.
Wikipedia says it’s 16,000x16,000 (which is way less than I thought). The way the math works, that’s 16x as big as a 4k monitor, so 16 GPUs would make sense. And there’s a screen inside and one outside, so double that. But I also can’t figure out why it needs five times that. Redundancy? Poor optimization? I dunno.
But wouldn’t that be only necessary if it needed to render real-time graphics at such a scale? If I’m correct, all its doing is playing back videos.
I think it’s doing some non-trivial amount of rendering, since it’s often syncing graphics with music played live.
I’m guessing it’s the department of redundancy department, is my guess.
Someone elsewhere in the thread suggested it might be a marketing thing on Nvidia’s part, and that makes a lot of sense.
I work for a digital display company, and it is definitely redundancy. There will be at least two redundant display systems that go to the modules separately so they can switch between them to solve issues. If a component fails on one side they just switch to the other.
Ah, nice. Thank you for bringing your expertise to my nonsense.