It’s not theoretical, it’s just math. Removing 1/3 of the bus paths, and also removing the need to constantly keep RAM powered
And here’s the kicker.
You’re supposing it’s (given the no refresh bonus) 1/3 as fast as dram, similar latency, and cheap enough per gigabyte to replace most storage. That is a tall order, and it would be incredible if it hits all three of those. I find that highly improbable.
Even dram is starting to become a bottleneck for APUs, specifically, because making the bus wide is so expensive. This applies to the very top (the MI300A) and bottom (smartphones and laptop APUs).
Optane, for reference, was a lot slower than DRAM and a lot more expensive/less dense than flash even with all the work Intel put into it and busses built into then top end CPUs for direct access. And they thought that was pretty good. It was good enough for a niche when used in conjunction with dram sticks
No, you misunderstood. A current standard computer bus path is guaranteed to have at least 3 bus paths: CPU, RAM, Storage.
The amount of energy required to communicate between all three parts varies, but you can be guaranteed that removing just one PLUS removing the capacitor requirement for the memory will reduce power consumption by 1/3 of whatever that total bus power consumption is. This is ignoring any other additional buses and doing the bare minimum math.
The speed of this memory would matter less if you’re also reducing the static storage requirement. The speed at which it can communicate with the CPU only is what would matter, so if you’re not traversing CPU>RAM>SSD and only doing CPU>DRAM+, it’s going to be more efficient.
PCIe 5.0 x16 can match DDR5’s bandwidth, that’s not the issue, the question is latency. The only reason OSs cache disk contents in memory is because SSD latency is something like at least 30x slower, the data ends up in the CPU either way RAM can’t talk directly to the SSD, modern mainboards are very centralised and it’s all point-to-point connection, the only bus you’ll find will be talking i2c. Temperature sensors and stuff.
And I think it’s rather suspicious that none of those articles are talking about latency. Without that being at least in the ballpark of DDR5 all this is is an alternative to NAND which is of course also a nice thing but not a game changer.
I don’t even think you know what you’re trying to say at this point, because it’s not making sense. Think what you will, but it’s obvious your conception of how computer architecture works is flawed. You’ll see this memory in machines and hopefully figure it out though. Good luck 🤞
And here’s the kicker.
You’re supposing it’s (given the no refresh bonus) 1/3 as fast as dram, similar latency, and cheap enough per gigabyte to replace most storage. That is a tall order, and it would be incredible if it hits all three of those. I find that highly improbable.
Even dram is starting to become a bottleneck for APUs, specifically, because making the bus wide is so expensive. This applies to the very top (the MI300A) and bottom (smartphones and laptop APUs).
Optane, for reference, was a lot slower than DRAM and a lot more expensive/less dense than flash even with all the work Intel put into it and busses built into then top end CPUs for direct access. And they thought that was pretty good. It was good enough for a niche when used in conjunction with dram sticks
No, you misunderstood. A current standard computer bus path is guaranteed to have at least 3 bus paths: CPU, RAM, Storage.
The amount of energy required to communicate between all three parts varies, but you can be guaranteed that removing just one PLUS removing the capacitor requirement for the memory will reduce power consumption by 1/3 of whatever that total bus power consumption is. This is ignoring any other additional buses and doing the bare minimum math.
The speed of this memory would matter less if you’re also reducing the static storage requirement. The speed at which it can communicate with the CPU only is what would matter, so if you’re not traversing CPU>RAM>SSD and only doing CPU>DRAM+, it’s going to be more efficient.
PCIe 5.0 x16 can match DDR5’s bandwidth, that’s not the issue, the question is latency. The only reason OSs cache disk contents in memory is because SSD latency is something like at least 30x slower, the data ends up in the CPU either way RAM can’t talk directly to the SSD, modern mainboards are very centralised and it’s all point-to-point connection, the only bus you’ll find will be talking i2c. Temperature sensors and stuff.
And I think it’s rather suspicious that none of those articles are talking about latency. Without that being at least in the ballpark of DDR5 all this is is an alternative to NAND which is of course also a nice thing but not a game changer.
I don’t even think you know what you’re trying to say at this point, because it’s not making sense. Think what you will, but it’s obvious your conception of how computer architecture works is flawed. You’ll see this memory in machines and hopefully figure it out though. Good luck 🤞