ITMI982068A1 - METHOD AND DEVICE FOR DIAGNOSING THE OPERATING STATUS OF STATIONS WITH RADIO IN A DIGITAL TELECOMMUNICATION SYSTEM - Google Patents

Description

DESCRIPTION of the industrial invention in the name

TEXT OF THE DESCRIPTION

Field of application of the Invention

The present invention relates to a method for diagnosing the operating status of radio base stations, Radio Fixed Part (RFP), in a digital telecommunication system, and in particular of an access subnet such as for example a DECT technology subnet composed of several cells. In particular, the proposed method allows to verify the correct functioning of an RFP limited to its functionalities of the physical layer PHysical Layer (PHL) and of the MAC protocol layer (Medium Access Control layer).

As is known, the DECT technology comprises a plurality of fixed two-way radio stations distributed so as to cover the areas concerned, and connected to a switching network which can be the public one or a private type switching network (PABX), and devices of portable users who connect via radio to fixed stations and are therefore able to communicate with each other and with other fixed users connected to the telephone network. The connections can be of the voice type, or allow data exchanges by occupying the equivalent of one or more voice "channels".

A first DECT network structure is schematically illustrated by way of example in Figure 1.

It includes groups of h (in the example of figure h = 4) fixed radio stations RFP (Radio Fixed Part) preferably connected to branches (in the example 3 branches) formed by connection lines or backbones L by means of drop / insert devices FROM. Without departing from the scope of the invention, it is obviously possible to connect each RFP station to the CCFP unit in a star, eliminating the aforementioned backbones and therefore obviously also the drop / insert devices DI.

Each RFP fixed station can manage by radio a certain number of PP (Portable Part) users, which are generally mobile.

The branches refer to a battery of TRAS transcoders, and the latter is connected, for example, to the public PSTN (Public Switching Telephone Network) by means of a central control fixed part (CCFP).

The interface between the CCFP and the DECT network, as regards the voice signal, is typically made up of digital channels at 64 Kbit / s. The CCFP unit is associated with a battery of TRAS transcoders which converts the eight-bit PCM (Pulse Code Modulation) encoding used on the PSTN side into a four-bit ADPCM (Adaptive Differential Pulse Code Modulation) encoding used on the DECT side. Thus on each channel at 64 Kbit / s. two 32 Kbit / s channels are bundled.

The 2.048 Mbit / s (bidirectional) backbone that connects the CCFP to the various RFP fixed stations therefore supports 48 voice channels plus a predetermined number of synchronism and signaling channels.

The area covered by a fixed station or cell is generally quite small, even reaching coverage of the order of tens or hundreds of meters in radius. Typical applications of personal telephone systems are found in industrial installations where they can replace the drafting of a wired network, in commercial complexes or urban centers, where they can advantageously replace public telephone boxes, and others.

The telecommunications network for personal telephony is digital. Radio access falls into the FDMA - TDMA - TDD category.

The system is TDD (Time Division Duplex) type as transmission and reception do not occur at the same time. More precisely, as illustrated with reference to Figure 2, the 10 millisecond base frame is divided into two halves: usually in the first 5 ms the fixed station transmits and the handsets receive (TX DECT half frame for the fixed station, and RX DECT for the handset ), and the opposite occurs in the next 5 ms. Each half-frame is made up of 12 time channels or time slots (from which it derives that it is a TDMA system) of the "full" type (see specification DECT ETS 300 175), each of which consists of 420 (or 424 as the case may be) bits . The time channels are transmitted or received using 10 (or more) different frequencies (from which it derives that it is an FDMA system) for a total of 120 (or more) channels available to the system, which are naturally allocated from time to time in order to do not create interference problems.

In duplex traffic channels (used for example for voice calls), the fixed unit and the mobile unit interact by transmitting at the same frequency on two time slots spaced 5 ms apart (located respectively in the first and second half frame).

For further details on the DECT system, please refer to the specifications issued by the European Telecommunications Standards Institute ", briefly ETSI. Obviously the technical problem of diagnosing the correct operation of radio base stations arises in the DECT systems in question.

Known art

In known DECT systems, this test operation is carried out by means of dedicated test equipment.

An example of dedicated test equipment is achievable by associating an alarm equipment, for example to the transmitter and to the receiver of the RFP and such equipment emits an alarm signal whenever it detects a malfunction of the transmitter and / or receiver.

The drawback of this solution is inherent in the fact that such alarm equipment has a non-negligible cost. In addition, such equipment does not provide any solution to the problem of monitoring the correct synchronization of the RFP in question with respect to the other RFPs in the system.

To overcome these drawbacks, devices called "test mobile" have been introduced in GSM systems, as they are associated with each station and are equipped with radio access equipment to the respective station, according to methods that completely coincide with the control equipment. access with which mobile devices are equipped. Each test mobile periodically accesses the respective station via radio to carry out specific tests. In the event that one or more tests fail, a message is sent to a central unit which thus receives information of the existence of a malfunction.

This solution, while being directly borrowable in a DECT system and while providing a solution to the problem of testing the correct synchronization of the station, implies the addition of substantial hardware to each station, significantly increasing the cost of the entire system. Finally, it should be noted that a reliable test element must itself be diagnosed.

Purpose of the Invention

The purpose of the present invention is to overcome the aforementioned drawbacks and limitations, and in particular, to provide a method for diagnosing the operating status of radio base stations without introducing dedicated test elements which could appreciably affect the cost of the radio. whole system.

Summary of the Invention

The invention achieves these purposes by means of a method having the characteristics set forth in claim 1 and by means of a system having the characteristics set forth in claim 9.

Further advantageous characteristics form the subject of the dependent claims.

The method according to the invention allows to monitor the status of a fixed station without introducing dedicated test elements, but by exploiting the stations already installed for the service and their operating mode. This allows to improve the quality of the service without introducing complications and without additional costs. In particular, the proposed method allows to verify the correct functioning of an RFP limited to its physical layer PHysical Layer (PHL) and MAC protocol layer (Medium Access Control layer) by exploiting the electromagnetic contiguity with the other stations of the same operator.

The proposed method, in addition to being useful for the above diagnosis operations, can be advantageously exploited by the operator also to obtain a whole series of useful information for the management of the system, among which are cited:

• have radio quality indications (such as the Bit Errar Rate (BER) and Frame Errar Rate (FER)) of the single station;

• detect any asynchronous stations at the air interface;

• build an electromagnetic coverage map of the system useful for highlighting the emergence of any unforeseen / existing obstacles during installation.

Brief description of the figures

The invention will now be described in more detail with reference to a preferred but non-limiting embodiment illustrated with reference to the attached drawings, in which:

Figure 1 (already described) illustrates the architecture of a DECT system

Figure 2 (partially already described) illustrates the structure of the DECT frame and in more detail the information fields of a full type time slot;

Fig. 3 illustrates the electromagnetic coverage areas of a multi-cell system that is connected "in a star" to N CCFP units.

Detailed description of a preferential embodiment of the invention

Referring again to Figure 2, the structure of a DECT time slot will be briefly recalled. The time slot comprises a field S reserved for the transmission of synchronism information and a field D reserved for the transmission of data in a broad sense.

The field S is used in particular for the recovery of the phase, and comprises two words, in particular a first word consisting of a sequence of bits alternatively of logic value one and of logic value zero for the recovery of the clock, and a second word characterized by fact that is a word of maximum correlation.

The data field in turn includes a field A and a field B.

Field A is normally used for reporting purposes, ie for the transmission of the report aimed at building, maintaining and breaking down the links.

Field B, on the other hand, is normally reserved for the transmission of actual information, ie the so-called payload.

As shown in Figure 2, field A is in turn composed of three subfields, the first of which is indicated with H and is reserved for the transport of a header or "header" H, the second, indicated with T or "Tail" is dedicated to the transport of information content, and the third is a useful subfield for error determination, known as CRC or cyclic redundancy code. The header H contains an encoding, expressed by means of three bits, which identifies a respective logical channel which, concretely, is transported in the second subfield T, that is, in the subfield relating to the content. Finally, the CRC field has the function of highlighting whether the logical channel transmitted from time to time is correct.

Among the logical channels transported in the content subfield T, for example, the Qt channel relating to system information, the Pt channel relating to paging information, etc. can be mentioned.

One of these logic channels is in particular the Cs channel which has a transmission capacity of 2 Kbit / s. According to the DECT standard, this Cs channel is reserved for the transmission of high-level signaling, i.e. third-level signaling or data.

In the absence of traffic channels (i.e. connections established with one or more PPs), the fixed unit must activate the transmission of at least one channel, called dummy bearer, to ensure the transmission of system information necessary to the mobile units. to access network services. The dummy bearer channel uses a radio carrier in the system band and a full type file slot in the first half frame. Therefore, a base radio station enabled for the service always has at least one radio channel active in transmission. The information transmitted in a radio channel (be it traffic or dummy bearer type) therefore consists of three adjacent fields, respectively: a synchronization field or field S, a field used for signaling transport or field A, and a field used for the transport of user data or field B.

Fields S and A are always present, while field B may be missing, as happens for example in dummy bearers.

The S field transmitted by the fixed unit differs from that transmitted by the mobile unit in that one is the conjugate of the other.

Among the information transmitted in field A, there is an information called system identity or RFPI (Radio Fixed Part Identity). This information is transported in a logical channel called NT, and consists of two parts: an identity portion of the access rights or ARI (Access Rigths Identity), and an RPN number, identifying the specific station that is transmitting this information, (Radio fixed Pari Number).

In normal operational operation, an RFP scans the time slots of the frame that it has free (i.e. that are not already active in transmission or reception) frequency by frequency, and this both to detect any access requests and to monitor the level of interference. of the channels.

In a geographical area served by an operator, each RFP identifies a cell, that is an electromagnetic coverage area, within which the PP (s) is visible and accessible. A wireless system is defined as "multi-cell" if it is composed of several RFPs (in fact by several cells) that transmit identity information in the logical NT channel that identifies the same system or operator, as well as themselves (through the RPN parameter). In Fig. 3 the electromagnetic coverage areas of a multicell system are illustrated. For asymmetrical connections it is possible that a radio unit transmits (or receives) a useful signal in both the two half frames.

It is also conceivable that, for the quality of the service, the contiguous cells present at the border areas of electromagnetic over-coverage (i.e. there are areas covered / served by several stations), and that a radio base station is always in electromagnetic visibility with at least one neighboring station. .

According to the invention, the aforementioned scanning mode is exploited to achieve the stated aim, i.e. the invention provides a first initial step consisting in preparing each RFP to receive in the first half frame a signal of the DECT type transmitted by another RFP of the same system / operator. In fact, returning to figure 2, it is evident that in the operation of the system according to the traditional methods that do not provide for the access of an RFP to other RFPs, each station is ready to listen to the field S presenting the configuration transmitted by the units. mobile radios only in the second half frame to detect any access requests of the PP mobile parts.

In the first half frame each station, again according to the traditional operating modes of the DECT system, merely monitor the degree of interference of the various channels to search for example the best channel in which to transmit the aforementioned dummy bearer.

The invention instead provides that each RFP is structured in such a way as to be predisposed to listen to the aforementioned S field (always with the configuration transmitted by the radio base stations) also in the first half frame and then decode field A and in particular search for the NT channel to detect and store the identity of the RFP station or stations with which it is in electromagnetic visibility.

According to the invention, therefore, the RFP synchronizes on the logical NT channel emitted by another radio base station and analyzes its content. If the identity information identifies the same operator / system to which it belongs, the RFP stores the identity parameter (RFPI) of the radio base station it has intercepted.

The RFPI identity parameters stored in this way are sent to the CCFP (Central Control Fixed Part) control center, periodically or upon request, to be analyzed by it.

From the analysis of this information, the CCFP is able to diagnose each RFP, ie to carry out the tests specified below.

Test if the specific station is able to receive correctly.

This test / diagnosis operation can be implemented indirectly by applying the method of the invention since if an RFP has synchronized and decoded the signal transmitted at least by another station, it is reasonable to conclude that this type of test has been successful.

Test if the specific station is able to transmit correctly.

This test / diagnosis operation can also be implemented indirectly by applying the method of the invention since if its system identity information or RFPI has been detected / stored by at least one other station of the system, it is reasonable to conclude that this test has also successful;

Test if the specific station is able to transmit synchronous frames in the air, with the other stations with which it has entered into visibility.

This test / diagnosis operation can also be implemented indirectly by applying the method of the invention since, in a dual way to the above, it is possible to diagnose a transceiver malfunction or an asynchronicity in the air if the specific station is never in visibility with at least one other RFP and / or is never detected by any RFP in the system.

In addition to a fault diagnosis, the invention also allows to monitor / control the network quality parameters and the electromagnetic configuration of a geographic area.

With regard to the quality of the network, the single station can in fact:

• estimate your own reception quality by calculating the probability of bit error, Bit Error Rate or BER, and of frame, Frame Error Rate or FER, known the signal transmitted (i.e. NT) by the intercepted RFP and the received field level, Received Signal Strength Intensity (RSSI). Given in fact that it is possible to establish a priori what is the probability of bit or frame error when the received field level adds up to a predetermined entity, if the BER or the detected RES has increased significantly compared to the predetermined one, it is it is reasonable to conclude that one's reception quality has significantly deteriorated due to the occurrence of some malfunction, for example;

• evaluate the level of synchronicity in the air with the other RFPs, for example by modifying the width of the correlation window (i.e. the time interval within which to search for the synchronous word / field). Each RFP, on the reception side, searches for the correlation word (ie the aforementioned S field) within a time interval called "correlation window" which is slightly wider than the duration of the actual S field to compensate for phenomena such as Jitter , temporal instabilities and propagation delays, that is the deviations of the real signal with respect to its ideal characteristics. In the optimal synchronization conditions, the aforesaid field S is perfectly lowered into the aforesaid correlation window, while in the presence of some synchronization problem the aforesaid time window may be too narrow so that in some cases it is sufficient to artificially introduce a slight delay / advance of the aforesaid time window (equal for example to the duration of N bits) in order to no longer be able to correlate with the received signal. . In conclusion, the level of synchronicity in the air can be tested according to the invention by introducing from time to time delays / advances of a predetermined entity and detecting, for example, how many delay bits are introduced to determine the loss of synchronization. If almost all the RFPs communicate to the CCFP central unit that they are perfectly centered with respect to the correlation window, while only one RFP communicates that it is synchronous at ± N bits (i.e. it is sufficient to introduce a delay of N bits because the correlation outside the correlation window) it is reasonable to conclude that this last RFP has problems of synchronicity in the air with the other RFPs, for example due to some malfunction.

With regard to the analysis of a geographical area, the invention makes it possible to put the CCFP data collection center in conditions of:

• trace the map of radio base stations in electromagnetic visibility, for example by monitoring if obstacles have arisen after installation (for example by noting that two stations previously in visibility have ceased to be visible);

• draw the map of the stations synchronous with each other.

The above advantages are obtained using the normal operating mode of the stations, without introducing dedicated test points and without additional commitment of the radio spectrum (in fact, the radio channels already allocated are used to offer the service).

Although the invention has been described with particular reference to a preferred embodiment, it is not to be considered limited to the latter, but extends to cover all the obvious variations and modifications that will be evident to the skilled in the art.

Claims (9)

CLAIMS 1. Method for diagnosing the operating status of a radio base station (RFP) in a digital telecommunication system in which the signals are organized in frames of pre-terminated duration and each frame is divided into a pre-terminated number of time intervals or time slots in which each time slot is structured so as to include at least one field (S) reserved for the transmission of synchronization information and at least one field (D) reserved for the transmission of data organized in logical channels and including at least one logical channel (NT) reserved for transmission of system and / or station identity information, said system comprising a central control unit (CCFP), a plurality of mobile devices (PP) and at least two radio base stations (RFP), characterized by the fact of providing for the phases of: I. determine the synchronization of each radio base station (RFP) on the logical channel (NT) reserved for the transmission of system and / or station identity information (RFPI) emitted by another radio base station of the same system / operator; II. check if the system identity information identifies the same operator / system to which it belongs; III. memorize the system and / or station identity parameter (RPN) of the other radio base station, if the aforementioned verification is successful; IV. To send the stored identity parameters to the aforementioned central control unit (CCFP) for further processing. 2. Method as in claim 1, in which said digital system is a system operating in accordance with the DECT standard, that is a system in which said frame is divided into two half frames during the first of which the stations (RFP) prepare themselves to monitor the level of interference of the channels while during the second half frame they are prepared to detect the access requests of the aforementioned mobile devices (PP), characterized by the fact that it includes the following phases: • prepare each radio base station (RFP) to tune in to the transmissions emitted by another radio base station (RFP) during said first half frame by searching for a synchronism word / field (S) presenting the configuration emitted by the base radio stations; • if the tuning operation is successful, decode the aforementioned field reserved for data transmission; • repeat the cycle of operations starting from phase II. 3. Method according to claims 1 and 2, characterized in that said delivery referred to in step IV takes place periodically. 4. Method according to claims 1 and 2, characterized in that said dispatch referred to in phase IV at the request of said control center (CCFP). 5. Method according to the preceding claims, characterized in that after carrying out the aforementioned phase III, a further phase is carried out which consists in calculating its own probability of bit error (BER) and frame (FER) by analyzing the data transmitted during said second field (D) from the intercepted radio base station (RFP), the transmitted signal and the received field level (RSSI) being known. 6. Method according to claims 1 to 4, characterized in that after carrying out the aforementioned phase III, a further phase is also carried out which consists in modifying the time interval within which to search for the aforementioned synchronism word / field (S) to assess the level of synchronicity in the air with other radio base stations (RFPs). 7. Method according to claims 1 to 4, characterized in that after carrying out the aforementioned phase IV, a further phase is also carried out by the aforementioned central control unit (CCFP) which consists in drawing a map of the base radio stations in electromagnetic visibility. 8. Method according to claims 1 to 6, characterized in that after carrying out the aforementioned phase IV, a further phase is also carried out by the aforementioned central control unit (CCFP) which consists in drawing a map of the base radio stations between of them synchronous 9. System for diagnosing the operating status of a radio base station (RFP) in a digital telecommunication system in which the signals are organized in frames of predetermined duration and each frame is divided into a predetermined number of time slots and each time slot being structured so as to include at least one field (S) reserved for the transmission of synchronization information and at least one field (D) reserved for the transmission of data organized in logical channels and including at least one logical channel (NT) reserved for transmission of system and / or station identity information, said system comprising a central control unit (CCFP), a plurality of mobile devices (PP) and at least two radio base stations (RFP), characterized in that it is structured in such a way as to implement the method referred to in claim 1.