WO1999066654A1 - Method and device for transmitting information at various carrier frequencies - Google Patents

Abstract

The invention relates to a method and device for transmitting information at various carrier frequencies by means of sudden frequency change. A random sequence of a number of N possible carrier frequencies fx is generated in addresses 1-N of a table (25) in a device (20). At least one part M of the N carrier frequency values fx is read sequentially from the corresponding addresses of the table, whereby said operation is periodically repeated and M≤N. Subsequently, information is transmitted in a device (4) at the corresponding carrier frequencies. The method and device can, for instance, be used in a mobile station or base station belonging to a mobile radio telephone system.

Description

description

Method and device for the transmission of information in different carrier frequencies

The present invention relates to a method and a device for transmitting information in different carrier frequencies by means of a frequency hopping method. The device and the method can, for. B. can be implemented in a mobile station or a base station of a mobile radio system.

The so-called frequency hopping spread spectrum system is known as a method for transmitting data on a plurality of carrier frequencies. A frequency hopping spread spectrum system is to be understood as a system in which a plurality of carrier frequencies are provided for the radio transmission of data and the carrier frequency currently used is changed at periodic intervals. In particular in the case of a time division multiplex (TDMA) system, the carrier frequency can be changed after each time slot or time frame of the time ultiplex transmission. Such a frequency hopping spread spectrum system has advantages in that the energy of the entire radio transmission is distributed over all carrier frequencies. This is particularly important if a generally available frequency band, such as the 2.4 GHz ISM (Industrial, Scientific, Medical) band, is used. In accordance with the relevant regulations (in the USA, FCC part 15), an upper limit for the maximum energy occurring per carrier frequency is set for this frequency band in order to keep interference to other participants as low as possible. For the frequency change it is mandatory that at least 75 different frequencies must be used within a period of 30 seconds. Furthermore, each frequency may be used for a maximum of 0.4 seconds in 30 seconds. On average, all frequencies must be used equally. The DECT standard defines 24 time slots, 12 each for uplink and for downlmk, in a 10 ms frame. However, the FCC part 15 only provides a bandwidth of less than 1 MHz in the ISM band. In order to meet this requirement, the number of time slots was reduced to 12 time slots in a 10 ms time frame, ie 6 time slots each for uplink and for downlmk.

With 6 time slots for each direction and while maintaining the DECT time frame of 10 ms, each time slot would have a length of 833 μs. The time slots in the DECT standard have a length of 417 μs. In the case of a slow frequency hopping system, there is an inactive DECT time slot of 417 μs between adjacent active ones

Time slots in which data are transmitted are required. With such systems, only 6 active time slots in each direction are therefore used for data transmission. If such systems, which operate on the basis of slow frequency hopping, are also to meet the requirements of FCC part 15 in the ISM band, an inactive Blmd time slot of 417 μs must again be present between adjacent active time slots. This Blmd time slot thus has half the length of a full time slot of 833 μs, which means that if a basic time frame of 10 ms is maintained, four active tent slots are available in each frame for uplink and for downlmk, between which Blmd time slots are sent. The four active time slots each have a length of 833 μs, while the Blmd time slots each have a length of 417 μs. With this structure, frequency programming for frequency hopping in the next following active time slot can also be carried out at the end of the previous active time slot. Wah ^¬ rend the Bl d time slots can in this case the programmed arrival fang frequency in the next active time slot are set. An advantage of the frequency hopping spread spectrum system is that by providing a large number of carrier frequencies, the system becomes less sensitive to interference. Furthermore, the system's security against third parties increases, since the third party generally does not know which carrier frequency is to be changed after a certain period of time.

Problems can arise if the number of usable carrier frequencies is not constant over time. This is the case, for example, when a carrier frequency identified as disturbed is blocked for a certain period of time and is therefore not released for use, and is released for use again after a certain period of time. Even with such a temporally fluctuating number of usable carrier frequencies, it must be ensured that, for example, the FCC part 15 requirements mentioned above are observed.

The present invention has for its object to provide a method and a device for transmitting information in different carrier frequencies by means of a frequency hopping method, in which the different carrier frequencies are provided in a simple and effective manner.

This object is achieved by a method and a device for transmitting information of different carrier frequencies with a frequency hopping method in accordance with the features of the independent claims. Advantageous further developments of the present invention are specified in the corresponding subclaims.

According to the present invention, a random sequence of a number of N possible carrier frequency values fx m addresses 1 - N of a table is provided for transmitting information m different carrier frequencies by means of a frequency hopping method. Then at least part M of the N Carrier frequency values fx are sequentially read out repeatedly from the corresponding addresses in the table, where M≤N. Then information is transmitted at the corresponding carrier frequencies. The method and the device according to the invention can z. B. m a mobile or a base station of a mobile radio system can be implemented.

When the random sequence of the number of N possible carrier frequency values addresses 1 - N of the table is provided, a random sequence of a number N of possible different carrier frequency values fx is generated, which are written into the corresponding addresses 1 - N of the table.

When connecting, e.g. B. between mobile units, a carrier frequency is first sampled. A decision is then made as to whether a specific message has been received on this carrier frequency during a specific period. If the decision is negative, a new carrier frequency is selected and this new carrier frequency is scanned. If the decision is positive, the table is provided using the message.

To synchronize e.g. B. units of mobile radio, a carrier frequency is scanned first. Then it is decided whether this carrier frequency is received during a certain period of time. If the decision is negative, a new carrier frequency is selected and this new carrier frequency is sampled. If the decision is positive, the carrier frequency ser ^¬ a location to be m the table overall examined and the Tragerfrequenzwerte be fx starting repeated periodically read out by the ^¬ ser address.

If a part M of the N possible carrier frequency values is read from the table, the remaining NM carrier frequency values are used to replace disturbed carrier frequencies of the M carrier frequency values. This ensures that even with a temporally fluctuating number of usable Carrier frequencies ensures that the FCC part 15 regulations mentioned above are complied with.

Before the periodically repeated reading, the table can be updated from the N-M carrier frequency values by replacing the carrier frequency values which correspond to disturbed carrier frequencies. N is e.g. B. 96 and M is z. B. 75 for the case of FCC part 15.

The above-mentioned method steps are implemented in each case corresponding devices or means in a device according to the invention.

The invention will now be explained in more detail using an exemplary embodiment and with reference to the accompanying drawings. Show it:

1 shows a mobile radio transmission system with a base station according to the invention,

2 shows a time frame of a data transmission standard as can be used in the present invention,

3 shows in detail the internal structure of a base station according to the invention,

4 shows a schematic illustration of a frequency hopping spread spectrum system, in particular also in the case of a storer avoidance mode,

5 shows an example of a table from which all stored carrier frequency values are periodically read out repeatedly,

6 shows a flowchart which illustrates a method for synchronizing mobile radio units, 7 is a flowchart illustrating a method of establishing a connection between cellular units;

8 shows a table from which only part of the stored carrier frequency values are read out periodically,

9 shows a flowchart which represents a method for synchronizing mobile radio units, in which disturbed carrier frequencies are exchanged,

FIG. 10 shows a flow diagram illustrating a method for establishing a connection between mobile radio units, FIG.

11 shows a table 25 from which only part of the stored carrier frequency values are read out periodically,

FIG. 12 shows a table 25, which is replaced by an undisturbed carrier frequency value by an undisturbed carrier frequency value, and

FIG. 13 shows a further table 25, in which another disrupted carrier frequency value is replaced by an undisturbed carrier frequency value.

1, the general structure of a mobile radio transmission is to be explained first. As is generally customary, the arrangement for radio transmission of data has a base station 1 and a plurality of mobile parts (mobile stations), wireless telephones 2, 3 .... The base station 1 is connected to the fixed network by a terminal line 10. An interface device, which is not shown, can be provided for communication between the base station 1 and the terminal line 10. The base station 1 has an antenna 6 by means of which, for example, communication with the mobile part 3 takes place via a first radio transmission path 8 with the mobile part 2 or via a second radio transmission path 9. The handsets 2, 3 ... each have an antenna 7 for receiving or transmitting data. 1 schematically shows the state in which the base station 1 actively communicates with the mobile part 2 and thus exchanges data. The handset 3, on the other hand, is in the so-called idle locked mode, in which it waits stand-by for a call from the base station 1. In this state, the mobile part 3 does not actually communicate with the base station 1, but rather receives the data from the base station 1 only at periodic intervals, for example of a time slot, in order to be able to re-synchronize its carrier frequencies fx.

The internal structure of the base station 1 is shown schematically in FIG. 1. The speech information data is fed to an RF module 4, which is controlled by a carrier frequency sequence unit. The exact structure of a base station 1 according to the invention will be described later.

With reference to FIG. 2, a transmission standard that can be used in the present invention will now be explained. As can be seen from FIG. 2, data in a plurality of time slots, in the illustrated case 24 time slots Zx, are transmitted on a plurality of carrier frequencies fx, ten of which are shown, one after the other, using a time division multiplex method TDMA (Time Division Multiple Access). In the case shown, work is carried out in alternating mode (duplex), i. that is, after the first twelve time slots Zx have been transmitted, the system switches to reception and the second twelve time slots (Z13 to Z24) are received in the opposite direction by the base station.

In the event that the so-called DECT standard is used for transmission, the duration of a time frame is 10 ms, and there are 24 time slots Zx, namely twelve time slots for the transmission from the base station to Mobilte len and another twelve time slots Zx for transmission from the handsets to the FestStation. According to the DECT standard, ten carrier frequencies fx between 1.88 GHz and 1.90 GHz are provided.

Of course, other frame structures are also suitable for use in the present invention, such as those in which the number of time slots per frame is halved compared to the DECT standard.

The present invention is used in particular for transmissions in the so-called 2.4 GHz ISM (Industrial, Scientific, Medical) frequency band. The generally accessible ISM frequency band has a bandwidth of 83.5 MHz. According to the FCC part 15 regulation, at least 75 carrier frequencies must be distributed over this 83.5 MHz. It is particularly advantageous to split the bandwidth from 83.5 MHz to 96 carrier frequencies, i. H. a channel spacing of 864 kHz. The frequency bands and standards mentioned above are given purely as an example. The basic requirement for applicability in the present invention is only that a frequency hopping spread spectrum is used, i. H. that several carrier frequencies are available and that the carrier frequency selected for transmission is changed from time to time. A prerequisite for such a change is that the data time slots Zx are transmitted (time division multiplex method). For example, the DECT standard and any other modified standard based on this DECT standard are suitable.

3, the internal structure of a base station 1 according to the invention will now be explained in more detail. As can be seen in FIG. 3, the RF module 4 is supplied with information data if the base station 1 is to transmit to a mobile part 2, 3... By means of the antenna 6 and is transmitted by the HF mo dul 4 information data is output when data is received from handsets. The RF module 4 modulates the digitally coded information data to a carrier frequency fx. The carrier frequency fx currently to be used is predetermined by a carrier frequency sequence unit, which is generally designated 20. A detection device 24 is provided in the carrier frequency sequencing unit 20, to which the demodulated signal is supplied by the RF module 4. Interference means that there is either a disturbance in the actual sense or an assignment by another transmitter. A disturbance in the sense of the present description can thus be detected by demodulating an received signal at a carrier frequency and detecting whether or not there is an em signal level at this carrier frequency. A disturbed carrier frequency is therefore a carrier frequency to which a signal is modulated that exceeds a certain threshold value.

Alternatively, the A-CRC value, the X-CRC value, a loss of synchronization or the RSSI value can be used for blocking.

The detection device 24 thus determines, for example, on the basis of the demodulated signal from the RF module 4, how high the signal portion modulated onto a specific carrier frequency fx is. If the detected signal component over a vorbe ^¬ agreed limit, outputs the detection device 24 em Storungs detection signal to a blocking / Freιgabeemheιt 21. Depending from the Storer detection signal from the Erfas- sungsemrichtung 24 outputs the locking / Freιgabeemheιt 21 a Sperrung- / Release format to a processor 23. This block / release format indicates which of the carrier frequencies fx are blocked or released again due to the detection of a fault by the detection device 24, as will be explained later. By means of the detection device 24 and the blocking / releasing device 21, an independent procedure is thus created, by means of which disturbed frequencies can be blocked and released again. In addition to the lock release information from the lock / release unit 21, the processor 23 is supplied with a sequence from a random generator 22. Based on the implied random algorithm, the random generator 22 generates a randomly distributed sequence of carrier frequency values within the usable frequency band in order to store a random series of carrier frequency values from a table 25 of the processor. The random generator 22 thus executes a procedure which is independent of the procedure for frequency blocking in the event of a fault. During operation, the processor 23 reads the carrier frequency values serially from the table and finally sends a control signal to the RF module 4, which specifies the carrier frequency value to be used to the RF module 4.

The processor 23 has the m on a memory provided Ta ^¬ beauty 25 whose function will be explained later and management.

The operation of a base station 1 and the method will now be explained in more detail with reference to FIG. 4. As shown in FIG. 4, a carrier frequency fl is used, for example, during a frame Rx of a mobile radio transmission, as shown in hatched lines in FIG. Thus, this frequency fl is the first value is supplied to the processor 23 of the table vomit ^¬ cherten random sequence, which in turn drives accordingly the RF module. 4 For the frame R2, it is assumed that the table 25 prescribes a frequency jump Pl to a carrier frequency f3 on the basis of the sequence stored in it.

The case is now assumed that the detection device 24 has detected, for example during a previous transmission, that the carrier frequency f _{2 is} disturbed, and the detection device 24 therefore emits a corresponding interference signal to the Has given blocking / releasing unit 21, which in turn has blocked frequency f2, which has indicated to processor 23. Furthermore, it is assumed that the random generator 22 prescribes the carrier frequency f2 previously detected as disturbed for the frame R3 on the basis of its determined sequence. Based on the coincidence of the prescribed carrier frequency f2 in accordance with the sequence in Table 25 and at the same time the blocking signal from the blocking / release unit 21 for the same carrier frequency f2, the processor 23 now replaces the carrier frequency f2 for the frame R3 which is actually prescribed but which is detected as being disturbed carrier frequency detected by the detection device 24 as not disturbed, for example the carrier frequency f, as indicated by the frequency hopping arrow P3. Instead of the carrier frequency 2 actually prescribed by the sequence, the RF module 4 is therefore driven to the substitute carrier frequency f4. By replacing the carrier frequency detected as disturbed, a modified sequence of carrier frequencies is created. The modified sequence only has undisturbed carrier frequencies. The fact that a carrier frequency detected as disturbed is replaced and is not skipped by a transition to the following carrier frequency means that the positions of the undisturbed carrier frequencies m of the modified sequence are not changed in comparison to the original sequence.

Based on this modified sequence consisting only of unge ^¬ disturbed carrier frequencies fx are thus two superimposed, independent procedures (Table 25 and locking / Freι- gabeemheit 21). This block can be lifted again by the block / release unit 21 as soon as a new one

Detection by the detection device 24 indicates that the previously disturbed carrier frequency is no longer disturbed. In this case, the blocking / release unit 21 em a release signal to the processor 23, which indicates that the processor 23 no longer has to replace the previously disturbed carrier frequency by another carrier frequency. Alternatively, the blocking / release unit 21 can automatically emit a release signal to the processor 23 without a new detection by the detection device 24 as soon as a predetermined time period has expired. Each of the procedures mentioned thus ensures that the entire specified frequency spectrum is used in an evenly distributed manner. By adjusting the times of the procedure for blocking frequencies, standards can thus be complied with.

An example of such a standard is the US regulation FCC part 15. This regulation stipulates that with a frequency hopping spread spectrum system, at least 75 different frequencies must be used within a period of 30 seconds. Each frequency may be used for a maximum of 0.4 seconds for 30 seconds. In addition, on average, all frequencies must be used equally.

The base station 1 is the master in frequency allocation, ie at the start of a connection establishment the random number generator in a mobile part is initialized with the state of the random number generator 22 of the base station 1. The same random number generator 22 then generates in the mobile part the same random sequence of carrier frequency values as is stored in table 25 of the base station and also stores it in a corresponding table 25. The mobile stations have a very similar structure to the base station shown in FIG. 3 . The mobile stations do not include the blocking / release device 21 and the detection device 24, but the random number generator 22 and the processor 23 with the table 25 and the RF module 4. It is also conceivable that the mobile station detects the disturbed carrier frequencies and notifies the base or base station. The present invention can thus be used or implemented both in a base station and in a mobile station. The procedure for frequency blocking, which is carried out by the detection device 24 and the blocking / releasing device 21, uses unidirectional protocol on the air interface during the entire connection time between the fixed station 1 and a mobile part 2, 3. If the detection device 24 finds one of the final possible frequencies fx as disturbed by the base station 1, the base station 1 thus informs all the mobile units with which it is actively connected that this disturbed frequency, when it is read from the table, is passed on another carrier frequency that is not detected as being disturbed is to be replaced. The frequency blocking is withdrawn by the blocking / releasing unit 21 when the blocked carrier frequency is suitable for transmission again or when it was blocked for longer than a previously defined time.

In FIG. 3 it can be seen that the processor 25 is assigned the table 25, which is provided, for example, in a memory. 3 and FIGS. 5 to 13, it will now be explained how the carrier frequencies fx are provided in accordance with the invention. As can be seen in FIG. 5, a total of N available carrier frequencies fx, for example 96, m, are entered in a table 25. The distribution of the carrier frequency values shown is only an example and any other distribution can be selected.

5 to 7, the provision of the carrier frequencies fx from table 25 is explained on the assumption that all available N carrier frequencies fx are used for the transmission of data and that there is no interference. 5 shows the table 25 stored in the processor 23. Each address 1 to 96 is assigned a corresponding carrier frequency fx, whereby all 96 carrier frequencies fx used are different. The random sequence of carrier frequency values fx stored in table 25 is generated by the random number generator 22 and m the Table 25 enrolled. The carrier frequency values fx from table 25 are converted during operation, ie when transmitting data m to the RF module 4, m corresponding carrier frequencies. The carrier frequency values fx are periodically repeated during operation from table 25 in the order of their addresses 1 - 96 serially. This considerably reduces the computational effort during operation since a new carrier frequency or a new carrier frequency value fx does not always have to be determined by the random number generator 22 during operation. The random sequence of carrier frequency values fx m of table 25 is generated each time the connection is established between mobile radio units and corresponding tables are written in.

For example, each base station of a mobile radio system can have a random sequence of carrier frequency values fx m of its table 25 exclusively assigned to it. A shift register or the like can be used, for example, to generate the random sequence of carrier frequency values fx m in the random number generator 22. When establishing a connection to a base station, a mobile station receives a specific message from the base station which initiates the generation of the random sequence of carrier frequency values fx, so that the identical table 25 is generated at carrier frequency values fx as m of the base station.

6, the synchronization of mobile radio units, for example the synchronization of a mobile station with a corresponding base station, is first described. It is assumed that the connection has already been established, i. H. that the mobile station has already generated the random sequence of carrier frequency values fx by the random number generator 22 and m has been stored in the table 25 of the processor 23. 6 shows a flow chart that the synchronization of, for example, a mobile station with a

Base station explained. Each of the method steps shown in the flowchart of FIG. 6 has a corresponding input πchtung m assigned to the processor 23. In other words, each method step shown in the flowchart of FIG. 6 of a corresponding device is implemented in the processor 23. The same also applies to the method steps shown in the flow diagrams of FIGS. 7, 9 and 10.

During synchronization, a carrier frequency fx is first sampled in a step 26 m of a corresponding device. The sampled carrier frequency corresponds to one of the carrier frequency values fx already stored in Table 25. In a step 27, a corresponding device is used to decide or determine whether this sampled carrier frequency has been received during a certain period of time. If the decision is negative, for example because the carrier frequency is disturbed, a new carrier frequency is selected, as shown in step 28, and this new carrier frequency is sampled. If the decision in step 27 is positive, the address m of the table 25 corresponding to this received carrier frequency is sought, namely in a step 29 with a corresponding device of the processor 23. Then, in a step 30 m with a corresponding device, the table m is searched 25 stored random sequence of the carrier frequency values fx, starting from this address, repeated periodically and read out sequentially. When synchronizing, no additional information about the frequency hopping algorithm is therefore necessary, since no changes in the periodically repeated frequency value table 25 occur.

FIG. 7 shows a flow chart to explain the establishment of a connection between mobile radio units. The method steps shown are implemented in corresponding devices of the corresponding mobile radio unit. At the start of establishing a connection, for example a mobile station with a base station, a step 31 m of a corresponding device is first described. voted selected carrier frequency sampled. In a step 32, a corresponding device determines or decides whether a specific message has been received on this scanned carrier frequency. The specific message can be, for example, the N _t message in the A field of the DECT standard. Other corresponding messages can be used in other standards. If it is determined in step 32 that the specific message has not been received, after a certain period of time has elapsed, which is determined in a step 33 m of a corresponding device, a subsequent step 34 m in a corresponding device is selected a new carrier frequency which is scanned. Steps 32 and 33 can be carried out in a single device.

If it is decided in step 32 that the specific message has been received, the table 25 is generated in a step 35 in a corresponding device. The various carrier frequency values m of a random sequence are generated by the random number generator 22 and the table 25 is written. The specific message or part thereof can be used to generate the random sequence, thereby ensuring that, for example, in a mobile station the same random sequence of carrier frequency values fx m is entered in table 25 as in the corresponding table 25 m assigned base station are available. In a step 36 m of a corresponding device, the carrier frequency values fx from the table 25 are then periodically repeated in the order of their addresses 1 to 96 in order to transmit data m at the corresponding carrier frequencies.

The mobile station knows from the specific message received m the scanned carrier frequency at which address of the table 25 the base station is located, and can use this address to read the subsequent carrier frequency values fx synchronously with the base station. 8 to 13 only em part M, z. B. 75, which periodically repeatedly reads the carrier frequency values stored in the table 25 m for the mobile stations and uses them for the transmission of data. The remaining part NM = 96-75 = 21 of the carrier frequency values m in Table 25 is used to replace disturbed carrier frequencies. As explained with reference to FIG. 3, the disturbed frequencies are e.g. B. determined by the respective base station. The information about the disturbed carrier frequencies is communicated to the respective mobile stations by the assigned base station, whereupon the disturbed carrier frequencies are replaced by undisturbed carrier frequencies.

For example, as shown in FIG. 8, 75 carrier frequency values fx can be read out from the corresponding addresses 1 to 25 of table 25 and used for the transmission of data, as FCC part 15 is prescribed as a minimum regulation m. The remaining 21 carrier frequency values in the addresses 76 to 96 are only used for the transmission of data if one of the carrier frequencies of the addresses 1 to 75 is recognized and communicated by the respective base station.

However, the generation of the random sequence of carrier frequency values also takes place here in such a way that all 96 carrier frequency values of a random sequence are generated by the random number generator 22 and are stored in table 25, each carrier frequency value fx being contained only once. If one of the carrier frequencies of the carrier frequency values fx contained in the addresses 1 to 75 is recognized as disturbed by the base station, the base station sends the mobile station a corresponding message to replace the disturbed carrier frequency with an undisturbed carrier frequency from the carrier frequency values m at the addresses 76 to 96 disturbed frequencies can be avoided. Are more than 21 Carrier frequencies disturbed, is caused by the disturbed carrier frequencies used em periodic noise floor.

The methods for synchronizing and establishing a connection between a mobile station and a base station, which are explained in flow diagrams in FIGS. 9 and 10, correspond essentially to the methods described in FIGS. 6 and 7, in each case to avoid repetitions Identical method steps are identified with the same reference symbols.

FIG. 9 shows a flowchart which explains the method steps for synchronizing a mobile station with a base station when only 75 carrier frequency values fx are repeatedly read out from the table 25 periodically. Steps 26 to 30 correspond to the steps shown in FIG. 6 and are also implemented in the processor 23 in corresponding devices. When synchronization method of FIG. 9, after step 29, m which the address m in the table is found 25, which corresponds to the carrier frequency received from ^¬ sampled and, em additional Verfahrensschπtt 37 m made of a corresponding device. In step 37, a specific message is received by the base station, by means of which the table 25 is updated. This means that the base station, when it detects a particular carrier frequency as disturbed, replaces the corresponding carrier frequency value in its own table 25 with an undisturbed carrier frequency value from one of the addresses 76 to 96 and transmits this information to the mobile station. The mobile station replaces the same

Tragerfrequenzwert so that, as the tables 25 of the Basisstati ^¬ on and the mobile station are identical, the from the table 25 of the mobile station periodically repeated read Tragerfrequenzwerte m continues exactly with those of the base station coincide, uber-. In the DECT standard, the specific message for updating table 25 can be, for example, the P _t or M message of the A field. After updating the table le 25 in step 37, the carrier frequency values m of the updated form are read from the table 25. In contrast to FIG. 6, however, only 75 of the 96 carrier frequency values available are used here.

FIG. 10 shows a flow chart which explains the establishment of a connection between a mobile station and a base station. The flowchart shown in FIG. 10 essentially comprises the same method steps as the flowchart shown in FIG. 7, but an additional step 38 for updating table 25 is also inserted here. The method steps 31 to 36 correspond to the method steps shown in FIG. 7. All of the method steps shown in the flow diagram in FIG. 10 are implemented in the processor 23 of the mobile station in accordance with corresponding devices. After step 35, in which the table 25 was generated by means of the random number generator 22, the mobile station receives a specific message for updating the table 25 to include disturbed carrier frequency values from the addresses 1 to 75 by undisturbed carrier frequency values from the addresses 76 to 96 to replace. Here too, the specific message for updating table 25 can be the P _t or M _t night of the A field in the DECT standard.

In Figs. 11 to 13 is shown in which way ge ^¬ disturbed Tragerfrequenzwerte the periodically repeated read addresses can be replaced by 1 to 75 non-disturbed Tragerfrequenzwerte from the non-read-out addresses 76-96 of Table 25. FIG. 11 shows a table 25 which contains a random sequence of 96 different carrier frequency values fx in addresses 1 to 96. Of these 96 different carrier frequency values fx, 75 carrier frequency values from addresses 1 to 75 are repeatedly read out periodically. If the base station determines that, for example, the carrier frequency is disturbed, which corresponds to the carrier frequency value f ₂ -> which is stored in the address 3 m in the tables 25 of the base station and the mobile station, it transmits this information. formation of the mobile station simultaneously with the instruction that the carrier frequency value f ₆ 6 located at the address 96 of the table 25 with the carrier frequency value f? ₇ to be exchanged. FIG. 12 shows an updated table 25, which shows the carrier frequency values f ₆₆ and f? ₇ of table 25 of FIG. 11 have exchanged places. The carrier frequency values from the addresses 1 to 75 are therefore repeated periodically and read out sequentially, even if faulty carrier frequencies are found. The disturbed carrier frequency values then swap places with undisturbed carrier frequency values from addresses 76 to 96.

If the base station then determines that the carrier frequency corresponding to the carrier frequency value f- ₇ is no longer disturbed, but instead the carrier frequency corresponding to the carrier frequency value f ₅₄ is disturbed, it first exchanges the carrier frequency value f _t -> back with its address 3 and correspondingly the carrier frequency value f _6b back to its address 96 and also gives the mobile station the corresponding instruction for this. The disturbed carrier frequency value f ₅ _ of its address 75 is then exchanged with the carrier frequency value f ₆₆ of address 96.

The original carrier frequency values are therefore always written back to their old locations or m their old addresses when they are no longer disturbed, before new, disturbed carrier frequency values are replaced.

Claims

claims

1. Method for the transmission of information in different carrier frequencies by means of a frequency hopping method, with the following steps:

Providing (22) a random sequence of a number of N possible carrier frequency values fx m addresses 1 to N of a table (25), periodically repeated reading (30, 36) of at least part M of the N carrier frequency values fx sequentially from the corresponding addresses in the table ( 25), where M≤N, and transmit (4) information m at the corresponding carrier frequencies.

2. The method according to claim 1, characterized in that the step of providing a random sequence of a number of N possible carrier frequency values fx m addresses 1 to N of a table comprises the following steps: generating (35) a random sequence of an N number each possible different carrier frequency values fx, writing the random sequence of the N carrier frequency values fx m the corresponding addresses 1 to N of the table.

3. The method according to claim 1 or 2, characterized in that the following steps are carried out to establish a connection: scanning a carrier frequency, deciding whether a specific message was received on this carrier frequency during a certain period of time, if the decision is negative, selecting one new carrier frequency and sampling this new carrier frequency, if the decision is positive, providing the table using the message.

4. The method according to claim 1, 2 or 3, characterized in that the following steps are carried out for synchronization: sampling a carrier frequency, deciding whether this carrier frequency was received during a certain period of time, if the decision is negative, selecting a new carrier frequency and sampling this new carrier frequency, if the decision is positive, search for the address of the table corresponding to this carrier frequency and periodically repeated reading of the carrier frequency values fx starting from this address.

5. The method according to any one of the preceding claims, characterized in that a part M of the N possible carrier frequency values is read from the table, the remaining NM carrier frequencies ^¬ being used to replace disturbed carrier frequencies of the M carrier frequency values.

6. Method according to claim 5, so that the table is updated from the N-M carrier frequency values before the periodically repeated readout by replacing the carrier frequency values which correspond to the faulty carrier frequencies.

7. Device for transmitting information in different carrier frequencies by means of a frequency hopping method.

means (22) for providing a random sequence of a number of N possible Tragerfrequenzwerten fx m Adres ^¬ sen 1 to N of a table (25), means (23) for periodically repetitively reading out at least a portion M of the N Tragerfrequenzwerte fx of sequentially the corresponding addresses in the table, where M≤N, and a device (4) for transmitting information in the corresponding carrier frequencies.

8. The device according to claim 7, characterized in that the device (22) for providing a random sequence of a number of N possible carrier frequency values fx m addresses 1 to N of a table comprises:

Means for generating a random sequence of a number N of possible different carrier frequency values fx,

Means for writing the random sequence of the N carrier frequency values fx m the corresponding addresses 1 to N of the table.

9. Apparatus according to claim 7 or 8, characterized in that a device is provided for producing a compound comprising: means (31) for scanning a carrier frequency, means (32) for deciding whether during a certain time ^¬ a particular space message was ^¬ catch emp on this carrier frequency, wherein if the decision is negative, a new transmitter ^¬ frequency selected and this new carrier frequency is selected, and if the decision is positive, the table under USAGE ^¬ dung of the message is provided.

10. The device according to claim 7, 8 or 9, characterized in that a device for synchronization is provided, which comprises:

Means (26) for sampling a carrier frequency,

Means (27) for deciding whether this carrier frequency was received during a certain period of time, wherein, if the decision is negative, a new carrier frequency is selected and this new carrier frequency is sampled and if the decision is positive, the address m of the table corresponding to this carrier frequency is searched for and the carrier frequency values fx are periodically read out repeatedly from this address.

11. The device according to one of claims 7 to 10, characterized in that the device (23) for reading out a part M of the N mog- lent carrier frequency values from the table (25), the remaining NM carrier frequency values for replacing disturbed carrier frequencies M carrier frequency values are used.

12. The device according to claim 11, characterized by a device (37 or 38) for updating, which updates the table before the periodically repeated reading by replacing the carrier frequency values, which correspond to disturbed carrier frequencies, from the N-M carrier frequency values.