DE1021016B - Circuit arrangement for telecommunication and telecontrol systems for signal transmission according to a frequency code system - Google Patents

Description

The invention relates to a signal transmission method according to the frequency code system for telecommunication and telecontrol systems, especially for the transmission of alarm signals. Signal transmission equipment according to the Frequency code systems are used for the transmission of signals or switching orders in remote dialing, Signal and remote control systems and the purpose of equipment that works according to other systems, avoiding rotating parts, such as dialers or synchronous distributors, increasing the transmission sensitivity, To save lines, to improve the transmission security against disturbances and to improve the transmission To enable lines with amplifiers in a simple manner.

In a known arrangement for identifying the desired subscriber in telephone systems groups are formed by means of frequency combinations, which are transmitted one after the other. The groups are made up of different elements according to the identification groups of the desired participant combined. The elements for all combinations] are taken from the same element pool. In addition to its element combination, each of the groups contains another element, which identifies the number of the group.

With all devices for signal transmission there is a risk of undesired actuation due to disturbances, so that special safety devices are provided. So with the tone dialing, which only uses one or two frequencies, applied speech protection devices through which prevented is that the receiving device responds and triggers unintentional signals due to voice frequency combinations occurring randomly in the signal frequency range. Known speech protection devices work in such a way that from the line or amplifier output the signal receiving device via a bandpass filter matched to the signal frequency and the speech protection device is fed via an appropriately matched bandstop filter. When receiving voice speaks to the speech protection device and leaves the possibly also responding signal receiving device will not take effect. Such a protective device has the disadvantage that it is against a wrong Signaling through deliberate interference, such as can be caused by whistling, does not Provides protection. It also interrupts signal transmission during the presence of speech. Another known device uses a voice-protected distant signal, when received for a For a certain period of time due to the disconnection of line connections, speech can enter the signal line prevented and at the same time the signal receiver is switched on. This known device achieves the

Circuit arrangement for telecommunication
and telecontrol systems for signal transmission according to a frequency code system

Applicant:

Standard Elektrik Aktiengesellschaft,
Stuttgart-Zuffenhausen,
Hellmuth-Hirth-Str. 42

Dipl.-Ing. Valentin Epinatjeff, Stuttgart-Zuffenhausen, and Johannes Matthieu, Stuttgart-Stammheim,

have been named as inventors

Speech protection by placing the frequency of the distant signal outside the transmitted voice band.

For example, alternating current of 25 or 50 Hz, direct voltage or inductive current surges are used. In order to but the disadvantage arises that the distant signal is not amplified in the same way as the voice frequencies can be. The lines will continue via the

go duration of signal transmission also separated, so communication is interrupted longer than necessary of the other line sections g. interferes, which requires measures to prevent self-excitement.

An arrangement for telephone systems is also known in which all signals are preceded by a distant signal. Both signals exist, i. H. the distant signal and the one that characterizes the actual switching order second signal, from a combination of several in the voice frequency band lying frequencies. This training serves to increase language security. In another known arrangement for telephone systems with tone frequency selection are at the beginning and end of each pulse train Transmit audio frequency pulses of a different type than the other pulses in the series. For this purpose, individual frequencies and different frequency combinations are used. Also need for the duration of each Impulses as well as the pauses in between, certain values are adhered to. The known arrangements but have disadvantages. Alone with the measure, a certain pulse ratio, so a certain one Duration of impulse and pause, to strive for, however, no proper signal transmission can be guaranteed. Since in the known arrangements audio frequency signals

709 810/97

of various kinds, e.g. B. only from a single frequency or from any combination containing any number of frequencies, are transmitted, there is no complete security against incorrect influences. It is not enough to include those contained in the signals sifting out individual frequencies exactly from the frequency band. One gets an improvement in that the frequency combinations are always combinations of a certain class be, d. H. that from the available frequencies there is always one and the same number of individual frequencies pulled out and used to form the combination or, in other words, that each signal is composed of the same number of individual frequencies. Interfering signals that instead of the predetermined Number of frequencies must contain a frequency more or less under all circumstances be eliminated because such signals no longer clearly characterize the relevant switching command.

Compared to the known devices, the invention has the advantage that an intentional or accidental Disturbance of the transmission device is excluded that the signal frequencies used in the voice band lie and are reinforced with this and that the signaling during a conversation without essential Impairment of the same can take place. The invention achieves this in that the individually of fast working Receiving switching means received single signal frequencies on delayed working memory switching means are transferred which, due to their delayed operation, will only be saved, if the incentive by the associated receiving switching means exceeds a predetermined duration, and which, in cooperation with a first test switch means, the predetermined number of times in the Individual frequencies contained in partial signals checked, and in cooperation with second and third test switching means, which check the duration of the pauses between the partial signals, only one switching order then let it come to execution when the duration of each of the two partial signals and the time interval Adhere to predetermined values between the two partial signals, and also the two partial signals in predetermined Arrive sequence and in each of the two partial signals the predetermined number of individual frequencies contain.

According to a further embodiment of the invention, the circuit arrangement is designed in such a way that on the receiving side the response delay of the memory switching means and on the transmitting side the incentive duration for actuating the receiving and thus the memory switching means is determined in such a way that they are definitely greater than the longest frequency mixture occurring in speech one of the switching means responds. According to a further embodiment of the invention, each of the two partial signals consists of an equal number η of a total of m individual frequencies, and the first test switching means only comes into effect if a corresponding number of memory switching means is set by the predetermined number of η individual frequencies.

In telecontrol technology methods for remote control of several switches are known in which the switching process is split into the selection of a specific switch and the actual switching command will. This measure is there to ensure the switching process and requires a feedback the correct selection made as well as the completed switching. So there are alternating in both Directions messages transmitted and an automatic control of the transmission processes made what requires a very elaborate facility.

The invention will now be explained in more detail on the basis of an exemplary embodiment with the aid of the drawing. The signal transmission device uses combinations of three of a total of five individual frequencies as partial signals and transmits the combination of frequencies / "2, /" 4 and fS as a second partial signal (post-signal) for each switching order. With the remaining nine partial signals, nine switching orders can be identified.

The outgoing signal transmission, not shown, sends a selection signal corresponding to the switching order to be transmitted, e.g. B. the combination of frequencies f 1, f2 and fS, and after a predetermined pause the post-signal f 2, fi and fS common to all switching orders.

The partially shown in the drawing incoming signal transmission takes both signals and outputs a corresponding switching order, provided that the two part signals and the intermediate pause predetermined W ^T erte adhere.

In the input of the incoming signal transmission, for selective reception of the individual frequencies fl to f5, the transformers Ül to US, which are matched to the frequencies fl to fS by means of various capacitors CX to C5 and are connected to the ignition electrodes of the cold cathode tubes Röl to Rö5 . In the following, only the arrangement used to receive the individual frequencies fl will be described first. The ignition electrode receives a suitable bias voltage from the auxiliary battery UhI , so that the tube Röl ignites when the frequency fl is received. The anode circuit of the tube Röl contains a receiving relay A and is fed by the office battery and an additional alternating current source Uh2. During each period of this additional alternating voltage, the tube goes out and ignites again, provided that the individual frequency voltage fl is still applied to the ignition electrode. When it responds, the relay A causes the storage relay Q 1 assigned to it to drop by counter-excitation. This relay normally carries closed current via the following circuit:

Earth, battery, WiI, QlI ,? | Νίτ> earth.

Relay A short- circuits relay QlI:

Earth, A2I, al, QlI, ^^, earth. ^Y # 111

At the same time, relay .4 energizes the counter-winding Q1 II via the following circuit:

Earth, battery, WiI, QlII, qll, all, al, Ä2I, earth.

With WiI , the fall time of Q1 is set so that it is definitely greater than the longest frequency mixture that comes in the language and that makes the tube Röl respond via the tuned transformer Ül . If relay .4 is briefly triggered by such speech or interference, relay Q1 does not drop out and is immediately re-energized when relay A drops out. This ensures that the Spdeherrelab Ql is only thrown off by the signal fl even in the presence of speech. When the relay Ql drops out , the assigned auxiliary relay I is actuated. Contacts of relay I, e.g. Uli, are used in conjunction with contacts of other storage auxiliary relays, e.g. B. 2III and 5IV, to select the signals, e.g. B. of signal 1, 2, 5.

If a complete selection signal is received, three auxiliary storage relays, e.g. B. I, II and V operated. One

suitable contact arrangement of contacts of these auxiliary relays allows the first test relay H to respond only when three of these auxiliary relays are operated, z. B. via the following circuit:

Earth, battery, H, 41, 211, 511, II, 31, earth.

This first test relay H actuates a second test relay Hl via contacts of the receiving relays A and C, which are not actuated during the subsequent post-signal and of which at least one is actuated with each selection signal. The second test relay only responds when a selection signal arrives as the first partial signal. It consists of the following circuit:

Earth, battery, Hl, aiii, hVl, earth. ¹ p

Thereafter, Hl remains in the following circuit as long as receiving relays A to E are actuated:

^ _J _. , "AlIII, 6III
Earth, battery, St. - _τΤί

aiii, AVI

Earth.

So Hl only responds if the three receiving relays are operated for a long enough time, and does not drop out as long as not all of the receiving relays have also dropped out. This controls the minimum duration of the selection signals and the presence of a pause. After relay Hl responds, the third test relay HH is energized in the following circuit:

Earth, battery, HHl, AIII, AVI, earth.

A capacitor is charged in parallel to HH1. When Hl falls, HH falls off with a great delay as a result of the capacitor discharge. The delay time is set precisely at the resistor Wi by counter-exciting the secondary winding of the relay HH in the following circuit:

Earth, battery, TFi,

Wi

, MII, AIII, AVI, earth.

The response of HH causes the fourth test relay H2 to be excited via the following circuit:

Oaths, battery, H2, WiI, earth.

Relay H2 with its contacts A2I to A2V prevents further receiving relays from being dropped, e.g. B. Q3 and Q 4.

The release time of HH determines the maximum permissible pause length between the selection signal and the post-signal by the fact that if the post-signal arrives late, i.e. after relay HH has dropped and before relay Y may respond, relay H2 drops out and thus at least one of the previous ones Selection signal brought to waste storage relay Q, in the selected example the storage relay Q1, can respond again. As a result, relay H drops out, so that relay Y cannot respond.

When the second partial signal arrives (post-signal), the receiving relays B, D and E respond. As a result, the first signal relay Y responds in the following circuit:

Earth, battery, Y, δIV, dlV, elV, All, AVII, earth.

Relay Y actuates the second signal relay VH and creates a second holding circuit for the fourth test relay H2 with the following circuit:

Earth, battery, H 2, yl, earth.

The relay VH interrupts the closed circuit of the control relay K , which drops out after a long delay, with its contact »All, which determines the maximum permissible duration of the post-signal. At the end of the after-signal, the circuit of the first signal relay Y is interrupted, which drops out and switches off the excitation of the second signal relay VH. This has its winding FiJII short-circuited with the contact vhl , so that it drops off with a considerable delay. If the duration of the post-signal was not too long, the control relay K has not yet dropped out at this point in time. There is then the following response circuit for the third signal relay V:

Earth, battery, VI, vhlll, ylll, kl, earth.

Relay V responds and actuates the fourth signal relay V2 with its contact ν I. At the same time it closes the circuit of the relay K with its contact ν III . With its contact vll it finally places earth on the contact arrangement formed by the contacts of the auxiliary storage relays I to V, for example 2III, Uli and 5IV, and thus triggers the signal indicated by the selection signal, e.g. B. Signal 1, 2, 5. The fourth test relay H2 is temporarily de-energized when the first signal relay 1 * drops out. It is delayed a little fall, so that it does not fall until the response of the relay V2 , through which its excitation is switched on again. When the second signal relay VH drops out , the response circuit of the third signal relay V is interrupted. This drops out with a delay because its secondary winding FII is short-circuited by contact v2ll of the fourth signal relay. When the third signal relay drops out, the response circuit of the fourth signal relay F2 is interrupted, which drops out with a delay and thus causes the fourth test relay H2 to drop out with a delay. Contacts of relay H2 close the closed circuits of the storage relays dropped by the selection signal and allow them to pick up again. The storage relay Q 1 picks up again in the following circuit, for example:

Earth, battery, WiI, QU, A2VI, earth.

The storage relays, e.g. B. Ql, let by opening their normally closed contacts, z. B. §1111, the associated storage auxiliary relay, z. B. I, delayed fall off. This interrupts the response circuit of the relay H , which drops out and thus restores the idle state of the circuit.

Claims (16)

Patent claims: 1.Circuit arrangement for telecommunication and telecontrol systems for signal transmission over the telephone lines discussed according to a frequency code system, in which each switching order is transmitted by two temporally separated partial signals and both partial signals consist of a combination of several individual frequencies in the voice frequency band and one of which is a partial signal Identification of the switching order, characterized in that the individual signal frequencies picked up by fast-working receiving switching means (e.g. £ 71, Röl, A) are transmitted to memory switching means (e.g. Ql, I) that operate with a delay only make a storage when the incentive by the associated receiving switching means exceeds a predetermined duration, and in cooperation with a first test switching means (H), which checks the predetermined number of the individual frequencies contained in the partial signals üft, and in cooperation with second and third test switching means (Hl, HH), which check the duration of the pauses between the partial signals, only allow a switching order to be executed if the duration of each of the two partial signals and the time interval between the two partial signals also adhere to the predetermined values two partial signals arrive in a predetermined order and the predetermined order in each of the two partial signals Number of individual frequencies included. 2. Circuit arrangement according to claim 1, characterized in that the response delay on the receiving side the storage switching means and, on the transmitting side, the incentive duration to operate the receive and so that the memory switching means are set so that they are certainly larger than the longest in the Speech occurring frequency mixture to which one of the switching means responds. 3. Circuit arrangement according to claim 1 and 2, characterized in that each of the two partial signals consists of an equal number η of a total of m individual frequencies and the first test switching means (H) only comes into effect when a corresponding number of η individual frequencies Number of memory switching means (z. B. I) is set. 4. Circuit arrangement according to claim 1 to 3, characterized in that one of the possible ( ^m \ combinations forms the one part signal common to all switching orders, while in each case one of the remaining f) - 1 combinations forms the other part signal for identifying a specific switching order, and that the second test switch means (Hl) together with a first signal switch means (Y) as a function of the first test switch means the sequence of the arrival of the partial signals is checked. 5. Circuit arrangement according to claim 1 to 4, characterized in that the partial signal for identifying a certain switching order is transmitted before the partial signal common to all switching orders and that the receiving switching means (z. B. Ül, Röl , A) and depending on the actuation of the first test switch means (H) the second test switch means (Hl) is actuated, which during its working state brings itself in dependence on the selection switch means characterizing the post-signal (δIII, dill, eil!) , that after the receiving switching means it is the last to return to its idle state. 6. Circuit arrangement according to claim 1 to 4, characterized in that the all switching orders common partial signal before the partial signal to identify a specific switching order is transmitted. 7. Circuit arrangement according to claim 6, characterized in that the third test switch means (HH) responds by the actuation of the second test switch means (AIII) and that the third test switch means also by the return of the second test switch means in its idle state, but with a large and defined delay, returns to its idle state. 8. Circuit arrangement according to claim 7, characterized in that a fourth test switch means (H 2) responds by actuation of the third Pi üfschaltmittel (MI) and that the actuation of further memory switch means (Ql to <25) is prevented by the response of the fourth test switch means ( h2I to Ä2X). 9. Circuit arrangement according to claim 8, characterized in that the return of the fourth test switching means in its idle state, the memory switching means (Ql to Q5) are returned to their idle state. 10. Circuit arrangement according to claim 8 and 9, characterized in that the response of the receiving switching means characterizing the post-signal (δIV, dlV, elV) and depending on the actuated first (AVII) and the non-actuated second test switching means (All) the first signal switching means (Y) is pressed. 11. Circuit arrangement according to claim 10, characterized in that a second signal switching means (VH) responds by the actuation of the first signal switching means and that the second signal switching means by the return of the first signal switching means in its retirement also, but with a large and defined delay, in its idle state returns. 12. Circuit arrangement according to claim 11, characterized in that a normally actuated and only with a long and defined delay returning to its idle state control switch means (K) is switched off by the actuation of the second signal switching means. 13. Circuit arrangement according to claim 12, characterized in that a third signal switching means (F) is actuated by the return of the first signal switching means to its idle state and as a function of the control switch still in its working position and the one that is still in its working position located second signal switching means. 14. Circuit arrangement according to claim 13, characterized in that by actuating the third signal switching means, the excitation of the control switching means is switched on again. 15. Circuit arrangement according to claim 14, characterized in that a fourth signal switching means (V2) responds by the actuation of the third signal switching means and that the fourth signal switching means by the return of the third signal switching means in its idle state also, but with a large and defined delay, in its idle state returns. 16. Circuit arrangement according to claim 15, characterized in that the fourth test switching means (H2) returns to its idle state with a delay and that it is actuated by the first (Y) and the fourth signal switching means (V2). Documents considered: German Patent No. 936 879; British Patent Nos. 560 794, 572 002. 1 sheet of drawings © 709 810/57 12.57