WO1998023120A1

WO1998023120A1 - Method and device for search on free channel

Info

Publication number: WO1998023120A1
Application number: PCT/FR1997/002012
Authority: WO
Inventors: Gérard Auger; Grégoire Eumurian
Original assignee: Thomson-Csf
Priority date: 1996-11-19
Filing date: 1997-11-07
Publication date: 1998-05-28
Also published as: EP0976276A1; AU5059098A; FR2756130B1; FR2756130A1

Abstract

The method consists in transmitting (3) during the communication test signals of a transmission channel in the silent time intervals when there is no speech or data transmission and in maintaining (7) a table of usable frequencies on the basis of its quality of transmission. The invention is applicable to automated radiocommunication systems

Description

Free channel search method and device.

The present invention relates to a free channel search method and device. It applies to the production of automated radiocommunication systems in which the search for a free channel takes place by the emission of test patterns successively on determined frequencies.

In these systems, a dialogue between transmitting and receiving radio stations allows the receiver of the receiving station to inform the transmitter of the other station of the frequency to be used preferentially and possibly of the backup frequencies. A corresponding standardized exchange type is for example described in MIL STD 1 88-141 A. When a communication is established, the stations remain either on the single frequency which has been selected if the dialogue takes place in simplex mode or on the couple of frequencies selected if the dialogue takes place in duplex mode. However, when one or other of the stations judges the transmission quality to be insufficient, a new search for a free channel using the backup frequencies takes place by temporarily interrupting the useful communication from a few seconds to a few tens of seconds. The system must then search for other frequencies when the quality of the backup frequencies which have been previously selected has itself deteriorated during the time of the communication. Naturally these operations take time and are detrimental to the proper routing of communications.

The object of the invention is to overcome the aforementioned drawback. To this end, the subject of the invention is a real-time search method and free-channel background task allowing voice or data communications at fixed frequency or frequency escape between transmitting and receiving electric radio stations, characterized in that that it consists in transmitting during communications the test signals of a transmission channel in silence time intervals where there is no speech or data transmission and in maintaining a table of frequencies usable according to its transmission quality. The invention also relates to a device for implementing the method.

The main advantage of the invention is that it makes it possible, by using speech or data transmission silences, to search for free frequencies in the background, without disturbing the transmission and by automatically switching to better frequencies or by warning operators that better frequencies are available. The device used allows a dynamic and permanent refresh of the frequencies used and in particular in frequency evasion, those of the frequency plane.

Other characteristics and advantages of the invention will become apparent from the following description given with reference to the appended figures which represent:

Figure 1 the different steps of the method according to the invention in the form of a flowchart.

Figure 2 a formatting of the test sequence used.

Figures 3 and 4 an embodiment of a device for implementing the method according to the invention.

The method according to the invention which is described below makes it possible to use speech silences in a radio link in order to carry out propagation tests on replacement frequencies.

Obviously the method applies for the transmission of data or signals other than speech. It takes place according to steps 1 to 7 of the flow diagram of FIG. 1. Stage 1 consists in transmitting the speech to the transmitter through a delay device of determined duration T and in permanent measuring in stage 2 the amplitude of the voice signal. If the amplitude measured has not exceeded a determined threshold S during the duration T, the voice signal is not transmitted and the corresponding silence is reconstituted in the receiver. Also for the duration T a frequency test is carried out in step 3. This test consists in transmitting instead of the voice signal, a "flag" signal having characteristics known to the receiver. The "flag" signal consists for example of a series of symbols of a digital modulation with frequency or phase displacement of a type known under the abbreviations m-FSK, m- PSK, GMSK. The flag signal can be followed as shown in Figure 2 the reference of the frequency to be tested and an indicator to inform the receiver of the direction of the test which can be either the direction of speech transmission or the opposite direction. Otherwise, the test frequency is determined by a predetermined sequence and clocked by clocks synchronized in the transmitter and the receiver. At the end of the transmission of the flag, the transmitter and the receiver switch in step 4 to the test frequency and one of the two transmits, depending on the direction of the test, a digital or analog test signal. The receiver of the test signal then performs in step 5 a measurement of the signal quality by determining, for example, and in a known manner the signal / noise ratio, the number of recognized symbols and the number and the amplitude of the paths. propagation received. The quality of the test frequency is then compared in step 6 to the quality of the frequency in use for transmitting speech, and to that of the other frequencies which have already been tested during speech silences.

The receiver then decides in step 7 either to replace automatically or by an operator in step 7a as soon as possible the frequency in use for the transmission of speech by the last frequency tested, or to classify step 7b this as a backup frequency, either to store in step 7c its quality for possible future use, or finally to classify 7d unusable (rejection).

The device for implementing the method which is shown in Figure 3 allows the transmission of a frequency test sequence in a transmitting station. It comprises a delay device 8 of duration T, coupled to the audio frequency input of a radio transceiver 9 via a switch 1 0. A vocoder 1 1 having a transmission delay equal to T can possibly be substituted for the delay device 8. A device 1 2 for measuring the level of the speech signal applied to the input of the delay device 8 is coupled to the input of a sequencer 1 3 via a speech silence detection device 14. The sequencer 1 3 ensures the carrying out of steps 1 to 7 of the method. It controls a generator 1 5 of the "flag" signal, a generator 1 6 of the index of the frequency to be tested and a device 1 7 coupled to a quality table or table of frequencies 18 to determine the choice of frequency to test and control the station's transmitter on this frequency. A clock 19 controls the sequencer 13 and the device 17.

The device which is represented in FIG. 4 where the elements homologous to those of FIG. 2 are represented with the same references, makes it possible to carry out a frequency test in a receiving station of a test sequence. It includes a "flag" signal detector 20 and a frequency detector to be tested 21 both coupled to the reception output of the transceiver 9. A frequency and alternation choice logic is coupled to the output of the frequency 21 for frequency and alternating control of the transceiver 9 of the receiving station. A vocoder 23 is coupled by its input to the output of the receiver of the transceiver 9 or to the output of a silence generator 24 through a switch 25. A quality test device 26 is coupled between the receiver output of the transceiver 26 and a memory 27 for recording in a memory table 27 the quality test results. These results are supplied to the frequency and alternation choice logic 22.

The method and the devices described above can operate either in duplex mode or in the alternation mode. In the case of duplex links, where normally only one correspondent speaks at a given time, the return direction is mainly composed of rests of sufficient duration to allow a free channel search. It is always the receiver of the test sequences which can, compare the frequencies, make its choice of the best frequencies and possibly decide to change the frequency of its correspondent. This simply takes place in speech silences following the flags, the flags of a connection direction being followed when the required value or frequency reference is required with a change indicator. In order to minimize possible disturbances, the effective change can be postponed until the next silence by being triggered by the corresponding "flag".

The same process can be implemented in the half-hour links, certain rests being assigned to the transmission of their preferred frequency by the receiver. However, this transmission can be deferred without great inconvenience until the next reversal of the direction of speech transmission and carried out on this occasion.

In the case of frequency evasion operation, the scrambled frequencies of the frequency plane can be replaced by free frequencies.

Claims

1. Real-time search method and free-channel background task allowing voice or fixed frequency data communications or frequency evasion between transmitting and receiving electric radio stations characterized in that it consists in transmitting (3) during communications test signals of a transmission channel in silence time intervals where there is no speech or data transmission and to maintain an array (18) of usable frequencies as a function of its transmission quality.

2. Method according to claim 1 characterized in that the frequency table is used to automatically replace the channel or channels used or to propose the replacement to an operator.

3. Method according to claims 1 and 2 characterized in that it consists in classifying (7 b) and memorizing (7 c) the transmission qualities of the channels tested before comparing them (6) with the transmission quality of the channel in during use.

4. Method according to any one of claims 1 to 3 characterized in that it consists in transmitting a test sequence composed of a "flag" signal followed by a frequency reference and a test direction indicator .

5. Method according to claim 4 characterized in that it consists in transmitting using a table arranged in a transmitter and / or a receiver a test sequence at the rate of clocks synchronized in the transmitter and the receiver.

6. Method according to claims 4 and 5, characterized in that the "flag" signal consists of a series of symbols of a digital modulation with frequency displacement.

7. Method according to claim 6 characterized in that the "flag" signal consists of a series of symbols of a digital modulation with phase displacement.

8. Method according to any one of claims 6 and 7 characterized in that the transmission quality of a channel is evaluated by measuring the signal to noise ratio, and / or the number of symbols recognized, and / or the number and amplitude of the propagation paths received.

9. Device for implementing the method according to any one of claims 1 to 8 characterized in that it comprises for the emission of the test sequence, a delay device (8) coupled to the audio input frequency of a radio transceiver (9) via a switch (10), a device (12) for measuring the level of the speech signal applied to the input of the delay device (8) coupled to the sequencer input (13) by means of a silence detection device (14), as well as a generator (15) of the "flag" signal and a generator (16) of the index of the frequency at test controlled by the sequencer (13).

10. Device according to claim 9 characterized in that it comprises for the reception of the test sequence, a detector (20) of the "flag" signal, a detector of frequency to be tested and of direction of the test (21), thus a frequency quality table coupled to a quality test device (26) and a frequency selection logic (22).

1 1. Device according to claim 1, characterized in that the channel is tested in the direction of speech or data transmission or in the opposite direction.