NO750226L - - Google Patents

Description

The present invention relates to a device for electric or radio-electric, two-way transmission between a central station and a certain number of terminal stations, where the terminal stations are respectively equipped with devices for visual reproduction, such as teleprinters, in which the frame, the so-called "unit frame ", for rendering a visual entity,

called "characters", consists of N^*^ fields in addition to columns and;N2 lines, as each field can assume two visually different states as a function of the character to be rendered. The invention aims at a transfer device which allows simplification of the terminal stations' equipment, and which at the same time makes the transfer operationally reliable. The transmission device according to the invention is characterized by the fact that the transmissions from the central station to the terminal stations work with rasters in (N^ + 1) groups of bits, certain rasters in so-called "character code" consisting of a first predetermined prefix, called character prefix, of ^ bits, followed by groups of bits representing the conditions to be applied to the fields in a unit frame for rendering a character, the other rasters, in "service code", being used for calls and various remote controls, including the remote control of the said devices, which comprise another, predetermined prefix, so-called "service prefix" of ^ bits, N1*N2<=^r ri^eli9serviceinf ormas ion.

Preferably, the messages that are sent from the terminal stations to the central station, and which comprise a certain number of predetermined messages that are abbreviated using conventional code words, will cause a feedback from the central

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the station consisting of a character or service raster that is interpreted by the terminal station so that it gets a clear and concrete check on good transmission and good interpretation of the message it has sent.

The invention will be better understood, and other features will become apparent with the help of the following description with reference to the drawings, in which

fig. 1 is a diagram for a design of a terminal station,

fig. 2 and 3 are detailed diagrams of the elements in fig. 1, and

fig. 4 is a diagram of a design of a central station which can cooperate with the terminal station in fig. 1.

In the various diagrams, the specific synchronizing devices which derive from conventional technology are not shown, with the intention of making the drawings clearer and the production simpler.

The considered stations can e.g. belong to an administrative or commercial organisation, comprising one or more centers to which decentralized units are linked.

Each center is then equipped with a "central station", and the associated units with corresponding "terminal stations".

In the design described, the transmissions work in alternating operation in each direction using any conventional type of modulation, whose modulation signal for the central station consists of an FSK signal (FSK = Frequency shift keying = frequency shift keying), with a low frequency Fq responding to "bit0", and a low frequency F^corresponds to "bit 1".

With basic modulation, all the signals sent by the central station consist of rasters of (N^+ 1) successive groups

of N2bits, either belonging to the "character code" or to the "service code".

The numbers N, and ^ are determined, as indicated above, by the unit frame characteristics of the visual rendering apparatus

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which are used in the terminal stations.

In this example, it is assumed that these devices are Philips teleprinters type A4, for which N = 7 and N2 = 7.

The raster's first group of ^ bits constitutes at the same time a start signal and an identification of the code, which can be a character or service code.

It should be noted that a single group of bits for = 7, resulting in 128 different rows, is usually far sufficient for the service messages to be sent.

The device according to the invention combines the advantage of sending

of rasters of constant length with information without redundancy for rendering those characters for which multiple errors are not enough to prevent recognition of the character, and abundant service messages. In the latter case, poor interpretation of the service messages can lead to serious disturbances.

Assuming that each service message can be expressed unambiguously by a series of b^, h^...bN on ^ bits, the transfer can, with redundancy, be carried out for each of the N, last groups to

form a code grid as a function of the series b,, b ...b .

1zN2

Assuming that each service message can be expressed unambiguously by a sequence b^, b^-.-bj^ of N, bits, the transfer can, with redundancy, be operated by repeatedly repeating each bit b, , b„.. ^ times in a row. .b.T .

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Usually, both solutions are possible. In the present example, where other = N2, it shall be assumed that the first method is used.

For the transmissions from the terminal stations, the modulating signal consists of "bi-frequency" words, each of which consists of a half-train of oscillations with a frequency f^ followed by a half-train with a frequency fy The frequency f. can be selected from a group of 8 predetermined frequencies, f-, to f0, the frequency f.

I ib j

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is selected in the same group, but shifted by a frequency f , the so-called repetition frequency, when it is equal to f^, since the frequency f upon reception is then interpreted as a repetition of f^.

This gives 64 bi-frequency words, of which 40, which represent characters, digits, punctuation etc, are used for messages that cannot be predicted, while each of the other 24 bi-frequency words alone represents a predetermined message.

In fig. 1, the shown terminal station comprises a transmitter-receiver station 11, of any known type for HF, VHF or UHF radio connections.

The station's low-frequency output is connected to an FSK demodulator 12 whose output in digital form restores the rasters received from the central station.

The output from the demodulator 12 is connected to the input of a logic circuit 13, which will be described with the help of fig. 2. This logic circuit does the following: a. Recognizes prefix STC (start of the character code rasters) and

prefix STF (start of the service code rasters).

b. Otherwise identifies, taking into account the abundance, the service message expressed by the rasters. In the first case, it indicates on its multiple output 132 with N2 wires (represented by a single connection) successively the N1 groups of N2 bits representing a character. In the second case, it emits on multiple output 133 with N2 threads the N2 bits representing the sent service message.

The logic circuit 13 also includes two auxiliary outputs

134 and 135, whose role will be explained later.

The station comprises a teleprinter of the type mentioned above, as well as its binary control unit, represented by block 14, which receives the signals from the outputs 132, 133, 134 and 135 of the logic circuit 13.

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Furthermore, the station comprises a unit 15, consisting of a keyboard with 64 keys which controls a tone generator. The 64 keys correspond to the 64 "bi-frequency words" that can be sent. Pressing a key causes a corresponding LF signal to appear on output 151 on keyboard 15, which is transmitted to modulation input 112 on transceiver 11.

A logic circuit 16, to be described later by means of

fig. 3, ensures the following functions:

a. Setting the transmitter-receiver 11 to transmit or receive by means of a signal emitted at its output 161, which is connected to a control input on the transmitter-receiver 11.

b. Operation permission or prohibition for the keyboard 15

by means of the signal emitted at the output 162, which is connected to an input on the keyboard.

c. Operation permit or prohibition for the teleprinter

14 by means of the signal emitted at the output 162,

which is connected to an input on the remote printer.

For this purpose, the circuit 16 receives on its inputs 164 and 166 the signals emitted from the outputs 133 and 135 of the circuit 13, and on its input 165 it receives a signal emitted from an auxiliary output 152 on the keyboard 15, which interprets "end-on -the sending" of a bi-frequency word.

Fig. 2 shows a design of the circuit 13 in fig. 1.

This comprises a clock 31 which emits a signal whose frequency is equal to k times the frequency of the received bits, where k is at least equal to 8. These pulses are applied to the clock input H of a shift register 33 with kN2 steps, whose input is connected to the input 130 on the logic circuit 13. Each received bit is then sampled k times, and the k samples of each bit are in turn registered in the register.

The output voltages from all stages in the register 33 are respectively applied to the kN^ inputs of a comparator 34 comprising |kN2 elementary comparators, which respectively on a first input receive the output signals from the kN2 stages in the register 33, and on a second input receive the signals obtained at k times to repeat each bit in the prefix of the character code's raster, or in short, in the "start character", so that on a perfect reception of a start character, each elementary comparer emits an equality sign. The outputs of the kN2 elementary comparators are connected to the kN2 inputs of a device which emits a signal when the number of its fed inputs is greater than a threshold value which is a relatively large fraction, e.g. about.

90%, of its total number of inputs, as the output from this last device forms the output of the comparator. The kN2 outputs from the register 33 are likewise connected to the kN2 inputs of a comparator 35 of the same construction as the comparator 34, except for what concerns the bits that are applied to the other inputs of the elementary comparators, so that it emits a signal when the ones written in the register 33 bits can validly be considered as resulting from the receipt of a "start message".

The outputs of the comparators 34 and 35 are respectively connected to the set input "1" in state 1 (logic 1) of a bistable flip-flop 40, and to the input "0" of the same flip-flop via two AND gates 50 and 51, as on their other input receives the output signal from another bistable flip-flop 53. As will be seen, flip-flop 53 goes to logic 1 at the end of each frame, so that at the beginning of a new frame, gates 50 and 51 are opened for passage of the output pulse from one or the other compares. The output 41 from the flip-flop 40 then gives a logic 1 after detection of a start character, and its companion output 42

logic 1 after detection of a start message.

The outputs of the gates 50 and 51 are in turn connected to an OR circuit 36, the output of which is connected to the "0" input of the flip-flop 53, which prevents that later detection of a possible sequence of N2bits, which reproduces a start signal, brings the system to cheat.

The circuit 13, on the other hand, comprises a rhythm regenerator 37 which receives the input signals of the circuit and the pulses emitted from the clock 31, and which, by using the transitions in the incoming signal, according to known technology emits an output signal with the frequency of the received bits centered on center of the bits. The output pulses from the regenerator 37 are applied to the clock input of a shift register 38 with N2 stages, whose bit input is connected to the input 130 of the logic circuit 13.

The output from the regenerator 37 is in turn connected to an N2 divider 39 which receives its pulses, as this divider can consist of a counter and include a reset input Z connected to the output of the OR gate 36, so that this gives an output -pulse after receiving the last bit in a group of N bits in a frame other than the start frame, and for receiving the first bit in the following frame, provided that this group is not the last. The output of the divider 39, which constitutes the output 134 of the logic

circuit 13 then emits an end-of-group signal which, in addition to its use in circuit 13, is applied to the teleprinter as an end-of-column signal.

The outputs from the N steps in the register 38 are respectively connected to the inputs of N2 flip-flops of type D, which are collectively represented by the block 43, these flip-flops assuming or retaining logic 1 or logic 0 depending on the level of the signal applied to their input, when their clock input receives a pulse.

These clock pulses are emitted by an AND gate 45 which on its two inputs respectively receives the signal from the output 41 of the flip-flop 40 and the output pulses from the divider 39. The outputs from the flip-flops in the unit 40 form the multiple output 132 on the logic circuit 13.

The output from the divider 39 is in turn connected to the input of an Nj^ divider 46, which can consist of a counter that is reset to zero at its input Z at the same time that the divider 39 is reset to zero by the output pulses from the OR gate 36, as the divider emits at its output an end-of-frame signal.

A circuit 47 comprises N2 inputs which are respectively connected to the outputs of the N2 steps in the register 38 via an electronic switch 48 consisting of AND gates and whose blocking signal is emitted in an AND gate 49, which receives the output signal from the divider 39 and the output signal from the flip-flop 40 The N2 inputs on the circuit 47 are the inputs of the N counters which are reset to zero at the beginning of each frame by means of the output pulses from the OR gate 36, and which are applied to the input Z on the circuit 47, each counter's count increasing by one unit each time the switch is closed and thereby applies a pulse to the counter input. Each counter is followed by a decoder which emits logic 1 at the moment the associated counter's count has reached 4, i.e. (N1+1)/2. A number of N2OG ports respectively receive the output signals from the N2 decoders, and are opened at the end of the raster by a raster end signal emitted from the output of the divider 46, the outputs from the N2 ports forming the multiple output 133 from the logic circuit 13.

The output signal from the divider 46 is applied to the "1" input of the flip-flop 53 and the first input of the AND gate 44, the second input of which receives the signal from the output 42 of the flip-flop 40. The output 135 of the gate 53 emits a signal for "end-of-service triggers ".

Fig. 3 shows a design of the circuit 16 in fig. 1.

The multiple input 164 of the circuit, which is connected to the multiple input 133 of the logic circuit 13, feeds this in parallel with the N2 bits which make up the service codes which are successively received on the multiple inputs of three decoding devices 61, 62 and 65, which are synchronized by means of a signal for "end-of-service rasters", which are applied to the input 166 of the circuit 16.

First decoder 61 emits logical 1 when the received service code is the start code for the considered terminal station's operation, and the second 62 when the service code is the code for "operation end" for this terminal station. These two signals, which define the operation or connection time with the central station, are sent at will by the operator of the latter when he wants to send a message to the considered terminal station, or give it the opportunity to send, as this other consideration naturally takes place periodically.

i The transmissions from the terminal station take place bi-frequency word after

bi-frequency word on reception of an additional signal, which applies to all terminal stations, but which is not valid for the terminal station that has been granted permission to connect.

Thereby, the output from the decoders 61 and 62 is connected respectively to the "1" input and the "0" input of a bistable flip-flop 63, whose output 162 constitutes the output of the circuit 16, and which allows or prohibits operation of the teleprinter 14 and the keyboard 15. The output of the rocker 63 is likewise connected to the control input of an audio or light signal device 64 which signals calls by the station until the operator terminates it. The circuit's multiple input 164 also feeds the multiple input on

a third decoder 65, which decodes the "permission to pass transmission" service code. The output of the decoder 65 and the output of the flip-flop 63 feed the two inputs of an AND gate 66, whose output is connected to the "1" input of a bistable flip-flop 67, whose output forms the output 161 of the circuit 16 and sets the transmitter-receiver 11 in the receive position when the flip-flop has logic 1. The flip-flop 67's return control circuit in logic 0 is formed as follows: A monostable flip-flop 68, connected to the output of the flip-flop 67, is set in its quasi-stable state when the flip-flop 67 goes to logic 1. The duration of its quasi-steady state is longer than the time it takes the operator to effect the transmission of a bi-frequency word by pressing a button on the keyboard.

The output of the monostable flip-flop 68 is connected to an input of an OR gate 69, the other input of which is the input 165 of the circuit 16, and which from the keyboard 15 receives a signal indicating the end of sending a bi-frequency word. The output of the OR gate 69 is connected to the "0" input of the flip-flop 67.

Fig. 4 shows a layout of the central station. Its mode of operation is as follows: As mentioned above, the central station's operator determines (when sending service registers for permission to connect and end of such permission) the time intervals in which an exchange connection is established with a given terminal station, as

Each service grid is different for the different terminal stations.

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In the course of each of these connections, the operator at the central station can immediately take over the transmission just when it suits him, or finally give permission to the terminal station for the transmission of a bi-frequency word. In this case, the bi-frequency word automatically becomes the subject of a feedback from the central station, as this feedback in turn is automatically followed by the sending of a new transmission permission for a bi-frequency word, etc. If the terminal station ceases to transmit despite that it has transmission permission, the operator at the central station can either resume or not resume transmission and so on, until he ends the connection with the terminal station in question by sending a service code "end of transmission permission".

For its internal operation, the central station uses a normalized alphabet, e.g. The ASCII alphabet, which comprises a certain number of "symbols" that are translated using "sequences" of binary signals.

To each character or service raster that can be sent by the central station, one of these symbols is associated with a double univoquement ("bi-univoquement"). On the other hand, there is of course also a double common correspondence between the 64 bi-frequency words that can be sent by a terminal station and the 64 rasters that are used as feedback for these 64 bi-frequency words.

The central station is shown in fig. 4, and comprises a transmitter-receiver station 71 whose LF output is connected to a demodulator 72 for bi-frequency words, and which comprises two groups of outputs 721 and 722, each comprising 8 wires corresponding to the frequencies f, to fQ. A given bi-frequent word, f. f answers

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for printing the signals on the i thread in the first group, and the j th thread in the second group.

The two groups of outputs of the demodulator 72 are connected with

two input groups on a dead memory 73 whose input signals make up the call signals, and which in parallel on its multiple output for each bi-frequency word received emits the sequence of binary signals representing the associated symbol Æra the normalized alphabet.

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The multiple output from the memory 73 is connected to the multiple input of an apparatus 80 for visual reproduction, which is observed by the operator.

The device 80 receives from the memory 73 symbols (in binary data) which supply the device with the rendering information and service signals that are necessary for the device's work, both sets of signals originating in bi-frequency words.

A raster generator 75, also consisting of a dead memory, receives on its multiple call input sequences of binary signals representing symbols associated with the rasters to be sent, and emits in sequence for each symbol the (N^+ 1)N2 bits in the raster for the associated character code or service code.

The output of the raster generator 75 is connected to the modulation input of an LF modulator 74 for FSK (Frequency Shift Keying), whose output is connected to the modulation input of the transmitter-receiver 71.

The multiple call input of raster generator 75 can be selectively fed in three ways by means of a set of OR gates 76, each gate having three inputs.

The first inputs of the OR gates, which constitute the multiple input 761, are respectively connected to the multiple output wires of a keyboard device 81, which is operated by the operator and which, in the assumed normalized alphabet, emits the raster signals he wishes to send, as binary signals . This keyboard is used to start sending all the rasters, except the feedback rasters and the service rasters that give permission for sending. The other inputs of the OR gates, which make up the multiple input 762 of the gates 76, are connected to the output of the memory 73 which presses these inputs

(as binary signals) the symbols for the rasters that will make up the feedback signals. Finally, the third inputs of the OR gates 76, which constitute their multiple input 763, are connected to the output of a device 77 which, when it receives a pulse on its control input, emits the binary translation of the j symbol that applies to transmit permission. This control input is for-

tied with the output of an OR gate 82 whose first input can receive a pulse at a maneuver from the operator's side. The other input of the OR gate 82 is connected to the output of a circuit which allows the automatic provision of transmission permits for a bi-frequency word given to a station as soon as it starts transmitting on the first permit given by the operator, and this as long as it does not comply with a transmission permit, or in exceptional cases, if the operator has not indirectly withdrawn the transmission permit by sending the "end of transmission" service signal to the terminal station in question.

For this purpose, the terminal station comprises a timer 78, mainly consisting of monostable flip-flops, the first of which is triggered by the pulses received from an auxiliary output 723 on

the demodulator 72, these pulses marking the end of the reception of a bi-frequency word. Output 782 on the timer

78 then emits in the course of a time TQ+ a signal which is pressed

the send-receive control input on the transmitter-receiver 71 via an OR gate 79, as this signal brings the transmitter-receiver into position for transmission. The time interval Tq is calculated so that it allows the feedback signal to be sent. At the beginning of the time T, a short pulse is sent from the output 781 of the timer 78 to the OR gate 82, as the time T allows the corresponding service burst to be sent.

The other input on port 79 can, upon the operator's intervention, receive a signal that maintains the transmitter-receiver 71 in the transmit position when the operator wishes to transmit using the keyboard 81.

Furthermore, what is stated below must be specified in relation to it in connection with fig. 1 to 4 described device.

With regard to the terminal station, it has mainly been assumed that the service grids necessary for the device's alternating operation,

which are decoded by decoders 61, 62 and 65 in circuit 16, as well as the service rasters necessary for teleprinter operation, are decoded in the teleprinter circuits which are synchronized by means of the "end-of-service raster" signal. It is clear jat normally can other service grids used for the different

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remote controls, are sent by the central station, these service rasters being decoded by decoders such as decoders 61, 62 and 65, whose output signals are routed to the appropriate devices.

Regarding the central station, it has been assumed that the received bi-frequency words interpret a character to be reproduced by the device 80 or a maneuver which is necessary for the functioning of this device and this is printed in the form of normalized binary symbols.

In this case, a bi-frequency word for a character, used as a feedback signal, will cause a character raster which, on the terminal station's teleprinter, controls the path of the character sent by the terminal station, or a raster which, if

it exists (which is normally the case), it controls the corresponding maneuver for the terminal station teleprinter.

If this maneuver had no counterpart, it would be artificially associated with another counterpart, e.g. drawn up according to a special way of writing interpreted by a feedback signal consisting of a character grid.

Of course, bi-frequency words can be sent for a purpose other than controlling the apparatus 80 for visual rendering, for example remote control of another user apparatus for bi-frequency words which decodes the normalized symbol(s) relating to the apparatus.

The terminal stations' apparatus for visual reproduction can be a different apparatus than a teleprinter, where the reproduction can be controlled by binary signals, the two visually different states e.g. can be achieved by optical processes.

Finally, it has been assumed that an operator is present at each station. The invention is nevertheless also applicable within the framework of a station where the operator is replaced by suitable micro-orderers.

Claims (7)

1.A system for two-way electrical or radio-electric transmission between a central station and a certain number of terminal stations, where the terminal stations are respectively equipped with apparatus for visual reproduction, in which the frame, called unit frame, for the reproduction of a visual unit, called "character" , consists of N1*N2 fields distributed over N, columns and N2 lines, as N-^ and N2 > 1, as each field can assume two visually different states as a function of the character to be reproduced, characterized by the fact that the transfers from the central station to the terminal stations take place with the help of grids with (N^ + 1) groups of N2 bits, where certain rasters, called "character" encoder rasters, consist of a predetermined first prefix, called character prefix, of N2 bits, followed by N-^ groups of N2 bits representing the states to be given to the fields in a unit frame for rendering a character, the other rasters, called "service" encoder rasters, being used for calls and various remote controls, comprising another predetermined prefix, called "service" prefix, of N2 bits, and that N1*N2 ^its mec^ abundance emits the service message. 2. Transmission device as specified in claim 1, characterized in that the messages sent by the terminal stations are transmitted in the form of short unit messages which can assume a limited number (N) of different forms, some of which form part of a longer message and others form messages which is compressed according to a code, and that the device at the central station includes automatic transmission means for a feedback signal for each unit message received, and that said grids are also used as feedback signals, N predetermined grids respectively being associated with the N forms of the unit messages. 3. Transmission device as specified in one of claims 1 or 2, characterized in that, as N2 bits are sufficient to unambiguously characterize the service messages, the last groups in each service grid repeat the same group of N2 bits that characterize the service message to be sent , and that, N being an odd number, the coding in the terminal stations of the service rasters is carried out by a majority decision that uses the N repetitions of each bit in the group of N2 bits that characterize the service message. 4. Transmission device as stated in one of claims 1 or 2, characterized in that, as N, bits are sufficient to unambiguously characterize all the service messages, each of the 1SL bits characterizing the service message to be sent is repeated N2 times in a row in the N, last groups of a service grid. 5. Transfer device as specified in one of claims 1-4, characterized in that, as the character and service prefixes are not excluded from the successive groups of N2 bits, they can be included in the N^* N2 last bits in the rasters, as the detection device for these prefixes, in terminai the stations, includes means which prevent erroneous detection of a prefix between the detection of a prefix and the end of a raster. 6. Transfer device as specified in one of claims 2-5, characterized in that it works in alternating mode and at the central station includes means for automatically retransmitting a new transmission permit after receiving a unit message from a terminal station, and sending a corresponding feedback signal. 7. Transfer device as specified in one of claims 2-6, characterized in that each unit message consists of an oscillation train which in turn exhibits two frequencies selected from a group of predetermined frequencies.