But if the concept of UMTS (Universal Mobile Telephone Services) - of individuals having a single universal number for all their communication services - is ever to become a reality, operators and service providers need to find a way to integrate satellite architectures and their distinct advantages of high-capacity and wide coverage with the more familiar terrestrial infrastructures.
Completed in June 2005, the IST-funded SAILOR project demonstrated the viability of combining telecom services from both terrestrial and satellite-based UMTS networks, to produce communication services that combine the best of the advantages from these widely differing infrastructures.
"Our main achievement was to develop a complete architecture for terrestrial and satellite-based services, with a working platform to demonstrate how the different service types could be integrated," says project coordinator Arnoldo Giralda of Telespazio in Rome. "Using this platform, we were able to show key functions in potential future services such as telelearning and telemedicine."
What are the advantages of integrating satellite-based services into a UMTS architecture? "Of course a key advantage is satellite's unique one-to-many broadcast or multicast capability," says Giralda. "Satellite services can effectively supply common information using a single channel to users over a wide area. Achieving this coverage with terrestrial networks would entail simultaneous use of large numbers of individual channels."
The SAILOR platform provides flexibility in terms of quality of services - the platform optimises all the functions to this end, saves network capacity through the ability to exploit the advantages of satellite technology, i.e. sending very large amounts of information using the minimum number of communication channels and minimises the cost of new services for telecoms operators and equipment manufacturers by making possible the design and use of low-cost communication terminals.
It embraces high-speed data, as well as voice services, and exploits the special features of satellite communication to best advantage, i.e. providing coverage to geographic areas suffering from limited or no telecommunications service (which can include ships at sea as well as land-based destinations), and boosting the bandwidth and hence speed of all connections. The platform also focuses on an 'exploitable' approach to combining the different architectures; the services offered are designed to be affordable as well as high-quality.
One important new function for example is in the area of controlling user access to services, to maintain service quality and prevent overload. Says Giralda, "the system provides us with the ability to accept or reject call requests from a user, according to the capacity of the system."
Another key achievement was the development of an innovative software Cellular Planning Tool to help optimise any integrated terrestrial/satellite cellular network layout. The new tool is designed to help operators plan the optimal cellular-antenna deployment to satisfy traffic needs for a certain area. "The tool enables us to design the deployment and coverage of cellular base stations and antennae so as to minimise the number of satellites required."
Now that SAILOR is complete, one of the project partners (Siemens) is already investigating how to implement the work undertaken within the project into its organisational procedures. The work on RASN (Radio Access Support Network), which covers the functions involved in interfacing IP networks and mobile architectures, is proving of particular interest. SAILOR's results are also feeding into the work of a number of key standardisation bodies; contributing to the relevant UMTS ETSI and 3GPP standardisation groups, which are involved in developing new market scenarios for the latest satellite systems and the network tools to support them.
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Source: Based on information from SAILOR