DE1234274B - Circuit arrangement for telecommunications, in particular telephone systems, in which characters are transmitted by alternating current pulses - Google Patents

Description

Circuit arrangement for telecommunications, in particular telephone systems, in which characters are transmitted by alternating current pulses The invention relates on a circuit arrangement for telecommunications, in particular telephone systems, in which signs by as periodic, damped oscillations in oscillating circles Generated alternating current pulses transmitted at a specific, single frequency will.

In a known circuit arrangement of this type (German Auslegeschrift 1128 472), an oscillating circuit is closed to generate damped oscillations for signaling, the capacitor of which is charged in preparation and the inductive coil of which has a secondary winding, via which the periodically damped oscillations are coupled to the line. This circuit arrangement has the disadvantage that every periodically damped oscillation transmitted to the line is initiated by switching click pulses. These make the circuit arrangement mentioned unusable for certain applications in which characters can only be formed by periodically damped oscillations of a certain frequency that are free from interference. This is e.g. B. required for telephone lines over which counting pulses are to be transmitted during calls as alternating current pulses lying below the voice frequencies.

Low-pass filters were therefore used in a further known circuit arrangement used, through which all when generating the periodically damped oscillation occurring interference voltages of higher frequencies, z. B. harmonic harmonics, Switch-on clicks and the like, are filtered out, so that only characters with one frequency be sent out below the voice band. This circuit arrangement has the Disadvantage of the expense of a low-pass filter. To improve this known circuit arrangement the vibration generator was carried out in another known circuit arrangement coupled oscillating circuits formed, of which a first one that generates the oscillation, more exciting and a second is a resonant circuit excited by the first, of which from which the vibration is transmitted to the line. These oscillating circles can be differently coupled. In them there is a coupling oscillation known per se generated, which increases to a maximum during a transient process and then sinks again.

The object of the invention is, while avoiding Interference voltages, harmonic waves, switch-on crackling and the like a circuit arrangement indicate which, with savings in filter elements, such as low-pass filters and the like, and a damped oscillation of a more specific one of multiple, coupled oscillating circuits Frequency is generated. This is achieved in that the resonant circuit has a capacitor has, which for the duration of the transmission of characters constantly in a for Emission of the characters provided cable is switched, and that the resonant circuit for the formation of alternating current pulses can be closed in this way via an inductive resistor is that a DC voltage is effective in it when it closes.

An advantage of the invention proceeds from the fact that the mark generating resonant circuit is coupled with its capacitor directly to the cable run 'and is that switching means are saved for coupling.

Another advantage of the invention is that by tapping the symbol voltage on the capacitor increases continuously from the moment it is switched on Voltage curve and, as a result, character current curve is guaranteed.

Another advantage of the invention is that when used commercial switching means a step-like increase in current in the resonant circuit as a result not absolute freedom from attenuation of the inductive resistance, z. B. a relay choke, does not come into effect as an interference voltage.

An advantage according to a further embodiment of the invention lies in the possibility of that different characters by different polarity of the first half-wave each alternating current pulse and / or by different individual frequencies the alternating current pulses.

In the F i g. 1 to 4 are shown in components that only contribute significantly to the understanding of the invention, but to which it is in no way restricted. In FIG. 1 is in extracts a voice connection between two. Participants shown via several connecting links. The devices TU and Tn2 of the two subscribers are connected via subscriber lines TL1 and TL2 and via dial-up links, not shown, to alternating current transmissions Ul and U2 in their dialing offices. The alternating current transmissions, which are also shown only in part, are connected to one another via a trunk line FL. The subscriber lines TL1 and TL2 and the trunk line FL are connected to the transmissions via locking line transformers T1, T2, T3 and T4.

From the alternating current Ul is essentially only the receiving circuit for alternating current pulses, z. B. counting pulses shown, the functionality of which is known per se. The relay Jl speaks through alternating current pulses which, for. B. are received via the trunk line FL, pulsed. The choke Dl and the capacitor C3 act together as a low-pass filter.

From the alternating current transmission U2 , only the components for the generation of damped oscillations are shown, which are transmitted as alternating current pulses. During the idle state and during the pauses separating the pulses to be transmitted, the capacitor Cl is charged in the following circuit: 1. -, Rl, Cl, R2, earth. During the pulses to be transmitted, the contact z of a relay (not shown) is closed. The capacitor Cl is now discharged when the contact z closes via the throttle Dl in the following circuit: 2. Cl, z, Dl, Cl. This discharge process leads to a damped oscillation in the resonant circuit described in circuit 2. The secondary branch running via the transformers T3 and T4 has no influence on the oscillating circuit, in particular no influence on the oscillating frequency. The resistors Rl and R2 of the choke D 1 are highly resistive against the direct current resistance, so that these resistors do not have frequency-determining influence on the closed Schwingk rice.

The capacitor C1 , located in the line of the alternating current transmission U2 and involved in the oscillation process during each pulse to be transmitted, represents a voltage source during the pulses to be transmitted, which causes a symbol current in the form of a periodically damped oscillation of a single frequency in the line. This symbol current pulse is free of cracking noises, since the current in the resonant circuit rises steadily after switching on and the simultaneously occurring S an-Z, ZD p voltage jump at the throttle does not take effect in the line.

In FIG. 2 shows a second exemplary embodiment of the invention. Only the circuits for generating vibrations are shown. The in the F i g. The partial circuit shown in FIG. 2 takes place in one of FIGS. 1 same arrangement application, in that it is switched on with the connection points a and b as well as the switching means Rl, Cl, R2, Dl, z in an alternating current transmission U2 .

At rest and in the. the pauses separating the pulses, only the contact z3 is closed, so that the capacitor C2 is bridged by the resistor R3 and is or remains discharged. To transmit pulses, the contact z3 is opened and the contacts z1 and z2 are closed so that the capacitor is charged in the circuit 3. Earth, z1, C2, z2, D2 , whereby the oscillating circuit mentioned in circuit 3 is excited . The damped oscillation caused in this way is the same as the oscillation described in connection with Fig. 1. The fact that in the case of FIG. 1 , the oscillation caused by a capacitor discharge and in the case of the arrangement described in FIG. 2, the oscillation is initiated by a capacitor charge, has no distinguishing characterizing effect for the oscillations.

As in FIG. 3 is shown, instead of a capacitor charging or discharging, the oscillation can be initiated by a capacitor charge reversal. In the idle state and in the pauses separating the pulses to be transmitted, the capacitor C4 is charged in the following circuit: 4. Earth, R4. z5, C4, z6, R5, -.

To generate the pulses, the contacts z5 and z6 and thereby the circuit 4 are opened. Furthermore, the contacts z4 and z7 are closed, so that the capacitor C4 is reloaded in the following circuit: 5. Earth. z7, C4, z4, D3 , those shown in FIG . The arrangement shown in FIG. 3 takes place in the same way as that in FIG. 2 and is particularly advantageous because of the greater range that can be achieved by doubling the voltage.

In Fig. 4 is of one of the in FIG. 1 the same voice connection shown only an alternating current transmission U3 shown, which z. B. is at the point at which in F i g. 1 the alternating current transmission U2 is located. The alternating current transmission U3 in FIG. 4 fulfills further tasks, namely the transmission of alternating current pulses, which are generated both by an oscillating circuit D4, C5 and by an alternating current generator G n , and also the reception of alternating current pulses by a pulse receiving relay J2. The inductive resistance (choke D4) is both a component of the resonant circuit D4, C5 and a component of the low-pass filter D4, C9 of the receiving circuit.

In the idle state, the circuit according to FIG. 4 ready to receive alternating current pulses which are sent via the long-distance line FL. The AC transmission U3 is sealed off from the lines FL and TL2 by line transformers T5 and T6. Incoming alternating current pulses energize relay J2 in the following circuit: The choke D4 and the capacitor C9 act as a low-pass filter. To transmit alternating current pulses, the alternating voltage source G n can be connected to the line via the connection contacts e2 and e3 of a relay (not shown) with the receiving circuit being disconnected (with the relay J) . This can be done for sending z. B. particularly long alternating current impulses for certain purposes under conditions that allow power clicks and harmonics on the line.

An oscillating circuit can also be formed to emit alternating current pulses. In preparation, the capacitor C5 is charged, as can be seen, via the resistors R8 and R7. The in the F i g. 1 unnamed capacitors of the line transformers T1 and T4 with high-pass properties are shown in FIG . 4 named C6, C7, C8. Three capacitors C5, C6, C7 are provided on the transmission side of the line transformer, two of which, C6, C7, preferably each have twice the capacitance value of the capacitor C8 , so that the high-pass properties of the line transformer T6 are not impaired. The capacitance of the capacitor C5 is relatively large, so that its effect in connection therewith is negligible.

To emit alternating current impulses dampened oscillations accordingly, the following resonant circuit, in which the charged capacitor C5 acts as a driving force, is formed by actuating the contacts z8, z9, zlff, -11 : 7. C5, z9, D4, el, z11, C5. The mode of operation of the relatively high-resistance resistors R7 and R8, via which the capacitor C5 is charged during the pauses that separate the pulses, can be neglected with regard to the oscillation process and is not considered here. Likewise, as shown in FIGS. 2 and 3 is shown, the switching principle of the resonant circuit can be implemented in a modified form. An alternating current pulse is transmitted to the long-distance line FL by the alternating voltage that occurs across the capacitor C5 and corresponds to a damped oscillation. The capacitors C6 and C7 act as alternating current resistors, through which the line alternating current and thus also the damping of the resonant circuit described in circuit 7 is limited.

A particular advantage of the in F i g. 4 is the double use of the throttle D4, in that it is part of both the low-pass filter and the resonant circuit.

Another advantage of the in FIG. The arrangements shown in 4 are the improved symmetry relationships for the speech lines.

Claims (2)

Claims: 1. Circuit arrangement for telecommunications, in particular telephone systems, in which characters are transmitted by alternating current pulses of a specific, single frequency generated as periodic, damped oscillations in oscillating circuits, characterized in that the oscillating circuit has a capacitor (C1, C2, C4, C5) , which during the duration of the transmission of characters is constantly connected to a line (L) provided for the transmission of the characters, and that the oscillating circuit for the formation of alternating current pulses via an inductive resistor (D1, D2, D3, D4) can be closed in such a way that a DC voltage is effective in it when it is closed. 2. Circuit arrangement according to claim 1, characterized in that the capacitor (C1, C5) in the line (L, T6) for vibration-free charging via resistors (R1, R2, R7, R8) to a DC voltage source during the breaks separating the alternating current pulses (+, -) is turned on and that the inductive resistor (D1, D4) can be connected to the capacitor (C1, CS) during the alternating current pulses to be generated by means of end-of-character contacts (z, zl, z11) . 3. Circuit arrangement according to claim 1, characterized in that the capacitor (C2) in the line (L) for vibration-free, during the pauses separating the alternating current pulses discharging is short-circuited via a resistor (R3) and during the alternating current pulses to be generated via an inductive resistor (D2) can be connected to a DC voltage source. 4. Circuit arrangement according to claim 1, characterized in that the capacitor (C4) in the line (L) for vibration-free charging via resistors (R4, R5) during the pauses separating the alternating current pulses is connected to a direct voltage source (+, -) and by means of signal transmission contacts (z4, z7) via an inductive resistor (D3) to preferably the same direct voltage source (+, -) with opposite polarity. 5. Circuit arrangement according to claim 1, characterized in that different characters are marked by a certain polarity of the first half-wave of each alternating current pulse. 6. Circuit arrangement according to claim 1, characterized in that different characters are marked by corresponding frequencies of the alternating current pulses that are individually assigned to them. 7. Circuit arrangement according to claim 1, characterized in that the inductive resistor (D4) can be switched as part of both the resonant circuit of the transmitting circuit and the low-pass filter of a receiving circuit. 8. Circuit arrangement according to claim 1, characterized in that the capacitor (C5) is connected symmetrically between the windings of a line transformer. Considered publications: in German patent application T 7370 VIIIa / 21a3 (published April 7 , 1955).