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Vicor Corporation today announced a ChiP-set for high performance GPU, CPU, and ASIC ("XPU") processors powered directly from 48 V. A driver, MCD4609, and a pair of MCM4609 current multiplier modules supply up to 650 A continuous and 1200 A peak. Owing to their small footprint and low profile (45.7 x 8.6 x 3.2 mm), current multipliers are placed close to the processor enabling reduced power distribution network (PDN) losses and higher power system efficiency. Powering GPU and OCP Accelerator Module (OAM) Artificial Intelligent (AI) cards, the 4609 ChiP-set is in mass production and available to new customers on the Vicor Hydra II evaluation board.
The 4609 ChiP-set adds to the Vicor Power-on-Package portfolio of Lateral Power Delivery (LPD) solutions. To raise the bar of current capability above the limits of LPD, Vicor's pioneering Vertical Power Delivery (VPD) will soon enable much higher current density. The VPD system delivers current from power converters vertically stacked under a processor through a capacitor network geared to a processor-specific pin-map. A GCM ("Gearbox Current Multiplier") is a specialized VPD embodiment incorporating a gearbox capacitor network as a layer in the vertical stack. By supplying current directly under the processor and eliminating PDN losses, GCMs will soon facilitate current densities reaching up to 2 A per mm².
Vicor IP on the critical path to Power-on-Package LPD and VPD solutions enables unparalleled current density and efficient current delivery for advanced processors in applications including AI accelerator cards, AI high density clusters and high-speed networking.
Power Component Design Methodology
The Vicor Power Component Design Methodology enables power system designers to reap all of the benefits of modular power component design - predictable component and system functionality and reliability, fast design cycles, and easy system configurability, re-configurability and scaling - while achieving system operating efficiency, power density and economy that rival the best alternative solutions. Utilizing the Vicor Power System Designer, engineers can select from an extensive portfolio of proven Vicor power components to architect, optimize and simulate their complete power system, all the way from their input sources to their point-of-loads. This innovative approach to power system design delivers fast time-to-market and state-of-the-art performance while minimizing the possibility of last-minute surprises and delays that so often occur with conventional or custom design methodologies.
View at TechPowerUp Main Site
The 4609 ChiP-set adds to the Vicor Power-on-Package portfolio of Lateral Power Delivery (LPD) solutions. To raise the bar of current capability above the limits of LPD, Vicor's pioneering Vertical Power Delivery (VPD) will soon enable much higher current density. The VPD system delivers current from power converters vertically stacked under a processor through a capacitor network geared to a processor-specific pin-map. A GCM ("Gearbox Current Multiplier") is a specialized VPD embodiment incorporating a gearbox capacitor network as a layer in the vertical stack. By supplying current directly under the processor and eliminating PDN losses, GCMs will soon facilitate current densities reaching up to 2 A per mm².
Vicor IP on the critical path to Power-on-Package LPD and VPD solutions enables unparalleled current density and efficient current delivery for advanced processors in applications including AI accelerator cards, AI high density clusters and high-speed networking.
Power Component Design Methodology
The Vicor Power Component Design Methodology enables power system designers to reap all of the benefits of modular power component design - predictable component and system functionality and reliability, fast design cycles, and easy system configurability, re-configurability and scaling - while achieving system operating efficiency, power density and economy that rival the best alternative solutions. Utilizing the Vicor Power System Designer, engineers can select from an extensive portfolio of proven Vicor power components to architect, optimize and simulate their complete power system, all the way from their input sources to their point-of-loads. This innovative approach to power system design delivers fast time-to-market and state-of-the-art performance while minimizing the possibility of last-minute surprises and delays that so often occur with conventional or custom design methodologies.
View at TechPowerUp Main Site