DDR5 Memory Specification Released: Setting the Stage for DDR5-6400 And Beyond
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[Image: 1811_SK_hynix_1Ynm_DDR5_DRAM_678x452.jpg]

Marking an important milestone in computer memory development, today the JEDEC Solid State Technology Association is releasing the final specification for its next mainstream memory standard, DDR5 SDRAM. The latest iteration of the DDR standard that has been driving PCs, servers, and everything in-between since the late 90s, DDR5 once again extends the capabilities of DDR memory, doubling the peak memory speeds while greatly increasing memory sizes as well.

Hardware based on the new standard is expected in 2021, with adoption starting at the server level before trickling down to client PCs and other devices later on.  

Originally planned for release in 2018, today’s release of the DDR5 specification puts things a bit behind JEDEC’s original schedule, but it doesn’t diminish the importance of the new memory specification. Like every iteration of DDR before it, the primary focus for DDR5 is once again on improving memory density as well as speeds. JEDEC is looking to double both, with maximum memory speeds set to reach at least 6.4Gbps while the capacity for a single, packed-to-the-rafters LRDIMM will eventually be able to reach 2TB. All the while, there are several smaller changes to either support these goals or to simplify certain aspects of the ecosystem, such as on-DIMM voltage regulators as well as on-die ECC.

Going Bigger: Denser Memory & Die-Stacking

We’ll start with a brief look at capacity and density, as this is the most-straightforward change to the standard compared to DDR4. Designed to span several years (if not longer), DDR5 will allow for individual memory chips up to 64Gbit in density, which is 4x higher than DDR4’s 16Gbit density maximum. Combined with die stacking, which allows for up to 8 dies to be stacked as a single chip, then a 40 element LRDIMM can reach an effective memory capacity of 2TB. Or for the more humble unbuffered DIMM, this would mean we’ll eventually see DIMM capacities reach 128GB for your typical dual rank configuration.

Of course, the DDR5 specification’s peak capacities are meant for later in the standard’s lifetime, when chip manufacturing catches up to what the spec can allow. To start things off memory manufacturers will be using today’s attainable densities 8Gbit and 16Gbit chips in order to build their DIMMs. So while the speed improvements from DDR5 will be fairly immediate, the capacity improvements will be more gradual as manufacturing densities improve.

Going Faster: One DIMM, Two Channels

The other half of the story for DDR5 is about once again increasing memory bandwidth. Everyone wants more performance (especially with DIMM capacities growing), and unsurprisingly, this is where a lot of work was put into the specification in order to make this happen.

For DDR5, JEDEC is looking to start things off much more aggressively than usual for a DDR memory specification. Typically a new standard picks up from where the last one started off, such as with the DDR3 to DDR4 transition, where DDR3 officially stopped at 1.6Gbps and DDR4 started from there. However for DDR5 JEDEC is aiming much higher, with the group expecting to launch at 4.8Gbps, some 50% faster than the official 3.2Gbps max speed of DDR4. And in the years afterwards, the current version of the specification allows for data rates up to 6.4Gbps, doubling the official peak of DDR4.

Of course, sly enthusiasts will note that DDR4 already goes above the official maximum of 3.2Gbps (sometimes well above), and it’s likely that DDR5 will eventually go a similar route. The underlying goal, regardless of specific figures, is to double the amount of bandwidth available today from a single DIMM. So don’t be too surprised if SK Hynix indeed hits their goal of DDR5-8400 later this decade.

Underpinning these speed goals are changes at both the DIMM and the memory bus in order to feed and transport so much data per clock cycle. The big challenge as always for DRAM speeds, comes from the lack of progress in DRAM core clock rates. Dedicated logic is still getting faster, and memory busses are still getting faster, but the capacitor-and-transistor-based DRAM underpinning modern memory still can’t clock higher than a few hundred megahertz. So in order to get more from a DRAM die – to maintain the illusion that the memory itself is getting faster and to feed the actually faster memory busses – more and more parallelism has been required. And DDR5 for its part ups the ante once more.
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Additional Info: https://www.tomshardware.com/news/ddr5-s...regulators
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