WO1999009670A1

WO1999009670A1 - Method and device for making available useful carrier frequency values for applications in mobile radiotelephone system

Info

Publication number: WO1999009670A1
Application number: PCT/DE1997/001747
Authority: WO
Inventors: Jürgen KOCKMANN; Uwe Sydon
Original assignee: Siemens Aktiengesellschaft
Priority date: 1997-08-14
Filing date: 1997-08-14
Publication date: 1999-02-25

Abstract

The invention concerns a method and a device for making available useful carrier frequency (fx) values for applications in mobile radiotelephone system. In a table (25), effectively useful carrier frequency values are written at addresses (1 to M), the number of said effectively useful frequency values being equal to M. The presently non-useful carrier frequency values are written at addresses M+1 to N, representing the number of all available carrier frequencies (fx). The present value of M is continuously brought, for example in a time interval, to a random number generator (22) which produces sequences containing M different values. The table (25) and the random number generator (22) are controlled and managed by a processor (23).

Description

description

Method and device for providing usable carrier frequency values for mobile radio applications

The present invention relates to a method and a device for providing effectively usable carrier frequency values for mobile radio applications. The invention further relates to a base station and a mobile radio system which has a device of the type mentioned.

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 division multiplex 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. For this frequency band, in accordance with the relevant regulations (in the USA the regulation "FCC part 15" defined by the Federal Communications Commission) an upper limit for the maximum pro

Carrier frequency occurring energy set to keep interference from other participants as low as possible. For the frequency change it is stipulated 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. In the time All frequencies must be used equally on average.

Another 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. The system's security against eavesdropping is also increased, as the third party usually does not know which carrier frequency is to be changed after a certain period of time.

The sequence of carrier frequencies that are used for transmission in succession is determined by an algorithm. Such an algorithm is implemented in an identical manner in the base station and in each mobile station of the mobile radio transmission. If a handset is thus synchronized with the associated base station, the handset and the base station will synchronously carry out the carrier frequency changes specified by the sequence of the algorithm.

Problems arise when 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 regulation mentioned above is complied with.

It is therefore an object of the present invention to provide a method and a device for providing usable carrier frequency values for mobile radio applications, which ensure that carrier frequencies are used effectively and uniformly even when the number of carrier frequencies fluctuates over time. According to the present invention, a method for providing usable carrier frequency values fx for mobile radio applications is provided for this purpose. First, a predetermined number N of carrier frequency values fx that are possible in principle is provided. At least one of the possible carrier frequency values fx can be blocked, so that the number of actually usable carrier frequency values fx is reduced to a number m <N. The number m of actually usable carrier frequency values fx are written in a table in the addresses 1 to m. The blocked carrier frequency values fx are written into the addresses (m + 1) to N. In this context, "blocking" is intended to mean that a certain carrier frequency should not be used for a certain period of time for some reason, for example because it was detected as being disturbed.

A random number generator can generate m different values, which are then each converted into the carrier frequency values fx, which are available at the respective address equal to the values generated by the random number generator.

If a carrier frequency value is blocked, the carrier frequency value to be blocked can be exchanged with the carrier frequency value of the address M and M can then be decremented by 1.

If a carrier frequency value is blocked and another carrier frequency value is released at the same time, the carrier frequency value to be blocked can be exchanged with the carrier frequency value to be released.

To release a carrier frequency value, the carrier frequency value to be released can be exchanged with the carrier frequency value of the address M + 1 and M can then be incremented by 1.

According to the invention, a device for providing usable carrier frequency values fx for mobile radio applications provided. The device has a table in which actually usable carrier frequency values are written in the addresses 1 to M. The number of carrier frequency values that can actually be used is equal to M. Currently, carrier frequency values that cannot be used are written into the addresses M + 1 to N, where N is the number of carrier frequencies available overall.

A random number generator can be provided which generates M different values. For this purpose, the current value of M is transmitted to the random number generator.

A table control can be provided which, when a carrier frequency value is blocked, exchanges the carrier frequency value to be blocked with the carrier frequency value of the address M and decrements M by 1.

The table controller can replace the carrier frequency value to be blocked with the carrier frequency value to be released if a carrier frequency value is blocked and another carrier frequency value is simultaneously released.

To release a carrier frequency value, the table controller can exchange the carrier frequency value to be released with the carrier frequency value of the address M + 1 and increment M by 1.

According to the invention, a base station for mobile radio applications is also provided which has a device for providing usable carrier frequencies of the type mentioned above.

According to the invention, a mobile radio system is also provided which consists of a base station and at least one mobile part, the mobile radio system having a base station of the type mentioned above. 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 fixed 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-hoping spread spectrum system, in particular also in the case of a jammer avoidance mode, and

5 to 8 show a schematic representation of the provision of carrier frequencies according to the invention in a table.

1, the general structure of a mobile radio transmission will be explained first. As is generally customary, the arrangement for radio transmission of data has a base station 1 and several 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 communication with the mobile part 3 takes place, for example, 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 is actively communicating with the mobile part 2 and thus data is being transmitted. swaps. 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 base station 1 is shown schematically in FIG. 1. The voice information data are supplied 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.

2, a transmission standard that can be used in the present invention will now be explained. As can be seen from FIG. 2, data are transmitted successively in a plurality of time slots, in the illustrated case 24 time slots Zx, on a plurality of carrier frequencies fx, ten of which are shown, in 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 time duration of a time frame is 10 ms, and 24 time slots Zx are provided, namely twelve time slots for the transmission from the base station to handsets and a further twelve time slots Zx for transmission from the handsets to the base station. 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. At least 75 carrier frequencies must be distributed over this 83.5 MHz in accordance with the "FCC part 15" regulation. A division of the bandwidth from 83.5 MHz to 96 carrier frequencies, ie a channel spacing of 864 kHz, is particularly advantageous. The above-mentioned frequency bands and standards are given purely by way of example The basic prerequisite for applicability in the present invention is only that a so-called frequency hopping spread spectrum is used, ie that several carrier frequencies are available, and that the carrier frequency chosen for transmission from time to time The prerequisite for such a change is that the data is transmitted in time slots Zx (time division multiplex method), for example the DECT standard and any other modified standard based on this DECT standard are suitable.

The inner structure of a base station 1 according to the invention will now be explained in more detail with reference to FIG. 3. 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 information data is output from the RF module 4 if data received by handsets. The RF module 4 modulates the digitally coded information data onto 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 sequence unit 20 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 a received signal on a carrier frequency and by detecting whether or not there is a signal level on this carrier frequency. A disturbed carrier frequency is therefore a carrier frequency onto 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 component modulated onto a specific carrier frequency fx is. If the detected signal component is above a predetermined limit value, the detection device 24 sends a fault detection signal to a blocking / release unit 21. Depending on the interference detection signal from the detection device 24, the blocking / release unit 21 gives a blocking / release information to a processor 23. This blocking / release information 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.

An independent procedure is thus created by means of the detection device 24 and the blocking / enabling device 21, 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. On the basis of a random algorithm implied in the random generator 22 generates a randomly distributed sequence of carrier frequency values. within the usable frequency band. The random generator 22 thus executes a procedure which is independent of the procedure for frequency blocking in the event of a fault. The processor 23 finally sends a control signal to the RF module 4, which specifies the carrier frequency value to be used for the RF module 4.

The processor 23 has a table 25 provided in a memory, the function and management of which will be explained later.

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 is shown hatched in FIG. 4. This frequency fl is thus the first value of the sequence generated by the random generator 22, which is fed to the processor 23, which in turn controls the RF module 4 accordingly. For the frame R2, it is assumed that the random generator 22 prescribes a frequency jump Pl to a carrier frequency f3 on the basis of its calculated frequency.

Let us now assume the case 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 has therefore given a corresponding interference signal to the blocking / releasing unit 21, which in turn blocks the signal the frequency f2 which has indicated to the processor 23. Furthermore, it is assumed that the random generator 22 prescribes the carrier frequency f2 previously detected as disturbed for the frame R3 based on its determined sequence. On the basis of the coincidence of the prescribed carrier frequency f2 in accordance with the sequence of the random generator 22 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 is detected as being disturbed by a from the detection device 24 as Carrier frequency detected without interference, for example carrier frequency f4, as indicated by 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 compared to the original sequence.

The basis of this modified sequence consisting only of undisturbed carrier frequencies fx are therefore two superimposed, mutually independent procedures (random generator 22 or blocking / releasing unit 21). This blocking can be released by the blocking / releasing unit 21 as soon as a new detection by the detection device 24 indicates that the previously disturbed carrier frequency is no longer disturbed. In this case, the blocking / releasing unit 21 issues 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 output a release signal to the processor 23 without a renewed 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 predetermined frequency spectrum is used in an evenly distributed manner. By adjusting the times in the procedure for blocking frequencies, standards can thus be met.

An example of such a standard is the US regulation "FCC part 15". This regulation prescribes that for one Frequency hopping spread spectrum systems must use at least 75 different frequencies within a period of 30 seconds. Each frequency can be used for a maximum of 0.4 seconds in 30 seconds. In addition, on average, all frequencies must be used equally.

Base station 1 is the master in frequency allocation, i.e. H. at the beginning of a connection establishment, the random number generator is initialized in a mobile part with the state of the random number generator 22 of the fixed station 1. The random number generators in the mobile part 2, 3 ... and in the base station 1 then generate the same carrier frequency values synchronously in the frame rate and independently of one another.

The procedure for frequency blocking, which is carried out by the detection device 24 and the blocking / releasing unit 21, uses a unidirectional protocol on the air interface during the entire connection time between the base 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 parts with which it operates active connections that this disturbed frequency, if by the frequency of the random number generator is to be replaced by another carrier frequency that is not detected as being disturbed. The frequency blocking is withdrawn again by the blocking / release unit 21 when the blocked carrier frequency is again suitable for transmission or when it was blocked for longer than a previously defined time.

In FIG. 3 it can be seen that a table 25, for example provided in a memory, is assigned to the processor 23. 3 and FIGS. 5 to 8, it will now be explained how, according to the invention, the actually usable carrier frequencies fx, that is to say the carrier frequencies fx, which are not currently blocked, are provided. As in 5, all the available carrier frequencies fx, for example 96, are entered in a table 25.

In FIG. 5, 96 frequencies f1 to f96 are entered under the corresponding address in table 25. The number of total carrier frequencies fx, 96 in the present case, is denoted by N. Certain carrier frequencies of the 96 carrier frequencies fx will be blocked for a certain period of time. Since, according to the US regulation "FCC part 15", as already explained above, at least 75 different frequencies must be used in a period of 30 seconds, with a total of 96 carrier frequencies present, a maximum of 21 carrier frequencies may be blocked over a longer period The number of the carrier frequencies fx that are actually available, that is to say the unlocked carrier frequencies, is denoted by M. The random number generator 22 in FIG. 3 therefore does not as a rule have to output sequences that have N different values, rather it is sufficient if it has M (actually available carrier frequencies) 3, the processor 23 therefore sends information to the random number generator 22 in order to transmit to it the number M of the actually available and unlocked carrier frequencies, for example the value M is updated in every frame - Siert and transmitted to the random number generator 22.

5, it can be said in summary that the table contains N addresses, each of which contains a possible frequency value fx. Each frequency value fx occurs only once in the table.

How the table is managed when one of the N carrier frequencies is blocked and thus becomes M ≠ N will now be explained. This case is shown in Fig. 6. It is assumed that it was detected that the carrier frequency f3 originally written in address 3 is disturbed. At the transition to the next frame, according to the invention, the the carrier frequency value f3 is written to the last address before a so-called pointer (pointer), the pointer always being at position N. At the same time, the register content of the address M, in the present example the frequency f96, is written into the address 3 of the blocked frequency. The last step is to decrement the pointer and thus M by 1.

As a result, the state as shown in FIG. 6 is created. The carrier frequency f3 to be blocked, which was originally written in the address 3, was exchanged with the carrier frequency f96, which was written in the address M (= 96). The pointer was then decremented to the address M = 95. The addresses with the number 1 to M therefore contain the usable frequencies, and the addresses behind the pointer (> M) contain the blocked carrier frequencies. The value of the pointer is equal to M, so that the random number generator 22, to which the value M is continuously transmitted, always generates sequences with address values that contain an unlocked frequency.

7, it will now be explained how, according to the invention, one carrier frequency value is blocked and at the same time another carrier frequency value is released. As an example, assume that the initial state is that shown in FIG. 6. As can be seen from a comparison of FIG. 6 with FIG. 7, the register contents, ie the carrier frequency values of the associated addresses, are exchanged very simply. In the example shown, it is assumed that the carrier frequency f3 blocked at the transition from FIG. 5 to FIG. 6 is to be released and at the same time the carrier frequency f94 not previously blocked is to be blocked. As can be seen in FIG. 7, the frequency f3 was simply written in the place of the previous address of the frequency f94 to be blocked, ie at the address 94, and at the same time the address f94 to be blocked under the previous address of the carrier frequency f3 to be released (address 96). registered. The The position of the pointer and thus M is not changed in such a process.

With reference to FIGS. 8a and 8b, it will now be explained how a blocked carrier frequency can be released again. It is assumed that the initial state of the frequency lock is as shown in Fig. 8a. As can be seen from a comparison of FIG. 8a with FIG. 8b, when a blocked carrier frequency is released, the register content of the address behind the pointer is exchanged with the register content of the frequency to be released and then the pointer and thus M are incremented by 1. Starting from FIG. 8a, it is assumed that the carrier frequency f95, which in the initial state is entered behind the pointer in the table and is therefore blocked, should be released. As can be seen from a comparison of FIG. 8a with FIG. 8b, according to the invention the frequency f95 m to be released is written in the address M + 1 and thus behind the pointer. In the present case, this is the address 94. At the same time, the previous register content of the address 94, namely the carrier frequency f94, is written to the address 95 of the carrier frequency f95 to be released. Finally, the pointer and thus M are incremented by +1. The state of FIG. 8b is thus reached

The invention can thus ensure that the number of actually available (not blocked) carrier frequency values can be used effectively and evenly.

Reference list

1 base station 2 handset 3 handset 4 RF module 6 antenna base station 7 antenna handset first radio transmission path

9 second radio transmission path

10 terminal line

20 carrier frequency sequence unit

21 Lock / release unit

22 random generator

23 processor

24 detection device

25 Table fx carrier frequency

Rx frame

Zx timeslot

Claims

claims

1. Method for providing usable carrier frequency values for mobile radio applications, characterized by the following steps:

Providing a predetermined number N of possible carrier frequency values fx,

Blocking at least one of the possible carrier frequency values fx, so that the number of actually usable carrier frequency values fx is reduced to a number M,

Write the M actually usable carrier frequency values fx in the addresses 1 to M of a table (25), and write in the blocked carrier frequency values fx in the addresses (M + 1) to N.

2nd Method according to Claim 1, that a random number generator (22) M generates different values which are each converted into the carrier frequency values fx which are present at the respective address equal to the values generated by the random number generator.

3. The method according to any one of the preceding claims, characterized in that the following steps are carried out when a carrier frequency value is blocked:

Exchange the carrier frequency value to be blocked with the

Carrier frequency value of the address M, and

Decrement M by one.

4. The method according to any one of the preceding claims, characterized in that when a carrier frequency value is blocked and another carrier frequency value is simultaneously released, the following step is carried out: Exchange of the carrier frequency value to be blocked with the carrier frequency value to be released.

5. The method according to any one of the preceding claims, characterized in that the following steps are carried out to release a carrier frequency value:

Exchange of the carrier frequency value to be released with the

Carrier frequency value of the address M + 1, and - incrementing M by one.

6. Device for providing usable carrier frequency values for mobile radio applications, characterized by: a table (25) in which actually usable carrier frequency values are present in the addresses 1 to M, the number of actually usable carrier frequency values being M, and in which the Carrier frequency values that cannot be used at the time are present in the addresses M + 1 to N, where N is the number of carrier frequencies available overall.

7. Device according to claim 6, characterized in that a random number generator (22) is provided which generates M different values.

8. Device according to one of claims 6 or 7, characterized in that a table control (23) is provided which, when a carrier frequency value is blocked, exchanges the carrier frequency value to be blocked with the carrier frequency value of the address M and decrements M by one.

9. Device according to one of claims 6 to 8, characterized in that the table controller (23) exchanges the carrier frequency value to be blocked with the carrier frequency value to be released when a carrier frequency value is blocked and at the same time another carrier frequency value is released.

10. Device according to one of claims 6 to 9, characterized in that the table controller (23) for releasing a carrier frequency value exchanges the carrier frequency value to be released with the carrier frequency value of the address M + l and increments M by one.

11. Base station for mobile radio applications, characterized in that it has a device (20) according to one of claims 6 to 10.

12. Mobile radio system consisting of a base station and at least one handset, characterized in that it has a base station (1) according to claim 11.