Electrical computers and digital processing systems: multicomput – Computer network managing – Computer network monitoring
Reexamination Certificate
1999-08-31
2003-08-26
Etienne, Ario (Department: 2155)
Electrical computers and digital processing systems: multicomput
Computer network managing
Computer network monitoring
C709S218000, C709S249000
Reexamination Certificate
active
06611867
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to communications networks and more particularly to implementing a hybrid network.
BACKGROUND OF INVENTION
The current telecommunication service providers' networks reflect the architecture of the Public Switched Telephone Network (PSTN) network as it has evolved over the last 100 years. This is largely based on circuit switched technologies. Initially, all telecommunication services were offered via a wired infrastructure. As the user-base increased and requirements changed over the last few decades, new types of services were created e.g. wireless PSTN, cable video, multi-service (PSTN, video, satellite). The networks that supported these services were created as parallel networks, along-side the existing PSTN network. As technologies matured, there was some convergence (e.g. they shared the same SONET backbone) in the network architecture. During the late 1980s, with the explosion of data networking and Internet, data networking networks like frame relay and Asynchornous Transfer Mode (ATM) were developed, and later large internet based data networks were constructed in parallel with the existing PSTN infrastructure. These data networks again shared the PSTN infrastructure only at the SONET backbone layer. This state of current networks is called the existing “Core”. Thus the “Core” network is a set of parallel networks; PSTN, wireless, satellite, cable, ATM, frame relay, IP. There is some interoperability between the services on these parallel network (e.g. PSTN, and wireless), but generally these networks are vertically integrated to provide distinct set of non-interoperable services.
Exponential growth in demand for Internet access and intranet services is driving the need for a communication infrastructure that can rapidly enable, transport, and guarantee performance for new communications services. This revolution is a result of a dramatic shift of customer preferences from products to services. Whether for financial transactions, home shopping, videoconferencing, phone calls, education or other data intensive applications, business and residential customers look to this “new world” infrastructure—the Next Generation Network—as a primary channel for service delivery.
Indeed, research indicates that data traffic will surpass voice by 10:1 within the next three to five years. Opportunities abound for communication service providers that can either reinvent their business models and service delivery capability or create new business ventures and solutions through alliances with high-tech, media and entertainment companies. Customer demands for new, innovative services, coupled with increasing competition and the blinding growth of the Internet and corporate intranets all create pressure to transform today's telecommunication networks on a global scale.
Communication service providers are favorably positioned to create the infrastructure necessary to support this demand. However, this dramatic convergence of telephony and data-centric technologies calls for radically new strategies to network design and deployment. This “new world” demands that communications companies transform their core network systems from voice-centric circuit-switched platforms to the packet-switched or New World Network.
While the infrastructure alone is essential to enabling this capability, it is also critical for companies to develop products and services that create incremental and sustainable differentiation—differentiation that is recognizable to customers. Just as important as the creation of the differentiation is the ability to convey such differentiation to customers. There is a pending need to present system capabilities to customers for sales purposes.
SUMMARY OF THE INVENTION
A system, method and article of manufacture are provided for implementing a hybrid network. Orders for network capacity are issued based on a forecasted demand in order to develop a hybrid network. The hybrid network is analyzed to identify network problems. Then, the hybrid network is provisioned in accordance with the network problems and service requests. Usage of the hybrid network is determined and network usage control functions are initiated based on the determined usage.
In one embodiment of the present invention, provisioned portions of the hybrid network are assigned identifiers. Hardware of the hybrid network may be managed by performing duties including installing the hardware of the hybrid network, performing work on the hardware of the hybrid network, and/or repairing the hardware of the hybrid network. Further, historic data of the network problems may be maintained, such as in a log. A notification of the usage of the hybrid network may be provided if the usage is above a predetermined amount.
Optionally, sub-processes may be used to support the method of the present invention. Such sub-processes include network capacity/trunk planning, software and data building management, scheduling management, logistics management, workforce management, security management, problem analysis and resolution, network performance monitoring and analysis, network traffic monitoring and analysis, network configuration and routing, network test management, network alarm and event correlation, and network usage data collection and consolidation.
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Accenture LLP
Etienne Ario
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