DE740481C - Circuit arrangement for tone frequency selection in telecommunications systems - Google Patents

Description

Circuit arrangement for tone dialing in telecommunications systems subject of the invention is - a circuit arrangement for Tonfrequenzfernwahl in telecommunications equipment, in which .the number impulse response and the control of the connection setup is effected by 'aufeinanderfölgende current pulses of different frequencies.

The following must be observed with this procedure; z..the distortion of the alternating current surge caused by the switch-on and switch-off processes.

_ z. The influence of unauthorized power surges on the receiver, both external and speech surges, which can lead to faulty signals: The known methods for audio frequency remote dialing in telecommunications systems see the posting of signals with the help of alternating current surges of a certain frequency, whereby . The device receiving the transmitted signals is provided with a band filter is that only allows currents of a certain frequency to pass. Be that way in most cases false signals avoided because it is unlikely that the speech stream could contain a pure frequency that corresponds to the frequency of the dispatched Signal would correspond. Other facilities to achieve a greater likelihood In addition, to avoid false signals, use signal streams of a specific Frequency, but of a precisely defined duration. Neither are institutions more new in which the sent signal is made by combining several at the same time dispatched alternating current surges of different frequencies is determined.

To significantly reduce the likelihood of errors and Shortening the duration of all signals as much as possible is based on the basic idea the invention proposed a device whose Beings in it insists that each character is determined both by the order of its replacement of the impulse of one frequency: by the impulse of another frequency as well as the duration of the individual power surges, which are repeated several times can.

As the simplest application example of the invention, the one in the enclosed Drawing schematically shown system from the field of long-distance dialing telephony to serve.

Fig. I shows the transmitting part of the system, Fig. 2 the receiving part and FIG. 3 shows a variant of the system according to FIG.

Between terminals i and 2 (strips III and IV) of the system according to FIG. 1 and the terminals of the system according to FIG. 2, also labeled, are a long-distance line switched on, which can be equipped with amplifiers. Between the terminals i and 2 of the receiver part (strips IX and K in Fig. 2) becomes a self-connecting center switched on.

Two frequencies are provided for sending the signals, namely 5oo p; s and iooo p / s. With the help of these frequencies, two signals are sent: the call signal and the end signal, each of which consists of three power surges consists.

The sequence of the call signal differs from the end signal the frequency of the power surges sent and the different duration of each Power surges.

The times of attraction and dropout of the individual relays are determined as follows. - The times are given in ms (milliseconds), where + denotes the tightening, - the falling. The times of attraction and release of the relays RN and RH are specified taking into account the settling time of the filter.

The system works in the following way: the calling subscriber Tfa comes from: the self-connection technology known voting organs _AS (call seeker), SJ (cord pulse relay), SK (cord control relay), SZ (cord test relay), LZl '(line selector) to the remote transmission, in which the following circuit closes: i. (Fig. I) ... plus contact SKa relay SL contact arm; contact of the line selector LW relay TC i and parallel resistor t- i-minus.

The relays SZ and TC i respond, and contact TC ia closes the circuit 2. (Fig. I) ... plus relay TO and parallel resistor r-2 contact TC ia contact TP id-minus.

The relay T0 responds and switches the high-frequency generator to the line to the receiver in the following circuit through the contacts TOa and TOc: 3. (Fig. I) ... Terminal GHi of the high-frequency generator contact TJ3b-IiontaktTOa-terminal i (strips III and IV ) Remote line (Fig. 2) Receiver hR-back, # - Terminal (strip 11I and IV contact TQc contact TJ3d = terminal GH2 of the high-frequency generator.

The high-frequency current surge is sent on the line to the receiver (Fig. 2). Simultaneously with: the circuit 2 «- earth the following circuits closed: q .. (Fig. I) ... plus relay TC2 and parallel resistor r3 - contact TC ic resistor r4 contact TP ic minus. "5. (Fig. I) ... plus self-induction Sf i relay TPi contact TC i b-minus.

The relay TC2 responds and closes the circuit through the contact TC2a: 6. (Fig. I) ... plus relay TJ3 and parallel resistor r8-resistor r7-contact TC2a-minus.

After 20 ms from the moment of closing of the circuit 6, i.e. after 3o ins from the beginning: the transmission of the high-frequency r_-current impulse, the relay TJ3 responds, interrupts the circuit 3 and closes the circuit 7. (Fig. I) . .. Terminal GN i of the low frequency generator - contact TJ 3a - contact TQa-terminal i (strips 111 and IV) -through long-distance line (Fig.2) back-terminal 2 (strips III and IV) -contact TQc-contact TJ 3c -Terminal GN2 of the low frequency generator. The high-frequency surge is thus ended and the low-frequency surge begins to be sent; this lasts until the relay TJ3 drops out.

In the meantime, the following processes occur: after 60 ms from the moment the circuit 5 closes, i.e. after 2oms from the start of the transmission of the low-frequency current surge, the relay TPi responds and through the contact TPia briefly closes the self-induction Sii in the circuit 5, interrupted by the Contact TPic the circuit 4 of the relay TC- and through the contact TPid the circuit z of the relay TO. The relay TC2 drops out and interrupts the circuit 6 of the relay TJ3 through the contact TC2a. The relay TJ3 drops out, interrupts the circuit 7 and again closes the circuit 3.

This will (end and begin the low frequency surge sending the next high frequency surge.

With your moment of response of the RelaisTPi. Contact TPib closes circuit B. (Fig. i) ... plus self-induction Si2 relay.TP2 contact TP i b-minus.

The relay TP2 responds, closes the self-induction through the contact TP2a It shorts and closes the circuit through contact TP2c: 9. (Fig. I). . plusupper Winding of the relay TJi contact and contact arm a of the line selector LW-Koptakt SLa self induction Si4 contact SYes --- contact SLb contact arm and contact .des Line selector LW lower winding of the relay TJi contact TP2c-minus.

The relay TJi responds and closes the following circuits: i o. (Fig. I) ... plus relay TI contact TJia-minus.

. i i. (Fig. I) ... plus relay TJ 2 and parallel resistance 6 resistance r5 contact TJic minus.

The relays TK and TJ 2 respond, and contact TJ2a closes the circuit i2. (Fig. I) ... plus relay TJ3 and parallel resistor r8-resistor r7-contact Ti 2a-minus.

After i - o ms from the moment of interruption by the contact TPid of circuit 2, i.e. after ioms from the moment of response of the relay TJi according to circuit 9, the relay TO drops out; - as a result, the transmission of the 8o ms lasting high-frequency current surges interrupted. The transmission of the audio frequency surges stops. The following relays - continue to work: SJ, SK, EL, TCi, TJi, TK, TJ2, TJ3, TPi, TP2. As can be seen from the courses described, the call signal consisting of a sequence of high, low and high frequency current surges was sent; the duration of the individual power surges was: 30 ms, 6o ms, 8o ms.

These surges pass through the trunk line to the receive transmission (Fig. 2); There they can be amplified by the amplifier KR and come to the receiving relay RA, which responds to currents of any frequency, and to the receiving relay RN, which is switched on by the band filter FN and is therefore only operated by low-frequency currents; they also come to the relay, RH, which is switched on by the band filter FH and is therefore only operated by high-frequency currents.

Relays RA and IZH respond under the influence of the first high-frequency current surge to the receiver. Contact RAa closes the following circuit: 13. (Fig.2) ... plus upper winding of relay RT and parallel resistor rio -resistor r9-contact RAa-minus.

After 20 ms from the moment the high-frequency current surge appeared, relay RH responds and closes through contact RHb. following circuit: 14- (Fig. 2) ... plus lower winding of the relay RT contact R.4b contact RTc contact RHb-minus.

Through the windings of the relay RT , the current flows in opposite directions; as a result, this relay does not respond in the given case.

This forms the criterion that it really is about the correct signal current surge. if it were an unauthorized current of a different frequency, neither the relay RN nor RH would respond; the circuit 14 would not be formed, and after 30 ms from the moment or formation of the circuit 13, i.e. 40 ms from the moment the unauthorized current surge arrives, RT will respond; sufficient conditions are thereby created so that the receiver is not actuated by this unauthorized power surge. If, on the other hand, the legitimate high-frequency current surge occurs, contact RHa closes the following circuit: 1 5. (Fig. 2) ... : plus contact RTb relay RP contact ROb contact RHa contact RNb-minus.

The relay RP responds and closes through the contact RPa holding circuit operated by the next surge of the call signal.

16. (Fig. 2) ... plus contact RTb relay RP contact RPa contact RHb or contact RNc-minus. The opening of the contact RPc prevents the response of the relay RQ when the low-frequency current surge flows through the Call alert.

After the end of the high-frequency current surge and the beginning of the low-frequency current surge, the relay RH drops out, the relay RN responds and closes the following circuit through the contact RAra: 17- (Fig. 2) ... plus relay RTl i-contact RPd-contact RNa-minus.

After the end of the low-frequency current surge and the start of the next high-frequency current surge, the relay RN drops out, the relay RH responds and closes the following circuit 1 8 through the contact RHd (Fig. 2) ... plus-Kbntakt RSb relay RK contact RTI ia contact RPb contact RHd-niinus.

The relay Rk responds and closes its through the contact Rlia Holding circuit.

i9. (Fig. 2) ... plus contact RSb relay RK contact RKa contact RHc or contact RNd-minus.

Furthermore, through the contact RKb, the loop to the called Headquarters closed and this causes the occupancy of the same.

2o. (Fig. 2) ... Terminal i (IX and X) self-induction Sis contact RKb contact RQe or contact RHg terminals 2 (IX and X).

After 10 ms from the moment the last current impulse of the call signal is terminated, the relay RA drops out, after 20 ms RH drops out, after 140 ms - RV i, after 220 ms - RP. The relay RK is active according to circuit i9 during the whole time until the final signal is effected.

The desired center sends the official signal; during this transmission, the relay RA responds; the circuit 13 is formed and the relay RT responds; neither the relay RP nor RQ can respond because the opening of the contacts RTa and RTb switches off the positive pole. -After the official signal has faded, the caller can dial; if the digit one is sent, the relay SJ (Fig. i) drops out for 60 ms. The circuit 9 is interrupted for a period of 60 ms by the contact SJca. The relay TI i drops out and closes the following circuit through the contact TI i b: a1. (Fig. I) ... plus relay TQ and parallel resistor r2 contact TKa contact TI i b-minus.

The relay TQ responds and switches the low frequency generator on the long-distance line I according to circuit 7; as a result, the Low frequency current surge.

Simultaneously with the closing of the circuit 21, the circuit ii of the relay TJ2 is interrupted by the contact 7J ic; this decreases and- interrupts by the contact TJ2a, the circuit 12 of the relay TJ 3. After 20 ms from the moment of interruption of the circuit 12, ie, after 30 ms from the moment when the transmission starts of the low frequency current pulse, the relay TJ3 drops interrupts the circuit 7 and closes the circuit 3. As a result, the low-frequency pulse is ended and the transmission of the high-frequency pulse begins.

After 10 ms from the moment when the high frequency current surge was sent begins, speaks as a result of the closing of the impulse-generating contacts of the number washer of the calling party to the relay ST and closes through the contact SJa Circuit 9 of relay TJ i. The relay TJ i responds and closes through the Contacts TI ia, TJ ic turn the circuits i o, i i of the relays TK, TJ2 and interrupts through the contact TJ ib the circuit 2i of the relay TQ. The relay TJ2 speaks and closes the circuit 12 of the relay TJ3 through the contact TJ2a.

After 20 ms from the moment the circuit 12 closes, that is after 60 ms from the moment when the high-frequency current surge begins to be sent, if the relay TJ3 responds, interrupts the circuit 3 and closes the again Circuit 7. As a result, the high frequency surge stops and the transmission stops of the low frequency current surge begins.

After 120 ms from the moment the circuit 2i was interrupted, So after 80 ms from the moment when the low-frequency current surge begins to be sent, the relay TQ drops out and interrupts the circuit through the contacts TQa, TQc 7; as a result, the transmission of the low frequency tronis stops.

The dialing of the number one by the calling subscriber causes the sending of the three subsequent power surges from the transmitting apparatus (Fig. I) to the receiving apparatus (Fig. 2): the low-frequency current surge of a duration of 30 ms, the high-frequency current surge of a duration of 60 ms and the low frequency current surge of a duration of 80 ms.

Under the influence of the first low-frequency current surge, relays RA, RX respond in the receiver apparatus (Fig. 2), and contact RNe closes the following circuit: 22, (Fig. 2) ... plus contact RTa relay RQ- and parallel Resistance ri i-contact RPc-contact RHe-contact RNe-minus.

The relay RQ responds, prevents the possible closing of the circuit of the relay RP by opening the contact RQb and remains in the following circuit via the contact RQa during further current surges .23. (Fig. 2) ... plus contact RTc relay RQ and parallel resistor ri i contact RQa contact RNc or contact RHb-minus.

After the end of the low frequency surge and the start of the high frequency surge If the relay RN drops out, the relay RH responds and breaks through the contact RHg the circuit 20; since the relay RQ is picked up, the loop becomes the called one Central interrupted.

After the end of the high-frequency current surge, the transmission of the next low frequency current surge, the relay RH drops out and through the contact RHg the loop that corresponds to the duration of the high frequency current surge Time, d. H. was interrupted during 6o ms, closes again.

Forward after i o ms. Moment of termination of the low frequency power surge the relay RA drops out, after 20 ms: the relay RN, after which the relay after Zoo ms. RQ drops.

If not., The digit one but, for example, the digit two is sent, the signal would be formed as follows: low-frequency current surge 30 ms, high-frequency current surge 60 ms, low-frequency current surge qo ms, high-frequency current surge 60 ms, low-frequency current surge 80 ms.

Accordingly, the loop becomes twice as long for the duration of the high-frequency current surge interrupted.

The closing signal in the example given is given at the moment in which the calling subscriber hangs up the receiver; this causes a break in the loop on the part of the calling party; As a result, the relay "SI drops out and interrupts the circuit 9 of the relay TI i through the contact STca and the circuit of the relay SK through the contact SJb. The relay TI i drops out and interrupts the circuit io of the relay TK through the contact TI ia , through the contact TI ic the circuit ii of the relay TI 2-; through the contact TI rb it closes the circuit 21 of the relay TQ. The relay TQ responds and closes the circuit 7 of the low-frequency generator through the contacts TQa, TQc; as a result When the circuit ii is interrupted: the relay TI2 releases and through the contact TI2a interrupts the circuit 12 of the relay TJ3. After 20 ms from the moment of interruption: of the circuit 12, i.e. after. 30 ms from the moment in which the transmission of the low frequency rush current starts, the relay TJ3 drops out, interrupts the circuit 7 and closes the circuit 3 of the high frequency generator he ends the low frequency surge and it starts sending the high frequency surge. e Simultaneously with the closing of the circuit 21 of the relay TQ, the contact TI id closes the following circuit: 2q .. '(Fig. i) ... plus relay TB self-induction Si3 contact Mb contact TJidminus.

The relay TB responds and closes the circuits: 25. (Fig. I) ... plus relay TB contact TBa contact TP 2b-minus.

26. (Fig. I) ... plus relay TQ and parallel resistor r2 contact TBc contact TP ib -minus.

27. (Fig. Z) ... plus relay TJ3 and parallel resistor r 8-Wi: resistor r7 contact TBb-minus.

After 20 ms from the moment the circuit 27 is closed, that is after 130 ms from the moment when the high-frequency current surge begins to be sent, if the relay TJ3 responds, it switches the high-frequency generator from the long-distance line and switches on the low frequency generator. As a result, the 130 msec will last The high frequency surge stops and the low frequency surge begins sending.

After 20 ms from the moment when the low-frequency surge began to be sent. the relay SK, which operates with a delayed effect, drops out, the circuit of the same is interrupted by the contact SJa, and the relays SZ, TC i, TP i, TQ, TP2, TB and TJ3 drop out one after the other. When the relay TQ drops out, the circuit 7 is interrupted; as a result, the transmission of the low frequency rush current is stopped.

Then the final signal is ended, this consists of three following Current surges: from the low frequency current surge with a duration of 30 ms, from which High-frequency surge with a duration of 130 ms and from the low-frequency surge of a duration of 340 ms.

The first low frequency surge, lasting 30 ms, causes the same processes in the receiver equipment (Fig. 2) as the first low frequency surge during dialing, ie relays RA and RX are energized and contact R.Ll # Te closes the circuit 22 of relay R0.

In front of the high-frequency current surge, the relay RH picks up for a period of 1 30 ms and interrupts the loop to the called center through the contact RHg; after 130 ms the high-frequency current surge is ended, the relay RH drops out and the loop is closed. In addition, contact RHf completes the following circuit: 28. (Fig. 2). . . plus self-induction Si 6 relay RV2 contact ROd contact RHfminus.

The extension of the high-frequency current impulse to 13o-ms causes the relay RV2 to respond; this does not pick up during dialing if the high frequency surge is only 60 ms. Contact RV2C closes the holding circuit: 29. (Fig. -2) ... plus contact Rh2a contact RV: 2c contact RNg-minus.

Under the influence of the next low-frequency current surge, that speaks Relay NN on and closes the circuit: 30. (Fig. 2). .. plus self-induction -Si 7 relay RS contact RL'2b contact ROc contact RiVf-minus.

If the low frequency surge is long enough, the relay speaks RS on, shorts and breaks the self-induction S 'i7 through the contact RSa through the contact RSb the circuit 18 of the relay RK.

According to Zoo ms from the moment of interruption of the circuit 18, i.e. 530 ms after receiving the first low-frequency current surge of the final signal in the receiver apparatus, the relay Rk drops out and finally interrupts the loop to the called center through the contact RKb, thereby causing the separation.

20 ms after the last low-frequency impulse has ended, relay RN drops out and interrupts circuits -22, 29, 30 through contacts RNc, RNe, RNf, RNg.

Zoo ms after the relay RN has dropped out, ie 720 ms after receiving the first low-frequency current surge of the final signal, the relays RQ, RV2, RS drop out, ie all the relays of the receiver equipment return to their idle state.

The frequency searcher formed in the embodiment according to FIG. 2 from all relays RA, RT, RN and RH controls that signal frequency currents are present during signaling and that an absence of these currents does not last longer than 30 to 40 ms. In this way there is assurance that the speech streams will not actuate the receiver. In addition, the frequency finder can be used to save the filters, namely a single filter according to FIG. 3 can be used instead of the two special filters FN and FH. The same is switched over by the changeover relay RU through the contact RT'd from adaptation to low frequency to adaptation to high frequency; At the same time as this adjustment, the switchover to one or the other receiving relay is effected by the relay RU.

For example, if a low frequency power surge arrives, speak the relay RA on; the filter FLt is at the low frequency when the relay RU has dropped out adapted, the relay RN responds and interrupts the contact RNla, so that the Relay RZ: T in your circuits 3r. (Fig. 3) ... plus the upper winding of the relay SU contact SAC contact RNhminus cannot respond.

If, however, a high frequency current surge arrives, the relay will RU respond in the circuit 31; the filter is adapted to the high frequency; the relay RH responds and breaks the contact RHh, so that the circuit: 32. (Fg.3) ... plus lower winding of relay SU contact RUa contact RHhminus only is closed so briefly that the relay HU does not drop out due to counter-excitation and continues to be attracted according to the circuits 3 i.

If the low frequency comes back after the high frequency, the relay RH drops out. The relay RLT is demagnetized in circuit 32, drops out and adapts the filter to the low frequency; If this frequency is available, the relay RU remains de-1 dropped; if this frequency is not there, the relay RL 'oscillates and seeks whether one of the specific frequencies is not available. The corresponding speed of oscillation of this relay can be determined by known means, e.g. E. by means of a flywheel on which relay anchors are achieved.

Claims (1)

PATENT CLAIMS: e.g. Circuit arrangement for telephone frequency remote dialing in telecommunications systems, in which the number current impulse and the control of the connection establishment are effected by successive current impulses of different frequencies, characterized in that each character is determined by the sequence in which the current impulse from one frequency is replaced by a current impulse of another frequency and by the relative duration this individual audio frequency current surges is determined. z. Circuit arrangement according to Claim 1, characterized in that the receiver has a frequency finder which is actuated by a current impulse of any frequency and which causes the receiver to be actuated in a certain time only by current impulses of a certain frequency and by the current impulses of others Frequency (in the filter permeability range) is only activated when the current surge of the previous frequency has dropped below the sensitivity limit of the receiver, regardless of the time of the start of the current surge of this second frequency. 3. A circuit arrangement according to claims 1 and z,. Characterized in that, the receiver has a filter; whose permeability range is changed by the frequency finder in accordance with the incoming current impulses of different frequencies and adapted to the frequency corresponding to the current impulse. 4. Circuit arrangement according to Claims 1, 2 and 3, characterized in that the adaptation of the filter to a new current surge from another frequency coming in the sequence is only effected when the previous current surge has fallen below the sensitivity limits of the receiver. To distinguish the subject matter of the application from the prior art, the following were considered in the grant procedure: German patent specification No. 48o 8i9, 555 951, 592 763 British patent specification No. 326 570,326 571; American Patent No. f 383 750; Special Print: The Standard Four-Frequency Remote Dialing System, issued by International Standard Electric Corporation, 193o.