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Carrier Grade Linux is a set of specifications which detail standards of availability, scalability, manageability, and service response characteristics which must be met in order for Linux to be considered "carrier-grade" (i.e. ready for use within the telecommunications industry). The term is particularly applicable as telecom converges technically with data networks and commercial off-the-shelf commoditized components such as blade servers.
Carrier-grade is a term for public network telecommunications products that require up to 5 or 6 nines (or 99.999 to 99.9999 percent) reliability, which translates into between 30 seconds (6 nines) and 5 minutes (5 nines) of downtime per year. The term "5 nines" is usually associated with carrier-class servers, while "6 nines" is usually associated with carrier-class switches.
The primary motivation behind the CGL effort is to present an open architecture alternative to the closed, proprietary systems that are currently used in telecommunication systems. These proprietary systems are monolithic (hardware, software and applications integrated very tightly) and operate well as a unit. However, they are hard to maintain and scale as telecommunications companies have to utilize the services of the vendor for even relatively minor enhancements to the system. Conventional wisdom in the telecommunications industry has it that a new feature takes 18 months and $ 1 million to deploy in an existing system.
CGL seeks to progressively reduce and / or eliminate this dependence on proprietary systems and provide a path for easy deployment and scalability by utilizing cheap COTS systems to assemble a telecommunications system.
The CGL effort is spearheaded by the Open Source Development Lab (CGL Working Group) that recently released CGL 3.1 in June 2005.
The OSDL CGLWG defines three main types of applications that carrier-grade Linux will support — gateways, signaling servers, and management.
Gateway applications provide bridging services between different technologies or administrative domains. Gateway applications are characterized by supporting a large number of connections in real-time over a large number of interfaces, with the requirement of not losing any frames or packets. An example of a gateway application is a media gateway, which converts conventional voice circuits using TDM to IP packets for transmission over an IP-switched network.
Signaling server applications, which include SS7 products, handle control services for calls, such as routing, session control, and status. Signaling server applications are characterized by sub-millisecond real-time requirements and large numbers of simultaneous connections (10,000 or more). An example signaling server application would include control processing for a rack of line cards.
Management applications handle traditional service and billing operations, as well as network management. Management applications are characterized by a much less stringent requirement for real-time, as well as by additional database and communication-oriented requirements. A typical management application might handle visitor and home location registers for mobile access, and authorization for customer access to billable services.
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