华为Cloud Matrix 384中需要多少光模块？

Core Viewpoint - The article discusses the architecture and data flow of Huawei's Cloud Matrix 384, emphasizing the integration of optical and electrical interconnections in its network design [2][3][9]. Group 1: Data Transmission Layers - The Cloud Matrix 384 includes three main data transmission layers: UB Plane, RDMA Plane, and VPC Plane, each serving distinct roles in data processing and communication [5][7]. - The UB Plane connects all NPU and CPU with a non-blocking full-mesh topology, providing a unidirectional bandwidth of 392GB/s per Ascend 910C [7]. - The RDMA Plane facilitates horizontal scaling communication between supernodes using RoCE protocol, primarily connecting NPUs for high-speed KV Cache transfer [7]. - The VPC Plane connects supernodes to broader data center networks, managing tasks such as storage access and external service communication [7]. Group 2: Optical and Electrical Interconnections - Although the Cloud Matrix 384 is often referred to as a purely optical interconnection system, it also utilizes electrical interconnections for short distances to reduce costs and power consumption [9]. - The article highlights the necessity of both optical and electrical connections in achieving efficient data flow within the system [9]. Group 3: Scale-Up and Scale-Out Calculations - For Scale-Up, each server's UB Switch chip corresponds to a bandwidth of 448GBps, requiring 56 400G optical modules or 28 800G dual-channel optical modules per server [12]. - The ratio of NPUs to 400G optical modules in Scale-Up is 1:14, and to 800G modules is 1:7 [12]. - For Scale-Out, a Cloud Matrix node consists of 12 Compute cabinets, and the optical module demand ratio is approximately 1:4 for NPUs to 400G optical modules [14].