DE1487742C - System for the transmission of information from a number of sensors to a central receiver - Google Patents

Description

The invention relates to a system for transmitting information from a number of transmitters to one Central receiver, in which facilities are provided in each donor, in chronological order a start pulse, a group of address pulses to identify the encoder and a Generate group of information pulses, and in which the receiver has devices that be set in action by the start pulse and the information in an assigned to the encoder Save shape.

Known systems of this type are used in particular for booking seats in means of transport, such as airplanes, rail ferries or the like, and are for a very complicated and comprehensive exchange of information determined and trained. The information is not only transmitted in one direction from Giver to recipient (booking or booking request), but also in the opposite direction from the central Recipient to the giver (booking confirmation or information about existing booking options) transfer. Accordingly, the facilities are both complicated and expensive central recipient, which is usually a data processing system, as well as the donors, where either teletype or a magnetic keypad combined with scanning of recording media are provided. Another disadvantage of the known systems is that they are very require a lot of human operation and that the receiver must be constantly ready for operation, what is going on in a waiting loop by a hr of the data processing system. Program, achieved, will.

In contrast, the invention is based on the object of a very simple, in device and Operation to create an inexpensive system that only allows one-way information transmission serves the donors to the recipient. All complicated processes, such as data processing, Inquiry from recording media, operation of a telex printer or the like can be dispensed with.

To solve this problem, a system of the type mentioned is characterized according to the invention: that each donor has the following facilities:

a) Two groups of on-off switches, of which the switches of the first group in one The combination corresponding to the address of the encoder can be set and the switches of the second Group in a combination corresponding to the information to be transmitted before the Transmission can be set manually,

b) a pulse generator which automatically generates a pulse train at specified time intervals,

c) and one of flip-flops connected in series and with these in various combinations connected NOR gates existing cascade circuit, the from the pulse train the first pulse as a start pulse directly to the encoder output and the following pulses in the series according to a switch of the first and second group, each pulse depending on the The switch position of the associated switch is fed to the encoder output or is suppressed;

and that the normally inactive state

located, can be put into operation by the start pulse Receiver has the following facilities:

d) a number of display devices each assigned to a transmitter with display means for Making the information visible

e) and a circuit consisting of NOR gates, which after receiving the address pulse group the display device assigned to it is ready for operation and its; after- £ ql'gerid.e Irifoimation impulse group supplies.

In this system, the information to be transmitted is only set by appropriately pressing the buttons assigned to the switches and can then be scanned and transmitted automatically at any time by triggering the pulse generator, the circuit controlling the correct time sequence of the scanning being particularly simple and reliable is. The recipient can use the _; Normal state be at rest and is only put into operation during the transmission process itself, but the information made visible by the display means is also available during the rest periods of the recipient.

The setup of the system according to the invention is particularly simple when used for transmission the information the public telephone network is used. Accordingly, according to a preferred embodiment, the output signal of each encoder corresponding to that generated in the encoder Pulse-modulated, to be fed into the telephone network

feeding AC signal.

The system is advantageously designed on the transmitter side so that the pulse generator consists of a astable multivibrator and one of this controlled, at the beginning and end shortened impulses the same frequency generating pulse shaper and that the cascade-connected flip-flops of the Generate pulse trains one after the other with double, quadruple, etc. periods of the multivibrator pulses and control the NOR gates connected to them in such a way that in successive time intervals a NOR gate sends a pulse coming from the multivibrator or the pulse shaper to the associated one Switch lets through, with the number of NQR- ^ gates the number of for the informauons transmission corresponds to the required time intervals; '

It is also advantageous if the receiver is one that operates at the same frequency as the transmitter pulse generator Impulse generator and one analogous to the G, eber. bistable multivibrators and NOR gates Has existing cascade circuit, which in a sequence triggered by the start pulse causes each of the NOR gates to output a pulse one after the other at time intervals, if in the time interval a pulse is received from the transmitter, with a first group of NOR gates a device consisting of further NOR gates for identifying a respective display device according to the combination of the received address pulses and with a second Group of NOR gates connected to the inputs of all display devices. The establishment to identify the display device can have a converter, which sequentially

3 4

at the same time, the receiver automatically displays all of the information received on the other received address pulses. In the following, an embodiment of the telephone connection achieved by dejr, operation finding with reference to the drawings, is explained in more detail. The operator at the transmitter station is separated again -in the usual manner of the transmitter, which ends provided at each transmitter station. In telephone systems, in which, the station called is connected to each other, FIG. the system described by each transmitter to the central system, in which the calling part - receiver; io recipient holds the line), changes the current situation. Fig. 3 shows a ■ circuit diagram for a. The process described ■ in so far as the disconnection of the telephone connection for use in the transmitter and receiver takes place automatically, if appropriate; "' the receiver device is switched off. "" Fig. 4 shows a bistable divider circuit ;. It would be conceivable that the information is thereby related to FIG. 5 shows an initiator circuit; * 5 transmit that signals from different Arn, Fig. 6 shows a, NOR circuit; plitude provides, which the various information. Fig. 7 shows a Pqrch ^ c generator circuit; represent rhation values or information quantities, FIG. 8j shows the circuit diagram of a. Oscillators, Mo- shall..Because of the fluctuations in attenuation or dulators and transmission amplifiers; Reinforcement that. with ordinary telephone lines FIG. 9 shows a schematic block diagram of the occurrence of 20 with a high degree of probability, and because of. Receiver, which is set up at the central receiving station of the underground existing in such lines, ,,,; '"or noise, in practice it is only possible to use two ' ν Fxg; 10 · shows the detector circuits of the receiver; amplitude values, or states, namely-Fig. 11 shows the initiator circuit, and; the multi-lent an» one , "- state in which a signal vibrator circuit of the receiver; 25 is transmitted, and an"> out "state, in which no signal is transmitted. Fig. 12; shows the gate and relay circuit of the receiver This leads naturally to the use of a binary system; the 'borrowed order in each encoder and in the absence of an impulse in a certain time catcher.' unit shows a zero or vice versa.

The Embodiment of the Invention Described In the following description it will be assumed

relates to a system for transmitting that a pulse indicates a one and; that. Missing

Information about the occupancy of different one pulse in a respective time unit

Types of rooms, namely single rooms, double 35 zero displays.

rooms, double rooms with bathroom, etc., from one In most cases, it is possible, by postal prepayment of hotels, which are forbidden in a large area, to have power signals scattered directly in the telephone, to a central reception feed lines. The. Hence, impulses have to come from the central administration of all station. Encountering an alternating current signal, for example, hotels can be provided, where the on the 4 ° of a sound signal of certain. Frequency, "consists of the most up-to-date information about which the current occupancy is to be maintained for a specified period of time". The recipient can will. The said rules specify the type of. unvoiced, signals also fixed at a central Zimmervermittlüngsbürq, d ^ e on Teiefon.-)) be installed. The information will only be transmitted via lines. If, for example, the transmitted over the ordinary telephone network, and 45 normal telephone lines F ^ eq ^ ence up to about, every transfer process happens automatically. 3 kHz transmits, each of the hotels according to the invention must of course be equipped with a purpose a frequency of 1.6 kHz an appropriate transmitter device. With the central modulation frequency the frequency of 1.6 kHz. and made accessible and usable, for example 50. However, this value is not essential to the invention and the information pertaining to the individual hotels may change depending on the local conditions and information displayed on corresponding display boards.

will. "The actuation of the transfer button by the

The schematic block diagram of FIG. 1 shows operator "causes a group of

a transmitter device, the first action of an encoded 55 pulse over the telephone network from the transmitter

service person is that they are in the usual. is sent to the recipient. A typical impulse, -

Way the telephony number of the central reception transmission sequence is shown in FIG. The GE-,

intercept station chooses. The operator waits all Irn.puisgru.ppe is divided into eleven time units,

then a response signal from the central receiving which are numbered from 1 to Xl. The time unit 1

station and presses as soon as it arrives, a 60 is taken by a start pulse 21. Select

“Start” or “Transfer” button 19 at the end of the transmitter for the duration of time unit 2 is a pause, in

device, whereby an initiator circuit 20, in which no signal is transmitted. While the next

Fi g. 5, a pulse is applied. Thereafter, four time units (time units 3 to 6) will be

the encoder works completely by itself and transmits a group of up to four pulses,

the information previously provided by an operator 65 To detect any discrepancy between the

person on a suitable voting board set sequences of the two. Oscillators in the encoder and in the

would. The giver works with the receiver in such a way that the receiver takes into account the impulses

together that immediately after the transmission of the address group, 'those from the third to the

sixth time unit Überlingen, each of a shorter duration than the time unit assigned to them. For example, the pulse 13 is shorter in duration than the time unit 3, and dead times 14 and 15 are provided on both sides of each pulse. This will be discussed in more detail later. The address information "identifies the respective transmitter, from which the information is transmitted, and is coded according to a binary system. As can be transmitted up to four pulses, the number of donor stations that can be identified, a maximum of 2 ^4, or 16. However, since it is preferable not to use "0000" as an identification signal, the number of addresses is limited to 15. This means that the system in the form just described can be used to obtain information regarding the occupancy etc. of fifteen different hotels If this number is not sufficient, it is of course possible to modify the system so that, for example, five time units are available for the address group, so that then up to five address pulses and correspondingly 32 or if the »O0000« combination is omitted, 31 different combinations can be transmitted.

After the address group in time units 3 to 6, there is a pause during time unit 7, after which a group of information pulses is transmitted. As can be seen from Fig. 2, are three time units 8, 9 and 10 are provided for this purpose, and during each of these time units a Impulse are transmitted. With binary coding, eight different combinations can be made transferred or, if the 000 combination is omitted, seven usable combinations. Also in this Case, the amount of information, i. H. the number of different ones available Code combinations can be enlarged as required by simply allowing more time units, so that a greater number of pulses are transmitted. Each of the in time units 8, 9 and 10 transmitted impulses is of shorter duration than the time units themselves and (cf. impulses 16 and 17) placed in the middle of the respective time unit by adding dead times provided on both sides of the pulse are.

After the information pulse group, a stop pulse 18 is transmitted in the eleventh time unit to indicate that the transmitted message has ended. . .

The in F i g. The device shown in FIG. 1 has an astable multivibrator 21 which supplies a square-wave signal. This is let through by a gate 22 when this is opened by a start signal which is supplied by the initiator circuit 20 when the transmission button 19 is depressed. The gate is of the usual design and does not need to be described in detail. F i g. 3 shows a circuit diagram of the astable multivibrator 21 using four transistors T1, T2, T3 and Γ4. All transistors are of the npn type.

The square-wave signal from the multivibrator 21 is fed to the first of a chain of divider circuits B 1 to BS , which are bistable trigger circuits and can be of conventional design. A single input signal is fed to the two inputs of each divider circuit via two diodes, one of which is biased in the reverse direction, depending on the current state of the circuit, so that successive input pulses in the divider circuit cause it to tip over from one state to the other. The outputs of the bistable divider circuits are connected to NOR gates N 1 to N 9 in such a combination that these gates successively output pulses in the form shown in FIG. 2 generate the sequence shown, the time units corresponding to half the periods of the divider circle B 2. At the same time in which the signals from the divider circuits B 1 to B 5 are fed to the NOR gates Nl to N 9 , pulses from the multivibrator 21 and from the divider circuit B 1 are fed to a Porch generator P in such a way that these pulses generated, which are shorter than the individual time units and moved approximately in the middle of each time unit, so that the in F i g. 2 arises, the duration of the pulses 13 being shortened by the dead times 14 and 15 occurring on both sides.

The manner in which the multivibrator 21 and the bistable divider circuits B 1 to B 5 function in order to generate the desired pulse train at the NOR gates N1 to N9 zn is explained in more detail by FIG. In this figure, a number of pulse states in the time units 1 to 11 are shown.

The upper line in FIG. 13, indicated on the left side with the reference numeral 21, represents the pulses supplied by the astable multivibrator 21. The next five pulse trains, labeled Bl to B 5, show the pulse outputs of the five bistable divider circles in relation to the multivibrator output. A line marked with Γ on the left-hand side indicates the time units 1 to 11 and represents the time base for all in FIG. Pulse trains 13 shown. The designated P pulse train constitutes the output of the Porch generator, while the designated O pulse sequence represents the output of NOR gate Nl to N 9. Thus, the line O represents the pulses that are available for feeding into a modulator 25 when all keys Kl to Kl of F i g. 1 to be closed.

The pulses of the multivibrator 21 successively trigger the first dividing circuit B1, which in turn triggers the second dividing circuit Γ 2, etc. All dividing circuits are essentially symmetrical elements that provide two outputs, one of which is always "high" and the other low at a given point in time is. For the sake of clarity, one of the outputs is denoted by 1 and the other by 0 in FIG. It will be understood, however, that if a part's output 1 is low (ie, at state 0) then output 0 must be high. The outputs 1 of the circles B2 to BS are shown in solid lines in FIG. 13, while the periods in which the outputs 0 are at a low level are indicated by dashed lines.

Initially, all four divider circles B 2 to BS are in the low level to which they were initially set, as will be explained in more detail below. The NOR gate Nl is connected to the four outputs 1 of the divider circuits B 2 to B 5 , which are all at a low level in the time unit 1. These connections are indicated by dots on the

Pulse trains of the outputs 1 from B 2 to 55, which are each connected to one another by a vertical dashed line, which leads to the symbol Nl . It can be seen that in the time unit 1 no blocking signals are fed to the NOR gate 1, so that its output is at a high level during this entire time unit. This is the start impulse. The NOR gate Nl is not influenced by the output porch generator P, since there is no connection from P to Nl .

At the end of the time unit 1, the multivibrator 21 switches the divider circuit 51 so that its output 1 goes to a high level. This high level is fed to the input of the divider circuit B 2 , which is also set so that its output 1 generates a high level. This in turn switches circuit B 2 etc. As a result, at the beginning of time unit 2, all outputs 1 of circuits B 2 to B 5 are at a high level and outputs 0 from B 2 to B 5 are all at a low level. Time unit 2 is a pause period during which no exit is desired. If a NOR gate were connected to the four outputs 0 of circuits B 2 to B 5, this NOR gate would generate an output signal during time unit 2. However, since no output signal is required or desired during this pause period, no NOR gate is connected to all four outputs 0 of the divider circuits B 2 to B 5 . The purpose of the pause period is that during it the address identification device of the recipient puts the corresponding selected display device in readiness before the actual information to be displayed is received. In a system with long time units (for example 50 milliseconds or more) this pause period 7 can be dispensed with.

During the time unit 3, the output 1 of B 2 is at a low level, while the outputs 1 of the divider circuits B 3, B 4 and BS are at a high level. Therefore, the NOR gate N2 is connected to the output terminal 1 of B 2 and the output terminals 0 of B 3, B 4 and BS . As a result, during this time unit 3, the NOR gate N 2 generates an output pulse which (when Kl is closed) is fed to the modulator 25. During unit time 4, outputs 1 of B 2, B 4 and B 5 are high, while output 1 of B 3 is low, and NOR gate N 3 is connected to output! of B3 and the outputs 0 of B 2, B 4 and 55 connected. During the time unit 4, the NOR gate N 3 does not receive any input signals from the divider circuits and consequently generates an output pulse.

The combination of connections from the divider circles to each individual NOR gate is clear, so that each NOR gate only emits an output pulse during the unit of time assigned to it generated. Note that there are no NOR gates with the combinations of outputs from 52 to 55 which generate output pulses of the NOR gates during time units 2 and 7 since these are pause periods in which an output pulse is never required.

The connections from the bistable divider circuits B 2 to 55 to the NOR gates N1 to N 9 are listed in the table below. From the sequence given in the table, it is easy to see how the table must be expanded in order to take into account the maximum number of sixteen different combinations which the four divider circles 5 2 to 55 can deliver.

Connections from the NOR gates Nl to 59
to the bistable divider circles 5 2 to 5 5

Time unit 10 1 gate 52 S3 54 BS 2 3 Nl 1 1 1 1-1 4th 0 0 0 0 ¹ S 5 N2 1 0 0 0 6th N3 0 r-l 0 0 7th N4 1-1 1-1 0 0 8th N5 0 0 1-1 0 9 r-l 0 1 0 20 ₁₀ N6 0 r-l 1 0 11th N7 1 1 1 0 N8 0 0 0 r-l N9 1 0 0 r-t

Pulses from the multivibrator 21 and the divider circuit 51 are fed into the Porch generator P, and it is designed in such a way that it can only be used during the half-periods of 21 in which one input at a high level and the other is at a low level, generates an output pulse, but not, when 21 and 51 are both high or both low. Because the porch generator is connected to each of the NOR gates TV 2 to IV9, the output pulse of these becomes NOR gates are limited to the middle part of the respective time unit in which the Porch generator generates an output pulse.

The same circuit principle with regard to the multivibrator, the divider circuits and the NOR gate is used applied in the receiver. The frequency of the multivibrator in the receiver and the associated divider circles defines similar time units. About slight differences in the frequencies of the two multivibrators to be able to allow and to absolutely ensure that one in a certain time unit The impulse appearing in the encoder is not partially in the previous or in the following time unit can appear in the receiver, the duration of the impulses in the encoder is shortened, as above described. This ensures that the pulses in the appropriate time units of the encoder are correctly recognized by the recipient.

The output of the porch generator 23 of FIG. 1

is fed to the NOR gates N 2 to N 9, but not to the NOR gate Nl , since the start pulse is not shortened during the time unit 1, as can be seen from FIG. 2 can be seen.

4 shows the circuit diagram of one of the bistable divider circuits 51 to 5 5. Each of these elements comprises four transistors 75, T 6, T 7 and Γ 8, which are also of the npn type. The two transistors

Γ 6 and Γ 7 are coupled in a similar way to that of the multivibrator, except that DC voltage couplings /? 7 and R8 are used, each connecting the collector of one transistor to the base of the other, so that the transistor pair forms a bistable arrangement. As will be explained in more detail below, a reset pulse is fed to the terminals 33 of all divider circuits at the end of the transmission process, so that

all of these circles back in for readiness can be reset to the desired state for the next transmission.

The successive pulses from the NOR gates are all fed to the common line 24 and from there to the modulator 25, which also receives a modulation frequency from an oscillator 26. The oscillator 26 generates essentially sinusoidal oscillations at a selected frequency of 1.6 kHz. Therefore, the modulator 26 outputs a 1.6 kHz Tonfrequenzschwingung in the times that are determined by the of the NOR gates Nl to N 9 coming pulses. The output of the modulator 25 is fed to an amplifier 27, from which the modulated pulse signals are fed to the transmission line.

The initiator circuit 20 of FIG. 1 is shown in FIG. 5. It has a pair of transistors T 9 and Γ10, which have been combined to form a bistable circuit. One terminal of the start or transfer button 19 is connected to the negative point 39 and the other terminal to the common point of the capacitors C9 and ClO and via a resistor 26 to the earth point 43, so that the closing of the transfer button causes the negative potential of the Point 39 via the resistor R 26 and the diode D 6 is applied to the emitter of the transistor Γ9 in order to put the circuit in one of its two stable states. On the other hand, a stop pulse supplied to the terminal 42 is supplied to the base of the transistor φ10 through the capacitor C11 and the diode D 8 to bring the circuit into the other stable state. The collector of the transistor Γ10 is connected via a resistor R 27 to the base of a third transistor Γ11 which, on the other hand, is also connected to the negative supply line 38 via a resistor R 28. The emitter of the transistor φ11 is connected via a resistor R 29 to the negative line 39 and also to an output terminal 44. The transistor Γ11 functions as an emitter follower, and the signal appearing at the output 44 is a reset signal which, in relation to the negative potential of the line 38, has either a high level (for resetting) or a low level, depending on the state of the transistors Γ 9 and TlO existing bistable circle.

Fig. 6 shows the circuit for each NOR gate Nl to N 9. The circuit shown has five input terminals 45 and 49. The NOR gates N 2 to N9 of FIG. 1 each have five inputs, only the NOR circuit 1 has only four entrances. The change is that one of the input terminals 45 to 49 and one of the input resistors R 30 to R34 connected to the input terminals are omitted. The other sides of the resistors R 30 to R34 are connected to the base of a transistor T 12, the emitter of which is at ground potential 43 and the collector of which is connected to a positive terminal 50 via a resistor R 35. The collector of the transistor Γ12 is connected via a diode D 9 to one contact half of a button 51, the other contact half of which leads to the starting point 52.

The NOR gate always generates an output signal when there is no input signal.

It thus generates a pulse which begins when all of the input signals at terminals 45 to 49 are removed and ends when an input signal appears at any of the input terminals.
F i g. 7 shows the circuit diagram of the Porch generator P of FIG. 1, which ensures that the in FIG. The shortened pulses 13 to 18 shown in FIG. 2 are generated and the two unused time segments 14 and 15 remain on both sides of the pulses within each available time unit. The circuit has two transistors Γ13 and Γ14, the emitters of which are connected to one another and to ground potential 43. Two input terminals 42 and 43 are provided which are each connected to the base of the transistor Γ13 via a resistor R 36 and R 37. Two further input terminals 64 and 65 are each connected to the base of transistor Γ14 through a resistor R 38 and R 39. The collector of the transistor T 13 is connected to a common point 70 via a diode D 10 and the collector of the transistor T 14 via a diode D 11. This point 70 is at the base of another transistor Γ15. The collector of the transistor TIS is connected to the positive line 68, while the emitter of the transistor T 15 is connected to the ground potential 43 via a resistor R 44. The transistor Γ15 is an emitter follower, and the output is tapped from its emitter at terminal 71.

One output of the multivibrator 21 (FIG. 3) from its terminal 28 is fed to the terminal 62 and the other output of the multivibrator 21 from its terminal 29 to the terminal 64. One output of the bistable divider circuit B 3 (FIG. 4) from its terminal 34 is fed to the terminal 63, while the other output of the bistable divider circuit from its terminal 36 is fed to the input terminal 65.

If only the multivibrator would work, the bases of transistors Γ13 and Γ14 would become conductive alternately. Due to the presence of the diodes D 10 and D 11, the respective working transistor would communicate its potential via the respective diode to the common point 17 and the base of the transistor Γ15, which would thus be continuously conductive, so that the output terminal 71 is constantly at a high level with respect to the negative lead 66 would be located. If only the feeds from the multivibrator were interrupted and only the bistable divider circuit worked, the same thing would happen. However, when both are operating, the two incoming square waves are out of phase with each other due to the nature of FIG. 4 described switching delay. As a result, there are time segments at the beginning and at the end of each half-wave in which one of the transistors 13 and Γ14 is kept non-conductive by the multivibrator and the other transistor is kept non-conductive by the bistable divider circuit. These time segments are dead times which have already been explained and which are shown in FIG. 2 with 14 and 15 are designated.

F i g. 8 shows the circuit diagram of the oscillator 26, which is followed by the modulator 25 and the transmission amplifier 27. The oscillator has a transistor Γ16, the emitter of which is connected to the earth point 43 via a resistor R 45, the resistor R 45 from a capacitor C12

is bridged. The collector of the transistor T 16 is connected via a resistor R 46 to a positive supply line 72 which leads to a positive terminal 73. A feedback which causes the transistor φ16 to oscillate is formed by a capacitor C13 which is connected to the ground line 74 via a resistor R 47. The common point of the capacitor C13 and the resistor R 47 is connected to one side of a further capacitor C14, the other side of which is connected both to a terminal of a third capacitor C15 and via a resistor R 48 to the ground line 74. The other terminal of the capacitor C 15 is connected to the base of a transistor Γ16 and via a resistor R 49 to the ground potential 74, furthermore via a resistor R 50 to a positive supply line 72 which leads to the terminal 73. The collector of the transistor Γ16 is connected to the base of a transistor Γ17, the collector of which is connected directly to the positive supply line 72 and whose emitter is connected via a resistor R 51 to the ground line 74 and also directly to the collector of the modulator transistor 18. The signal from the NOR gates on line 24 of FIG. 1 is fed to the base of transistor 18 through a resistor R 52. The emitter of the transistor T 18 is connected to the ground line 74 via a resistor R 53 and is also directly connected to the base of a transmission amplifier transistor T19, the collector of which is connected directly to the positive supply line 72 and the emitter of which is connected to the primary winding 75 of a transformer generally designated 76 is in series with a resistor 54 at ground potential 74. The transformer 76 is an impedance matching transformer and the two secondary terminals 77 are connected to the telephone transmission line.

During operation, the transistor T 16 oscillates at a fixed frequency which, as mentioned above, is expediently 1.6 kHz; The oscillations are fed to the base of transistor T 17, which works as an emitter follower and whose output is fed to the collector of transistor Γ18. The signal from the NOR gates causes transistor T 18 to be alternately conductive and non-conductive. The output signal, which consists of oscillating trains forming the pulses controlled by the JNOR gates, is applied to the base of transistor φ19, the output of which is fed from its emitter via transformer 76 to the transmission line.

A complete operation of the encoder takes place as follows. When the operator presses the transmission button 19, the initiator circuit 20 delivers a signal which opens the gate 22. The multivibrator 21, which is in operation (or can be, if desired activated by the initiator circuit 20), transmits a square wave signal via the gate 22 to the first stage Bl of the bistable splitter group which is displaced by the first half period in its other state. When the divider circuit taps over, the divider circuit ^ ß 1 transmits a signal to the NOR gates N 2 to N 9. Every time a bistable divider circuit changes its state, the output pulse generated triggers the following bistable divider circuit. The pulse trains generated by the bistable divider circles each have integer fractions of the multivibrator frequency, so that after combination in the NOR gates N1 to TV 9, as described above, they deliver the successive pulses. The porch generator P transmits pulses to the NOR gates 2 to 9 in order to ensure that the pulses supplied by these circuits are of a smaller width than the available time unit, as already explained. Since a narrower pulse is not required for the NOR gate N 1, this does not receive a '

ίο Signal from the Porch generator P. The various connections between the divider circuits B 1 to B 5, the Porch generator P and the NOR gates Nl to N 9 are such that during a half cycle of B 2 (which is the first time unit 1 defined in FIG. 2) the NOR gate Nl emits a pulse to the common line 24 and from there to the modulator 25. During the duration of this pulse, the modulator 25 transmits oscillations from the sinusoidal oscillator 26 to the amplifier 27 for transmission. The next half cycle of B 2 is a quiet period, and during the next half period of Bl, NOR gate N 2 provides a pulse, which is shortened by the Porch generator P. This pulse is only delivered to the common line 24 when the key Kl is closed. When it is closed, the pulse is delivered to the modulator 25, which then allows another burst of oscillations from the oscillator 26 to the amplifier 27 for transmission. When the key i £ 2 is open, the modulator 25 remains idle. This process is repeated for the NOR circuits N 3 to N 9. The address of the. Donor station is constantly set by closing the appropriate selection of keys Kl to K 4, while the information to be transmitted from a particular donor station is set immediately before the transmission by closing the corresponding combination of keys K 5 to Kl . These keys K 5 to K 7 are of course selected by the operator. The last pulse transmitted by the NOR gate N 9 is not controlled by a key, since this is the stop pulse that should be transmitted in any case. There is also a connection from NOR gate N9 back to initiator circuit 20 so that the stop pulse transmitted via the transmission line is also fed to initiator circuit 20 via line 53 at terminal 42 in FIG Restore state of rest: The overturning of the initiator circuit causes the gate 22 to be closed and also provides a reset signal from the terminal 44 in FIG. 5 via line 54 to all divider circuits B 1 to B 5 in order to return them to the state that is required at the beginning of the next transmission.

F i g. 9 shows a schematic block diagram of the receiver device. As can be seen from this figure, the input signal coming from the transmission line becomes an input line 78 received and fed to a tuned amplifier 79 and from there to a diode pump circuit 80, which is followed by a Schmitt trigger circuit 81. The circuit diagrams of these three units are shown in FIG. 10 shown.

As shown in FIG. 10, the signals received over the telephone lines become the primary winding a matched input transformer

84 supplied. A matching resistor 55 is connected in parallel with the secondary winding 85 of this transformer. One side of the secondary winding 85 is connected to the base of a transistor Γ 20 via a capacitor C15. The transistor acts as a voltage amplifier, while the capacitor C 15 is selected so that, together with the reactance of the transformer 85, it resonates substantially at the frequency of the pulse bursts of 1.6 kHz.

The output supplied by the collector of the transistor T 20 is fed via a capacitor C17 to the common point of two diodes D 12 and D 13, which are in series between the base of a transistor Γ21 and the ground potential 88. A capacitor C 18 and a leakage resistor R 59 are also located between the base of transistor Γ 21 and ground potential 88. The collector of transistor Γ 21 is connected to positive supply line 86 and its emitter is connected to ground line 88 via a resistor R 60.

In operation, when the first train of 1.6 kHz oscillations is received, ie the start pulse, these oscillations are amplified in the transistor Γ 20 and a voltage is built up on the capacitor C 18 via the diodes D 12 and D 13 The number of periods of the 1.6 kHz frequency is sufficient to make the transistor Γ 21 conductive. The output of the transistor Γ 21, which is an emitter follower, is fed from its emitter to the base of the first transistor Γ 22 of the Schmitt trigger 81.

The second transistor that the Schmitt trigger has is transistor Γ23. As is known, the Schmitt trigger is a bistable arrangement which is in one of its states when an applied input voltage is below a certain level and which changes to the other state when the input voltage rises above this level. In this special arrangement, during a few periods at the beginning of the oscillation train, which make up the start pulse, the base voltage of transistor Γ20 is built up so that this transistor becomes conductive, which also increases the voltage drop across resistor R 60, so that the base of the transistor Γ22 supplied voltage is sufficient to cause the Schmitt trigger to switch to the other state. The output of the Schmitt trigger is tapped from the collector of transistor Γ23 and fed to the base of another transistor Γ24, which is an emitter follower and whose collector is directly connected to the positive supply line 86, while its emitter is connected to a terminal 89 via a resistor R66 which is connected to the above-mentioned negative supply line. The output is taken from the emitter of the transistor T 24 via an output terminal 90.

The measure that a certain number (which need not be more than three or four) of periods is counted before the receiver is actuated by an incoming impulse, has the purpose of actuation by the noise or by stray impulses in the telephone line to prevent. The output from the Schmitt trigger S consists of direct current pulses, which are an image of the pulses at the output of the NOR circuits of the encoder.

The output of the Schmitt trigger is supplied to a initiator circuit 82 and a series of NOR gates NlO to ΛΊ3 and N14 to N eighteenth The NOR gates are identical to those used in connection with FIG. 6, while the initiator circuit is shown in Fig. 11 and will be described below. The circuit of FIG. 11 includes an astable multivibrator 83 (FIG. 9) which is designed to operate at exactly the same frequency as the multivibrator 21 of FIG. 1 works, as well as a bistable circuit (consisting of the transistors Γ25, Γ26, Γ27 and Γ28), which is triggered by the incoming start and stop pulses that are fed to points 91 and 96, respectively.

When the Schmitt trigger 81 tips over and generates its output signal at the terminal 90 (FIG. 10), this signal is fed to the start terminal 91 of the initiator circuit and puts it into its other state. This causes a signal from the collector of a transistor T 26 to be transmitted to the base of the transistor Γ29, which sets the multivibrator 83 in operation. The output signal of the multivibrator is taken from a terminal 98. This output is fed to a bistable divider which is composed of the circles B B 6 to 10 and has the same arrangement as the bistable divider circuits Bl through B5 (Fig. 4). These dividers work in exactly the same way and provide signals to NOR gates N 10 through N 13 and N 15 through N 17.

When the multivibrator 83 is operating, the controls in time units 3, 4, 5 and 6 of FIG. 2 occurring pulses the NOR gates N10, NU, N12 and iV13 in the appropriate order, and the output signals of the NOR circuits are fed to an address memory.

In the embodiment described, it is assumed that each of the information stores has one Has information board on which numbers light up to indicate the information, namely from the time the information is fed in until the time the information is deleted and is replaced by the next information transfer. The information transmitted is thus accessible at any time simply by looking at the display board.

Since the received pulses arrive one after the other, a converter which is connected to the outputs of the address NOR gates must be provided to convert the time sequence into parallel display. This converter notes the four output signals appearing one after the other from the four NOR circuits N 10 to N 13, so that the complete address can be recognized after the fourth pulse. This converter consists of four bistable circuits, which can be of the same structure as those used in the divider chain, and have already been described above and at 99 to 102 in FIG. 9 were shown. The output signals from the converter are fed to a further group of NOR gates. There are as many of these NOR gates as there are different addresses in the system, and each NOR gate is assigned to a display panel. For each individual binary coded address there is only one NOR gate at a time. One of these final NOR gates N 19 is shown in FIG. 9 shown together with the associated relay 103,

Ιό

104 and 105 and a gate 106. These arrangements will be explained in more detail in connection with FIG. 12. Thus, when the address pulses have been received, the NOR gate operates and enables a group of relays in the selected display panel. In the embodiment described, relays with twin coils are used, one coil being the working coil _: and the other being the reset coil, ie in opposite directions. Direction, works. The next pulse arriving via the input line 78 (in the time unit 7 of FIG. 2) is fed to a NOR gate N 14, which emits a signal, in response to which the information on the display panel cancels that was previously from the Address NOR gates selected information store has been shown. This NOR gate N14 can be operated automatically, since the address has been completely received and recognized. It can also be actuated by a pulse transmitted during the time unit 7, which would then occur with every transmission process, as well as the start pulse and the stop pulse, which are transmitted in the time units 1 and 11.

Fig. 12 shows in detail the relay arrangement of a display board with three relays 103, 104 and 105. The pulse from the NOR gate R14 is fed to an emitter follower transistor Γ31 , whose collector is connected directly to a positive supply terminal 107 and the emitter via a resistor R 81 to the Ground potential 43 is connected. The signal from emitter Γ 31 is fed through a diode D16 to the work coil of relay 103 and to the work coils of the corresponding relays in all other display panels. In the same way, emitter followers (not shown) which are assigned to the NOR gates N16 and N 17, signals via diodes D 17 and D 18 to the working coils of the relays 104 and

105 and also the work coils of the corresponding relays in all other display panels.

When the address of the display board associated with NOR gate N 19, gate 106 and relays 103, 104 and 105 is selected, the signal from N 19 is applied through resistor R 84 to the base of transistor φ32 which the gate 106 forms. The emitter of transistor Γ 32 is at ground potential 43, and its collector is connected to the return lines of the work coils and the reset coils of all relays. The base of the transistor Γ 32 is connected to a negative supply terminal 108 via a resistor R 82. Thus, if there is no signal from the NOR gate N 19, the transistor Γ 32 is blocked, so that the return lines of all relay coils are practically interrupted. However, if the address of the display panel associated with relays 103 to 105 is selected, transistor Γ32 will conduct and all relay coils will be able to operate.

The NOR gate N 14 is connected to the base of a further transistor Γ 33, the collector of which is connected to a positive supply terminal 109 and the emitter of which is connected to a negative supply terminal 110 via a resistor R 83. A line 111 from the emitter of transistor Γ32 is connected via diodes D19, D 20 and D 21 to the reset coils of relays 103, 104 and 105 , and furthermore via corresponding diodes to the reset coils of all other relays, the other, unselected display panels assigned.

In operation, transistor Γ32 is made conductive by a signal applied to its base through resistor R 84 from NOR gate N 19 when the address of the corresponding display panel is selected. This closes the return lines of the work coils and the reset coils of all relays associated with this particular display panel. The reset pulse which appears immediately thereafter on line 111 is applied to the reset coils of all relays in all display panels. However, since only the returns in the selected panel are closed, only the relays in the selected panel are reset. In the same way, pulses from the NOR gates N 15, N 16 and NIl are fed to the respective working coils of the relays in all display panels, but again only the relays in the selected display panel are actuated since the return lines are only closed in the selected display panel .

An essential feature of the transmission system according to the invention is the following: It is Of course, it is possible to change the length of the time units 1 to 11 over a large range. However, it is entirely possible to design the system so that the transfer and the change of the information displayed takes less than a quarter of a second, including the time that is required to clear the relays according to the new information transmitted and re-enter to adjust.

The last pulse, ie the stop pulse to be transmitted in the time unit 11 (FIG. 2), is fed to the NOR gate N 18. The output pulse from this circuit is applied to the stop terminal of the initiator circuit 82 shown in FIG. This causes the initiator circuit 82 to return to its initial state, the multivibrator 82 is switched off and a reset signal is also emitted from the terminal 96, which the reset terminals of all bistable divider circuits B 6 to B 10 (via the terminal 33 of F i g. 4) is fed, so that all these circuits are returned to the state required to start the next transmission.

Claims (5)

- Patent claims: 1. System for the transmission of information from a number of sensors to a central one Receiver in which facilities are provided in each donor in chronological order a start pulse, a group of address pulses to identify the encoder and a Generate group of information pulses, and in which the receiver has facilities, which are set into action by the start impulse and the information in one of the encoder store assigned shape, characterized in that each encoder has the following devices: a) two groups of on-off switches (Kl • _; to Kl), of which the switches are the first "j group (Kl to K 4) in one of the addresses ~ 'J of the appropriate combination adjustable and the switches of the second group (KS to Kl) can be set manually in a combination corresponding to the information to be transmitted before the transmission, b) a pulse generator (21) which automatically generates a pulse train at predetermined time intervals generated, , ... c) and connected in series-connected flip-flops (Bl to 55) and with these in different combinations NOR gates (Nl to N existing cascade circuit 9) of the pulse sequence the first pulse as the starting pulse directly to the generator output and feeds the following pulses one after the other to a switch of the first and second group, each pulse being fed to the transmitter output (27) or suppressed depending on the switch position of the associated switch; and that the normally inactive state can be put into operation by the start pulse Receiver has the following facilities: d) a number of display devices, each assigned to a transmitter, with display means to make the information visible, e) and a circuit consisting of NOR gates (N 10 to N 18) which, after receiving the address pulse group, puts the display device assigned to it in readiness for operation and supplies it with the following information pulse group. 2. System according to claim 1, characterized in that the output signal of each encoder one modulated by the pulses generated in the encoder and fed into the public telephone network AC signal is. 3. System according to claim 1 or 2, characterized in that the pulse generator consists of an astable multivibrator (21) and one controlled by this, at the beginning and end shortened pulses of the same frequency generating pulse shaper (P) and that the flip-flops connected in series (B 1 to B 5) sequentially generate pulse trains with double, quadruple, etc. periods of the multivibrator pulses and control the NOR gates connected to them (Nl to N 9) in such a way that in successive time intervals a NOR gate each has one from Multivibrator or impulse coming from the pulse shaper lets through to the associated switch (Kl to Kl) , the number of NOR gates corresponding to the number of time intervals required for the transmission of information. 4. System according to one of claims 1 to 3, characterized in that the receiver has one with the same frequency as the transmitter pulse generator (21) working pulse generator (83) and one of the transmitter analog, from bistable tilting 'stages (B6 to BIO) and NOR gates (NlO to N 18) existing cascade circuit that sequentially each of the NOR gates caused to delivery of a pulse in a triggered by the start pulse sequence of time intervals (NlO to N18), if a pulse is received by the encoder in the time interval, and that with a first group of NOR gates a device consisting of further NOR gates for identifying a respective display device in accordance with the received address pulses and with a second group of NOR gates the inputs of all display devices are connected. 5. System according to claim 4, characterized in that the means for identifying the display device comprises a converter consisting of bistable flip-flops (99 to 102) which simultaneously represents the address pulses received one after the other. For this purpose 2 sheets of drawings