NO140084B - DEVICE FOR RECEIVING AND DISTRIBUTING A BINARY CODED INFORMATION - Google Patents

Description

This invention relates to a device for reception

and sending a binary-coded information consisting of an address, a command and a control signal formed by both, where the information is to be transmitted to at least one receiving station.

A method has previously been proposed for the transmission of secured, digital commands with return responses, whereby the command is issued as selective calls or collective calls,

in that the transmitted information consists of an address, a command and one of both formed redundancy. Methods are also known,

by which the binary transmitted call is entered and stored in the receiver and checked for correctness after completion of reception. A disadvantage of this method is that a transmission error can only be detected after the entire call has been received, so that there is a loss in terms of transmission speed and reception readiness. From GB-PS 977 134 it is also known to simultaneously transmit a control redundancy consisting of an address and an information part, i.e. an address and a command part, so that it is possible in the receiver in a manner known per se to carry out an error check. A method has also been proposed by means of which a transmission error can be recognized already while the address call is running in, so that the receiver can be brought back to rest more quickly. In this way, the recipient will be ready for new reception more quickly. In order to achieve security against errors, it is also known that after correct reception in the receiving station's ion, an acknowledgment signal is sent back to the calling station.

The purpose of the invention is to provide a device

which is able to satisfy the above-mentioned requirements, and which contains as few elements as possible, which task is solved by there in the receiver upon reception by means of a transmitted

synchronization signal, via a start/stop switch a clock generator is started which, via an electrical step switch, leads the received address to a comparison link, in which the address is compared with the address of the receiving station, that a comparison latch is arranged which is arranged to be controlled by the comparison link for in the event of a deviation between at least one bit of the received address from the receiver station's address, to control the start/stop switch to the stop position in order to thereby bring the receiver back to the rest state and, in the event of a match between the addresses, to feed subsequent command calls to a command distributor, that there a calculator is arranged for, during the information input of the address and command call, to form another control signal which is compared in the calculator with the first control signal entered at the same time, in order, in the event of agreement between the two control signals, to release the entered command call for control, that the clock generator in the receiver station on transmission from this station, is arranged to start by means of an output signal from an automatic receiver/transmitter switcher, which output signal is fed out via the start/stop switcher, whereby the clock generator by means of the electronic stepper switch switches on a synchronizing signal, a set address call and a command call output via an evaluation link to an output, and the calculator is adapted to provide a control signal determined by the address and command calls. above the step switch to be added to the transmitted signal, that at least the start/£top switch, the clock generator, the step switch, the address, a bit switch, the comparison latch, the command distributor, the calculator and a matrix with the associated command indicator are common to the receiver and transmitter the runs, in that, if a whole group of stations is arranged to be called (collective call), the receivers are partly provided with comparison links which, after receiving a collective call criterion, are arranged to prevent a further address check, and partly with delay devices which, in the case of send calls, in terms of time delays the acknowledgment signal that is otherwise sent out over data is transmitted without error, as the delay device in each individual receiver is mutually coordinated so that the acknowledgment signals come one after the other in the station that sends out the collective call.

Due to the double utilization of all elements in the device both for reception and for transmission, a strong reduction in the number of elements used is achieved.

An advantageous device for carrying out the method according to the invention will be described in more detail with reference to fig. 1, which shows a block core above such a device, and fig. 2 which shows a supplement to the block diagram for an advantageous further development.

In fig. 1, a start^top link 1 is in the "stop" position. On receipt of a start signal, e.g. when transitioning from a binary 1 to a binary 0, the start/top link 1 is brought into the start position, whereby the subsequently received signals are controlled, as a clock generator 2 is released. The clock signal controls an electronic step switch 3 which, by means of its output signals, controls the mechanical or electrical setting of a selective call number 4 and a bit switch 5 and thus bit by bit requests regarding this station's set number digit (selective call number) and leads these via a switch 6 to a comparison link 7, in which then the received signals are compared bit by bit with the selective call number issued by the electronic step switch 3. If the two signals match, the comparison switch 7 shows no output signal. If, however, the two compared binary characters are different, an output signal is triggered in the comparison link 7, which is transferred to the start/stop link 1

across a comparison latch 8, a signal which sets the start/stop link 1 in the stop position. With the help of the output signal from this link, the station assumes its basic position.

In parallel with the receiver signal running into the comparison link 7, the command part of the information arrives in a clock-controlled command distributor 9. Furthermore, the entire information is transferred via a switch 28 to a redundancy calculator 10. Since the link's selective call number and thus the selective call number's binary sequence is known, can the first part of the pulse telegram containing the address is controlled by the comparison link 7, but not the subsequent characters of the command which can practically be chosen completely arbitrarily. After the already mentioned check of the address, the comparison block 8 is engaged above the electronic step switch 3, so that the output signal from the comparison link 7 can no longer cause the start/stop link to react for the subsequent part of the pulse telegram. When the Wommandodel of the information has been received, a switch 11 is closed, so that the command distributor 9 is clock-controlled during this time. After the last binary character of the command has been received, the switch 11 is opened, so that the command information received over the command distributor's 9 input line is stored in the command distributor and can be displayed via a matrix 12 in the command indicator 13 after the redundancy check has been carried out. After the entire pulse telegram has been received in the redundancy calculator 10, it must take a specific final position, if the signal has not been disturbed.

The correct setting of the redundancy calculator 10 after an information has been received, triggers in a redundancy control port 14 a release command for a switch 15 which e.g. when the battery voltage is switched over the matrix 12, it brings information to the indication, which is waiting in the command indicator 13. At the same time as this signal, the input of the command distributor 9 is preferably blocked until the indication is deleted, so that a possibly subsequent, disturbing command cannot falsify the already correctly stored command.

By suitably connecting the elements described so far with further such elements, according to the invention, it can be ensured that the elements described so far can also be used when sending information, such as an acknowledgment call, which will be explained in more detail below.

With the aid of the release signal from the redundancy control port 14, an automatic receiver/transmitter switchover 16 is switched on and switches - with or without delay - from its previously assumed receiver position to the transmitter position, which causes the issuance of the receipt to be initiated: At the time of the issuance of the redundancy the control signal, the step switch 3 takes a position which causes a reconnection of the start/stop switch 1, which in turn disconnects the clock generator 2 and brings the electronic step switch 3 back to the starting position. As the automatic receiver/transmitter switchover reacts, the station in this case does not take the receive-out position, but the send-out position.

The output signal from the automatic receiver/transmitter switching 16 controls switches 17, 18 and 19, so that a binary output 20 is connected through and a binary input 21 is disconnected. With the help of the same signal, the comparison block 8 is also affected, so that output signals that may arrive from the comparison link cannot affect the start/stop link 1. With the help of the output signal from the automatic switching, the start/stop link 1 is also set to "start ", so that the electronic step switch 3, which has in the meantime assumed its rest position, receives the clock signal again and, as in the case of reception, is supplied for setting the selective call number 4 and the digit switch 5. During the time when the selective call number is asked, the information reaches the switch 22 over the switch 6 and further over the last switch 17 directly to the binary output 20. At the same time that the selective call number is connected through the electronic step switch 3, the binary output signal from the switch 6 also arrives via the switches 19 and 28 to the redundancy calculator 10.

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After the control of the selective call number has been carried out via the step switch 3, the contents of the command distributor 9 are controlled via a command memory control circuit 24. A switch 25 is closed during the command, while the switch 6 is open. The information stream or sequence from the storage controller 24 to the binary output 20 and to the redundancy calculator 10 is the same as for the address. With the aid of the storage controller 24, the receiver command which is entered and stored in the command distributor 9 is controlled and on the basis of this an output pulse telegram is formed which is identical to the input pulse telegram. The calculation of the redundancy takes place in a similar way as during the reception of the information, both address and command therefore arrive via the switch 28 to the redundancy calculator 10 and trigger the calculation process in the known manner. After the command part of the pulse telegram has passed, switch 28 is opened and likewise switch 22, while switch 23 remains closed. Thereby, it is achieved that the redundancy calculator 10 is blocked so that any subsequent signals, and the binary character sequence calculated up to this point, the so-called rddun dance, via the output of the redundancy counter and the switch 23 reach the binary output 20, which happens immediately in connection with the sending of the command combination. After the last redundancy bit has been transmitted, the electronic step switch 3 has reached its end position which again switches this to the receiving output position, as the automatic receiver/transmitter switching 16 has not reacted in this case. This also happens via the start/stop link 1, which also interrupts the clock signal. With this process, the delivery of the receipt, i.e. the return of the received information as a receipt, is finished.

If this facility is now to issue a command, i.e. act as a transmitting station, a similar signal stream is emitted as described under the acknowledgment, however with the difference that the automatic receiver/transmitter switching 16 is intervened directly and the transmission cycle is triggered. The information that is to be transmitted in the form of a command or a message must be entered in advance into a memory, and then the existing command distributor 9 can be used, which is connected by means of a corresponding, not shown in the drawing, coding matrix for application during transmission. After the direct triggering of a transmission cycle, as a result of the output setting of the electronic step switch 3, the automatic receiver/transmitter switch 16 is switched in this case to "reception" and is maintained in this position during the reception of the receipt.

If the acknowledgment occurs during the pre-determined time, the processing of the acknowledgment signal takes place exactly as in the processing of a pulse telegram which is to transmit a command. The difference, however, is that the redundancy control signal affects the automatic receiver/transmitter switching 16 in such a way that a renewed transmission is prevented, as the switching once again assumes the initial position "reception". If the acknowledgment signal arrives with an error, the redundancy control port 14 will not emit any release signal, so that the automatic receiver/transmitter switching 16 is switched back to "send" after the predetermined time and a sending of the pulse telegram is carried out according to the already described scheme.

One in fig. 1 link not shown takes over all tasks with regard to deletion, e.g. of the command indication and feedback of the store and the redundancy calculator. As already described, it is necessary that the called station is synchronized on the calling station. In order to reduce phase errors, the clock transmitter 2 is suitably composed of an oscillator and a frequency divider, the oscillator oscillating at a frequency which is a multiple, but at least five times the clock frequency. It is appropriate that the oscillator oscillates all the time and that the start/stop link acts on the frequency divider.

During practical operation, it may happen that a further command is entered in the command distributor that the listener receives, as this has not been deleted by the relevant operator,

and a new command occurs. In order to prevent the new command from being lost in the receiving station and also to prevent the command from the station issuing its command, as already described, from continuing to be repeated (since no acknowledgment calls are received from the called station), there can, as shown in fig. 2, in an advantageous further development of the invention, it is ensured that the command distributor 9 is supplemented with a simple indication store 27 and a release port 26. In this way, the first arriving command will still be available in the indication store 27. The last arriving command can, after its correctness is has been checked, the first command is superimposed in the command distributor 9.

This happens in such a way that the command located in the command distributor is transferred to the indication store and indicated from there by means of the release signal from the redundancy control port 14 which briefly releases the release port 26. A subsequent falsified command will indeed be stored, but cannot be indicated, since as a result of the absence of the redundancy control's release signal, no transfer to the indication storage 27 takes place. In this case, the information only needs to be stored in the command distributor 9 from the end of the command reception until the redundancy control has found place. For the rest of the time, the storage condition is unimportant, which can lead to a simplification of the connection.

The principle of a conference call shall be described in more detail below. A group call is understood to mean one where all or a group of recipients can be called regardless of their selective call numbers. In the case of a decadal selective call number system, so-called pseudo-tetrads (digits 10 to 15) arise in the binary coding for each digit of the selective call number.

For the reception of a collective call, a value judgment link is provided which is connected in parallel with the comparison link 7 and suitably arranged for the first selective call number which responds to the digit of the pseudo-tetrad common to all stations. For the subsequent address part, for which the comparison link 7 was disabled (by the pseudo-tetrade link reacting), any arbitrary digit combination, preferably a digit of the pseudo-tetrad, can be sent. The utilization of the command and the redundancy takes place as described above.

By the device reacting to the collection number, it can be achieved by suitable connection precautions that the receipt during collection calls does not occur or that the receiving stations in time order (e.g. in accordance with the digit order of the receiving station's call number) automatically issue a receipt in the form of their own or the collection number.

To check the quality of a transmission line and/or the receiver station's operational readiness, it is also possible to transmit "blind" commands to the receivers. On the sending station, these are treated as normal commands, and on the receiving station, they are outwardly imperceptibly processed, i.e. a feedback is also triggered there,

but this happens without indication in the receiver. These conditions are suitably met by the fact that the command is indeed introduced into the command distributor 9 1 but is not decoded in the matrix 12 and thus is not indicated either, even if the switch 15 is closed and the acknowledgment is triggered by means of the redundancy control signal. In the case of a switching device with an indication memory, the last transmitted command will not be written over the previous command.

Claims (8)

1. Device for receiving and sending binary-coded information consisting of an address, a command and a first control signal formed by both where the information is to be transmitted to at least one receiving station, characterized in that in the receiving station upon reception using a transmitted synchronization signal, via a start/stop switch (1) a clock generator (2) is started which, via an electrical step switch (3), leads the received address to a comparison link (7), in which the address is compared with the receiving station's address (4), that a comparison block (8) is arranged which is designed to be controlled by the comparison link (7) in order to control the start/stop switch (1) to the stop position in the event of a deviation between at least one bit of the received address from the address of the receiving station to bring the receiver back to the rest state and to, upon agreement between the addresses, to feed subsequent command calls to a command distributor (9), that there is device and a calculator (10) for, during the information input of the address and command call, to form another control signal which is compared in the calculator (10) with the first control signal entered at the same time in order to release the entered command call for control, if there is agreement between the two control signals, that the clock generator ( 2) in the receiving station when transmitting from this station, is arranged to start using an output signal from an automatic receiver/transmitter switch (16), which output signal is fed out via the start/stop switch (1), whereby the clock generator (2 ) by means of the electronic step switch (3) switches on a synchronization signal, a set address call and a command call which is fed out via an evaluation link (24) to an output (20), and the calculator (10) is adapted to of the address and command calls to provide a control signal which is intended to be added to the transmitted signal above the step switch (3), that at least the start/stop switch (1), the clock generator (2), the step switch (3), the address (4), a bit switch (5), the comparison latch (8), the command distributor (9), the calculator (10) and a matrix (12) with an associated command indicator (13) is common to the receiving and sending processes, in that, if a whole group of stations is arranged to be called (collective call), the receivers are partly provided with comparison links which, after receiving a collective call criterion, are arranged to prevent a further address check, and partly with delay devices which, when sending a call, temporally delay the acknowledgment signal that is otherwise sent out over data is transmitted without error, as the delay device in each individual receiver is mutually coordinated so that the acknowledgment signals come one after the other in the station that sends out the collective call. 2. Device according to claim 1, characterized in that it is provided with devices for blocking the command distributor's (9) input after receiving a properly controlled command until the command is deleted. 3. Device according to claim 1, characterized in that the command distributor is designed as a sliding register. 4. Device according to claim 1, characterized in that the command distributor (9) is connected after a registration distributor (27), that there is connected between these a release port (26) which is controlled by the calculator (10) and that an earlier in the registration distributor ( 27) entered command can be overwritten by a re-entered command that is checked for correctness. 5. Device according to claim 1, characterized in that the electronic step switch (3) contains a device which, after inputting the last bit of the transmitted pulse train, is arranged to set the start/stop switch (1) in the stop position and the electronic step switch (3) in the initial position. 6. Device according to claim 1, characterized in that the receiver/transmitter switch (16) is arranged to be controlled by the calculator (10) via a control signal port (14) so that after receiving a correctly judged command, a release signal is switched to "send" and to actuate the start/stop switch (1) to start. 7. Device according to claim 1, characterized in that the clock generator (2) is composed of an oscillator which is designed to be operated continuously, and a frequency divider, and that the oscillator frequency is many times, preferably at least five times greater than the clock frequency. 8. Device according to claim 7, characterized in that the switching of the clock frequency is arranged to take place by switching the frequency of an oscillator and/or by switching the dividing factor of a frequency divider.