To support the server-to-server traffic that virtualized data centers require, the networking spine will generally rely on high capacity 40 Gbit/s and 100 Gbit/s switch fabrics with aggregate throughputs now hitting 12.8 Tbit/s. But the ‘one size fits all’ approach being employed to develop these switch fabrics quickly leads to a costly misalignment for data center owners.
The switch can aggregate the data from lower speed network interfaces and so act as a front-end to the core network fabric. But such switches tend to be far more complex than is actually needed - often derived from older generations of core switch fabric. They perform a level of switching that is unnecessary and, as a result, are not cost effective when they are primarily aggregating traffic on its way to the core network’s 12.8 Tbits/s switching engines. The heightened expense manifests itself not only in terms of hardware complexity and the issues of managing an extra network tier, but also in relation to power and air-conditioning. It is not unusual to find five or more fans inside each unit being used to cool the silicon switch.
An attractive feature of this standard is the ability to allow port extenders to be cascaded, for even greater levels of modularity.
Reference designs have already been built that use a simple 65W open-frame power supply to feed all the devices required even in a high-capacity, 48-ports of 10 Gbits/s. Furthermore, the equipment dispenses with the need for external management. The management requirements can move to the core 12.8 Tbit/s switch fabric, providing further savings in terms of operational expenditure. It is a demonstration of exactly how a more modular approach can greatly improve the efficiency of today's and tomorrow's data center implementations.