Broadband wireless communication systems for high mobility scenarios

Abstract

Over the last few years multimedia and data-based services experienced a non-stopping growth. Unlike before, people do not use the services only from a static location, but they are continuously on the move between different scenarios, using their mobile devices to access data-based services. In parallel, commuter traffic from rural areas is also rising, since most of work places are in and around cities. During transportation, people intensively employ mobile devices to work, access to social networks, or as an entertainment means. Internet access is required for most of these services. Currently, GSM for Railways (GSM-R), which is based on the Global System for Mobile Communications (GSM), is the most widely used communication system between trains and the elements involved in operation, control, and intercommunication within the railway infrastructure. However, GSM-R is not well suited for supporting advanced services such as automatic pilot applications or provisioning broadband services to the train staff and passengers. Besides trains, the increasing number of broadband services available for mobile devices motivated the migration from third-generation mobile networks to fourth generation ones, mainly Long Term Evolution (LTE). Therefore, LTE seems to be a good candidate to substitute the GSM as the fundamental technology for railway communications. In this work a complete study on the performance of high capacity broadband wireless communication systems for high speed vehicles is presented, based on measurement campaigns in actual high speed environments. Special attention is devoted to the case of LTE in high speed trains. Techniques to greatly reduce the cost and complexity of measurement-based evaluations in high speed scenarios are proposed and proven to work analytically, by means of simulations and by measurements in actual high speed environments. With the aim of checking the validity of the findings of this work for the latest advances in wireless communication systems, proposals for fifth generation (5G) communication systems, currently still under definition, were also considered. Moreover, the performance of the proposals for 5G communication systems was also evaluated by means of simulations as well as by measuring in high speed environments. The source code of both the GTEC Testbed and the GTEC 5G Simulator is publicly available under the GPLv3 license at https://bitbucket.org/tomas_bolano/gtec_testbed_public.git.