NO865159L - PROCEDURE AND DEVICE FOR NON-AUDIOUS IDENTIFICATION CODE EXCHANGE BETWEEN A FEW WIRELESS STATIONS. - Google Patents

Description

The present invention relates to a method for exchanging identification codes between a pair of wireless stations, more specifically a wireless telephone of the type specified in the introduction to claim 1.

Telephone devices usually have a connection with the telephone connection point via a cable with a length of a few metres. The connection between the receiver and the telephone set via the telephone line is considerably shorter. During a telephone conversation, the user is forced to be in one place and can hardly move from that place during the conversation.

An improvement came when so-called loud-speaking telephones appeared which made it possible for the user to move freely a few meters during the telephone conversation.

With the aim of extending the user's range of motion, the so-called cordless telephones were introduced in several countries. Exchange of information between a base station and the associated mobile station of a pair of wireless stations (cordless telephones) is effected via a radio channel. The base station is connected to the main connection point or a private branch via a connection box so that the user can access the public telephone network. Due to the fact that the base station and the mobi1 station are connected via a radio channel, the range of movement of the user can be increased to a radius of approximately 200 meters from the specific terminal.

In West Germany, e.g. 40 radio channels available for transmission and information, operating at 900 MHz frequency range. In the transmission area mentioned above, the probability that the same radio channel is occupied by an adjacent cordless telephone is small. If there is a forb indel request, a search cycle for a free radio transmission terminal is started, and the channel is seized. To ensure that the message to be sent between a pair of wireless stations cannot be overheard by other pairs of wireless stations or to ensure the debiting of the call, each pair of radio stations has a coding device, the code (identification) of each transmitter at the mobile station or in the base station is part of the device and is independent of the telephone number of the participant in the telephone conversation.

At the mobi 1 station, the radio channel search is started with the action of a cable switch. At the base station, a valid, incoming call on the subscriber's line will trigger a radio channel ing. EP-B1 0 074 940 describes radio channel searching and identification of code switching caused by radio connection setup in more detail. The radio transmission channel recognized as free is occupied, and the transmitter is activated and the identification code is sent as a data telegram via the radio transmission channel. After each release of such a data telegram, an acknowledgment telegram is awaited for the corresponding opposite station. When such an acknowledgment telegram is received, the received identification code (acknowledgment telegram) is compared with the identification code at the sending end. When there is a match between these two codes, the corresponding transmitter for the pair of radio stations stops sending the identification code.

In an article in "ntz", number 38 (1985) vol. 7, pages 468 to 471, a cordless telephone for the frequency range 800 MHz is described. On page 468, it is described that 40 radio channels are automatically managed and that when the base station is stationary, all 40 radio channels are scanned sequentially to check whether there is a call requesting the establishment of a connection with the mobile station. Channel polling is effected cyclically, as it is first checked whether the radio channel that has just been polled is busy and whether this channel is not known to be free and subsequent connection to the radio transmission channel which is the next in the cycle is effected. On page 470, it is described that during the call an identification code is exchanged every fifteen seconds. During this identification code exchange, the voice transmission is briefly interrupted and the transmission of the data telegram is just audible in this blank interval. Short interruptions in the voice transmission are usually felt as a nuisance to the user of a cordless phone.

The purpose of the invention is therefore to provide a method for identification code exchange during the telephone conversation which does not include interruptions in the conversation.

This purpose is achieved by means of a method of the type mentioned at the outset, the characteristic features of which appear in claim 1.

The method according to the present invention has the advantage that an audible exchange of identification code is effected during the conversation, the data telegram being sent being an inaudible on/off band signalling. The coupling from an in-band signal to an inaudible out-of-band signaling is easy to provide, as it is possible to use preferably standard commercially available microprocessors to generate and evaluate the signals.

According to claim 2, the identification code is distributed over several telegram blocks, whereby an advantageous fast reaction time and low frequency operation is provided during the transmission of the identification.

The embodiment according to claim 3 has the advantage that the identification code sent with a reduced level is a small contribution to the total signal, so that the identification code only affects the total signal to a small extent and does not in itself act as any interference.

According to claim 4, in the event of disturbed operation, the individual telegram blocks are repeatedly sent so that the transmission reliability can be increased in a simple way.

If the transmission of the identification code is effected during the conversation using an amplitude modulation method and the transmission of the identification code is effected during the connection setup by using a frequency keying method (claim 5), the advantages of simple processing by the microprocessor are provided and only small additional -cost and construction effort are required for symmetry and filtering purposes.

By using the telegram structure defined in claim 6, a simple synchronization between the stations of pairs of wireless stations is provided.

Further advantageous embodiments and methods according to the present invention are described in the subclaims.

The circuit arrangement for providing the method according to the present invention is of a simple construction and on the transmitting side only a changeover switch and an additional low-pass filter are required as additional circuit cost and construction effort, both in the base station and the mobile station. In order to separate the in-band signals and the out-of-band signals, a filter with steep flanks such as a low-pass filter is not necessary.

In what follows, the invention will be described in more detail by means of an example with reference to an embodiment shown in the accompanying drawings, where: Fig. 1 shows a block diagram of a pair of wireless

stations.

Fig. 2 shows the individual signalization phases of the method according to the present invention. Fig. 1 shows the block-circuit diagram of a pair of radio stations consisting of a base station BS and a mobile station MS with only the parts necessary to understand the invention shown.

The base station BS and the mobile station MS each have an identification code store KSP which is connected to a microprocessor MPB or MPM, respectively. The identification code read by means of respective microprocessors MPB and MPM is supplied to a code converter CWB and CWM. The output of the respective code converters CWB and CWM is connected with a low-pass filter TPlog also with a changeover switch UB and UM respectively. The respective changeover switches UB and UM are always connected by a logical combination network, e.g. a summing amplifier SB or SM, respectively, whose output is connected via respective low-pass filters TP4 or TP5 to respective transmitter/receiver devices S/E-B and S/E-M. An amplifier V whose output is always connected to respective low-pass filters TP2 and TP3 is connected to the receiver branch of the transmitter/receiver device S/E-B at the base station BS or S/E-M in the mobile station MS respectively. The cut-off frequency of the low-pass filter TP2 is in the range of approximately 150 Hz and the cut-off frequency of the low-pass filter TP3 is in the range of approximately 1.6 kHz. Separation of the in-band and out-of-band signaling is effected by two low-pass filters TP2 and TP3 respectively, with specific signals being assessed by respective microprocessors MPB and MPM.

At the "rest stage" (no voice use), the identification, e.g. a data telegram with a bit rate of 1.2 kbit/s sent in the voice band, which in the public telephone network is in the frequency band from 300 to 3 kHz. By means of this in-band signaling, a rapid identification code exchange can be effected before the start of the call.

During the telephone conversation, a noticeable interruption in the conversation connection must be prevented when such an identification exchange as described earlier is effected. With this phase method according to the present invention, a so-called out-of-band signaling is effected with superimposition of identification (data telegram) and conversation. A significantly lower bit rate, e.g. a bit rate of 32 bit/s is used for the transmission of this data telegram.

For modulation of the identification code, baseband modulation "SIN-FFSK" or "Manchester" is used, which have characteristic frequencies of 0.6 kHz and 1.2 kHz. For out-of-band signaling, an audio frequency located outside the voice band is keyed at half the data rate, the subcarrier being, for example, located in the range of 127 Hz.

Fig. 2 shows in more detail different signaling phases in the method according to the present invention. In the case of an outgoing call from the mobile station, pressing the fork switch to set up the connection between the mobile station MS and the base station BS will cause the identification code K to be read several times and the confirmation in the base station (the confirmation Q). Also subsequent connection of public exchange A is confirmed in the base station BS and then a signal switching U is effected, which is also confirmed. The transmission of a data telegram mentioned in the above is always effected by means of the in-band signaling transmitter IBS. After a proper switch to the out-of-band signaling ABS, the line-ready tone is sent to the mobile station MS. If the dialed numbers Z are now fed in using a keyboard placed in the mobile station MS, the connection from the out-of-band signaling ABS to the in-band signaling becomes IBS. The first digit sent by the mobile station MS is confirmed by the base station BS (via Q) and immediately afterwards the base station BS sends a numbering signal request W. Then the digit Z is sequentially sent until, via a numbering signal storage S, the base station BS informs that the numbering procedure has been completed concluded. By means of a signal switching U, corresponding release of the call and change to out-of-band signaling ABS is effected. During the transmission of the band signals, the LF branch which is not necessary is "attenuated" via a corresponding attenuation circuit.

For a call center by the base station BS, the identification codes K, which are confirmed by the mobile station S, are always sent for setting up a connection from the base station BS by using in-band signaling IBS. After the connection has been set up, the dial tone is activated by means of a telegram F, then a public connection A is effected and when the public central connection has been provided, corresponding signaling switchover U is effected. When the call has ended, the station MS causes a break B of the connection.

In accordance with the preferred embodiment, the identification code is distributed over several telegram blocks. The individual telegram block includes one after the other, a block synchronization, a block number and a special identification code part. Block synchrony sees no one has a length of e.g. 4 bits, the block number a length of 2 bits and, when divided into four blocks, the identification part has a length of 5 bits. With a 20-bit identification code, it is almost possible to have 1 million different identification codes so that a high degree of protection against illegal listing can be provided. For sending such a block and the above-mentioned 32 bit/s bit rate, a time of approximately 344 ms is required and the telegram interval has a duration of e.g.

31 ms.

Asynchronous data transmission in conjunction with half-duplex operation frees up the microprocessor and provides a corresponding noise reduction in the two-wire mode of operation. The change from out-of-band to in-band signaling is effected in case of erroneous telegram transmission, whereas switching from in-band to out-of-band signaling is effected by means of a special telegram. While, on the other hand, the in-band signal is sent at the same level as the voice signal, the level of the out-of-band signal is reduced and stored above the voice signal. During the transmission of in-band signals, the acoustic transducers (L,M) of the cordless telephone are switched to the off state. Compared to the out-of-band signaling ABS, broadband filters are required for the in-band signaling IBS. The microprocessors MPB or MPM respectively take over the task of filter switching, signal generation and signal detection.

For a cordless telephone, a code exchange is effected every fifteen seconds, for identification code exchange none of the prior art requires a data transmission with 1.2 kbit/s in the voice band and a corresponding attenuation of the acoustic converter and the telephone line during the data transmission. In the method according to the present invention, an inaudible identification code exchange is effected during the telephone conversation, the identification code exchange being terminated by an erroneous transmission after a period of approx. 3 seconds. It is thus possible to effect in a simple manner an identification code exchange several times during the fifteen second period to increase the certainty that only associated pairs of radio stations are in communication with each other.

Claims (11)

1. Method for the exchange of an identification code between a pair of wireless stations, more specifically a cordless telephone with several radio channels, in which to set up a connection via a radio channel that is found to be free (in-band signaling) an identification code exchange is effected between associated pair of wireless stations and by which, when there is a match between the identifications, the radio connection is connected, characterized in that during the call a connection from in-band signaling (IBS) to out-of-band signaling (ABS) is repeatedly effected and thus, an inaudible alternating identification is effected between the stations (BS, MS) of a pair of wireless stations, the identification code (K) being sent in a frequency band which is located outside the frequency band for voice transmission. 2. Method according to claim 1, characterized in that for this purpose of exchanging an inaudible identification code, the identification (K) is distributed over several telegram blocks. 3. Method according to claim 1, characterized in that during a non-audible identification code exchange, the out-of-band signals are superimposed on the speech signal at a reduced level. 4. Method according to claim 2, characterized in that in the event of a disturbed operation of a telegram block which is detected as being incorrect, the telegram block is repeated several times. 5. Method according to claim 1, characterized in that out-of-band signals are amplitude modulated and the in-band signals are frequency modulated. 6. Method according to claim 2, characterized in that a telegram interval is always placed between the telegram blocks. 7. Method according to claim 1, characterized in that during the call the identification code (K) is sent regularly at intervals of a few seconds. 8. Circuit arrangement for carrying out the method according to claim 1, characterized in that in the transmission direction the identification code (K) is stored in the base station (BS) and in the mobile station (MS) in an identification code store, read with the help of the microprocessor (MPB, MPM) and supplied to a code converter (CWP, CWM), that a low-pass filter (TP1) and a switching switch (UB, UM) are connected to the encoder (CWB, CWM), that for switching from in-band signaling to out-of-band signaling (IBS, ABS) the microprocessor (MPB, MPM) connects one of the outputs of the low-pass filter (TP1) or the output of the encoder (CWP, CWM) with the changeover switch (UB, UM) and that in the receiving direction separation of the in-band signaling from out-of- band signaling (IBS, ABS) effected in the base station (BS) and in the mobile station (MS) by means of parallel-arranged low-pass filters (TP2, TP3) which have different blocking frequencies and are arranged in the receiver branch between the microprocessor (MPB, MPM) and the receiver amplifier (V) . 9. Circuit according to claim 8, characterized in that the out-of-band signaling (ABS) is sent in a frequency range below 300 Hz, as a result of which the transmission width is reduced and the signal processing operation in the microprocessor (MPB, MPM) is simplified. 10. Transmitter for use with a circuit device according to claim 8, characterized in that the identification code (K) stored in an identification code store (KSP) is read using a microprocessor (MPB, MPM) and supplied to a code converter (CWP, CWM), that a low-pass filter (TP1) and a changeover switch (UB, UM) is connected to the code converter (CWP, CWM), that for switching from in-band signaling to out-of-band signaling (IBS, ABS) the microprocessor (MPB, MPM ) either at the output of the low-pass filter (TP1) or at the output of the encoder (CWP, CWM) with the changeover switch (UB, UM). 11. Receiver for use with the circuit device according to claim 8, characterized in that the separation of in-band signaling from out-of-band signaling (IBS, ABS) is effected by means of two parallel arranged low-pass filters (TP2, T3) which have different blocking frequencies and which is arranged in the receiver branch between the microprocessor (MPB, MPM) and the receiver amplifier V.