DE4120995C1 - 16 KHz telephone metering pulses supply circuitry - uses transistor of opto-coupler followed by monoflop transistor to derive pulses from exchange meter to operate tariff meter at calling subscriber's appts. - Google Patents

Abstract

The circuitry feeding 16 kHz rated charge pulses to subscriber lines (T1n-A1) includes a controlled a.c. voltage amplifier (V) connected on the input side, via a coupling capacitor (C1), to a central a.c. voltage generator (G) and, on the output (load-) side, inductively via a bandpass filter (BP) to a subscriber line (T1n-A1), which includes a network-side 16kH3 blocking circuit (BSp). The rated charge count pulses are scanned by a scanning circuit formed by the four-pole network protection diode (D4), the current limiting and response threshold resistor (R6) and the optocoupler (OK) diode bridged by a response delay capacitor (C3). ADVANTAGE - Suitable for any type of telephone exchange including older models and plan numbers.

Description

The invention relates to a circuit arrangement for feeding of 16 kHz charge pulses on subscriber lines for Subscriber location in telephone switching systems. The 16 kHz fee impulses are from the DC counts arriving at the call counter in office derived. Be without interfering with the ongoing conversation according to the value of the conversation counts on the Subscriber lines that transmit a charge display enable the calling subscriber at the subscriber location.

A circuit arrangement is known (EP-02 06 279 B1), where the 16 kHz charge pulses over a bandpass inductively from a transformer to the subscriber line be transmitted. To a central AC voltage source with Voltage doubler circuit is used to control the control input of the MOSFET switch connected with an RC parallel element a current source circuit for switching the AC voltage interposed by a the pulse generator downstream level adjustment circuit is controllable.

The disadvantage is that the 16 kHz generator is the full to be switched Power must be exerted, so that only a limited number can be switched on from subscriber lines. The Use of this pulse clock to determine which to switch Duration of the 16 kHz charge pulses is in use the combination with older telephone switching systems (pp. 20-50; pp. 56/58; ATZ-63/64) is no longer sufficient in every case because tolerance and system possible shorter 16 kHz pulses and with insensitive receiving circuits no longer in everyone  If a charge pulse is displayed at the subscriber station and thus an admissible false indication can be brought about.

The object of the invention is to find a circuit arrangement which allows it, regardless of the system-related form of origin of the charge pulse this into such a predetermined To transform pulse duration as an AC pulse, in particular a safe and clear one even with older systems system-dependent charge pulse display at each subscriber station is guaranteed.

This is without logic modules with the otherwise required additional voltage source with minimal additional component expenditure to solve. The sampling circuit for the DC counts should be at the lowest Designed effort and universal only with a small change be applicable for all applications.

The object of the invention is achieved by the in claim disclosed features solved.

As essence of the invention lies in the double use of functional levels, d. H. once in the use of the optocoupler as Voltage sampler for the incoming DC counts and the transistor as a switching stage transistor and the other additionally in the novel and unusual use of these both function levels as a monoflop circuit. This double exploitation for the integrated pulse shaping that only under the additional use of the passive timer a specifiable minimum length of the 16 kHz AC voltage pulse secured regardless of the input pulse length and thus in any case, a system-independent correct fee display is guaranteed at the call station. So there is none internal logic with the required additional power supply necessary. Despite different switching systems to be connected is a uniform sampling circle of the charge count applicable. Is the charge meter with a free switch contact is only an increase in the resistance value the current limiting and response threshold resistance.  

This voltage scan also leaves a clearly separate one Evaluation and display for two connections.

The solution according to the invention is explained in more detail using an exemplary embodiment. The drawing shows the circuit diagram for feeding 16 kHz charge pulses onto subscriber lines to the subscriber station. The circuit arrangement is used to decouple the 16 kHz charge pulses via a bandpass BP on the a; a 1 - and b; b 1 wires and continue via the subscriber lines Tln-A 1 to the call station, a band-stop for 16 kHz being inserted on the exchange side.

The charge counting pulses reaching the charge counter Z via the c / z wire are to be connected to the scanning circuit of the charge counting pulse AK-GZI in accordance with the polarity. The charge counting pulses are sampled by the reverse polarity protection diode D 4 , the current limiting and response threshold resistor R 6 and the diode of the optocoupler OK bridged with a response delay capacitor C 3 , the sampling circuit of the charge pulse AK-GZI. In the collector circuit of the transistor of the optocoupler OK, a switching stage and monoflop transistor T is connected, the collector of which is connected both to the control input of the AC voltage amplifier V and via the time-determining circuit C 2 ; R 3 ; R 4 is connected to negative operating voltage potential -U _B. From the connection point of the two time-determining resistors R 3 ; R 4 is connected to the base of the optocoupler OK, whose emitter is at a negative operating voltage potential -U _B. An AC voltage amplifier V is connected via a coupling capacitor C 1 from a central AC voltage generator G, the output of which is via a blocking diode D 3 via the interference voltage limiting diodes D 1; 2 and on the other hand via the winding of the bandpass BP is at negative operating output potential -U _B.

The different possible operating variants for provision the charge counts, especially in older systems such as Pp. 29-50, pp. 56/58, ATZ-63/64. . ., are simplified about the c / z wire is shown arriving at the meter Z.  

Appropriate connection of the scanning circuit of the charge counting pulse AK-GZI to the respective switching system can be used to scan both positive and negative, or the connection can be made directly via a switching contact of the charge counter Z, with the current limiting then occurring in the scanning circuit of the charge counting pulse AK-GZI - And response threshold resistance R 6 must be increased in value.

In the idle state, the scanning circuit of the charge counting pulse AK-GZI is currentless and the optocoupler OK cannot respond. The switching stage and monoflop transistor T and the AC voltage amplifier V are thus blocked. The 16 kHz AC voltage of the central AC voltage generator G applied to the coupling capacitor C 1 is not coupled in, so that no 16 kHz AC voltage pulse is transmitted via the bandpass to the wires a; a 1 and b; b 1 can be transmitted to the subscriber line Tln-A 1 .

With the response delay capacitor C 3 , a response delay is achieved which prevents a response to short-term disturbances.

In the event of occupancy, the call counter Z only flows in Fault current for which the sampling circuit of the charge counting pulse AK-GZI is dimensioned such that the optocoupler OK does not yet respond.

If a counting pulse is triggered via the c / z wire, talks about the current increase of the meter Z on. By increasing the voltage the threshold of the Scanning circle of the charge counting pulse AK-GZI exceeded. The transistor of the optocoupler OK now switches through and thus also the switching stage and monoflop transistor T, which the AC voltage amplifier V activated.

The alternating voltage of the central alternating voltage generator G is coupled via the coupling capacitor C 1 to the alternating voltage amplifier V and amplified via the bandpass filter BP to the a; a 1 - and b; b 1 cores coupled to the subscriber line Tln-A 1 of the call station. The central alternating voltage generator G is only slightly loaded by the input resistance of the coupling stage of the alternating voltage amplifier V.

A bandstop BSp for 16 kHz prevents this 16 kHz frequency from reaching the exchange. With the switching of the switching stage and monoflop transistor T, the switching time of the mono-flop begins, which is determined by the time-determining capacitor C 2 and the time-determining resistors R 3 ; R 4 is fixed and generates a required minimum pulse length. With the time-determining resistor R 4 as a voltage divider resistor, the feedback to the base of the transistor of the optocoupler OK takes place via the base resistor R 5 . However, if the pulse time of the pulse arriving on the c / z wire exceeds the switching time of the mono-flop, the pulse duration of the charge count pulse alone determines the pulse duration of the 16 kHz AC voltage pulse to be transmitted. In this way, the dual function of the function levels ensures that the charge display at the call station is triggered reliably even when working with older systems, even if the charge counts on the c / z wire are shorter in time.

List of the reference numerals used

a; a 1 a-core, speaking cores
b; b 1 b-wire, speaking wires
AK-GZI scan circuit of the charge count
BP 16 kHz bandpass
BSP 16 kHz bandstop
c c-wire occupancy wire
C 1 coupling capacitor
C 2 time-determining capacitor
C 3 response delay capacitor
D 1 ; D 2 interference voltage limiting diode
D 3 blocking diode
D 4 reverse polarity protection diode
G central AC voltage generator
OK optocoupler
R 1 ; R 2 basic voltage divider
R 3 ; R 4 time-determining resistance
R 5 basic series resistor
R 6 current limiting and response threshold resistance
T switching stage and monoflop transistor
Tln-A 1 subscriber line
VSt exchange
Z charge counter
-U _B negative operating voltage potential
⟂ Earth potential

Claims (1)

Circuit arrangement for feeding 16 kHz charge pulses on subscriber lines (Tln-A 1 ), in which a controllable AC voltage amplifier (V) on the input side via a coupling capacitor (C 1 ) to a central AC voltage generator (G) and on the output side inductively via a bandpass filter (BP) a subscriber line (Tln-A 1 ) is connected which has a 16 kHz blocking circuit (BSp) on the exchange side, characterized in that the collector of the transistor of an optocoupler (OK) is connected in series from a first base voltage partial resistor (R 1 ) and a second Base voltage partial resistor (R 2 ) is connected to earth potential (⟂) and the base of a monoflop transistor (T) is connected to the connection point between the first and second base voltage partial resistor (R 1 , R 2 ), that the emitter of the monoflop transistor ( T) with earth potential (⟂) and the collector of the monoflop transistor (T) with both Ste Uereingang the AC voltage amplifier (V) and a series circuit of time-determining capacitor (C 2 ) and two time-determining resistors (R 3 , R 4 ) with operating voltage potential (-U _B ) that the base of the transistor of the optocoupler (OK) over a base resistor (R 5 ) is connected to the connection point of the two time-determining resistors (R 3 , R 4 ) and the emitter of the transistor of the optocoupler (OK) is at the operating voltage potential (-U _B ) and that in the sampling circuit for the charge counting pulses (AK- GZI) a response delay capacitor (C 3 ) of the diode of the optocoupler (OK) is connected in parallel, which is followed by a current limiting and response threshold resistor (R 6 ) and a reverse polarity protection diode (D 4 ).