Avaya VSP 8000 Series

Avaya VSP 8284XSQ

The Avaya Virtual Services Platform 8000 Series, or VSP 8000, is a standalone Ethernet Switch, manufactured by Avaya and intended for use in Campus network and Data Center deployment scenarios.

The VSP 8000 is new category of high-performance Ethernet Switches developed by Avaya to leverage the latest generation application-specific integrated circuit chipsets. The Virtual Services Platform 8284XSQ is the first product in the VSP 8000 Series and is a fixed, compact form-factor Ethernet Switch designed to satisfy mainstream Campus Core Switch requirements.

The VSP 8284XSQ is an 84-port Ethernet Switch, supporting a mix of 10 Gigabit Ethernet and 40 Gigabit Ethernet ports. Network operators may choose to deploy it either in conventional IP Routed network topologies or as part of a network virtualization solution using the Avaya VENA Fabric Connect technology. Fabric Connect is an extended implementation of the IEEE 802.1aq standard for Shortest Path Bridging (SPB), and the VSP 8200 will be interoperable with third party products that also implement this Standard.

The product is typically positioned as the Core Switch in mid-market and small-to-medium Enterprise networks, or as an Aggregation/Distribution Switch in larger networks. Due to its ability to support both conventional and virtualized networking technologies – and operate both concurrently - the VSP 8000 is suitable in deployment scenarios that require high-availability, network segmentation, and dynamic provisioning. Additionally, the high-density of 10 Gigabit Ethernet (80 ports), plus support for 40 Gigabit Ethernet (4 ports), makes the VSP 8284XSQ model suitable for use as a Data Center Middle/End-of-Row Switch.

History

In November 2010 Avaya introduced "Virtual Enterprise Network Architecture" (VENA) as its overarching solution set of networking technologies. The role of VENA is to concentrate development activity on a set of key enabling technologies that will be made available, individually or collectively, across multiple hardware platforms. In this way, it is Avaya’s intention to at least partially abstract software functionality from hardware capability; certain considerations remain - processing and memory capacity - but, in general, VENA technologies would largely become hardware-independent.

An important foundational element to VENA was the release of the Fabric Connect technology, an implementation of the IEEE 802.1aq SPB, extended and enhanced by Avaya to integrate Layer 3, IP Routing, and IP Multicast capabilities, in addition to the topology, loop-avoidance, multi-path, and Layer 2 functionality native to SPB. Fabric Connect also conforms to the IETF RFC 6329 Standard for IS-IS extensions to support SPB.

In April 2014, Avaya announced the VSP 8000 Series as part of its participation in the Interop trade event in Las Vegas.[1][2] Following on from 2013,[3] Avaya was again selected to be the provider of the InteropNet network backbone, delivering an end-to-end virtualized network solution based on Fabric Connect technology.[4][5]

In June 2014, Avaya launched the VSP 8000 Series with the release of the first product in the line, the VSP 8284XSQ Ethernet Switch.

Product Specification

The VSP 8284XSQ is a fixed, compact form-factor Ethernet Switch that operates the Virtual Services Platform Operating System (VOSS), and provides eighty 1/10 Gigabit Ethernet SFP+ ports and four 40 Gigabit Ethernet QSFP+ ports. The VSP 8284XSQ supports high-availability AC power (1+1), field-replaceable fan trays, and front-to-back airflow.

The system inherits VOSS from the Avaya VSP 9000 modular, chassis-based product, in the same manner as the Avaya VSP 4000 fixed-format Ethernet Switch. Implementing VOSS meant that the VSP 8000 automatically inherited support for two key VENA technologies: Fabric Connect for end-to-end network virtualization, and Switch Cluster for high-availability device virtualization, in addition to supporting conventional IP Routing.

VSP 8284XSQ Ethernet Switch base hardware configuration:

The VSP 8284XSQ is based on a high-performance Broadcom chipset rated at 2.56Tbit/s, and while not alone in utilizing this component, the packaging in what Avaya term a “Compact Form-Factor” was unique at the time of launch. At just 2 Rack Units, the VSP 8284XSQ delivers very high 10/40 Gigabit Ethernet port density, particularly considering the typically deployment scenario would involve dual Switches.

Compact Form-Factor

Avaya has rolled-up a confluence of technology advancements to deliver the Compact Form-Factor (CFF) concept. The first is something called ‘die shrink’, a term that refers to the scaling of semiconductor devices, essentially the mass of transistors that form a chipset. Shrinking a semi-conductor die, creating superior circuit density, is made possible by using a more advanced fabrication process. This reduces overall costs of the chipset, and more capacity and capability can be delivered by leveraging the most advanced chipsets, and typically these newer designs are more power efficient. This has been occurring in PC and Server markets for years - a phenomenon commonly referred to a ‘Moore’s Law’ - and now it has made its way to networking. What this specifically delivers is the ability to drive more high-capacity connections using a more intense chipset. These developments have reached the point where it’s the physical requirement of the interfaces that determine now how small the box can be made, rather than size being driven by a mass of circuitry behind the front panel.

In parallel, there has been an advance in the functionality of network virtualization, such as the Avaya VENA Fabric Connect technology, an extended implementation of the Shortest Path Bridging standard. Fabric Connect offers the ability to create a simplified network that can dynamically virtualize elements, empowering efficient provisioning and utilization of resources, thereby reducing the strain on the network and IT personnel. Network virtualization offers an alternative to conventional offerings and it delivers innovative services and solutions while maintaining Ethernet’s key value propositions of simplicity and cost-effectiveness.

Finally, there a subtle but important transition in how the various physical connectivity requirements - the actual interfaces - are delivered. A traditional Chassis-based solution requires multiple interface module types in order to cover a broad range of physical media types and interface speeds, from copper to various forms of fiber, and from 10/100Mbit/s, through to 10Gbit/s and now beyond. However, the commoditization of Pluggable Transceiver technology is making that traditional approach largely redundant, thereby highlighting its inherent inefficiency. Many now recognize that a better way to deliver versatility of interface is to leverage the wide array of available Transceivers, be they SFP, SFP+, or QSFP+ format. This change means that a networking device can support multiple interface requirements by leveraging low-cost Transceivers.

See also

References

  1. "Avaya Networking Solutions Close the Gap between Data Center and End Devices". Avaya. 26 March 2014.
  2. "Avaya Networking Solutions Close the Gap between Data Centre and End Devices". SDN Zone. 25 March 2014.
  3. "InteropNet 2013: Unbreakable! Avaya Fabric Connect Delivers on All Fronts". Avaya. 15 May 2013.
  4. "Interop".
  5. "InteropNet: The show behind the show". Network World. 1 April 2014.

External links

This article is issued from Wikipedia - version of the 10/27/2014. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.