- AMD may have a new platform for upcoming Ryzen CPUs — AM5+ socket and Granite Ridge CPUs listed in a microcode extraction tool Tom’s Hardware
- The launch of AMD’s Zen 5 processors is close, as motherboard manufacturers begin rolling out BIOSes supporting the next-gen chips PC Gamer
- ASUS X670 AGESA 1.1.7.0 update enables initial support for Zen5 “Granite Ridge” CPU series VideoCardz.com
- AMD Zen 5 Architecture to Introduce Enhanced 512-bit Floating Point Unit guru3d.com
- AMD AM5+ Platform Mentioned With Two Granite Ridge “Ryzen Zen 5” CPUs In Microcode Extraction Tool Wccftech
Tag Archives: socket
ASUS unveils AMD B650 motherboard series with AM5 socket
B650 motherboard guide: ROG Strix, TUF Gaming, ProArt, and Prime bring PCIe 5.0 and DDR5 to everyone
The latest X670E motherboard platform introduced a wealth of cutting-edge features to accompany AMD’s latest 7-series CPUs. Headlined by PCIe 5.0 connectivity and across-the-board DDR5 support, our X670E motherboards cater to enthusiasts ready to extract every ounce of performance they can get out of their new AMD processor. Now, mainstream PC builds can get in on the action, too. Our B650E and B650 boards offer tremendous value for anyone assembling a next-gen machine. This B650 motherboard guide walks you through our different product families to help you find the model that best fits your needs and budget.
Shopping for a gaming-first motherboard that delivers exceptional performance and exudes confident style? Start with our ROG Strix lineup. From the flagship ROG Strix B650E-E Gaming WiFi to the compact-yet-mighty ROG Strix B650E-I Gaming WiFi, these boards bring high-end features and sizzling good looks. Perhaps you’d prefer a straightforward gaming board that delivers essential features in a no-frills design? Check out our TUF Gaming family. Available in either ATX or micro-ATX form factors, these products deliver everything you need for a reliable gaming build and nothing that you don’t.
Gamers aren’t the only folks out there looking at everything that AMD’s new chips have to offer. For the creative professionals out there—and anyone who aspires to take their talents in CGI, filmmaking, engineering, or design to the next level—the ProArt B650-Creator offers great connectivity and sophisticated style. Last but not least, our wide range of ASUS Prime motherboards offer everything you need for an all-around-excellent PC.
Raised to the power of five
Our B650E and B650 motherboards bring a wealth of next-gen features. Even the CPU socket received an upgrade for the occasion. The all-new AM5 socket is an LGA-style socket, so the pins are on the motherboard, not the CPU, making any accidental bending or damage to the pins less likely. AM5 supports up to a 170W TDP, enabling exceptional compute performance for high-core-count CPUs in heavy workloads.
But it’s not just the CPU socket that’s enjoying a next-gen upgrade. B650E and B650 motherboards support the latest DDR5 RAM. With data rates 50% faster than previous-generation DDR4 memory, DDR5 unleashes a new tier of performance, and our motherboards offer a host of hardware and firmware optimizations that enable users to overclock capable kits to the absolute limit.
B650E and B650 motherboards also boast PCIe 5.0 connectivity. Every option in our lineup includes at least one onboard PCIe 5.0 M.2 slot ready for the fastest storage drives on the market. To prep your PC to take full advantage of next-gen PCIe 5.0 graphics cards, pick up one of our B650E motherboards. These higher-end options boast at least one PCIe 5.0 x16 slot. And with double the link speeds of PCIe 4.0, the new standard provides us with the bandwidth to deck out our B650E and B650 motherboards with a comprehensive selection of high-speed ports. Every ROG Strix, TUF Gaming, and ProArt B650 motherboard offers an onboard high-speed USB 3.2 Gen 2×2 Type-C port.
Go big on performance and style with ROG Strix
The ROG Strix line takes the high-end ROG DNA and distills it into gaming-first motherboards that are ready for anything. Whether you’re building a decked-out ATX gaming rig or a compact Mini-ITX machine, you’ll find the motherboard you need right here. Whichever ROG Strix board you choose, you’ll find high-end circuitry, convenient design elements, and features built to boost your gaming experience. Integrated I/O shields ease the installation process and look gorgeous behind your case’s side window. High-end VRMs stand ready to drive the entire swath of today’s Ryzen chips, while Intel-powered 2.5Gb Ethernet and Wi-Fi 6E offer cutting-edge networking. And our industry-leading gaming audio immerses you like never before with an ALC4080 codec and a Savitech SV3H712 amplifier.
Interested in tuning and tweaking your new AMD Ryzen CPU for maximum performance? Out of all our B650E and B650 motherboards, the ROG Strix models are best equipped for overclocking. A quick trip into their UEFI BIOS is all it takes to boost light-load clocks through Precision Boost Overdrive (PBO)—a move that enhances overall system responsiveness for most builders. Looking for more manual control over your CPU’s performance? We primed the ROG Strix B650E-E Gaming WiFi and ROG Strix B650E-I Gaming WiFi to satisfy your thirst for pushing your processor to its limits. Both offer particularly robust power solutions and access to our Dynamic OC Switcher and Core Flex tools.
ROG Strix B650E-E Gaming WiFi
Atop the stack sits the flagship ROG Strix B650E-E Gaming WiFi. The premium option for any builder intending to take the B650E platform to its limits, this decked-out motherboard offers a premium selection of features. Its optimized power solution readies you to overclock your Ryzen CPU with 16+2 teamed power stages with 8+8 ProCool power connectors. Two PCIe 5.0 x16 slots stand ready for next-gen add-on cards. Four onboard M.2 slots—two of which are wired for PCIe 5.0—make it a breeze to install a lightning-quick storage array for your gaming library. To keep it all cool, each M.2 slot has its own high-performance heatsink, and massive VRM heatsinks with high-conductivity thermal pads silently use the cooling air moving through your case to keep the circuitry operating comfortably.
The ROG Strix B650E-E Gaming WiFi goes above and beyond to make your build process easy and intuitive. The dedicated PCIe Slot Q-Release button makes it a breeze to release your graphics card from the primary PCIe 5.0 x16 slot. Our M.2 Q-Latch system ensures that you’ll never again lose a tiny M.2 screw while installing a drive. BIOS FlashBack™ support gets your new build up and running without a hitch by letting you update your board’s firmware with nothing more than a power supply and a USB flash drive. And with a premium connectivity selection including 19 USB ports, DisplayPort 1.4 and HDMI 2.1 ports, and a Thunderbolt 4 header, you’ll have no trouble assembling your full battlestation.
We also took advantage of this new platform to augment the audio solution that we offer in our mainstream ROG Strix motherboards. We’ve upgraded to the USB-based ALC4080 audio codec—and we’ve included a high-performance Savitech SV3H712 AMP to drive audiophile-grade sound to your headset. DTS Sound Unbound serves up immersive spatial audio, and our Sonic Studio III+ suite gives you precise control over the output.
| ROG Strix B650E-E Gaming WiFi | |
|---|---|
| Size | ATX |
| Memory | 4 x DIMM, up to 128GB, DDR5 |
| PCIe | 2 x PCIe 5.0 x16 (@x16 or x8/x4) 1 x PCIe 4.0 x16 (x4) |
| Storage | 1 x 22110 (PCIe 5.0 x4) 1 x 2280 (PCIe 5.0 x4) 2 x 2280 (PCIe 4.0 x4) |
| Networking | 1 x 2.5Gb Ethernet WiFi 6E |
| Audio | Realtek ALC 4080 Savitech SV3H712 AMP |
| USB4® Support | 1 x Thunderbolt™ (USB4®) header |
| Rear I/O | 3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 6 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
| Front I/O | 3.2 Gen 2: 1 x USB Type-C® 3.2 Gen 1: 2 x USB Type-A 2.0: 4 x USB Type-A |
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
| Cooling | 8 x fan headers |
ROG Strix B650E-F Gaming WiFi
Perhaps you love the aesthetics and overall feature set of the ROG Strix B650E-E Gaming WiFi, but you don’t have an immediate need for two PCIe 5.0 X16 slots and two PCIe 5.0 M.2 slots. Check out the ROG Strix B650E-F Gaming WiFi. In many ways, this motherboard is a mirror image of its elder sibling, but it offers one PCIe 5.0 x16 slot and one slot for a next-gen PCIe 5.0 M.2 drive—just the ticket for many a mainstream gaming PC.
Otherwise, you’ll find a broadly similar feature set between the two motherboards. The same stealthy black finish adorns their massive VRMs, shrouds, and heatsinks, similar Aura Sync RGB LED accents provide a bold flourish of color, and they offer the same suite of DIY-friendly design features.
| ROG Strix B650E-E Gaming WiFi | |
|---|---|
| Size | ATX |
| Memory | 4 x DIMM, up to 128GB, DDR5 |
| PCIe | 1 x PCIe 5.0 x16 (@x16) 1 x PCIe 4.0 x16 (@x4) |
| Storage | 1 x 2280 (PCIe 5.0 x4) 2 x 22110 (PCIe 4.0 x4) |
| Networking | 1 x 2.5Gb Ethernet WiFi 6E |
| Audio | Realtek ALC 4080 Savitech SV3H712 AMP |
| Rear I/O | 3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 2 x USB Type-A, 1 x USB Type-C® 3.2 Gen 1: 4 x USB Type-A 2.0: 4 x USB Type-A |
| Front I/O | 3.2 Gen 2: 1 x USB Type-C® 3.2 Gen 1: 2 x USB Type-A 2.0: 4 x USB Type-A |
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
| Cooling | 7 x fan headers |
ROG Strix B650E-I Gaming WiFi
If you’re building a PC for your home entertainment center or dorm room—or anywhere that space is a primary limiting factor—an ATX system might just be too large for your needs. To support the Mini-ITX build of your dreams, we offer the ROG Strix B650E-I Gaming WiFi. This compact motherboard might fit easily into one hand, but it offers a high-end set of gaming features.
As a B650E board, it boasts both a PCIe 5.0 x16 slot and a PCIe 5.0 M.2 slot, making it ready for the fastest graphics cards of today and tomorrow. Its versatile and high-end connectivity selection, including a USB 3.2 Gen 2 port with DisplayPort ALT mode, gives you everything you need for your build. And conveniences like the pre-mounted I/O shield simplify the process of building in the tight confines of a Mini-ITX case.
| ROG Strix B650E-I Gaming WiFi | |
|---|---|
| Size | Mini-ITX |
| Memory | 2 x DIMM, up to 64GB, DDR5 |
| PCIe | 1 x PCIe 5.0 x16 (@x16) |
| Storage | 1 x 2280 (PCIe 5.0 x4) 1 x 2280 (PCIe 4.0 x4) |
| Networking | 1 x 2.5Gb Ethernet WiFi 6E |
| Audio | Realtek ALC 4080 Savitech SV3H712 AMP |
| USB4® Support | 1 x Thunderbolt™ (USB4®) header |
| Rear I/O | 3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 4 x USB Type-A, 1 x USB Type-C® 2.0: 2 x USB Type-A |
| Front I/O | 3.2 Gen 2: 1 x USB Type-C® 3.2 Gen 1: 2 x USB Type-A 2.0: 2 x USB Type-A |
| Aura | 1 x Addressable Gen 2 headers 1 x Aura RGB header |
| Cooling | 3 x fan headers |
ROG Strix B650-A Gaming WiFi
No offense to those who prefer the classic black aesthetic for their gaming PCs, but there’s something special about a white-themed build. White finishes focus and amplify the RGB LED illumination of your build—or provide a clean, cohesive aesthetic on their own merits. For the foundation of your next white build, look no further than the ROG Strix B650-A Gaming WiFi.
As with all our B650E and B650 motherboards, the ROG Strix B650-A Gaming WiFi boasts an onboard PCIe 5.0 M.2 slot and DDR5 support. If a PCIe 5.0 x16 slot strikes you as more of a nice-to-have than a need-to-have feature for your next PC, this motherboard might be a better fit for you than the higher-end ROG Strix B650E motherboards. Its PCIe 4.0 x16 slot is more than capable of getting you in the game with a high-end graphics card.
| ROG Strix B650-A Gaming WiFi | |
|---|---|
| Size | ATX |
| Memory | 4 x DIMM, up to 128GB, DDR5 |
| PCIe | 1 x PCIe 4.0 x16 (@x16) 1 x PCIe 4.0 x16 (@x4) |
| Storage | 1 x 2280 (PCIe 5.0 x4) 1 x 2280 (PCIe 4.0 x4) 1 x 22110 (PCIe 4.0 x4) |
| Networking | 1 x 2.5Gb Ethernet WiFi 6E |
| Audio | Realtek ALC 4080 Savitech SV3H712 AMP |
| USB4® Support | 1 x Thunderbolt™ (USB4®) header |
| Rear I/O | 3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 3 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
| Front I/O | 3.2 Gen 2: 1 x USB Type-C® 3.2 Gen 1: 2 x USB Type-A 2.0: 4 x USB Type-A |
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
| Cooling | 7 x fan headers |
Get ready for action with battle-forged TUF Gaming motherboards
If your top priorities for a motherboard are reliable operation, sensible good looks, and essential gaming performance, then our TUF Gaming lineup was built for you. We designed these boards to give gamers high-quality options ready to go the distance.
Our TUF Gaming B650 motherboards offer a powerful value proposition for a next-gen AMD Ryzen gaming build. Available in either ATX or micro-ATX form factors, these boards offer DDR5 support, a PCIe 5.0 M.2 slot for blazing-fast storage, and an onboard USB 3.2 Gen 2×2 USB Type-C® port for fast, versatile connectivity. High-bandwidth 2.5Gb Ethernet comes standard, and WiFi 6 is available for those who need it.
Looking to complement your TUF Gaming motherboard with an array of components and peripherals with the same aesthetic? The TUF GAMING Alliance is a collaboration between ASUS and trusted PC component brands to ensure compatibility across a wide range of parts, such as PC cases, power supplies, CPU coolers, memory kits and more. With new partnerships and components being added regularly, the TUF Gaming Alliance will continue to grow even stronger.
| TUF Gaming B650-Plus WiFi | TUF Gaming B650-Plus | TUF Gaming B650M-Plus WiFi | TUF Gaming B650M-Plus | |
|---|---|---|---|---|
| Size | ATX | Micro-ATX | ||
| Memory | 4 x DIMM, up to 128GB, DDR5 | |||
| PCIe | 1 x PCIe 4.0 x16 (@x16) 1 x PCIe 4.0 x16 (max @x4) |
|||
| Storage | 1 x 2280 (PCIe 5.0 x4) 1 x 22110 (PCIe 4.0 x4) 1 x 2280 (PCIe 4.0 x4) |
1 x 2280 (PCIe 5.0 x4) 1 x 2280 (PCIe 4.0 x4) |
||
| Networking | 1 x 2.5Gb Ethernet WiFi 6 |
1 x 2.5Gb Ethernet | 1 x 2.5Gb Ethernet WiFi 6 |
1 x 2.5Gb Ethernet |
| Audio | Realtek ALC S1200A | Realtek ALC897 | ||
| USB4® Support | 1 x Thunderbolt™ (USB4®) header | |||
| Rear I/O | 3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 2 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
3.2 Gen 2×2: 1 x USB Type-C® 3.2 Gen 2: 2 x USB Type-A 3.2 Gen 1: 1 x USB Type-A 2.0: 4 x USB Type-A |
||
| Front I/O | 3.2 Gen 1: 2 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
3.2 Gen 1: 2 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
||
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
|||
| Cooling | 7 x fan headers | 6 x fan headers | ||
ProArt empowers creators with powerful performance and sophisticated style
Gamers aren’t the only ones planning new builds around AMD’s latest Ryzen CPUs. Creative professionals like engineers, designers, videographers, animators, and game developers all tend to have workflows ready to take full advantage of multicore CPUs, high-bandwidth DDR5 RAM, and speedy PCIe 5.0 storage. For these creators and more, ProArt motherboards provide superb connectivity, plentiful high-speed storage options, and professional style.
The ProArt B650-Creator carries on that tradition with a feature set that provides incredible value for a budget-conscious creative build. DDR5 support lets you take advantage of the raw bandwidth provided by the latest high-end kits, and a PCIe 5.0 M.2 slot allows you to enjoy the dizzying transfer rates of a cutting-edge drive.
Looking for a motherboard that can harness more than one graphics card? The ProArt B650-Creator has what you need. Its twin PCIe 4.0 x16 slots can operate in an x8/x8 configuration so that you can take full advantage of a pair of graphics cards.
Versatile connectivity is a must for any creative workstation, so the ProArt B650-Creator includes a connector for a front-panel USB 3.2 Gen 2×2 Type-C port—and it’s wired for Quick Charge 4+ so that you can use it to conveniently and speedily recharge your other devices. We’ve also wired one of the USB 3.2 Gen 2 Type-C ports on the rear I/O panel to support an alternate mode that provides DisplayPort 1.4 output up to 8K/60Hz.* Whether you want to use the port for high-speed 10Gbps file transfers or connecting an additional high-resolution display, the choice is yours.
| ProArt B650-Creator | |
|---|---|
| Size | ATX |
| Memory | 4 x DIMM, up to 128GB, DDR5 |
| PCIe | 2 x PCIe 4.0 x16 (@x16 or x8/x8) 1 x PCIe 4.0 x16 (max at X4) |
| Storage | 1 x 2280 (PCIe 5.0 x4) 1 x 22110 (PCIe 4.0 x4) 1 x 2280 (PCIe 4.0 x4) |
| Networking | 1 x Realtek 2.5Gb 1 x Realtek 1Gb |
| Audio | Realtek ALC 897 |
| USB4® Support | 1 x Thunderbolt™ (USB4®) header |
| Rear I/O | 3.2 Gen 2 with DP Alt Mode: 1 x USB Type-C ® 3.2 Gen 2: 3 x USB Type-A, 1 x USB Type-C® 2.0: 2 x USB Type-A |
| Front I/O | 3.2 Gen 2×2: 1 x USB Type-C® with Quick Charge 4+ 3.2 Gen 1: 2 x USB Type-A 2.0: 4 x USB Type-A |
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
| Cooling | 7 x fan headers |
ASUS Prime covers all the bases
Our ROG Strix, TUF Gaming, and ProArt families serve gamers and power users ready to extract every last drop of performance from their systems. While our Prime boards offer many of the same enthusiast-grade features, they’re also quite content to serve as reliable platforms for your work and everyday computing. For anyone building a budget-friendly PC that melds all-around capability and subtle style, a Prime board is the ideal choice.
For B650, we’re offering Prime motherboards in four variations. Pick between the ATX and micro-ATX form factors, make a judgment call on whether you need wireless networking, and you’re ready to go. Regardless of your choice, you’ll enjoy high-speed wired networking through a Realtek 2.5Gb Ethernet controller, a PCIe 5.0 M.2 slot, and DDR5 support.
Our Prime B650 motherboards will also make it easy for you to upgrade your processor down the road. Through BIOS FlashBack™, you’ll be able to quickly update your board’s firmware with nothing more than a power supply and a USB flash drive. This will pave the way for you to stay up to date with AMD’s subsequent generations of Ryzen CPUs for as long as AMD maintains backward compatibility, all the while using the same Prime B650 motherboard.
| Prime B650 Plus | Prime B650M-A AX | Prime B650M-A WiFi | Prime B650M-A | |
|---|---|---|---|---|
| Size | ATX | Micro-ATX | ||
| Memory | 4 x DIMM, up to 128GB, DDR5 | |||
| PCIe | 1 x PCIe 4.0 x16 (@x16) 1 x PCIe 4.0 x16 (max @x4) |
1 x PCIe 4.0 x16 (@x16) | ||
| Storage | 1 x 22110 (PCIe 5.0 x4) 1 x 22110 (PCIe 4.0 x4) |
1 x 2280 (PCIe 5.0 x4) 1 x 2280 (PCIe 4.0 x4) |
||
| Networking | 1 x Realtek 2.5Gb | 1 x Realtek 2.5Gb WiFi 6 |
1 x Realtek 2.5Gb | |
| Audio | Realtek ALC 897 | |||
| USB4® Support | 1 x Thunderbolt™ (USB4®) header | N/A | ||
| Rear I/O | 3.2 Gen 2: 3 x USB Type-A, 1 x USB Type-C® 3.2 Gen 1: 2 x USB Type-A 2.0: 2 x USB Type-A |
3.2 Gen 2: 2 x USB Type-A 3.2 Gen 1: 2 x USB Type-A 2.0: 4 x USB Type-A |
||
| Front I/O | 3.2 Gen 1: 2 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
3.2 Gen 1: 2 x USB Type-A, 1 x USB Type-C® 2.0: 4 x USB Type-A |
||
| Aura | 3 x Addressable Gen 2 headers 1 x Aura RGB header |
|||
| Cooling | 6 x fan headers | 5 x fan headers | ||
Source: ASUS
« end of the press release »
Everything you need to know about Zen 4, socket AM5, and AMD’s newest chipsets
AMD
AMD’s Ryzen 7000 launch is bigger than just the processors. The processor architecture is changing, but it’s also being accompanied by changes to everything from the chipset to the physical socket that the chips plug into. The last time this many things changed at once was back in 2017, when the first-generation Ryzen chips originally launched.
So we’re publishing two Ryzen pieces today. One is a look at the actual chips’ performance and power efficiency, located here. This one will focus on all the other changes, including the ones that will be with us long after Ryzen 7000 is old news.
We’ll split this piece up into four parts that cover the four major components of the Ryzen 7000 launch: 1) the Zen 4 CPU core, 2) the on-chip I/O die that supports the CPU’s non-CPU features and handles internal connectivity, 3) the 600-series chipsets that handle most external connectivity, and 4) the physical AM5 socket that will outlive all of the other components by a few years.
The CPSC Says Plug To Socket, Not Plug To Plug, Please
When the power goes out, it goes without saying that all the lights and sockets in a house stop working. Savvy rural homeowners stock up with candles, batteries, LED lights, and inverters. More foolhardy folks simply hook up their home electrical system to a generator using a mains lead with a plug on one end between the generator and a wall socket. This should be so obviously dangerous as to be unnecessary, but it’s become widespread enough that the US Consumer Product Safety Commission has issued a warning about the practice. In particular, they’re concerned that there’s not even a need to wire up a lead, as they’re readily available on Amazon.
The dangers they cite include electrocution, fire hazard from circumventing the house electrical protection measures, and even carbon monoxide poisoning because the leads are so short that the generator has to be next to the socket. Hackaday readers won’t need telling about these hazards, even if in a very few and very special cases we’ve seen people from our community doing it. Perhaps there’s a flaw in the way we wire our homes, and we should provide a means to decouple our low-power circuits when there’s a power cut.
It’s likely that over the coming decades the growth of in-home battery storage units following the likes of the Tesla Powerwall will make our homes more resilient to power cuts, and anyone tempted to use a plug-to-plug lead will instead not notice as their house switches to stored or solar power. Meanwhile, some of us have our own ways of dealing with power outages.
Plug image: Evan-Amos, Public domain.
Large Dinosaur Predators – Such As T. rex – Evolved Different Eye Socket Shapes To Allow Stronger Bites
New research shows that large dinosaur predators evolved different shapes of eye sockets to better deal with high bite forces.
According to new research, large dinosaur predators, such as Tyrannosaurus rex, evolved different shapes of eye sockets to better deal with high bite forces.
While in many animals, including most dinosaurs, the eye socket is just a circular hole in the skull housing the eyeball, this is very different in large carnivores.
A new study reveals how the unusual elliptical, or oval eye sockets found in the skulls of these predators, could have evolved to help the skull absorb impact as they pounced on prey. This research, by scientists at the University of Birmingham, was published today (August 11, 2022) in Communications Biology.
Skull and life reconstruction of Tyrannosaurus rex with original eye socket and eye (left) and hypothetical reconstruction with circular eye socket and enlarged eye (right). Credit: Dr. Stephan Lautenschlager, University of Birmingham
Dr. Stephan Lautenschlager, Senior Lecturer for Palaeobiology at the
“The results show that only some dinosaurs had eye sockets that were elliptical or keyhole-shaped,” said Dr. Stephan Lautenschlager. “However, all of those were large, carnivorous dinosaurs with skull lengths of 1 m or more.”
Computer simulations of hypothetical dinosaur skulls. Colors indicate skull stress. High stresses occur in the skull with a round eye socket (top), lower stresses in a skull with a keyhole-shaped eye socket (bottom). Credit: Dr. Stephan Lautenschlager, University of Birmingham
Dr. Lautenschlager tested what purpose these unusual eye socket shapes could have by using computer simulations and stress analysis.
The results demonstrated that a skull with a circular eye socket was more prone to high stresses during biting. However, if these were replaced with other eye socket shapes stresses were significantly reduced. This allowed top predators, including Tyrannosaurus rex, to evolve high bite forces without compromising skull stability.
The study also showed that most plant-eating species and juvenile individuals retained a circular eye socket. Only large carnivores adopted other morphologies, such as elliptical, keyhole-shaped, or figure-of-eight-shaped eye sockets.
Skulls of different dinosaurs showing variation in eye socket shape (stippled outline). Credit: Dr. Stephan Lautenschlager, University of Birmingham
Dr. Lautenschlager added: “In these species, just the upper part of the eye socket was actually occupied by the eyeball. This also led to a relative reduction of eye size compared with skull size.”
The researchers also investigated what would have happened if eye size had increased at the same rate as skull length. In such a case, the eyes of Tyrannosaurus rex would have been up to 30 cm (12 inches) in diameter and weighed nearly 20 kg (44 pounds). This is instead of an estimated 13 cm (5 inches) and 2 kg (4.4 pounds).
Reference: “Functional and ecomorphological evolution of orbit shape in mesozoic archosaurs is driven by body size and diet” by Stephan Lautenschlager, 11 August 2022, Communications Biology.
DOI: 10.1038/s42003-022-03706-0
AMD EPYC Genoa Server CPU & SP5 Socket With Heatsink Gets Close Up Shots, Massive Chip With Massive Performance
AMD’s EPYC Genoa 9000 CPUs and the accompanying SP5 socket with its heatsink have been pictured once again. The next-gen EPYC lineup is going to feature a monstrous amount of performance packed under the hood with up to 96 cores and 400W TDPs as disclosed within specifications that leaked a few days ago.
AMD EPYC Genoa 9000 CPU With Zen 4 Cores & SP5 Socket With Heatsink Pictured – Big, Badass, and Blazing Fast Server Chip
The AMD EPYC Genoa 9000 CPUs feature support for new memory and new capabilities. In the most recent details from the company, reports state that the SP5 platform will also introduce a brand new socket, featuring a massive 6096 pins arranged in the LGA socket format. This processor will be AMD’s most significant socket design, adding 2002 pins more than the current LGA 4094 socket set.
For AMD to access those 96 cores, the company has to cramp more cores into its EPYC Genoa CPU package. AMD will achieve this by incorporating up to 12 CCDs. Each CCD will offer eight cores based on the new upcoming Zen 4 architecture. That aligns with the expanded socket size and could be witnessing a considerable CPU interposer — much more prominent than current EPYC CPUs. The processor is reported to feature a 320W TDP which can be configurable to up to 400W.
AMD EPYC Milan Zen 3 vs EPYC Genoa Zen 4 Size Comparisons:
| CPU Name | AMD EPYC Milan | AMD EPYC Genoa |
|---|---|---|
| Process Node | TSMC 7nm | TSMC 5nm |
| Core Architecture | Zen 3 | Zen 4 |
| Zen CCD Die Size | 80mm2 | 72mm2 |
| Zen IOD Die Size | 416mm2 | 397mm2 |
| Substrate (Package) Area | TBD | 5428mm2 |
| Socket Area | 4410mm2 | 6080mm2 |
| Socket Name | LGA 4094 | LGA 6096 |
| Max Socket TDP | 450W | 700W |
Photos of the socket have been seen before online, but the new designs showcase at a much higher resolution in the recent photo set. Likewise, we also see a picture of the SP5 heatsink that will be attached with up to eight Torx screws.
The next-gen data center AMD EPYC Genoa CPUs will launch in Q4 2022 and is anticipated to show before rival Intel reveals the mass production of its Xeon Sapphire Rapids. It is also reported that both AMD and Intel processors have been available to select customers for premature deployment and testing.
News Sources: Twitter, Reddit, VideoCardz
AMD EPYC Genoa “Zen4” CPU gets pictured some more along with its massive SP5 socket and heatsink
AMD EPYC Genoa poses for new photos
Earlier this week YuuKi_AnS revealed the specs of the EPYC 9004 series based on Genoa silicon. These are the upcoming data-center series featuring AMD Zen4 architecture. Based on this information, the new EPYC will feature up to 96 cores and 360W of TDP, a 50% increase in cores and 28% in TDP compared to Zen3 EPYC Milan series.
EPYC Genoa will be encapsulated into a new AMD SP5 package and for LGA-6096. This basically means that Genoa will require entirely new motherboards and as a result new cooling solutions.
AMD EPYC Genoa Engineering Sample, Source: YuuKi_Ans/Reddit
The photos of this new socket have been posted before, but the new ones might be the highest resolution of them yet. Furthermore, there is a photo of the SP5 heatsink attached with as many as 8 torx screws.
AMD SP5 socket and heatsink, Source: YuuKi_Ans/Reddit
AMD Genoa is set to launch in the fourth quarter this year, most likely before Intel deploys its Xeon Sapphire Rapids in volume. Both processors have already been available to first customers, either for early deployment or for testing. In any case, this is how such photos end up posted online.
Source: YuuKi_AnS, Reddit
Intel 14th Gen Core desktop “Meteor Lake” allegedly requires new LGA-2551 socket
Please note that this post is tagged as a rumor.
Intel might be saying goodbye to LGA1700/1800 already in 2023
According to the latest rumors from Moore’s Law is Dead, Raptor Lake-S might be the last desktop series for the LGA1700 socket.
14th Gen Core Meteor Lake
It would appear that the rumors stating Intel will keep 3 generations on the same socket are untrue. In the fourth quarter of 2023 when Intel is expected to launch a new desktop series codenamed Meteor Lake, an entirely new socket might be required.
The LGA 2551 wouldn’t be much bigger than the LGA1700 socket though. According to MLID, it’s 38 × 46 mm, which means 0.5 mm wider and 1 mm taller socket. However, the 2551 indicates it will have 50% more pins.
MLID posted a real photo (although slightly altered) of the alleged LGA 2551 processor:
Intel LGA2551 CPU, Source: MLID
Furthermore, MLID reaffirms the rumors that were shared by other leakers over the past few weeks, but has a different idea on the expected launch date. In this case, we should expect MTL-S in fourth quarter of 2023, not in 2024 as mentioned elsewhere. Unfortunately, MLID is not confirming the core configuration for desktop Meteor Lake series, so one might guess it could be similar to Raptor Lake.
Intel Meteor/Arrow lake rumors, Source: Moore’s Law is Dead
15th Gen Core Arrow Lake
The Lion Cove/Skymont cores might already debut with Arrow Lake. These new microarchitectures were previously rumored for Lunar Lake. As mentioned in previous leaks, the 15th Gen Core would not see an increase in Performance cores, but Efficient cores count would double over Raptor Lake, now counting 32 in total.
More importantly, Arrow Lake desktop would be compatible with LGA 2551 socket, so at least two generations would be supported by the new desktop platform. This architecture is expected to compete with AMD’s Zen6 architecture, which has not been confirmed by the company yet. One shouldn’t expect Arrow Lake sooner than second half of 2024 though.
| Intel Mainstream CPU Roadmap (RUMORED) | |||||
|---|---|---|---|---|---|
| VideoCardz | Alder Lake | Raptor Lake | Meteor Lake | Arrow Lake | Lunar Lake |
| Desktop Launch Date | Q4 2021 | Q4 2022 | Q4 2023 | 2H 2024 | 2024+ |
| CPU Node | Intel 7 | Intel 7 | Intel 4 | Intel 20A | Intel 18A |
| Big Core µArch | Golden Cove | Raptor Cove | Redwood Cove | Lion Cove | TBC |
| Small Core µArch | Gracemont | Gracemont | Crestmont | Skymont | TBC |
| Graphics µArch | Xe-LP | Xe-LP | Xe-HPG | Xe-HPG | Xe2-HPG |
| Max CPU Core Count | 16 (8C+8c) | 24 (8C+16c) | TBC | 40 (8C+32c) | TBC |
| Max GPU Core Count | 96 EU | 96 EU | 192 EU | 320 EU | TBC |
| Desktop Socket | LGA1700 | LGA1700 | LGA 2551 | LGA 2551 | TBC |
| Memory Support | DDR4/DDR5-4800 | DDR4/DDR5-5600 | DDR5 | TBC | TBC |
| PCIe Gen | PCIe 5.0 | PCIe 5.0 | PCIe 5.0 | TBC | TBC |
| Intel Core Series | 12th Gen Core | 13th Gen Core | 14th Gen Core | 15th Gen Core | 16th Gen Core |
Source:
[Moore’s Law Is Dead] Intel Arrow Lake, Meteor Lake, Raptor Lake Leak: Crazy Performance, Crazier Delays (16,999 views)
170W Socket Power Limits, 5.5 GHz Stock Clock Speeds, Smart Access Storage & More
During the latest episode of PCWorld’s ‘The Full Nerd’ webcast series, guests Robert Hallock (AMD Director of Technical Marketing) and Frank Azor (Chief Architect of Gaming Solutions) answered a series of questions and further detailed the Ryzen 7000 Desktop CPUs and the features we will be seeing on the AM5 platform.
AMD Details Ryzen 7000 Desktop CPUs & AM5 Motherboard Platform Features
So there were a range of questions asked and both Robert and Frank did an absolutely splendid job in answering them to the folks over at PCWorld. We have slowly been getting more details on the AMD Ryzen 7000 CPU and AM5 platform showcased since the Computex 2022 unveil and well, let’s start off with the latest information.
Some of the things that were confirmed in the interview include:
- Ryzen 7000 is 125W TDP / 170W Package Power
- Ryzen 7000 5.5 GHz Demo Was In Stock-Spec (No Overclock)
- Ryzen 7000 Double L2 Cache is IPC-Benefit
- Ryzen 7000 CPUs Have 28 PCIe Gen 5 lanes (24 Usable)
- 1:1 Infinity Fabric Clock (No Frequencies Mentioned)
- B650 Motherboards will support overclocking (like B550 series)
- Integrated RDNA 2 GPU supports both Video encode/decode
- Integrated RDNA 2 GPU For Commercial/Diagnostic Purposes
- Smart Access Storage Details (Requirements Highlighted)
AMD Ryzen 7000 CPU Package Power: 125W TDP For Ryzen 7000 CPUs & 170W Package Power For AM5 Socket
First of all, the TDP (Thermal Dissipation Power) figures for AMD Ryzen 7000 CPUs are going to be 125W while the PPT (Package Power Tracking) is going to be 170W. AMD provided this information in a reply to whether the 170W figure was an actual TDP for the upcoming chips or an upper-bound limit for the package.
As per AMD, this is an increase of around 28W over the AM4 package power limit (PPT) which was 142W while the CPUs had a TDP of 105W. According to AMD, motherboard manufacturers will now be able to deploy more premium power characteristics on their motherboards which should allow for better overclocking opportunities for enthusiasts and overclockers.
So what we want to clarify is that it’s a 170 Watt socket power which with AMD, that spec is PPT (Package Power) for us. That doesn’t mean that every CPU is going to go up to 170 Watts but it’s 30 (Watt) higher than the socket AM4 power cap which was a 142 (watts). And we did this to mainly improve multi-thread performance as many of the core count chips were actually held back in overall compute performance by relatively modest socket power.
The other point that I want to make is that by raising the minimum required socket power or minimum spec, you also raise the power delivery with every motherboard built to that spec so you get more robust power characteristics on all the boards which we are pretty excited about as well, It should be good for people who want to experiment with overclocking, people who appreciate premium board designs.
Robert Hallock (AMD Director of Technical Marketing)
Furthermore, Robert confirmed that the AMD Ryzen 7000 CPUs feature a total of 28 PCIe Gen 5 lanes, confirming our previous leaks. The thing is that out of those 28 lanes, only 24 are usable by the discrete GPU and M.2 storage devices since the rest of the four lanes are connected to the 600 series PCH. As for the chipsets themselves, Robert also confirmed that B650 motherboards will be fully supportive of overclocking like their B*50-class predecessors. We have more information on that and the B650E chipsets here.
AMD Ryzen 7000 5.5 GHz CPU Demo Was On Stock Spec, No Overclocking Or Premium Components Used
As for the 5.5 GHz clock speed gaming demo, Robert reassured that the frequencies were entirely on stock spec. The motherboard used was a reference X670 design and the cooling was a standard ASETEK 280mm AIO cooler. It is also obvious that no overclocking was involved since the clocks varied between 5.1 to 5.5 GHz.
AMD showcased some insanely fast frequencies with the same Ryzen 7000 CPU sample hitting up to 5.52 GHz but we did see some variation in the clock speeds which started at 5.1 GHz and went up to the max 5.52 GHz speed which everyone is talking about. Interestingly, Robert states that in the respective game demo, they saw most of the threads clocking up to 5.5 GHz (that’s 32 threads for the prototype that was used). The 16-core Ryzen 7000 prototype was produced around Late April or Early May so AMD could still squeeze more headroom out of this chip if they want to or just let overclockers do the job.
AMD Ryzen 7000 16-Core Pre-Production Sample ‘Gaming’ Clocks:
We used a 280mm (ASETEK) watercooler so nothing exotic it’s just a dual 140 loop that you can buy from Amazon or Newegg. It was running an AMD reference motherboard so one of our internal AM5 socket motherboards, a 16 core prototype part built in late April or early May and we just plugged it in and ran it. It was not an overclocked part, its just the natural frequency of that particular prototype.
So in the game, we were running most of the threads around 5.5 (GHz), it depends on the game load, depends on the scene, of course, clock speed fluctuates up and down so somewhere between 5.2 and 5.5 is pretty common on all the threads playing that game. So I wanna reassure people that this was nothing exotic in terms of cooling and nothing exotic in terms of parts selection or config or overclocking. It is exactly what you see, you plug in a Ryzen 7000 series part and play the game, & that’s the frequency!
Robert Hallock (AMD Director of Technical Marketing)
AMD Ryzen 7000 Can Achieve 1:1 Infinity Fabric Clock, Doubles The L2 Cache
Robert also talked about how the doubling of the L2 cache can help improve IPC-related core performance. The L2 cache wasn’t increased dramatically since more L2 cache results in more hits but it also means poor latency and dies sizes getting bigger which adds to the cost. So AMD found a ground where the L2 cache is increased enough to add to the performance benefits of the Ryzen 7000 Desktop CPUs.
So L2 cache, we did double it in Zen 4, it is an IPC benefit, it helps the core contain internally more information, overall it improves throughput and so it will be beneficial to multiple categories of workloads, be it integers like gaming or more floating-point like stuff like scientific and creative workloads.
Robert Hallock (AMD Director of Technical Marketing)
On getting asked if the new AM5 platform will run DDR5 memory at a 1:1 ratio with the Infinity Fabric, Robert replied ‘Yes’ but didn’t mention what frequencies it would run up to. That’s another topic of discussion when we will get closer to the official launch of the Ryzen 7000 Desktop CPUs on the AM5 motherboards.
AMD Ryzen 7000 RDNA 2 iGPUs: Video Encode/Decode, APUs Still Happening For Desktops!
As for what the new RDNA 2 iGPUs on the Ryzen 7000 Desktop CPUs bring to the table, AMD states that with an integrated graphics on their entire CPU portfolio, they can expand their business into the commercial segment and that makes a lot of sense since a lot of consumers there don’t require a discrete graphics card and want something that is as simple as plug-and-play.
For DIY builders, the RDNA 2 iGPU can provide troubleshooting and diagnostic capabilities where users with graphics cards can debug if their graphics card is faulty or not or for other purposes. The same can be applied to users without graphics cards or those waiting on one who can’t turn on their PC until they get their discrete GPU.
Frank Azor took the topic to a more interesting space by stating that while AMD Ryzen 7000 CPUs will have ‘little graphics’ cores compared to the ‘bigger graphics’ cores on APUs, they will still host some of the Smart Eco technologies boasted by notebooks. While AMD’s RDNA 2 iGPUs can allow for sub-50W power usage in idle mode, Smart Shift on Desktop CPUs with RDNA 2 iGPUs can switch from discrete graphics to integrated graphics for light-weight workloads and offer sub-5W power or even mW power.
The other thing is that, unlike AMD’s Navi 24 GPUs, the Ryzen 7000 iGPU based on the same RDNA 2 core architecture (but on a 6nm Rembrandt revision) will come with a VCN engine that supports both AV1 Video Encode and Decode.
We still think of the Ryzen 7000 series as a CPU. The graphics cores in that IO die are not many, the purpose of adding graphics is three-fold. One, it greatly expands these products in the commercial market where they don’t buy discrete at all, they just want to turn it on, have video encode/decode and light up some displays for office work and that’s what the GPU in the IO die will offer so that’s a huge business opportunity for us on the Ryzen PRO side as we start migrating these components over to that business.
The second is for diagnostic purposes, how do you know that you have a bad graphics card? Well, you have to swap in another graphics card but with the graphics core we have, you can do a little bit of troubleshooting thirdly, we were thinking about users who are planning to buy a discrete graphics, and it’s still in transit in the mail but all the other hardware has arrived first so it’s all sat there, looking at a pile of components and don’t have a GPU to actually set that all up. That would go away with the Ryzen 7000 series.
We are still going to do APUs with big graphics so APUs ‘BIG GRAPHICS’, CPUs ‘little graphics’. That would be our strategy going forward.
Robert Hallock (AMD Director of Technical Marketing)
We are developing a lot of technologies that make use of integrated graphics in many ways and there are things that we are able to do with technologies such as Smart Shift ECO where we can turn off the discrete graphics and we can run the notebook off of the iGPU and say you want that because you want less heat, longer battery life (even when you are playing a game) or you want less fan noise or lower power consumption, there’s all these benefits to it. Because we have that thin integrated graphics in Ryzen 7000 series, it’s going to allow us to bring more of these types of smart technologies over to the desktops aswell so those customers can get some of these benefits.
Frank Azor (Chief Architect of Gaming Solutions)
As for whether we will see a iGPU disabled variant of Ryzen 7000 Desktop CPUs, Robert did state that all Zen 4 chips will have integrated RDNA 2 graphics so those in hopes of seeing a ‘KF-esque’ variant should be a bit dissappointed.
AMD Smart Access Storage vs Direct Storage? They Are The Same Thing But SAS Is The Shortcut!
Moving over to the Direct Storage side of things, AMD introduced its own technology known as Smart Access Storage SAS. Users have been confusing it as a replacement for Direct Storage when in fact, SAS is based on the same algorithms and APIs as Direct Storage and allows the NVMe SSD to directly communicate with the discrete graphics. Frank provides a detailed explanation of what SAS is below:
I have seen Smart Access Storage in action and it works pretty well! The primary difference between Direct Storage and Smart Access Storage is that, think of, first of all, Smart Access Storage uses Direct Storage so that’s really important to know. It’s not a replacement for it is something that we built that takes advantage of Direct Storage, it uses the compression algorithms and APIs that Direct Storage promotes, supports, and endorses and asks ISVs to design so it’s fully compatible with them.
What we do a little differently with Smart Access Storage is that because we own an entire platform from an architecture perspective, end to end, from CPU to all the way to storage subsystem to all the way to graphics, that allows us to create more efficient streamlines between the game content and GPU itself. We can avoid some parts of the PC subsystem in order to reduce latency and increase performance to reduce bottlenecks when it comes to decompressing game assets and streaming game assets on the GPU.
Smart Access Storage is more of a ubiquitous solution that has to work across a lot of different combinations of hardware that are out there and those combinations may include mixed configurations, let’s say AMD’s CPU and somebody else’s graphics card. and that’s getting more and more complex, you are gonna have three graphics card partners, you have two CPU partners, that may even get more complex, so because it’s more of a hiding compatible ubiquitous solution, there’s more overhead built in order for it to be compatible so there are more CPU calls than more system memory that it has to do in order for it to work so there’s more decompression and management that is done in the CPU versus in our solution, it’s a direct pipe from NVMe to the GPU with those bottlenecks and overheads removed.
We have designed Smart Access Storage to be as open as possible from a compatibility perspective so that’s why we are using Direct Storage we are going to work with Direct Storage titles and we are going to optimize to work with Direct Storage. We don’t have any intention of developing our own algorithm or API since we don’t want to create a walled garden or another walled garden in the industry, so ideally what we would like to have to happen and this is how we designed Smart Access Storage is that you have a Direct Storage compatible game and you have an all AMD desktop or laptop, we’ll have a foundational infrastructure in place so that so we can avoid those routes that add latency and some of those bottlenecks because of compatibility and we kinda short cut and allow the NVMe to direct send data over to the GPU for decompression. So that’s our architecture and our approach is fully compatible but when we can take a shortcut because we have the end-to-end platform, we are gonna enable that shortcut to be taken.
Frank Azor (Chief Architect of Gaming Solutions)
Frank Azor also says that AMD Ryzen 7000 CPUs and the AM5 platform will feature SAS support across the board but there will be a list of SSDs and components that specifically meet their SAS requirements. Not all Gen 4 and Gen 5 SSDs will be compliant with Smart Access Storage:
We have an authorized vendor list of parts that we are developing right now with NVME drives and controllers that are meeting our performance requirements around Smart Access Storage. Just because you have a PCIe Gen 4 or the upcoming Gen 5 drive, it doesn’t mean that those drives are going to be able to keep up with the performance demands and capabilities of Smart Access Storage so something folks should understand is that today a lot of the reason why your NVMe drive isn’t able to fully capitalize on its theoretical performance capability is that there are bottlenecks in the data fabric and those bottlenecks exist in different parts of the PC so that often affects your theoretical versus real performance.
What will happen with Smart Access Storage is that once you remove all those paths from point A to point Z that are your obstacles (bottlenecks), suddenly, your NVMe drive will become the bottleneck because the dGPU can receive the data extremely fast but if your NVMe drive was designed from the get-go counting on these bottlenecks along the data path, then you knew you didn’t put much performance on it because you knew it was going to get wasted. You may have used a slower controller or not used the most premium parts or not optimized your product for the highest theoretical limit that it can reach.
Frank Azor (Chief Architect of Gaming Solutions)
As for the launch, the AMD Ryzen 7000 Desktop CPUs are said to launch this fall which means the earliest we are going to see the chips in action is September 2022.
AMD Mainstream Desktop CPU Generations Comparison:
| AMD CPU Family | Codename | Processor Process | Processors Cores/Threads (Max) | TDPs (Max) | Platform | Platform Chipset | Memory Support | PCIe Support | Launch |
|---|---|---|---|---|---|---|---|---|---|
| Ryzen 1000 | Summit Ridge | 14nm (Zen 1) | 8/16 | 95W | AM4 | 300-Series | DDR4-2677 | Gen 3.0 | 2017 |
| Ryzen 2000 | Pinnacle Ridge | 12nm (Zen +) | 8/16 | 105W | AM4 | 400-Series | DDR4-2933 | Gen 3.0 | 2018 |
| Ryzen 3000 | Matisse | 7nm (Zen 2) | 16/32 | 105W | AM4 | 500-Series | DDR4-3200 | Gen 4.0 | 2019 |
| Ryzen 5000 | Vermeer | 7nm (Zen 3) | 16/32 | 105W | AM4 | 500-Series | DDR4-3200 | Gen 4.0 | 2020 |
| Ryzen 5000 3D | Warhol? | 7nm (Zen 3D) | 8/16 | 105W | AM4 | 500-Series | DDR4-3200 | Gen 4.0 | 2022 |
| Ryzen 7000 | Raphael | 5nm (Zen 4) | 16/32 | 170W | AM5 | 600-Series | DDR5-5200/5600? | Gen 5.0 | 2022 |
| Ryzen 7000 3D | Raphael | 5nm (Zen 4) | 16/32? | 105-170W | AM5 | 600-Series | DDR5-5200/5600? | Gen 5.0 | 2023 |
| Ryzen 8000 | Granite Ridge | 3nm (Zen 5)? | TBA | TBA | AM5 | 700-Series? | DDR5-5600+ | Gen 5.0 | 2024-2025? |
16 Cores of Zen 4, Plus PCIe 5 and DDR5 for Socket AM5, Coming This Fall
During the AMD Keynote at Computex 2022, its CEO, Dr. Lisa Su officially unveiled their next generation of Ryzen processors and the successor to the highly successful Ryzen 5000 series. The new family, the Ryzen 7000 series, will feature up to 16 Zen 4 cores using TSMC’s optimized 5 nm manufacturing process.
AMD Ryzen 7000 also officially marks the end of its long-serving AM4 socket, with the new AM5 LGA1718 socket replacing it with a freshly announced trio of new performance-driven chipsets, including X670E, X670, and B650.
AMD Ryzen: A Brief Recap of Five Years Reinvigorating the Desktop
Since AMD’s original Ryzen (Zen) debuted back in 2017, AMD has consistently innovated and progressed its core architecture in a way that before Zen, no one other than AMD itself thought possible. Some of the main advancements that came with Zen included the new AM4 socket, which is undoubtedly one of the most successful in its history and brought DDR4 memory to the mainstream market. In 2018, AMD shipped its updated Zen+ microarchitecture through the Ryzen 2000, based on GlobalFoundries more efficient and optimized 12 nm architecture, along with a notable uplift in IPC performance gains to boot.
Moving forward into 2019, AMD debuted the Zen 2 architecture, which was used as the basis for the Ryzen 3000 series of CPUs. Switching to TSMC’s high-performance 7 nm manufacturing process, AMD delivered higher performance levels over Zen/Zen+, with double-digit gains in IPC performance and a completely new design shift through the use of chiplets.
This continued into 2020 when AMD started shipping its Zen 3 core with monumental gains over Zen 2, with up to 19% gains in IPC over Zen 2, as well as the introduction of its Resizable BAR feature, higher levels of L3 cache than ever before, and the introduction of PCIe 4.0 to desktop.
AMD Ryzen 7000: Bringing Zen 4 and 5 nm to Consumer Desktop
The latest in AMD’s arsenal, and perhaps one of the most highly anticipated processor announcements of the year, the AMD Ryzen 7000 family has finally been announced with some new features designed to deliver a premium desktop experience. We’ve known for a long time that the Zen 4 microarchitecture is based on an optimized TSMC 5 nm manufacturing process, but we haven’t learned some of the more detailed intricacies until now.
Although the TSMC 5 nm manufacturing process was initially found in smartphones, with Apple and Huawei both championing the transition, Zen 4 marks the first use of 5 nm for desktop systems. The AMD Ryzen 7000 and Zen 4 are similar to Zen 3, including a chiplet-based design, with two Core Complex Dies (CCDs) based on TSMC’s 5 nm manufacturing process.
While AMD isn’t going into great detail on the Zen 4 architecture today – they have to save something to disucss for later in the year – for now the company is disclosing that Zen 4 will come with 1MB of L2 cache per CPU core, which is twice the amount of L2 cache as found on Zen 3 (and Zen 2) CPU cores. Meanwhile L3 cache will remain a subject for another day; AMD isn’t offering details on its L3 cache or whether we will see Zen 4 models with its 3D V-cache stacked packaging.
Coupled with that L2 cache improvement, AMD is aiming for higher clockspeeds, thanks to their architectural design and TSMC’s 5nm process. Officially the company is only claiming “5GHz+” max turbo clockspeeds for now, but in a demo video shown by Dr. Su, AMD’s pre-production 16 core Ryzen 7000 chip was shown to be boosting to above 5.5GHz, which is a significant uplift from the sub-5GHz speeds of AMD’s current Ryzen 5000 desktop chips.
As a result of these cache, architectural (IPC), and clockspeed improvements, AMD is touting a greater than 15% increase in single-threaded performance. And, checking AMD’s disclosure notes, this is based on early Cinebench R23 notes, comparing their pre-production 16C Ryzen 7000 chip to a 16C 5950X. Given the significant clockspeed increases that AMD has demoed on this chip, this does imply that most of AMD’s performance improvements are coming from the clockspeed improvements rather than IPC uplift. However Cinebench is a single benchmark, and for the moment we don’t have any further information on what core architectural changes AMD has made.
Though AMD is disclosing that Zen 4/Ryzen 7000 is getting AI acceleration instructions. Like so many other aspects of the chip, more details are to come, but it sounds like AMD is adding some instructions for manipulating data with common AI data formats such as bfloat16 and int8/int4.
For Ryzen 7000, AMD is also introducing a new 6 nm I/O die (IOD), which replaces the 14 nm IOD used in previous Zen 3 designs. Marking a first for AMD, the new IOD is incorporating an iGPU, in this case based on AMD’s RDNA2 architecture. So with the Ryzen 7000 generation, all of AMD’s CPUs will technically be APUs as well, as graphics is a basic part of the chip’s construction. What this means for the future of AMD’s monolithic desktop APUs is uncertain, but at a minimum, it means that all (or virtually all) of AMD’s CPUs will be suitable for use in systems without discrete graphics, which although not a huge deal for consumer systems, is very much a big deal for corporate/commercial systems.
The new IOD also affords AMD the opportunity for some significant platform power savings. Not only is TSMC’s 6nm process well ahead of GlobalFoundries’ old 14nm process, but the design process has allowed AMD to incorporate many of the power-saving technologies that were first developed for the Ryzen 6000 Mobile series, such as additional low power states and active power management capabilities. As a result, Ryzen 7000 should fare much better at idle and low utilization workloads, and it’s a reasonable assumption to see the IOD drawing less power at load, as well (at least with graphics disabled). Though at full load, with up to 16 cores running at over 5GHz, the CCDs are still going to draw a lot of power.
On the matter of power, it’s also noteworthy that AMD is indicating that Ryzen 7000 will operate at higher TDPs. While AMD isn’t announcing official SKUs at this point, they are explicitly noting that the new AM5 platform allows for TDPs (CPU Package Power) up to 170 Watts in this generation, which is up from the 105W TDPs of the AM4-based Ryzen 5000 series.
Last, but certainly not least, AMD’s Zen 4 microarchitecture combined with the new IOD also brings about a host of new features, including official support for PCIe 5.0, much like Intel introduced with its Alder Lake (12th Gen Core) architecture. Combining AMD Ryzen 7000 with an X670E, X670, or B650 motherboard will provide up to 24x PCIe lanes split between slots and storage devices. Based on AMD’s disclosures, it sounds like all of the lanes coming off of the Ryzen 7000 chip itself will be PCIe 5.0-capable, but it will be up to motherboard manufacturers to actually design their boards to support PCIe lanes at the highly-sensitive 5.0 speeds. As a result, Ryzen 7000 chips plugged into some lower-end motherboards will only offer a far more limited number of lanes at PCie 5.0 speeds, with the rest operating at PCIe 4.0 speeds.
AMD’s AM5 Platform: Socket LGA1718 with Three New Chipsets – X670E, X670, and B650
As the announcement of AMD’s Ryzen 7000 family of processors officially brings the previous AM4 platform to an end. Ryzen 7000 will be the first family of processors using AMD’s new AM5 platform, which AMD is also disclosing the first deals of today. Using a LGA-type socket with 1718 pins, AM5 is the other piece of the puzzle in introducing DDR5 and PCIe 5.0 support, as well as higher processor TDPs.
The big news on the I/O front is of course PCIe 5.0 support. This is intended to be used to drive next-generation video cards (and other accelerators) as well as next-generation SSDs, with AMD expecting the first PCIe 5 consumer SSDs to be avaialble just in time for the AM5 platform launch. With up to 32GB/sec of bandwidth in each direction, PCIe 5.0 will offer a lot of bandwidth, but its very tight signal integrity requirements are also in part what required AMD to move to a new socket, with LGA apparently being a better fit.
AM5 also brings quad-channel (128-bit) DDR5 support to AMD’s platforms, which promises a significant boost in memory bandwidth. And, in an interesting move, AMD is offering only DDR5 support. Unlike Intel, whom we saw support both DDR5 and DDR4 with its Alder Lake platform last year, AMD is not including any kind of support for older memory formats here.
Given the high-level nature of today’s disclosures, AMD unsurprisingly isn’t talking about supported memory speeds. But based on their testing footnotes for their pre-release processor performance claims, we see that AMD did test with DDR5-6000 memory. So while almost certianly using overclocked (XMP) memory there, it implies AM5/Ryzen 7000 has some memory overclocking headroom to offer.
One interesting thing that we’ve already mentioned is that AMD Ryzen 7000 will move to support processors up to 170 W on Zen 4, as opposed to 105 W TDP found on processors such as AMD’s previous Ryzen 9 5950X. AMD is also using a new heat spreader (IHS) design on Ryzen 7000, which AMD has done to allow compatibility with previous socket AM4 coolers. This means that theoretically, users looking to upgrade to Ryzen 7000 will be able to use pre-existing coolers with socket AM4 support.
Supporting the new AM5 platform will be a trio of new new motherboard chipsets: X670E, X670, and B650. Starting with the flagship X670E ‘Extreme’ chipset, this is designed for its most premium models, focusing on extreme overclocking, with a full loadout of PCIe 5.0 support – meaning support for two PCIe 5.0 graphics slots, as well as at least one PCIe 5.0 M.2 slot for storage. Which from AMD’s specifications we can infer would be in a x8/x8/x4 loadout, using PCIe lane bifurcation to split off 8 lanes from a first PCIe x16 slot to a second slot when both are in use.
Interestingly, AMD differentiates X670 into two market segments compared to previous iterations such as X570, X470, and the X370 chipsets. While both the X670E and X670 cater to enthusiasts, X670 is designed to be a slightly downmarket offering, taking a step back in the amount of functionality motherboard vendors are expected to offer with those boards. In particular, X670 does not require PCIe 5.0 support for the PCIe x16 slots – while many boards will offer it, an X670 board would also be allowed to implement PCIe 4.0 instead. Do note, however, the PCIe 5.0 is still required for at least one M.2 slot for NVMe SSDs.
Between the two versions of the X670 chipset, it seems as though the most premium models such as ASUS’s ROG Crosshair series, MSI’s MEG series, and GIGABYTE’s Aorus Xtreme series will be based on X670E, in order to separate it from the more mid-range focused and more widely affordable X670 options.
Finally, we have the B650 chipset. As with previous AMD B-series chipsets, will target mainstream users with more affordable options. Like the rest of the AM5 chipsets, B650 requires PCIe 5.0 support for at least one M.2 slot for storage, while it does away with PCIe 5.0 support for PCIe slots entirely. It also doesn’t have any overclocking support explicitly mentioned. At a high level B650 sounds a lot like X670 with overclocking enabled, but we’ll have to wait to hear from AMD and motherboard vendors for more explicit details.
Along with the announcement of X670E, X670, and the B650 chipsets, AMD has announced some of the most premium motherboards we can expect to see for the launch of Ryzen 7000. This includes a range of flagship and premium X670E boards from families we’ve seen many times before, including the ASRock X670E Taichi, the ASUS ROG Crosshair X670E Extreme, the Biostar X670E Valkyrie, the GIGABYTE X670 Aorus Xtreme, and the MSI MEG X670E Ace motherboards.
We don’t have any official specifications from motherboard vendors regarding the announced models at the time of writing. Still, we expect to start receiving specifications, controller sets, and power delivery information very soon.
On the power delivery front, AMD has confirmed that AM5 will support AMD’s Serial Voltage 3 (SVI3) standard. First introduced as part of the Ryzen 6000 Mobile series, SVI3 allows for finer grained power control and significantly faster voltage response capabilities. And for desktop boards in particular, SVI3 also supports a larger number of power phases, which will be especially useful for high-end X670E motherboards.
Rounding out the AM5 platform, since all of AMD’s Ryzen 7000 CPUs will have integrated graphics, AM5 as a whole has graphics support baked into every tier of motherboards. AM5 motherboards will be able to support up to four display outputs using a mix of HDMI 2.1 and DisplayPort 2.
Finally, the platform will come with an upgrade to AMD’s USB capabilities, though seemingly not as much as we had first hoped. According to AMD, the platform supports up to 14 SuperSpeed USB 20Gbps (USB 3.2 Gen 2×2) Type-C ports. Notably, AMD isn’t saying anything about USB4 here, so while 20Gbps ports are nothing to sneeze at, it doesn’t look like AM5 will offer the higher speeds and other perks of USB4 – at least not with this first generation of products.
AMD Ryzen 7000 Processors: Coming Fall 2022
Despite AMD essentially opting for a paper launch of its latest Ryzen 7000 family of processors, it hasn’t actually provided any details surrounding its SKUs or expected pricing. From the AMD Keynote during Computex 2022 hosted by CEO Dr. Lisa Su, we know AMD is planning to offer Ryzen 7000 with up to 16 cores, but it remains to be seen if AMD will go for even more cores in the coming months.
We know that on AM4 over the progression from 2017 to 2020 of AMD’s Ryzen family, Zen initially came with 8C/16T options (Ryzen 7 1800X), while we saw AMD double this capability with 16C/32T options such as the Ryzen 9 3950X.
It remains to be seen if we will see Ryzen 7000 with more than 16C models, but for now, that’s what AMD is sticking with, at least for Computex 2022. AMD did say we will get more information on its Ryzen 7000 family of processors and Zen 4 and the AM5 socket in the coming months as we head towards a full retail launch in the fall of 2022.