Abstract:
The present invention relates to wireless cellular telecommunication networks and, in particular, to control and management of self organizing wireless cellular telecommunication network. A method for network planning and frequency optimization in LTE networks by determining the optimal base station configuration parameters, comprises a base station initialization, an initial base station configuration, an iterative measurement procedure, an optimization process, a verification of operation, and a periodical maintenance procedure.

Description:
FIELD OF THE INVENTION 
     The present invention relates to wireless cellular telecommunication networks and, in particular, to control and management of self organizing wireless cellular telecommunication network. 
     BACKGROUND OF THE INVENTION 
     Wireless cellular telecommunication networks comprise a core data network and a wireless network. The wireless access part of the network must be carefully planned in order for each user to receive the radio signal of sufficient quality. The strength and quality of the signal in the core part of the network enable adequate capacity of services in the wireless telecommunication network. 
     The proper coverage of a geographical area with a radio signal is provided by means of macro base stations grouped in a cluster of cells. In order to increase the wireless network capacity, distributed small base station entities have been considered which have been defined as nano, pico and femto base stations with a smaller radio coverage in comparison to macro base stations. 
     Operating parameters, such as operating frequency, antenna orientation, transmission intensity and so forth, are essential for optimal wireless access telecommunication network operation. Within a discrete geographic region the base stations are assigned a limited number of carrier frequencies. Suitable choice of many other operating parameters is also important. The of a base station or of an individual mobile terminal often has a profound effect on both the interference generated for other base stations or for users who are not the intended receiver of the transmission. This reduces the probability of successful transmission reception by the intended receiver. A variety of other operating parameters, in addition to the operating frequency, such as antenna orientation, hand-off thresholds, traffic power limits, and pilot power fraction of total amplifier power similarly affect network function. 
     In establishing an operating communications network, identification parameters are set for each base station, often enumerating as many as few hundred base stations for a metropolitan area. Thus, significant planning based on above mentioned parameters typically precedes such establishment. Although at least some of these parameters are adjusted as the network evolves, the incipient choices are carefully made to avoid initial network failure or to avoid an excessive duration and area of unacceptable operation. Even after the network becomes operational, further base stations are added as the network expands. Such additional base stations have identification and operating parameters that require initialization. A poor initial choice of parameters has the potential for causing a network failure or unacceptable degradation of reception for existing users. 
     Currently, radio networks are being planned using specialized planning software which initially estimates the radio signal from different base station sites. The planning software is then used to calculate interference between base stations which affects the performance of the radio network. In addition to planning software, different kinds of measurement equipment is used in radio network planning, such as field measuring devices, a radio network control system, and specialized software for comparing the estimated and measured data, presenting the information in visual form or in other ways. Traditional network planning comprises radio frequency measurements to determine environmental factors and extensive simulations based on the measured data to determine the optimal placement and parameters of base stations. 
     One purposed approach for reducing complexity of the network management, thus reducing the expenditures, is auto configuration. In auto configuration procedures a base station automatically establishes some or all of its own identification and operations parameters upon initialization. 
     SUMMARY OF THE INVENTION 
     The invention describes a method for auto configuration of mobile telecommunication networks. The auto configuration procedure is based on the location data, provided by the base station using a variety of inputs. Following the initialization procedure, the self organizing network (SON) server calculates a set of safe operating parameters which are sequentially fed to the newly initialized base station. Newly initialized base station is set into signal generation mode, and neighbouring base stations are sent a command to begin a measurement mode. The measurement is conducted by the neighbouring base station by communicating with the stationary mobile stations. Relevant characteristic data of the mobile radio network at the position of the mobile radio station are acquired by the mobile radio terminal device under normal conditions of use and the measured data is sent to the neighbouring base station. Neighbouring base station relays the data to the SON server for further analysis. The procedure is repeated for all calculated candidate configurations. 
     The subsequent further processing of the thus forwarded data can advantageously be used for planning and optimization of the radio network infrastructure (neighbourhood planning, setting of operating parameters, etc.). 
     Main motivation for described procedures is the reduction of the complexity of network management processes and consequential reduction of operational expenses. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
       A method for auto configuration of mobile telecommunication networks according to the present invention will be described in details hereinafter with references to the accompanying figures, wherein 
         FIG. 1  shows schematically steps of a method according to the invention carried out on the SON server; 
         FIG. 2  shows schematically steps of a method according to the invention carried out on a new base station; 
         FIG. 3  shows schematically steps of a method according to the invention carried out on neighboring base stations. 
     
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
     A sequential diagram of an algorithm carried out on said SON server can be depicted from  FIG. 1 . Lists of neighbouring base stations, mobile terminals and configuration files for a new base station are prepared on said SON server. The latter determines a start of the precise synchronised measurement, and receives measured data upon finished measurements and calculates optimal operational radio parameters in order to start a new base station. In addition, said SON server takes care of the verification steps. 
     A method is carried out on said SON server taking care of the execution of the measuring procedure in said self organizing network. At the beginning, said SON server waits for an initialization request from a new base station (step  11 ). When such a request is received by said SON server, it prepares for said new base station a list of configuration files comprising operational parameters (step  12 ). When said list is ready, said SON server transmits the first configuration file to a new base station (step  13 ). In the next step, said SON server sends a command to execute measurements to a new base station (step  14 ) and to neighbouring base stations (step  15 ) which are determined by means of the location and the orientation of an antenna of the new base station and selected frequency being determined in the first configuration file. Said SON server is put into a state where it waits for expected measuring results from the neighbouring base stations (step  16 ). A measuring process is repeated for all further configuration files (step  17 ). When all the intended measurements are finished, said SON server carries out an optimization process of operational parameters (step  18 ). The calculated optimal configuration file is transmitted to a new base station (step  19 ). Said new base station is marked as an operational one (step  110 ), thus the latter become equivalent to the others in the network and is ready to receive mobile terminals. During the starting hours and days the measurement with optimal parameters are repeated several times (step  111 ) which is necessary in order to confirm the adequacy of the assigned radio parameters. If the verification fails (step  112 ), the process is repeated for all files, wherein again there are searched optimal operational radio parameters of the system. Said SON server also comprises a schedule of a so called system maintenance, when several times a year the adequacy of the base station (step  113 ) radio parameters are verified again. 
     A sequential diagram of an algorithm carried out on a new base station may be depicted from the  FIG. 2 . Based on the time synchronisation with said SON server said new base station starts to broadcast a synthesized radio signal of a full power with radio parameters determined by said SON server. Said base station operates as the operational base station, yet it does not accept any mobile terminals. 
     Upon start-up, said base station acquire by means of a DHCP protocol (step  21 ) an address of said SON server and transmits to the latter the data of its own location and antenna orientation acquired by means of a GPS receiver and electronic compass (step  22 ). Said new base station is put in a state for obtaining the configuration file (step  23 ). When said configuration file is received, the radio parameters (step  24 ) are set accordingly. When said new base station receives a signal impulse (step  25 ) which represents a time synchronised request for a measurement (step  26 ), it starts at the time To with the broadcasting of a synthesized radio signal (step  27 ). After the planned time frame for carrying out an individual measurement (step  28 ) has expired, said new base station stops transmitting the synthesized radio signal (step  29 ). Upon the finished measurements, said new base station receives from said SON server an optimal configuration file representing radio parameters for operating of said base station which may now receive mobile terminals (step  210 ). 
       FIG. 3  represents a sequential diagram of an algorithm carried out on neighbouring base stations. Said neighbouring base stations are determined within said SON server on the basis of the information regarding the position and the orientation of the antenna of a new base station, separately for each frequency measured. Neighbouring base stations carry out radio measurements by means of stationary mobile terminals which are, within the time frame provided for carrying out said measurements, connected with the base stations. The measuring process on the mobile terminals is standardized. 
     When the neighbouring base station receives a request for measurement from said SON server, it prepares a list of stationary mobile terminals (step  31 ). Said stationary mobile terminals are terminals where measurements of radio conditions do not change over time. At the time To (step  32 ) the neighbouring base stations start sending cyclic standardized requests for measurement to all attached stationary mobile terminals. Said mobile terminals answer the requests with measuring the results, and the base station accepts said results and provides them with time stamp. The measurement is finished at the time T&gt;To+ΔT (step  33 ), when said neighbouring base station sends measuring results to said SON server (step  34 ).