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Tunnels


AM/FM broadcast and DAB. Add to this some requirements for ease of system operation and maintenance under harsh environmental con- ditions, and you have a complex set of require- ments from a variety of services. Try and put this into a nice new shiny structure and then you have the architects to appease as well plus the radio system providers.


Field strength requirements During the design and planning process, it is es- sential to know what is required in the tunnel network. As well as the type and size of the area to be covered there are the field strength require- ments for various services to be considered – all essential considerations for designing a success- ful confined space scheme. In order to provide a signal along the entire


length of a tunnel, you need to understand how radio signals behave in confined spaces. While the obvious solution would be to install antennas at each end of the tunnel, the process of transmitting radio frequencies to the entire tunnel is not that simple. Obstructions from a moving train for example, or the sheer length of the tunnel, could mean unacceptable attenu- ation of the signal and an unreliable system. In many cases, there may also need to be a degree of surface coverage, particularly in areas such as station entrances or road tunnel portals, but equally too much external coverage may also be a problem particularly in central city locations. In general terms, the distance from confined


space to surface coverage should be minimal, which is important for systems that require a cellular element. Mobile cellular network operators providing services in a tunnel may prefer cell handover to take place underground to avoid overloading the surface system when a potentially large number of users try and change cells as the train exits the tunnel. Te important consideration is the power re-


quired to radiate signals across entire networks. Careful calculation of the system power budg- ets need to be carried out to determine power levels needed, which will determine cable types to be used and give predictions of signal levels, against the customers’ requirements for system coverage.


Cabling matters Te solution of choice for providing radio communication in tunnels is the radiating ca- ble, effectively a coaxial cable with a number of holes in it where signal leaks out (hence the term ‘leaky feeder’), with small antennas along its length. Tis can be equated to holes in a water pipe. Radio signals leak out of the ‘hole’ in the same way that water leaks from holes in a pipe. However, there are two major losses to consider when designing a system.


LAND mobile January 2013 Firstly there is coupling loss, the loss of sig-


nal from the cable to the user. High coupling loss means lower RF level to the user but gener- ally lower longitudinal loss along the length of the cable, while low coupling loss means more signal to the user, but less signal to reach the end of the tunnel. Longitudinal loss relates to how much signal is lost along the way. It is important to get the balance right to


ensure all portables within the tunnel receive optimal signal, while transmitting the sig- nal along the entire length of the tunnel for complete coverage. Lower longitudinal losses generally mean larger diameter cables with a consequent increase in material and installa- tion costs. Radiating cables should be installed with


careful planning, particularly when specifying the spacing of the cable from walls, metal ca- ble trays and other objects. Failure to adhere to manufacturer’s recommendations could lead to severe reductions in performance with higher longitudinal and unpredictable coupling loss variations. One area that can catch out the unwary is the installation of radiating cables above false ceilings. Many of these ceilings are comprised of fibreboard with a metallic back- ing or metal foil interior and this type of tile will have a disastrous effect on the radiation from the cable.


Source of signals Implementing a communication system in tun- nels requires a number of decisions to be made, one of which is whether to use a dedicated base station or cell enhancer as a means of determin- ing the source of signals that are fed into the confined space network. Dedicated base station equipment can serve the underground network alone, or using a cell enhancer (also called an off air repeater) can take a signal from the surface and rebroadcast it underground. Implementing a cell enhancer, which is es-


sentially a high gain amplifier designed to re- ceive and retransmit signals from a local site, can lead to its own set of problems – high gain amplifiers connected effectively to an- tennas can exhibit a nice feedback loop. Tis technique is widely used to provide coverage for emergency services in small road tunnels. Te off air repeater is the common way of pro- viding coverage of FM Band 2 broadcast and DAB services – even AM on long and medium wave are used in some locations. Special consideration should be taken when handling cabling in railway tunnels, which have high voltage overhead line equipment (OHLE) or powered third rail systems. Te radiating cables will be running parallel to the OHLE over considerable distances. Te elec- tromagnetic field produced is capable of in- ducing high voltages into the radiating cables,


During the design and planning process, it is essential to know what is required in the tunnel network. As well as the type and size of the area to be covered there are the field strength requirements for various services to be considered


which may only be less than three metres away. Tis can be a considerable hazard for mainte- nance technicians, which is why DC blocks at intervals and appropriate earthing systems must be installed. All fault conditions need to be evaluated – it’s not a good idea for the radiating cable to provide the return path for powering an electric train.


Finding the right partner Providing a reliable and robust RF communi- cation in a tunnel network is not a simple task, and requires a significant amount of planning and testing. While the technology is vitally important, it is also necessary to find a pro- vider that understands the entire process, from planning and design to installation and main- tenance. Mobile radio specialists can help put together a design to suit individual needs, carry out rigorous testing on-site up until the point it is operational, then provide ongoing support through the life of the system.


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