DE3616488A1 - Subscriber circuit for a domestic telephone system - Google Patents

Abstract

Subscriber circuits for a domestic telephone system do not need to perform all the tasks defined by the so-called BORSCHT functions. The AC ringing current, DC feed current and audible tones are often supplied asymmetrically, and detection and evaluation means are provided in the subscriber circuit to identify loop closure. To reduce circuit cost, a voltage regulator with a pulsed load resistor is provided in the subscriber circuit to supply the DC feed current and audible tones and to identify loop closure, and the AC ringing current is supplied by means of a TRIAC. The loop signal is fed to a control device and a ringing disablement device and evaluated in the control device for ringing disablement. Automatic ringing disablement when the handset is taken off-hook in the subscriber device is achieved by combining the loop signal and the ringing enablement signal in the ringing disablement device.

Description

The invention relates to a subscriber circuit for a Home telephone system with the features of the generic term of Claim 1.

The tasks of subscriber circuits (also called subscriber substitution) arranged between subscriber facilities and the subscriber exchange are known under the keyword BORSCHT functions. The individual letters of the keyword BORSCHT stand for the following functions:
battery, ie feeding the subscriber equipment
overvoltage protection, ie protection of the subscriber device against external voltages
ringing, ie calling the subscriber facility
signaling, that is to say, on the subscriber line between the subscriber exchange and the subscriber device
coding, ie method for source coding of an analog voice signal (switching system with digital switching)
hybrid, ie separation of the two transmission directions of a full duplex connection on a two-wire subscriber line
testing, ie manual or automatic testing of the subscriber line system and the subscriber equipment from the subscriber exchange.

In Unterrichtsblätter, 1982, No. 2, pages 55 to 66 different embodiments for a home telephone system described. The power supply of a home telephone system takes place from the AC network. To control the home a microprocessor is provided, which among other things, that was done by a caller ID Detection of the alternating call current on the outside line evaluates which produces audible tones and this constant current sources modulated, etc. (see in particular page 59). The DC supply voltage is separated for each subscriber facility through those already mentioned Constant current sources and the switching of the outside call AC is controlled by the microprocessor.

The tasks of the discretely constructed subscriber circuit are the supply of such a home telephone system Subscriber facility, loop signal detection and the call alternating current feed. From Electrical After Richterwesen, 1983, No. 2, pages 193 to 197 is one small private branch exchange known, which also one Microprocessor, a switching matrix, subscriber sets and one Power supply and a. having. The microprocessor is used u. a. to recognize the loop status and the call circuit (see page 194), for feeding the participants device and for loop signal detection uses an unbalanced constant current source and for the supply direct current or call alternating current feed becomes a current connected to the AC network supply used (see page 196).

The aforementioned subscriber circuits require one high circuit complexity, especially for equal meals power and audio tone feed as well as for the detection and evaluation means for detecting loop closure.

The invention has for its object a part to be switched on for a home telephone system give that for the AC, DC supply and audio input and for the detection of Loop closure requires little circuitry is.

This task is accomplished according to the invention by a participant circuit with the features of claim 1 solved.

A triac must be provided for the supply of AC alternating current per se from DE-OS 27 42 677 or DE-OS 28 01 372 known. Furthermore is made of semiconductor circuit technology by U. Tietze et al, Springer-Verlag Berlin, 1971, pages 205 to 206 the keying of constant voltage sources known. By using Triac and integrated voltage regulator (e.g. TDB 7800 from Siemens) can the subscriber circuit inexpensive and with low circuitry can be built.

Preferred embodiments of the invention are in the Subclaims specified.

The invention is based on one in the Drawing shown embodiment described in more detail and explained. It shows

Fig. 1 shows an embodiment of the subscriber circuit according to the invention and

Fig. 2 shows the time course of the voltage at the input and at the output of the voltage regulator.

In Fig. 1, a home telephone system is provided with the facilities required for understanding the invention. The home telephone system has a switching matrix KF , a power supply StrV , a control device ST , subscriber circuits TS , subscriber lines TL and subscriber devices TE . In the subscriber circuit TS a call alternating current feed RE , an audible tone feed HE , a feed direct current feed SE and a call switch-off device RA are arranged.

A protective diode D 1 is arranged in the supply direct current feed SE , the anode of which is connected to the subscriber line TL and the cathode of which is connected to an input of a voltage regulator SR . Furthermore, a DC voltage source SQ is arranged in the DC feed-in supply SE , the positive terminal of which is connected to the subscriber line TL and the negative terminal of which is connected to ground. A Zener diode D 2 connected to the cathode of the protection diode D 1 protects the voltage regulator SR from high voltage when the call is switched on and the subscriber device TE is short-circuited. This Zener diode can be omitted if the voltage regulator SR is sufficiently voltage-resistant (dashed line in FIG. 2).

In the audio input HE a switching transistor T 2 is arranged, the base connection of a key signal H is supplied to the control device ST , the collector connection to which is connected to a first connection of a first resistor R 2 and whose emitter connection is connected to ground . The second connection of the first resistor R 2 is connected to a first connection of a second resistor R 3 , the second connection of which is connected to ground. The common connection of the two resistors R 2 and R 3 is connected both to the output of the voltage regulator SR and to supplying a loop signal S to the control device ST and the call switch-off device RA with these devices.

In the call switch-off device RA , a NOR gate NOR is arranged, at the one input of which a call switch-on signal R generated by the control device ST is present.

The loop signal S already mentioned is fed to the second input of the NOR gate NOR . The output of the NOR gate NOR is connected to the base of a transistor T 1 arranged in the call switching device RA . The emitter terminal of the transistor T 1 is grounded and the collector terminal of the transistor T 1 is connected to a first terminal of a capacitor C 1 arranged in the call switch-off device RA . At the second connection of the capacitor C 1 , the call AC feed RE is connected.

A resistor R 1 is arranged in the call alternating current feed RE , the first connection of which is connected both to the gate of the TRIAC TR and to the second connection of the capacitor C 1 arranged in the call cut-off device RA . Both the main current path of the TRIAC TR and the power supply StrV are connected to the second connection of the resistor R 1 .

Furthermore, a coupling capacitor C 2 is provided in the subscriber circuit TS , the first connection of which is connected both to the main current path of the TRIAC TR and to the switching matrix KF and to the second connection of which one wire of the subscriber line TL is connected.

The mode of operation of the subscriber circuit according to the invention is described and explained in more detail below. A commercially available integrated voltage regulator of the type TDB 7800 with only three connections is arranged in the SE direct-current feed. This controller has internal thermal overload protection, short-circuit current limitation, protection of the output transistor and an internally generated reference voltage. Such an integrated voltage regulator SR supplies a constant voltage at the output which is independent of the input voltage supplied via the protective diode D 1 . When under load, the current consumption of the integrated voltage regulator SR is only dependent on the load within the (slight) fluctuations of the own current consumption of the integrated voltage regulator. If the load is changed rhythmically, in particular by connecting the first and second resistors R 2 , R 3 in parallel, a tone is heard in an acoustic transducer. To generate different tones, the control device ST is provided in connection with the switching transistor T 2 in the subscriber circuit TS according to the invention, the pulse sequence of the key signal H determining the tone frequency.

The integrated voltage regulator SR only delivers a constant voltage at the output if there is a voltage with a higher potential at the input. This voltage is switched on by means of a fork switch contact GU arranged in the device TE and a loop direct current determined by the load flows through the loop thus closed.

In Fig. 2 the time course of the voltage at the input and at the output SE or SA of the voltage regulator SR is shown when the fork switch contact GU is closed when the call is switched on. The subscriber lifts, ie the hookswitch GU is closed so appears at the output of the voltage regulator SR instead of a pulse train of a continuous pulse and by temporal Be this voltage rating in the control device ST, the Rufeinschalt generated by the control device ST signal R is switched off again.

The TRIAC TR arranged in the call alternating current feed RE is ignited when the transistor T 1 connects the capacitor C 1 to ground and a voltage which is phase-shifted with respect to the voltage at the cathode is thus present at the gate. The TRIAC TR is DC-separated from the subscriber line TL by the coupling capacitor C 2 , since otherwise the TRIAC TR cannot be deleted again when the subscriber is lifted by the subscriber and the loop direct current flowing in the process. If the TRIAC TR is extinguished during the zero crossing of the call alternating voltage and a voltage is still present at the output of the controller SR , the subscriber has lifted the handset.

The coupling capacitor C 2 is used in addition to the ringing AC supply also for coupling in and out the speech signal.

The permissible input voltages for the coupling points arranged in the switching matrix KF and the voltage regulator SR must be greater than the maximum voltage resulting from the superimposition of the DC supply voltage (from the DC voltage source SQ) and the AC signal voltage (from the StrV power supply ) when the handset is removed by the subscriber. Since the integrated voltage regulator SR is destroyed by voltages with a negative potential, the protective diode D 1 is provided.

Claims (6)

1. subscriber circuit for a home telephone system with asymmetrical ringing AC, DC and Hörton-feed into the subscriber line and with detection and evaluation means for detecting loop closure, characterized in that for DC and Hörton feed (SE, HE) and To detect the end of the loop, a voltage regulator (SR) with a sensed load resistor (HE) is provided, a TRIAC (TR) is provided for the ringing alternating current feed (RE) and that direct current and audio signal feed (SE, TE) and ringing alternating current feed are provided (RE) are connected to each other via a call switch-off device (RA) connected to a control device (ST) . 2. Subscriber circuit according to claim 1, characterized in that in the DC feed-in solution (SE) a protective diode (D 1 ) whose anode is connected to the subscriber line (TL) and whose cathode is connected to an input of the voltage regulator (SR) , and one with the subscriber line (TL) and ground connected DC voltage source (SQ) are arranged. 3. Subscriber circuit according to claim 1 and 2, characterized in that a switching transistor (T 2 ) is arranged in the audio tone feed (HE) , the base connection to a key signal (H) of the control device (ST) is supplied, the Collector connection with a first connection of a first resistor (R 2 ) is the and whose emitter connection is connected to ground, that the second connection of the first resistor (R 2 ) is connected to a first connection of a second resistor (R 3 ) , whose second connection is to ground and that the common connection of the two resistors (R 2 , R 3 ) both with the output of the voltage regulator (SR) and for supplying a loop signal (S) to the control device (ST) and to the call switch-off direction (RA) with these facilities (ST, RA) is connected. 4. Subscriber circuit according to claim 1, characterized in that a NOR gate (NOR) is arranged in the call switch-off device (RA) , one input of which is generated by the control device (ST) Rufein switching signal (R) and the latter Output is connected to the base of a transistor (T 1 ), that the emitter terminal is connected to ground and the collector gate terminal is connected to a first terminal of a capacitor (C 1 ), the second terminal of which is connected to the alternating current feed ( RE) is connected. 5. Subscriber circuit according to claim 1 and 4, characterized in that a resistor (R 1 ) is arranged in the ringing alternating current feed (RE) , the first connection of which is connected both to the gate of the TRIACs (TR) and to the second connection of the in the call switch-off device (RA) arranged capacitor (C 1 ) is connected and its second connection is connected to both the main current path of the TRIACs (TR) and a power supply (StrV) . 6. Subscriber circuit according to claim 1, characterized in that both the main current path of the TRIACs (TR) and a switching matrix ( KF) with a first connection to a coupling capacitor (C 2 ) are connected, the second connection to the subscriber line (TL) connected is.