NO116586B - - Google Patents

Description

Simplex telegraph system with interrupter.

The present invention relates to a simplex telegraph system

in which in one direction, the traffic direction, traffic signals are sent in blocks from a master station, between which blocks there are pauses in which the receiving station (the slave station) can send" in the other direction one of two service signals indicating respectively correct or incorrect reception of the last received block group, and in which system the traffic transmitting station sends a block group with certain signals (combination no. 1) indicating the end of the traffic transmission.

The purpose of the invention is to arrange interrupting means in such systems. In switching circuits such as these, where the transfer of information always takes place in one direction, the information-sending subscriber who is waiting for a response must, after finishing his message, inform the receiving subscriber of this. In the telex traffic that occurs, this notification of "over",

using the alphanumeric and plus sign combinations. In telex circuits containing a radio-telephone link, it is common for the change of traffic direction to be indicated by combinations of alphanumeric, plus and question marks. The latter combinations are also used in the simplex radio circuits mentioned above.

If desired, however, the subscriber receiving the information in telex circuits can himself begin transmission against the message arriving at his station, due to which the message is distorted both at his station and at the station transmitting the information. This is perceived by the transmitting subscriber as a request to stop the transmission. The reason for this can e.g. be that the receiving subscriber urgently wishes to communicate something to the sending subscriber, or that his receiving equipment is not working so that it is necessary to interrupt the transmission.

In telex circuits in which a radio-telephone connection is also used, the receiving subscriber can intervene in the communication, provided that the radio-telephone connection is a duplex system.

In telex circuits where a simplex radio telephone connection is used, it is impossible for the receiving subscriber to intervene to stop the information transmission, as the radio connection is one-way.

The invention aims to eliminate this one-sidedness in simplex telegraph systems. This is achieved by the traffic receiving station being provided with interrupting means to interrupt a telegram during transmission and to do this without introducing unwanted signals, which means comprises a first generator which produces a third service signal which differs from the two mentioned service signals, which generator can is started on the initiative of the traffic receiving station in the artificially introduced regular intervals due to the division of the telegram into blocks of constant length, thereby indicating to the traffic sending station that an exchange of the traffic transmission is desired, where the traffic sending station is provided with a second detector that receives the third service signal and then delivers an output pulse which starts a second generator which produces a delimited block group of signals indicating to the traffic receiving station that the change of traffic direction has begun and where the traffic receiving station is provided with a third detector which receives the delimited block burst signals and then supplies an output pulse which starts a third generator which produces a block group of service signals indicating that the traffic direction change has been completed.

This is achieved by the receiving station making use of a third service signal which has such a "mark-space" relationship that it can only occur with double transpositions of one of the existing service signals. When the information transmitting subscriber requests traffic direction change, he sends a combination of alphanumeric, plus and question marks, for which the receiving station responds by sending the third service signal. The main station responds to this service signal with a

special signal group such as consists of pause characters p-a-|3, after receiving which this information receiving station switches to transmission mode and by means of a group of signals I requests service signals from the original information transmitting station. After receiving the signals I, the latter station switches to the information receiving state.

When using this connection method, it is strictly speaking the information-receiving station that requests reconnection, even if this happens at the prompting of the information-transmitting station in the form of the received alphanumeric, plus and question marks.'I

However, it is possible for the subscriber receiving information there

to effect transmission of the third service signal, e.g. by means of a special combination of signals (except the combination of alphanumeric, plus and track target characters), so that the switching takes place as described, but not at the request of the station transmitting the information. In systems in which the recipient knows the information sender=; ikkp is synchronized with feedback signage,

as is the case with Norwegian patent no. 108,251, and in which the service signals consist of the marking frequency and the spacing frequency respectively, the third service signal is formed from these two frequencies which are sent alternately in equally long intervals. In consideration of the alternation between the frequencies, the operating time on both frequencies is chosen equal to or equal to a multiple of the stride length, but this is not functionally necessary.

The detection of these alternates with the information transmitter

station can happen in different ways. As an example, the so-called flywheel circuit (parallel resonance), i.e. a stage circuit which is sharply tuned for the frequency by means of which the change is provided. After start-up using the received frequency converters, this emits a voltage which after some periods is sufficiently high to switch over a trigger circuit, which indicates the third service signal.

Other methods consist of storing the received frequency change in

a shift register whose recorded frequency switching information provides the desired indication.

The invention will now be described in more detail" with reference to the drawings, after which

Fig. 1 shows the "prolbp" of the switching process,

Fig. 2 is a code example for the three service signals and the signal I, Fig. 3 shows how the service signal R3, which is sent in the form of frequency converters, is detected, Fig. 4 shows the termination possibilities for a received series of frequency converters, Fig. 5 is a block diagram of an exemplary embodiment of a transmitter-receiver system for use in the system according to the invention .

Fig. i shows a time diagram for the traffic between stations X

and Y deposited on a time scale. In city time 0, station X sends information in the form of the letters a, b, c in block 1.

This information is received at the information receiving station

Y, after which this station requests the next block (2) using the service signal R2 (T4-5). Station X has finished the transfer and is sending block 2 with the combination of alphanumeric, plus and question marks. Station X thereby indicates that station Y can start sending information. After receiving this block correctly and understanding the handover request, station Y transmits the service signal R3 (T10-11).

Upon correct reception of this signal R3, station X sends a block comprising the information: the pause signal (3-oc-|3 (T12-15)

which at station Y causes switching to the information-transmitting state (T16). This station sends a block of signals I

which gives station X information that the switchover has been completed. On receipt of this block of signals I, station X switches itself to the information receiving state and sends the service signal RI, whereby it requests a block 1. Station Y responds to this block by sending the letters p, q,,

r in a block 1 (T23-26), and the traffic can be carried out normally, with station Y being the information transmitter and station X the information receiver. Fig. 2 shows an example of the structure of these signals I and the service signals, whereby at least a double transposition is necessary to convert one of these signals into another. Fig. 3 shows a connection between stations X and Y where the service signal 3 from station Y is formed by frequency change,

and the station X has a receiver that does not work synchronously, but sends the signal at a specific time P to a shift register where

it changes the register elements in accordance with the frequency shift provided that the shift time pulse does not coincide with the frequency shift byebldics.

In fig. 4, the diagram 1 represents part of the received series of frequency converters, formed at the frequencies f1 and f2. Diagram 2a relates to the gate circuit which, at time P, controls the shift register in accordance with the incoming frequency by means of time pulses represented by arrows. Diagram 2b shows the state of the register elements that indicate the frequency change pattern. In this case, it has been assumed that the time pulse occurs midway between the two frequency transitions.

Diagrams 3a, 5a and 5a relate to the same gate circuit as 2a,

but in 3a and 5a the time pulse closely coincides with the frequency transition for the received frequency converters. The result of this is that the register elements can assume any arbitrary state, which is indicated in diagrams 3b and 5b by a horizontal hatched rectangle. In the diagram<*>fa, the time pulse appears again midway between the two frequency transitions so that the diagram

*+b shows the frequency change in the states of the register elements.

If no synchronism occurs between the receiver at station X and the transmitter at station Y in a circuit described in Norwegian patent nos. 108,251 and 108,966, the local time pulse at station Y can occupy any position between that shown by diagram 2a and that according to 5a, whereby only the positions corresponding to the diagrams 2a and 5a>result in an undetermined register element combination. Any other position of the time pulse relative to the signal will result in either the register combination according to diagram 2b or according to ^b. Both show the frequency switching screen.

in

If a result such as shown in diagrams 3b or 5b occurs, this is to be considered a distortion, whereby a request for repetition is transmitted by means of a group of signals I. If the station Y1 has actually sent frequency-alternating signals, this station of course repeats the transmission

when receiving the signals I from station X, but twice.

with a phase shift of jlA period so that f requen Jover-; the times will now be in the correct position in relation to the ;ids-...' pulses and. the recording* of the frequency change pulses did not take place normally, In reality the deceleration time produced f

about. half of a square pulse interval.

In fig. 5 schematically shows an embodiment of a transmitter-receiver according to the invention..'

The five-unit coded traffic signals are applied from a tape reader TR to a code converter CC1 and are there transformed into seven-unit signals which, via an OR circuit and a keying circuit K, are applied to a radio transmitter RT. This station that sends traffic signals is switched to "master" state, and the station that receives these signals is switched to "slave" state.

At the slave station, the signals are received in a radio receiver RR and printed over a discriminator Di a shift register SR by a code converter CC2 to the printer Pr.

The end of the traffic transmission is indicated by sending a specific group of signals from the master station to the slave station. This group includes the signals alphanumeric, plus-bg spbrsmaal characters (combination no. 1).

In the slave station's receiver, this specific group of signals is demodulated in a first detector D1 which includes means for successive demodulation of the alphanumeric, plus and question mark signals as well as a register for storing these signals. The detector gives an output pulse after receiving the specific block group. This output pulse is applied via an OR circuit to a generator G1 which generates the third service signal R3.

This signal generator can also be started on the initiative of the slave station and this can be done manually as shown in the figure, but also electronically.

The third service signal R3 is applied across the OR circuit and the switching circuit K to. the slave station's radio transmitter RT. At the main station, the third service signal R3 is received in the radio receiver RR and demodulated in a detector D2 which gives an output pulse. This output pulse is applied to a generator G2 which generates a specific block group p-oc-p (combination no. 2).

This specific group of blocks is applied to the main station's radio transmitter RT via the OR circuit and the switching circuit K. At the slave station, this specific group is demodulated by a third detector D3 comprising means for demodulating an a-signal and a p-signal as well as a special register Re2. This detector then gives

an output pulse which is applied to a third signal generator G3

which generates a block group comprising three signals I. These signals are applied to the slave station's radio transmitter via the OR circuit and the switching circuit K and are sent out from there. The output pulse from the third detector D3 is also applied to the device that determines the state of the master station, and with the help of an output pulse from the detector D2, the slave station is switched over from slave

to main state.

At the original main station, the block group with the signals I is received and demodulated by a fourth detector Th. After demodulation, this gives an output pulse which is applied, an AND circuit. If there is also an output pulse from detector D2, the device that determines the master/slave state is switched from master to slave state.

After receiving the block group of signals I, the station now in the slave state sends a service signal RI (this is a specific seven-unit signal) to request the transmission of the first group of traffic signals from the station now in main state, and then the traffic transmission continues in the opposite direction to the original one (see also fig. 1).

The code for the different signals is shown in the lines that connect the shift grid SR with the different detectors.

Claims (5)

1. Simplex telegraph system in which in one direction, the direction of traffic, traffic signals are sent in blocks from a master station, between which blocks there are pauses in which the receiving station (slave station) can send in the other direction one of two service signals indicating respectively correct or wrong reception of the last received block group, and in which system the traffic transmitting station sends a block group with specific signals (combination no. 1) indicating the end of traffic transmission none, characterized in that the traffic receiving station is provided with an interrupting device to interrupt a telegram during the transmission and do this without introducing unwanted signals, which means comprises a first generator (Gl) which produces a third service signal (R3) which differs from the two mentioned service signals, which generator can be started at the initiative of the traffic receiving station in the artificially introduced regular intervals due to the division of the telegram in blocks of constant length, thereby indicating to the traffic transmitting station that a change of the traffic direction is desired, where the traffic transmitting station is provided with a second detector (D2) which receives the third service signal and then delivers an output pulse which starts a second generator (G2 ) which produces a limited block group of signals (p-a-p) (combination no. 2) which indicates to the traffic receiving station that the change of traffic direction has begun and where the traffic receiving station is provided with a third detector (D3) which receives the delimited block group of signals (p-a-p) and then supplies an output pulse which starts a third generator (G3) which produces a block group of service signals (signal I) indicating that the switch has been done. 2. Simplex telegraph system as stated in claim 1, characterized in that the traffic transmitting station is provided with a fourth detector (Th) which is applied to the block group of service signals (signal I) and delivers an output pulse which starts a service signal generator which sends a service signal (RI or R2) requesting the traffic receiving station to send a block group of traffic signals. 3. Simplex telegraph system as stated in claim 2, characterized in that the traffic receiving station is provided with a first detector (Dl) which is impressed on the block group of delimited signals (combination no. 1) and emits a pulse which starts the signal generator (Gl) for the third service signal . h. Simplex telegraph system as stated in one or more of the claims 1-3> characterized in that in systems in which block groups are requested by means of service signals, these signals are formed by sending a marking or spacing signal, e.g. at the marking or spacing frequency in a frequency shift decoding system used for the transmission, the third service signal being formed by sending a rhythmically alternating sequence of a marking or spacing signal, e.g. at said marking or spacing frequency, the alternating rhythm preferably corresponding to the duration of a signal element used in this system or to a multiple of this duration. 5. Simplex telegraph system as specified in one or more of claims 1 - characterized in that upon receipt of a request for repetition of the third service signal, the retransmission of this signal is shifted in time in relation to the previous transmission, the time shift corresponding to a quarter of the duration of a signal element used in this system.