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Les avancées dans le domaine de la mémoire GDDR7, qui devrait être plébiscitée par les futures cartes graphiques gaming, se poursuivent, Micron annonce la production de puces GDR7 32 Gbps, ce qui permettrait d'atteindre une bande passante maximale de 1.5 To/s, grâce à une interface mémoire de 384 bits. Micron Technology a annoncé aujourd'hui l'échantillonnage de sa mémoire graphique GDDR7 de nouvelle génération avec la densité de bits la plus élevée de l'industrie. S'appuyant sur la technologie DRAM 1et#946; (1-beta) de Micron et sur une architecture innovante, Micron GDDR7 offre une mémoire haute performance de 32 Gb/s dans une conception optimisée en termes de puissance. Avec plus de 1,5 To/s de bande passante système, soit une bande passante jusqu'à 60 % supérieure à celle de la GDDR6, et quatre canaux indépendants pour optimiser les charges de travail, la mémoire GDDR7 de Micron permet des temps de réponse plus rapides, un gameplay plus fluide et des temps de traitement réduits. La mémoire GDDR7 offre également un rendement énergétique supérieur à 50 % par rapport à la mémoire GDDR6, ce qui permet d'améliorer les performances thermiques et de prolonger la durée de vie de la batterie, tandis que le nouveau mode veille réduit la consommation d'énergie en veille jusqu'à 70 %. Les fonctions avancées de fiabilité, de disponibilité et de facilité d'entretien (RAS) de la mémoire GDDR7 de Micron améliorent la fiabilité des appareils et l'intégrité des données sans compromettre les performances, ce qui élargit le spectre des applications de la mémoire GDDR7 de Micron à l'intelligence artificielle, aux jeux et aux charges de travail informatiques à hautes performances. La mémoire GDDR7 de Micron offre des performances élevées qui augmentent le débit jusqu'à 33 % et réduisent le temps de réponse jusqu'à 20 % pour les charges de travail d'IA générative telles que la création de texte à partir d'images. En outre, Micron prévoit que les cartes graphiques construites avec la GDDR7 offriront une amélioration de plus de 30 % des images par seconde (FPS) pour le ray tracing et la rastérisation par rapport aux tendances actuelles de la GDDR6 et de la GDDR6X dans les résolutions 1080p, 1440 et 4K.7 L'ajout de la GDDR7 complète le portefeuille de produits de pointe de Micron pour les applications d'inférence d'IA de pointe sur les composants CPU, NPU et GPU avec des options de mémoire DDR, LPDDR et GDDR. Pour les applications de jeu, la mémoire GDDR7 de Micron permet un gameplay amélioré par l'IA avec des paysages, des joueurs et des scénarios adaptables grâce à la mise à l'échelle des performances et de la mémoire tampon. […]
Lire la suiteSi Elon Musk n’obtient pas un vote favorable des actionnaires le 13 juin, il pourrait être tenté de quitter Tesla. C’est notamment un package de rémunération d’une valeur de 56 milliards de dollars qui pourrait faire basculer l’avenir du chef d’entreprise.
Un gestionnaire de mots de passe conçu par Apple devrait être présenté lors de la WWDC 2024. L'application, dont le nom serait Passwords, risque de bousculer le secteur.
For Computex week, Micron was at the show in force in order to talk about its latest products across the memory spectrum. The biggest news for the memory company was that it has kicked-off sampling of it's next-gen GDDR7 memory, which is expected to start showing up in finished products later this year and was being demoed on the show floor. Meanwhile, the company is also eyeing taking a much larger piece of the other pillar of the high-performance memory market – High Bandwidth Memory – with aims of capturing around 25% of the premium HBM market.
Micron's first GDDR7 chip is a 16 Gb memory device with a 32 GT/sec (32Gbps/pin) transfer rate, which is significantly faster than contemporary GDDR6/GDDR6X. As outlined with JEDEC's announcement of GDDR7 earlier this year, the latest iteration of the high-performance memory technology is slated to improve on both memory bandwidth and capacity, with bandwidths starting at 32 GT/sec and potentially climbing another 50% higher to 48 GT/sec by the time the technology reaches its apex. And while the first chips are starting off at the same 2GByte (16Gbit) capacity as today's GDDR6(X) chips, the standard itself defines capacities as high as 64Gbit.
Of particular note, GDDR7 brings with it the switch to PAM3 (3-state) signal encoding, moving from the industry's long-held NRZ (2-state) signaling. As Micron was responsible for the bespoke GDDR6X technology, which was the first major DRAM spec to use PAM signaling (in its case, 4-state PAM4), Micron reckons they have a leg-up with GDDR7 development, as they're already familiar with working with PAM.
The GDDR7 transition also brings with it a change in how chips are organized, with the standard 32-bit wide chip now split up into four 8-bit sub-channels. And, like most other contemporary memory standards, GDDR7 is adding on-die ECC support to hold the line on chip reliability (though as always, we should note that on-die ECC isn't meant to be a replacement for full, multi-chip ECC). The standard also implements some other RAS features such as error checking and scrubbing, which although are not germane to gaming, will be a big deal for compute/AI use cases.
The added complexity of GDDR7 means that the pin count is once again increasing as well, with the new standard adding a further 86 pins to accommodate the data transfer and power delivery changes, bringing it to a total of 266 pins. With that said, the actual package size is remaining unchanged from GDDR5/GDDR6, maintaining that familiar 14mm x 12mm package. Memory manufacturers are instead using smaller diameter balls, as well as decreasing the pitch between the individual solder balls – going from GDDR6's 0.75mm x 0.75mm pitch to a slightly shorter 0.75mm x 0.73mm pitch. This allows the same package to fit in another 5 rows of contacts.
As for Micron's own production plans, the company is using its latest 1-beta (1β) fabrication process. While the major memory manufacturers don't readily publish the physical parameters of their processes these days, Micron believes that they have the edge on density with 1β, and consequently will be producing the densest GDDR7 at launch. And, while more nebulous, the company company believes that 1β will give them an edge in power efficiency as well.
Micron says that the first devices incorporating GDDR7 will be available this year. And while video card vendors remain a major consumer of GDDR memory, in 2024 the AI accelerator market should not be overlooked. With AI accelerators still bottlenecked by memory capacity and bandwidth, GDDR7 is expected to pair very well with inference accelerators, which need a more cost-effective option than HBM.
Speaking of HBM, Micron was the first company to formally announce its HBM3E memory last year, and it was among the first to start its volume shipments earlier this year. For now, Micron commands a 'mid-single digit' share of this lucrative market, but the company has said that it plans to rapidly gain share. If all goes well, by the middle of its fiscal 2025 (i.e., the end of calendar Q1 2025) the company hopes to capture a mid-20% share of the HBM market.
"As we go into fiscal year 2025, we expect our share of HBM to be very similar to our overall share on general DRAM market," said Praveen Vaidyanathan, vice president and general manager of the Compute Products Group at Micron. "So, I would say mid-20%. […] We believe we have a very strong product as [we see] a lot of interest from various GPU and ASIC vendors, and continuing to engage with customers […] for the next, say 12 to 15 months."
When asked whether Micron can accelerate output of HBM3E at such a rapid pace in terms of manufacturing capacity, Vaidyanathan responded that the company has a roadmap for capacity expansion and that the company would meet the demand for its HBM3E products.