This provides headroom and future scalability for DDR5-enabled systems. Plus, its unique features enable future chip density to grow from today's 16 GB up to 24 GB, 32 GB and beyond, quadrupling the module density of DDR5 over DDR4 DRAM.
Micron's DDR5 memory technology advancements offer higher bandwidth per core, nearly doubling the effective memory bandwidth to provide multi-core CPUs with the data they need for multi-tasking and other demanding PC applications.ĭDR5 allows for better power efficiency, decreasing operating voltage to 1.1 volts. Whether a PC is used for business, learning, creativity, interactive entertainment or personal use, the computing experience is defined by performance, flexibility and efficiency. Micron, today announced the immediate availability of Micron Crucial DDR5 desktop PC memory products that deliver up to 50% faster data transfer speeds over previous-generation DDR4 memory, providing mainstream PC users with enthusiast-level performance. Hence, the PCIe 5.0 lanes offer backward compatibility with PCIe 4.0 and PCIe 3.0 devices. The PCIe 5.0 lanes offer higher bandwidth than PCIe 4.0. The next-generation DDR5-enabled Intel platform uses a base memory frequency of 4800 MHz and can up over 6000 MHz in memory overclocking. The 12th generation Intel Core processors, also known as the Alder Lake CPUs, come in with up to 16 cores, and the Intel Intelligent Overclocking Technology to deliver boost clocks of up to 5.2 GHz.
Along with the iGame Z690 Series motherboards, COLORFUL also presents the Battle-AX DDR5 Memory for the Intel Z690 motherboards. The COLORFUL iGame Z690 Ultra D5 supports DDR5 memory while the iGame Z690 Ultra supports DDR4 memory - offering flexible build options.
The Intel Z690 platform is also the first mainstream desktop platform launched to support DDR5 memory.
The new Intel Z690 Series motherboard features support for PCIe 5.0 - unlocking support for the next-generation PCI Gen 5 devices. eDP applications include laptops, all-in-one PCs, premium tablets, automotive displays, and other systems that incorporate a display panel with a video or graphics video source.Ĭolorful Technology Company, introduces the Intel Z690 Series motherboards for the 12th generation Intel Core processors. Enhancements to the eDP standard have continued since its introduction more than 10 years ago, thanks to contributions by major OEMs through the VESA organization. eDP is widely adopted for larger, higher-resolution displays as it provides the highest resolutions, refresh rates and color depths using a low wire count with low EMI radiation. These include an improved panel self-refresh protocol coupled with enhancements to VESA's Adaptive-Sync protocol, a combination that results in added power savings and improved motion image quality.įor devices such as laptop PCs with an embedded display, eDP is the electrical interface for transporting video data from the system's graphics hardware to the internal display panel. Replacing eDP 1.4b, published in 2015, eDP 1.5 retains all key features of the previous specification while adding additional capabilities and performance. The Video Electronics Standards Association (VESA ) announced today that it has published the Embedded DisplayPort (eDP) Standard version 1.5. The system will utilize Intel Xeon Sapphire Rapids processors with HBM memory and the powerful Ponte Vecchio GPU with 47 tiles and over 100 billion transistors.
As per preliminary calculations done by The Next Platform, the system's estimations point towards 2.43 ExaFLOPs peak and around 1.7 ExaFLOPs in sustained workloads at dual-precision FP64 math. With Ponte Vecchio GPU behind the project, it seems like the GPU is performing better than expected.Īccording to Intel's CEO, Pat Gelsinger, the system will reach over 2 ExaFLOPs at peak and a bit below in sustained workloads. However, they left Intel with room to do a little bit extra. The contract bound Intel to create accelerators that are powerful enough to achieve this magical number. The supercomputer aims to reach two ExaFLOPs of computing power once the installation system is completed and powered.
The project aims to build a machine capable of cranking over one ExaFLOP of computing at sustained workloads. Intel's Aurora supercomputer is a $500 million contract with the US Department of Energy to deliver an exascale supercomputer for Argonne National Laboratory.