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AMD launches the first 7nm GPUs, but they're not for you


You'll have to wait a while longer for gaming cards. AMD is following through on its promise of releasing 7-nanometer GPUs -- not that you can use one yet. The company has formally launched Radeon Instinct MI50 and MI60 cards that use the denser, more efficient chip technology to accelerate specialized computing tasks like AI, cloud services and scientific calculations. The MI60 in particular is billed as the fastest double-precision accelerator of its type, pumping out 7.4 teraflops when crunching 64-bit floating point data. Both boards pack very high-bandwidth (up to 1TB/s) HBM2 memory and can work together in "hive rings" of up to four GPUs thanks to 200GB/s peer-to-peer links. The MI60 will make the promise of 7nm GPUs a reality by shipping to data centers before the end of 2018, while its more accessible MI50 counterpart should arrive no later than the first quarter of 2019. This isn't the 7nm gaming card many people are clamoring for, but it's still a milestone for the computing industry -- you can finally find 7nm tech in a GPU outside of a mobile chip. NVIDIA's RTX graphics hardware remains built on a 12nm process. Look at this as AMD laying the groundwork for 2019, when 7nm could is more likely to find its way inside your gaming rig.

AMD reveals Zen 2 processor architecture in bid to stay ahead of Intel


Advanced Micro Devices revealed the Zen 2 architecture for the family of processors that it will launch in the coming years, starting with 2019. The move is a follow-up to the competitive Zen designs that AMD launched in March 2017, and it promises two-times improvement in performance throughput. AMD hopes the Zen 2 processors will keep it ahead of or at parity with Intel, the worlds biggest maker of PC processors. The earlier Zen designs enabled chips that could process 52 percent more instructions per clock cycle than the previous generation. Lisa Su, CEO of Santa Clara, California-based AMD, made the announcement at an AMD press and analyst event in San Francisco. So much has really happened in the last two years, she said. Ive been CEO for four years. Its been an incredible four years. But we are just at the beginning of our journey. Zen has spawned AMDs most competitive chips in a decade, including Ryzen for the desktop, Threadripper (with up to 32 cores) for gamers, Ryzen Mobile for laptops, and Epyc for servers. In the future, you can expect to see Zen 2 cores in future models of those families of chips. AMDs focus is on making central processing units (CPUs), graphics processing units (GPUs), and accelerated processing units (APUs) that put the two other units together on the same chip. Zen 2 is our next-generation system architecture, Su said, noting chips using it will be made with 7-nanometer manufacturing, where the width between circuits is seven billionths of a meter. Su said the new chips will be targeted for the workloads of the future, including machine learning, big data analytics, cloud, and other tasks. AMD is going after the $29 billion total available market for data center chips by 2021. We see strong double-digit growth for the foreseeable future for the overall market, she said. We are not looking at incremental changes. The products you are seeing today are the products of the decisions we made four or five years ago. They were bets on where we think the market was going. The Zen-based designs are AMDs most competitive in a decade, and it now has every major computer maker using the Epyc chips for servers, from HP Enterprise to Dell. It is also feeding chips to data centers that run cloud deployments for Microsoft, Baidu, Tencent, Oracle, and others. AMD and Amazon Web Services announced today that Amazon Elastic Compute Cloud will use AMD Epyc CPUs, so customers can get access today to instances running on the AMD processors. Intel noted that it has an extensive relationship with AWS. The next-generation Epyc platform is code-named Rome, which will debut next year with 7-nanometer technology. Mark Papermaster, AMD chief technology officer, said AMD took a holistic design approach to creating Zen 2. Zen 2 marks the delivery of our promise of continuity, he said. We called a play and we are delivering. We are executing. Zen 2 chips are sampling today at 7-nanometer manufacturing, compared to the shipping 14-nanometer Zen processors that debuted in 2017. Zen 3 is on track to debut on 7-nanometer in 2020. AMD is using TSMC, the chip contract manufacturer, to make its 7-nanometer chips. Intel, meanwhile, has delayed its equivalent chips, dubbed 10-nanometer but at the same technology level, until late 2019. Zen 2 can get twice the throughput thanks to better branch prediction, or predicting what kind of processing will be necessary for the next computation. It also has better 256-bit load/store floating point processing, or double the previous generation. Zen 2 will also have stronger built-in security, where data can be fully encrypted as it is transferred to memory. You will see a huge jump as we go to Zen 2 products, Papermaster said. Intel has not yet made a comment, but it has scheduled a December 11 event to talk about its architecture. AMD also has a chiplet design approach with modular components on the chip that can more efficiently feed and receive data from processor cores. It will also have higher instructions per clock than the original Zen products. Kevin Krewell, analyst at Tirias Research, noted that AMD did not describe the instructions per clock cycle for Zen 2, but he assumes it will be better than the original Zen. He noted the doubled floating point performance figure was impressive. Forrest Norrod, senior vice president at AMD said that Epyc adoption can lead to 45 percent lower total cost of ownership (TCO) compared to Intel-based systems. He said that comes as a result of lower admin, licensing, hardware, and space costs. Pete Ungaro, CEO of Cray, said onstage that Crays next Shasta supercomputer with use AMD Epyc processors. The machine will be made for government agencies such as the Lawrence Berkeley National Laboratory and run at 100 petaflops.