DE2620250A1 - Voice unit communications system - phase or frequency keys composite data blocks which check bits whilst voice link is suppressed during transmission - Google Patents

Abstract

The voice communications system uses phase or frequency shift keying to transmit binary data blocks with check bits during breaks in voice communication. A data coupler gives up its stored data bits in response to a timing circuit. The timing circuit also controls a parallel/serial converter coupled to the coupler's outputs. The check bit is inserted into the data block at the converter's output. The composite blocks are then phase or frequency keyed and the voice communication suppressed during the subsequent transmission of a composite block.

Description

State of the art

The invention relates to a radiotelephone according to the genus of Main claim. A voice and data transmission method is known (DT-AS 23 20 722), for the simultaneous transmission of data and voice via a Message channel this channel is divided into two sub-channels. The known procedure but is too complex for most applications because it is on the receiving side the data signals have to be filtered out of the speech signals. Farther the so-called storage telegraphy is known for data telegrams and language can be transmitted on the same channel and during the transmission of a binary encoded data telegram the voice transmission is suppressed. The data telegrams in this case have an extremely short duration, so that the speech interruption hardly ever occurs can be perceived. The data telegrams are sent out at fixed time intervals using an error protection. If the known method for automatic Transmission of the identification of vehicles used in radio networks, so can automatically after pressing an emergency call button belonging to the two-way radio a data telegram can be sent, which in addition to the identifier also at least contains emergency information. In addition, it can take place at certain time intervals during transmission and an emergency call tone can be sent out for a certain period of time. In the end can also switch the two-way radio from Send to receive or from receive to send can be provided.

Until now Previously known two-way radios with a Data providers meet the aforementioned requirements in a satisfactory manner. The technical effort for the data transmitter and the space required for its installation in a walkie-talkie but are relatively large, so that for example a Replacing a tone sequence generator with a data generator is not easily feasible is. Another disadvantage is that the known radiotelephones with a data transmitter neither in terms of the transmission speed nor the Transmission type (synchronous or asynchronous transmission) or at the level of the keying frequency are variable.

Advantages of the Invention The radiotelephone according to the invention with the characterizing features of the main claim has the advantage that the data telegrams to be sent out with relatively little effort and very little Power consumption can be generated. Another advantage is that due to of the specified structure an existing two-way radio that is used for the tone sequence call is set up without additional space requirements for digital data transmission can be converted.

The measures listed in the subclaims are advantageous Further developments and improvements of the radiotelephone specified in the main claim possible. It is particularly advantageous if the ones required for identification and emergency calls Components and units on two circuit boards joined together in a sandwich construction are housed. This not only reduces the space required for the data transmitter reduce, but also also a change of the data supplier from the delivery of data telegrams of a first number of bits to a second number of bits by just using the data switch and the parallel-to-serial converter containing printed circuit board is replaced.

Exemplary embodiments of the invention are shown in the drawing shown on the basis of several figures and in more detail in the following description explained. The drawing shows in FIG. 1 a block diagram of one of the generation data transmitter serving data telegrams and emergency signals for a two-way radio, FIG. 2 shows a diagram of a complete data telegram, FIG. 3 shows a diagram of a sequence of data telegrams in a different time scale than in Fig. 2, Fig. 4 A to 4 G a time curve of the output voltages at each circuit point in the block diagram According to Fig. 1, Fig. 5 is a detailed circuit diagram of the one marked A in Fig. 1 Circuit part, FIG. 6 shows a complete circuit diagram of the one marked with B in FIG Circuit part, FIG. 7 7 A to D each show a course over time of output voltages at different switching points of the for the emergency call existing circuit part and Fig. 8 a circuit addition, which relates to the refers to the power supply to be switched on when the emergency call button is pressed.

A data transmitter according to FIG. 1 contains a data switch 1, a time circuit 2 (circuit part framed by dash-dotted lines in FIG. 1), a parallel-series converter 3 (transmitter), a device for error protection 4, a signal generator 5, a first NAND circuit 6, an inverter circuit 7, a send button 8, a first output 9 for a blocking signal and a second output 10 for the data telegrams. The time circuit 2 consists of a first oscillator 11, a first monostable Flip circuit 12 with an input 13 and an output 14, a first bistable Flip-flop 15, a second NAND circuit 16, a second and third monostable Flip circuit 17 and 18, a first electronic counter 19, a time delay circuit 20, a fourth monostable multivibrator 21 and a timer 48 together.

The data and / or identifier is switched via a switch 22 from fed to a power source 23 of the radio transceiver.

All of the aforementioned components and units are used to generate Data telegrams according to FIG. 2, the frequency-shift keyed signal of which is a high-frequency carrier modulated, while an emergency button 24, a second one, is also used for the emergency call bistable tilting Flip-flop 25, a diode 26, a transistor switching stage 27, a third output 28 for outputting a control signal for the transmitter relay of the Radiotelephone, a second oscillator 29, a third NAND circuit 30, a NOR circuit 31 and a second electronic counter 32, this is preferred a binary counter.

The following first describes how the data transmitter works without Emergency call explained.

For example, if the two-way radio belongs to a vehicle in one Radiotelephone network with automatic identification, so should when the send button is pressed 8 at certain time intervals t (FIG. 3) w a characterizing the vehicle in question Identifier in the form of a data telegram according to FIG. 2 are sent out.

Such a data telegram comprises, for example, 28 bits. For the The frequency shift keying procedure is used for the data telegram. That means here the keying of two different frequencies f1 and f2, namely the The binary value H is expressed by the frequency f1 and the binary value L is expressed by the frequency f2.

In the present example, the data telegram comprises two data blocks Db1 and Db2, and each data block begins with a start bit Sta (asynchronous transmission method), which is followed by eight data bits including an emergency call bit and a stop bit. The two immediately successive data blocks are followed by at least five, in the present example eight check bits Pr, the meaning of which is explained below will. Begin- Start and stop bits Sta, Sto are control bits that not applicable in the case of synchronous data transmission. The data telegrams according to FIG. 2 are for a duration tD of approximately 40 ms at the specific distance tw between 2 s and 10 s can be selected, transmitted repeatedly; see Fig. 3.

The identifier is a number that is permanently assigned to the radiotelephone.

A bit sequence of H (high) and L (low) signals corresponding to this number is constantly available in parallel at inputs 101 to 114 of data switch 1 as soon as the Radio has been switched on via switch 22. Simultaneously with switching on of the radio, the parallel-series converter 3, the first bistable multivibrator 15 and the second flip-flop circuit 25 through one of its reset inputs 33 applied reset signal brought into a defined starting position.

If the transmit button 8 is then actuated at a point in time t1 (see FIG. 4 A), so receives an input of the first oscillator 11, which is a start-stop oscillator represents the ground potential, which causes the oscillator to be a pulse train 4 B at its two outputs 34, 35 to be delivered.

The pulse sequence has corresponding to the time interval t between w two successive data telegrams have a period T of, for example, 2.5 s and a pulse duration of about w 10 ms.

The pulse train emitted at the output 35 is determined by the ZeitverzöqeruIsgsschalEtlng 20, which caused the transmitter to run out with unmodulated carrier. allowed, converted into a pulse train according to FIG. 4C and one only on a falling edge responsive input of the fourth monostable multivibrator 21 supplied. The time between t2 and t3 serves as a lead time for the data evaluator. The latter Flip-flop outputs a pulse train according to FIG. 4 D at its output 36, which indicates a first input 37 of the first NAND circuit 6 is located. A second entrance 38 the NAND circuit 6 is connected to an output 39 of the device 4. This The output has at a time t2 at which the input 37 of the NAND circuit 6 is on Has a low signal, a high signal; see Fig. 4 E. The logical connection gives the NAND circuit 6 sends a signal (Fig. 4 F) to an input 40 to enable the signal generator 5 and to the inverter circuit 7, so that the first output 9 of the data transmitter has a low signal that suppresses voice broadcast; see. Fig. 4 G.

Since the output 39 of the device 4 for the duration tD of a data telegram emits an L signal, remains even when the fourth monostable multivibrator 21 flips back into its stable state at a point in time t4, the locking signal obtained according to Fig. 4G.

The actual generation of a data telegram according to FIG. 2 takes place in the following way. The first one switched on by pressing the send button 8 Oscillator 11 also emits the pulse sequence shown in FIG. 4B at its output 34 away. The output is an input that only reacts to falling edges first nonostabi Len KippscI'altung 12 connected, which is a very brief one short Has a service life of about 100 ps, so that it emits a pulse train at its output 14 emits needle-shaped pulses, which begins at time t3 (see. Fig. 4B).

With the falling edge of the needle-shaped impulses, that is, for the first time at time t3, the device 4 is brought into a specific starting position and the first flip-flop 15 flipped into its second stable state, in which there is a change from an L signal to an H signal at its output. Since the parallel / serial converter 3 has an H signal at an output 41 at this point in time outputs, which is at a first input 42 of the second NAND circuit 16, and at a second input 43 the signal changing from low to high is only reacting to a falling edge second monostable multivibrator 17 in their tilted quasi-stable position, in which it is connected to an input 44 of the parallel-series converter 3 emits a certain signal that causes the converter to receive the data from the data switch 1 taken over first eight data bits of the first data block Db1 with addition one start and one stop bit Sta, Sto each to be output to a data output 45. The signals of the data block arrive at a data input 46 of the device 4, in which the Bits are stored first. As soon as the first ten data bits the parallel to serial converter 3, the output 41 briefly emits an L signal and then immediately return to the H state. The L signal causes the third monostable Toggle circuit 18 to advance the counter 19 by one step.

At the same time, the monostable multivibrator 17 is another specific one certain Signal at input 44, which adds the eight bits of the second data block a start and stop bit at the data output 45 and in the device 4 can be saved. As soon as these bits are delivered, the converter 3 delivers its output 41 again briefly an L signal, which is via the third monostable Toggle circuit 18 advances the counter by one step. So there is. the counter in a position in which it sends an L signal to a clear input 47 the first bistable flip-flop 15 emits, which thereby in its initial state tilts back and prevents further transmission of data bits.

The data, start and stop bits stored in the device 4 are supplemented by eight check bits Pr according to a cyclic code (see Fig. 2) that error detection is possible on the receiver side. Used for coding a suitable polynomial, for example x8 + x² + x + 1, is used, a Hamming distance = 4 meet.

The complete data telegram is available at the output of device 4 as a bit sequence, the binary values of which by frequency shift keying by means of the signal generator 5 can be converted into the two different keying frequencies fl, 2 f2. That Keyed data telegram arrives at output 10 of the identifier, which is accompanied by is connected to the modulation input of the transmitter.

The clock 48 connected to the parallel / serial converter 3 determines the transmission speed of the data bits.

By By using the same reference numbers As in FIG. 1, the detailed circuit diagram of FIG relieved. Some structural units of the circuit part A in FIG. 1 are shown in FIG. 5 framed by dash-dotted lines.

The units 1, 3, 17, 18 contain integrated circuits from CMOS type.

The following describes the generation of the emergency call bits within the data telegram and the emergency ringtone with reference to FIGS. 1 and 7 A to 7 D explained.

If the emergency call button 24 is actuated, the diode 26 transmits the Ground potential at the input of the first oscillator 11, whereby the generation of a Data telegram, as already described in detail above, runs. One and only The difference is that this is also provided for an identification signal generation Emergency bit No (Fig. 2) a predetermined binary value characterizing the emergency call, for example L, which is recognized accordingly in the evaluator. One emergency bit each per data block is provided because it increases the security of the Evaluation increased.

The generation of an emergency call will now be described.

With the brief actuation of the emergency button 24 also receives the second bistable flip-flop 25 belonging to the further time circuit 49 das Ground potential (see. Fig. 7 A) and thereby tilts from a first stable state in the second stable state. It gives a certain at its first output 50 signal Signal from (see. Fig. 7 B) that the transistor switching stage 27 causes a signal at the output 28 to excite the to the radio corresponding transmitter relay. At a second output 51 of the second bistable In the second stable state, flip-flop 25 also has a corresponding signal 7B, which is fed to an input 52 of the parallel-serial converter 3. The emergency call bits to be supplied by the parallel serial converter are obtained from this signal the predetermined binary value L. A third output 53 of the second bistable multivibrator In the second stable state, 25 also emits a signal according to FIG. 7B, which is called an H signal, which is supplied to a first input of the third NAND circuit 30 is, whereby the frequency f1 of the already switched on signal generator 5 to Output of the NAND circuit 30 is switched through. The NOR circuit 31 is linked the output signal of the second oscillator 29, that is a start-stop oscillator, with the output of the NAND circuit 30 and thus supplies the intermittent at its output Emergency tone (see. Fig. 7 C and 7 D).

The signal from the second oscillator is also applied to a counter input of the second counter 32 which is preset so that it is at a first output 54 a signal to the transistor switching stage that changes at intervals of about 10 s 27 and at a second input 55 after about 20 minutes an impulse to reset the second bistable flip-flop 25 or

to automatically end the emergency call. The switching stage switches then the walkie-talkie at intervals of about 10 s periodically from sending to receiving or from receiving back to sending.

is If the emergency call has ended after about 20 minutes, by pressing the emergency button 24 again, the above-described Process to be repeated.

In Fig. 6 are components or units included in the circuit part B occur in FIG. 1, provided with the same reference numerals as in FIG. The circuit parts A and B (Fig. 1) are each housed on a circuit board. For electrical The connection between the circuit boards is a six-pole plug device 56 (Fig. 1) provided. Both circuit boards are arranged one above the other in a sandwich construction, so that they take up as little space as possible. The one from the two circuit boards The composite data transmitter module can be easily integrated into a two-way radio accommodate in what space for a designed as an exchangeable module Tone sequencer is available. The division into two circuit boards has above in addition, the advantage that only one plate needs to be replaced when you instead of a data telegram with a first number of data bits, a data telegram wants to send out with a second number of data bits.

So that an emergency call can also be sent out when the two-way radio switched off, that is, the switch 22 (Fig. 1) is open, the in Fig. 8 can be used. The circuit for the walkie-talkie is in this case turned on by operating a device switch 57, the one Circuit for a first relay 58 closes, closes to that the switch 22 belongs. If the device switch 57 is not closed, the Power supply for the two-way radio also by pressing the emergency call button 24 switched on, whereby a circuit for a second relay 59 is closed. The second relay 59 has a switch 60 which is connected in parallel to the device switch 57 and which takes on the function of a self-holding contact. Is the second relay 59 excited by pressing the emergency button 24, the circuit for the first relay 58 closed, from the current source 23 via the field winding of the relay 58, a diode 61 and the closed switch 60. When not actuated Emergency call button 24 and open switch 60 is the positive potential of the power source 23 via the excitation winding of the second relay 59 to the one connected to the emergency call button Input of the second bistable flip-flop 25 (Fig. 1).

In certain cases it can be an advantage when generating the The data telegram to be sent is a phase shift keying instead of the frequency shift keying (FSK) (PSK) to be applied.

If the data are to be transmitted synchronously, an input 62 of the parallel-serial converter 3 with a signal of a certain logic state applied in which the converter sends out the data blocks without start and stop bits. In this case, the first eight data bits of a data telegram are used, for example for the synchronization of the data recipient. The result for 'pure data transmission The lost bits are then stored in an additional data block of the data telegram housed,, Ä (replacement of circuit board A).

Claims (14)

Claims 1.) Radiotelephone with a transmitting part, which is preferably can periodically send out data telegrams symbolizing an identifier of the device, each data telegram comprising a sequence of binary data and check bits, their Binary values are sent out with frequency or phase shift keying, and where for the transmission of the data telegrams briefly interrupted the voice transmission is characterized by an electronic data switch (1) that contains all data bits stores, an electronic time circuit (2), which the data switch for delivering the Stored data bits in the form of data blocks comprising several bits (Db1) caused at their outputs, one connected to the outputs of the data switch and from the time circuit controlled parallel-to-serial converter (3), the block by block recorded data bits as a sequence of data bits at its outputs, a Device for error protection (4) connected to the outputs of the converter, which adds check bits (Pr) determined according to a cyclic code to the sequence of data bits, a signal generator (5) connected to the error protection device, the the frequency shift keying or phase shift keying of the data and check bits causes while the time circuit (2) for the duration of the transmission of the data telegram a certain Emits blocking signal to interrupt the voice transmission. 2. Radiotelephone according to claim 1, characterized in that the Transmitter part of the radio transceiver an emergency button (24) and a further time circuit (49), which causes when the emergency button is pressed that first one of the identifier the radio communication device corresponding data telegram is sent out that second before the data telegram is sent, each data block (Db1, Db2) has a specific one Binary value having emergency bit (No) is assigned that third between each two successive data telegrams an emergency tone of a first specific one Duration is sent out, which is one of two keying frequencies supplied by the signal generator (f1, 2), and that fourthly, the sending of emergency tones after a second determined Duration is interrupted. 3. Radiotelephone according to claim 1 or 2, characterized in that that the electronic data switch (1), the electronic timing circuit (2) and the parallel-series converter (3) on a first printed circuit board (A) and that the further time circuit (49), the device for error protection (4) and the signal generator (5) on a second printed circuit board (B) are accommodated and that both circuit boards form an interchangeable sandwich module are summarized. 4. Radiotelephone according to claim 1, characterized by a to the first electronic time circuit (2) belonging first oscillator (11), the one periodic pulse train with a pulse period (Tw) equal to the duration between emits two consecutive data telegrams, through one through the Pulse train controlled first monostable multivibrator (12) for transforming the pulses the pulse train into very short pulses, through one with the first monostable multivibrator connected first bistable multivibrator (15), which at each pulse of the first monostable Flip-flop switching from a first stable state to a second stable state toggles, by a second monostable multivibrator (17), the parallel-series converter (3) each causes the delivery of the next data block (Db1, Db2) if the first monostable multivibrator is in the second stable state and the Parallel-to-serial converter has just delivered a block of data by means of a clock (18) for generating clock signals for the serial output of the individual bits the parallel-series converter and a first electronic counter that after each time a data block is output by the parallel-serial converter by one counting step is switched on, each time the switch is switched on, the data switch to output the the next data block belonging data bits to the parallel-serial converter and when the last data block of a data telegram is output, the first bistable Resets the toggle switch to the first stable position. 5. Radiotelephone according to claim 2, characterized in that the further time circuit (49) also causes that when the emergency call or send button is pressed the walkie-talkie automatically switches from sending to receiving at certain time intervals is switched. 6. Radiotelephone according to claim 2 or 5, characterized in that that the emergency call tone consists of a square wave signal voltage with a pulse frequency exists, which corresponds to one of the two keying frequencies (f1, f2). 7. Radiotelephone according to claim 1 or 4, characterized in that that the data switch (1) has a single switch for each data block (Db1, Db2) (Fig. 5). 8. Radiotelephone according to claim 1 or 4, characterized in that that the time circuit (2) also has an output (35) of the first oscillator connected time delay circuit (20) and one with the time delay circuit connected fourth monostable multivibrator (21) has, from the output signal Blocking signal (Fig. 4 G) for blocking the voice transmission during the data transmission as well as a specific signal for switching the signal generator on or off (5) is derived. 9. Radiotelephone according to claim 4, characterized in that the further time circuit (49) essentially a second bistable multivibrator (25), a second oscillator (29), a second electronic counting circuit (32) and has a transistor switching stage (27) and that the further timing circuit with the Emergency button (24) and the parallel-serial converter (3) is connected that the second bistable toggle switch when pressing the emergency button (24) from a first in reaches a second stable state in which she a certain Outputs signal that firstly sends the parallel-serial converter to provide the emergency call bits (No) causes, secondly, the response of a transmission relay of the radio transceiver causes and thirdly ensures that the signal generator (5) as a continuous tone emitted emergency tone is forwarded to a logic circuit that the Emergency call tone at the specified intervals for the specified duration at the data telegram output (10) of the data supplier. 10. Radiotelephone according to claim 9, characterized in that the Logic circuit is a NOR circuit (31) with two inputs, at the first Input of the emergency tone of the signal generator (5) and at its second input a from the second oscillator (29) delivered periodic pulse train is a Duty cycle of about 1: 1 and a pulse duration corresponding to the emergency call duration or pause. 11. Radiotelephone according to claim 9 or 10, characterized in that that the second oscillator (29) with an input of the second electronic counter (32) is connected, which is preset so that it is after a certain Duration at a first output (54) a signal to reset the second bistable Toggle switch (25) releases. 12. Radiotelephone according to claim 2, 9 or 10, characterized in that that the second oscillator (29) has an input for blocking the delivery of its pulse train and that this Singailg with the output (9) for the locking signal @@@@@@@ 13th Radiotelephone according to Claim 11, characterized in that the second electronic Counter (32) is also preset in such a way that it is connected to a second input (55) a signal at a certain, periodically repeating time interval to automatically switch the two-way radio from sending to receiving or from Reception to send gives. 14. Radiotelephone according to one of claims 2 to 13, in which the Power supply is switched on by means of a device switch Circuit for a first relay is closed, whose switch is the power source connects to the device circuit, characterized in that when not actuated Device switch a switch-on is made possible that when you press the Emergency button (24) a circuit for a second relay (59) is closed, the in the energized state a switch (60) closes, which bypasses the device switch and closes a self-holding circuit for the second relay.