NL1002288C2 - Test system for telecommunications network with mobile users - Google Patents

Abstract

The network has a number of Base Stations (BS) which are located in different geographical positions. The Mobile Users (MU) make calls via a low power radio to their nearest base station, and via the nearest base station to the called user. The simulator units (SIM.UNIT) are directly connected to the base stations, and are used to test connections, call data records. The simulator units are synchronised via the GPS satellite system (GPS SAT).

Description

Title: Network Test System BACKGROUND OF THE INVENTION

The invention relates to a test system for testing a telecommunication system by means of simulation units, which are each connected via a local subscriber interface to the telecommunication system 5 and controlled by a simulation program, the execution of the simulation programs of different simulation units are synchronized by means of external signals.

Such a system, in particular intended for testing the production of Call Detail Records (CDRs) in the telecommunication exchanges, is known from applicant's earlier application EP-637884; insofar as this is clear, it is deemed to form part of this application.

In said earlier application it is proposed inter alia to synchronize the start of the different subprograms (program steps) from which the simulation programs in the simulation units are built up, using 'broadcasted' start code signals such as the DCF77 time code signals.

Said previous application assumes 'broadcasting' of 20 start code signals; in all simulation units, the received start code signals, which effect the start of corresponding program steps, are equal. The applicant has now come to the insight that other than purely 'broadcasted' signals can also be used for the synchronization of (sub) programs at different locations. Furthermore, when testing telecommunication systems, there is a need to record the geographic data of the simulation units. This is particularly the case with mobile telecommunication systems.

30 SUMMARY OF THE INVENTION

The invention is based on the insight that it is possible to make use of signals other than merely broadcasted signals, namely signals which form part of a geographical positioning system, such as GFS. Such systems make use of various signals, broadcast by satellites, from which the geographic position of the receiver can be calculated. Although each of the satellites has broadcast its signal in itself, the signals 10 02 20 «.

2 when received in receivers at different locations, at the same time uneven signal content due to transit time differences. The position of that receiver can be calculated from the content of the signals from the various satellites in a GFS receiver. Optionally, 5 a correction code to be received from terrestrial ground stations can also be included in that calculation (DGPS system). Systems other than GFS are also known or will be developed in the future.

In addition to the coordinates, the exact signals can also be calculated from the received signals, as is known, inter alia, from J07183828.

The invention thus proposes to use these types of signals as start code signals for synchronizing simulation units. There are several options for using satellite signals as synchronization signals: 1. A time code can be calculated from the received satellite signals, which in turn can serve as a synchronization code. The start codes of the subprograms are compared with the calculated time code.

2. No time code is calculated but one of the satellite signals 20 is used directly as a synchronization signal. Since the content of that satellite signal differs per location, the satellite signal or the start codes must be corrected location-dependent. After correction, the start codes and the satellite signal are then tested for equality. Yet another option is not to correct the satellite signal or the start codes, but to correct the algorithm by which the satellite signal and the start codes are "matched" location-dependent.

Since the satellite signal, the start codes or the match algorithm are corrected depending on the geographical location — after all, the content of the satellite signal is related thereto — that location must be known. There are two options: the location data can be keyed in, for example, or it can be calculated from the signal content of the other satellite signals.

The use of GPS signals makes it possible to record a geographical place code in the simulation unit when the simulation program is executed. This option is particularly important when testing mobile networks, where it is important to detect irregularities in the creation of (afterwards)

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3 CDRs, namely where the simulation units (as simulated A or B subscriber involved in the production of those CDRs) were located.

IMPLEMENTATION EXAMPLES

Figure 1 shows a test system according to the invention. Figures 2, 3, 4 and 5 show some implementation examples of a simulation unit according to the invention.

Figure 1 shows a telecommunications network provided with base stations BS for mobile communication. These base stations are on the one hand connected to the 'fixed network', while on the other hand they can maintain connections with mobile users MU. The network uses mobile simulation units that test the network in the same way as normal mobile users. All actions that normal users can perform can also be performed by the simulation units. For example, the simulation units can initiate connections to each other, terminate connections, forward their 'number', etc. It is important that the actions of the simulation units must be able to be accurately synchronized. This allows situations to be created that can be 'difficult' for the network. Situations of this kind - referred to in the applicant's earlier application as 'test scenarios' - are carried out by the simulation units under the control of program steps which are synchronized by signals received by the simulation units from GPS satellites. 25 different options can be followed, which have already been indicated above.

Figures 2, 3, 4 and 5 show simulation units that are largely similar to each other, but the use of the satellite signals is different. In Figure 2, the satellite signals in a GPS-30 unit are converted into both a time code and a geographic code. The time code serves as a synchronization code and is compared for this purpose to the start codes of the simulation program. The geographical information is only stored. In Figure 3, the GPS unit does not first calculate the time code from the three satellite signals, but one of the 35 satellite signals is used directly as a synchronization signal. Since the value of that signal depends on the geographic location of the GPS unit, a conversion (correction) must take place in each simulation unit for the satellite signal (in 10 02288.

4 different, geographically spread simulation units) can be used as a synchronization signal. This conversion is performed on the basis of the geographical code (coordinates) calculated by the GFS unit from the three satellite signals. In Figure 3, the 5 start codes are converted, after which those converted start codes are compared with the satellite signal. In Figure 4, the satellite signal is converted, after which that converted satellite signal is compared with the start codes. In Figure 5, neither the start codes nor the satellite signal are converted, 10 but the comparison algorithm — which is in Figures 2, 3 and 4: IF Xn / Y-1 THEN START WITH STARTCODE n — is set depending on the geographical code: IF Xn / Y = f (Z) THEN START WITH START CODE n, where Xn represents start code n, Y the time code (figure 2) or the satellite signal (figures 3, 4 and 5) and Z the geographical code. The simulation unit shown in figure 2 comprises a control element, for instance a PC, loaded with a simulation program. The simulation program includes several subprograms, each of which includes a test scenario. During the execution of a test scenario, connection to the telecommunications network can be made via a network interface and a transceiver allowing connection, via network base stations, to the network and to other simulation units. Each subprogram has a start code. A subprogram can be activated by passing the start code of that subprogram to the simulation program.

The controller also includes a COMPARE function for comparing time code and start codes, as well as a register for storing the geographic code of the simulation unit. The simulation unit also includes a GPS unit, consisting of a number of satellite receivers. In the GPS unit, the time code and geographic code are calculated from the 30 satellite signals received. The latter code, together with the log data of the executed test scenario, is stored in the PC. The time code - which is also stored with the log data - is used in this exemplary embodiment for synchronizing test scenarios to be executed simultaneously in the different simulation units. For this purpose, in each simulation unit, the time codes calculated by the GPS unit are always compared with the different start codes. As soon as the time code equals one of the start codes, that start code becomes 1 0 02 28 8.

5 simulation program passed, after which the subprogram associated with that start code is executed.

In the previous embodiment, the synchronization codes (the time codes) are the same in all simulation units. This is not the case in the following exemplary embodiments. Figure 3 shows a simulation unit in which the GPS unit does not generate a time code, but transmits one of the satellite signals unprocessed. The GPS unit can therefore be a bit simpler. The geographical location code is, however, calculated from the satellite signals. That location code is stored in the log file 10 of the test scenario. In addition, that location code is used to make a correction that is necessary because the satellite signal (single) to be used for synchronization has a different value in the simulation units at the different locations. In the implementation example of Figure 3, the values of the start codes are converted using the location code (into "start codes" ") and then compared by the COMPARE means to the satellite signal (" sat.signal 1 "). If the value of a converted start code is equal to the value of the satellite signal, the test scenario associated with the 20 corresponding unconverted start code is executed.

Figure 4 shows a simulation unit which is roughly the same as that in figure 3. However, now the start codes are not converted, but now the value of the satellite signal is converted ("sat.signal 1" ") · The COMPARE device compares the values of the start codes with the converted (location corrected) value of the satellite signal. In case of equality, the corresponding subprogram is executed.

Finally, figure 5 shows an exemplary embodiment in which neither the satellite signal nor the start codes are converted. Instead, the COMPARE function is location corrected using the location code.

It should be noted that if the location of the simulation units is already known and therefore does not need to be calculated by the GPS unit, a receiver that can receive only one satellite signal can suffice instead of the GPS unit. Correction of either the start codes (figure 3), the satellite signal (figure 4) or the COMPARE function (figure 5) then takes place by means of (in another 10 0 2 28 8 6 manner, for example manually) in the simulation unit defined geographical coordinates.

It is to be noted that although a particular test system has been envisaged in the present invention, the invention is in fact more widely applicable, namely in any real-time distributed multitasking system, ie a system in which processors at different locations are simultaneously , different processes are performed. According to the invention, the execution of those processes is then synchronized by means of signals to be received at those locations, which are intended for geographical location determination.

REFERENCES

EP-637884 [ROYAL PTT NETHERLANDS NV] J07183828 [MITSUBISHI ELECTRIC CORP.]

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Claims (12)

1. Test system for testing a telecommunication system by means of simulation units each connected to the telecommunication system via a local subscriber interface and controlled by a simulation program comprising one or more subprograms, each with a start code, the start of corresponding subprograms in different simulation units is synchronized by means of one or more external signals, CHARACTERIZED in that said one or more external signals are constituted by one or more signals 10 intended for geographic location. 2. Test system according to claim 1, CHARACTERIZED in that in each simulation unit the geographic location signals are converted into a time code which is then compared with the start codes in that simulation unit, where, if, for a given start code, the comparison result has a predefined value, the subprogram associated with that start code is started. Test system according to claim 1, CHARACTERIZED IN THAT a simulation unit records a location code indicating the geographic location of that simulation unit. Test system according to claim 3, CHARACTERIZED IN THAT in each simulation unit the position code is derived from the geographic location signals. Test system according to claim 3 or 4, CHARACTERIZED IN THAT in each simulation unit the start codes of the different subprograms are converted using the location code of that simulation unit, comparing at least one of the geographic location signals with the converted start codes in that simulation unit and wherein, if the comparison result for a given converted start code has a predefined value 30, the subprogram associated with that start code is started. 6. Test system according to claim 3 or 4, CHARACTERIZED IN that in each simulation unit the at least one of the geographic location signals is converted using the location code of that simulation unit, the converted signal being compared with the start codes in that simulation unit and where, if the comparison result for a specific start code has a predefined value, the subprogram associated with that start code is started. 10 02 28 8. Test system according to claim 3 or 4, characterized in that a comparison value is predefined on the basis of said location code, after which at least one of the geographic location signals is compared with the start codes in that simulation unit and wherein if the comparison result for a given start code is equal to said predefined comparison value, the subprogram associated with that start code is started. Test system according to claim 1, characterized in that the geographic location signals are from alien transmitters. Test system according to claim 8, characterized in that the geographic location signals are part of the GPS system or its successors. Test system according to claim 1, characterized in that the signals intended for geographical positioning signals, at least in part, originate from terrestrial transmitters. 11. Simulation unit for testing a telecommunication system, comprising a subscriber interface for that telecommunication system, as well as control means comprising a simulation program with one or more subprograms each comprising a start code, CHARACTERIZED BY means for receiving one or more signals which are intended for geographical positioning, as well as means for processing one or more of those signals into synchronization codes, for synchronizing the simulation program together with the start codes. 12. System in which different processes are carried out simultaneously, at different locations, characterized in that said different processes are at least partly synchronized with the aid of a signal intended for geographical positioning. 1 0 02 2f «