SE512337C2 - Method and apparatus in a subscriber line circuit - Google Patents

Abstract

In a subscriber line interface circuit having an amplifier (16) for generating private metering signals to be transmitted through the subscriber line interface circuit to a subscriber station via a subscriber line (2, 3), the amplitude of the private metering signals is adapted to the length of the subscriber line (2, 3) in that the amplitude is adapted and latched in discrete steps to the DC line voltage once the subscriber station goes off-hook and unlatched when the state of the subscriber line interface circuit changes to stand-by mode.

Description

15 20 25 30 51.2 537 If the subscriber line is koit, this means that the call meter signal amplitude in the subscriber device will be much higher than what the call meter signal detector is intended for.

Consequently, the call meter signal detector will receive a higher signal amplitude than it is dimensioned for. As a result, no call meter signal detection will take place in the subscriber set.

IUS 5 452 345 describes a programmable meter signal generator by means of which the meter signal voltage can be programmed to a suitable level for a specific subscriber line. The call meter signal level on the subscriber line is sensed and controlled in such a way that the subscriber line circuit is not overloaded.

DISCLOSURE OF THE INVENTION The object of the invention is to provide a method and an apparatus in a subscriber line circuit for automatically adjusting the amplitude of the saintal network transceiver signals to an arbitrary subscriber line length.

This is achieved according to the invention in that the call network signal level is adapted in discrete steps to the line DC voltage.

Hereby, the subscriber line circuit according to the invention can be used to transmit call meter signals without knowledge of the actual length of the subscriber lines.

DESCRIPTION OF THE DRAWINGS The invention is described in more detail below with reference to the accompanying drawing, in which the single figure shows a block diagram of an embodiment of a device according to the invention. ii 10 15 20 25 30 sig 337 PREFERRED EMBODIMENT The single visar clock shows a call meter signal injection circuit in a subscriber line circuit.

The rest of the subscriber line circuit is not displayed.

A call meter signal generator I is arranged to generate call meter signals to a subscriber device (not shown). Call meter signal lines are injected on a subscriber line which comprises an a-wire 2 and a b-wire 3 via a call meter signal output terminal 4 via the subscriber line circuit in a manner not shown in the figure.

In accordance with the invention, the multiplicity of the call meter signals from the generator 1 is adapted to the length of the subscriber line 2, 3.

To accomplish this, the injection circuit includes a line voltage sensing circuit 5 for sensing the line DC voltage, i.e. DC voltage between the a-wire 2 and the b-wire 3, in the subscriber line circuit. The output terminal of the line voltage sensing circuit 5 is connected to one input terminal of at least one voltage comparator. In the embodiment shown there are two voltage comparators 6 and 7. The second input terminal of the voltage comparator 6 is connected to a reference voltage generator 8, while the second input of the voltage comparator 7 is connected to a reference voltage generator 9, which generates a reference voltage which of the generator 8 generated the reference voltage.

A "1" will appear on the output terminal of the comparator 6 if the line DC voltage sensed by the shielding circuit 5 is higher than the reference voltage generated by the generator 8.

Similarly, an "1" will appear on the output terminal 7 of the comparator 7 if the sensed line DC voltage is higher than the reference voltage generated by the generator 9. The output terminal of the comparator 6 is connected to a data input terminal D of a flip-flop 10 which has an output terminal Ö as well as a clock input terminal CK and a reset input terminal CLR.

Correspondingly, the output terminal of the comparator 7 is connected to a data input terminal D of a flip-flop 11 which is identical to the flip-flop 10.

The reset input terminals CLR of the flip-flops 10 and 11 are connected to the output terminal of an inverter 12 whose input terminal is connected to a mode input terminal 13 on which a "1" occurs when the subscriber line circuit is in active mode and an "0" occurs when the subscriber line circuit is emergency mode.

The flip-flops 10 and 11 of the clock input terminal CK are connected to the output terminal of an AND circuit 14. AND one input terminal of the AND circuit 14 is connected to the mode input terminal 13, while its other input terminal is connected to a loop detector input terminal 15. On this loop terminal an "1" if the subscriber device is in a lure-off state, while an "0" occurs when the subscriber device is in a lure-on state; When a "1" appears on the output terminal of the AND circuit 14, i.e. on the flip-flops 10 and 11 of the clock input terminal CK, the output terminal 6 is locked to the signal on the data input terminal D.

In accordance with the invention, the call meter signal generator 1 is connected to the output terminal 4 via an operational amplifier 16 in that the generator 1 is connected to the operational amplifier 16 "+" - input to the "-" input terminal via a resistor 17. 10 15 20 25 §12 337 This is achieved by the connection point between the resistor 17 and the input terminal of the operational amplifier 16 "-" - being connected to at least one voltage-controlled switch via a resistor.

In the embodiment shown, the connection point 18 is connected to two voltage-controlled switches 19 and 20, respectively, via respective resistors 21 and 22.

Switches 19 and 20 can be transistor switches.

The switch 19 is controlled by the voltages which occur across the Ö output terminal of the flip-flops 10 and 11, while the switch 20 is controlled by the voltage which occurs across the Ö output terminal of the flip-flop 11.

When switches 19 and 20 are in the position shown in the figure, i.e. broken, the gain of the operational amplifier 16 is equal to 1 corresponding to a short subscriber line or a low subscriber line voltage. When either of the switches 19 and 20 is closed, the gain is increased corresponding to a longer subscriber line.

To ensure that only one of the switches 19 and 20 is closed at a time, the switch 19 is controlled via an AND gate 24 which has one input connected directly to the output of the rocker 10 ë. The second input of the AND gate 24 is connected to the output of an inverter 23, the error terminal of which is connected to the flip-flop of the flip-flop 11 which controls the switch n? 20.

In the embodiment shown, the flip-flop 10 is assumed to control the gain of the amplifier 16 in correspondence with a lower call meter signal gain than the gain set by the flip-flop 11. Thus, if the output of the rocker 10 is high, the switch 19 will close only if the output of the rocker 11 is low. On the other hand, if the output of the rocker 11 is high, the switch 20 will always be closed.

For example, when the switch 19 is closed, i.e. a "1" appears on the output of the flip-flop 10, the gain of the operational amplifier 16 will be equal to (R17 + R21) / R21.

When the subscriber device is detected as being in the on-hook state, i.e. a "1" appears on the loop detector input terminal 15, the gain of the amplifier 16 is locked if the subscriber line circuit is in active mode.

The reading of the gain of the amplifier 16 is stopped when the subscriber line circuit switches to standby mode, i.e. when an "0" appears on the mode input terminal 13.

The reason for causing the amplification of the amplifier 16 to cease when the subscriber line circuit switches to standby mode is to ensure that call meter signals can be transmitted even if the subscriber device is in a sleep state as long as the line is considered active, i.e. as long as the subscriber line circuit is in active mode. It is, for example, common for so-called efte pulses are sent after the subscriber has switched to standby mode after a call.

Claims (2)

10 15 20 25 30 5; 2 357 Patent claims Method for adjusting the amplitude of the meter signals to the length of the subscriber line, in a subscriber line circuit with an amplifier for transmitting call meter signals via a subscriber line to a subscriber device, characterized in that - the line DC voltage is sensed, - that the sensed line DC voltage is compared with at least one reference voltage corresponding to a certain subscriber line length, - that depending on the sensed line DC voltage being higher than said at least one reference voltage, a control signal is generated to increase the gain of the amplifier and to increase the amplitude of the meter signals correspondingly, - that the amplifier's gain is locked when the subscriber apparatus is detected by handset and the subscriber line circuit is in active mode and - that the reading of the amplifier's amplification is stopped when the subscriber line circuit switches to standby mode. Device for adapting the amplitude of the meter signals to the length of the subscriber line in a subscriber line circuit with an amplifier (16) for transmitting number meter signals via a subscriber line (2, 3) to a subscriber device, characterized in that it comprises - means (5) for sensing the line equalizer , - means (6, 7) for comparing the sensed line DC voltage with at least one reference voltage (8, 9) corresponding to a certain subscriber line length, - means (10, 11) for depending on the sensed line DC voltage being higher than said at least a reference voltage generates a control signal to increase the gain of the amplifier (16) and to increase the amplitude of the meter signals correspondingly, means (14) for locking the gain of the amplifier when the subscriber device is detected by handset and the subscriber line circuit is in active mode and means ( 12) to cause the reading of the amplifier's gain to cease when the subscriber line circuit enters standby mode.