FR2605164A1 - Internal or external ringing mode loop-detection device - Google Patents

Abstract

Detection is carried out by measuring the duty cycle of the line current, the device comprising an input circuit, a zero-pass detector, an integrator and two comparators. The detector includes a comparator 11, a unit consisting of two current generators 12, 13 and a bridge of diodes D1 to D4 supplying current to a hysteresis resistor, a follower amplifier 14 for short-circuiting the hysteresis resistor under external ringing, and a current generator 10 connected to the comparator under internal ringing, in order to compensate for a leakage current in the line, and to earth under external ringing. The output of the comparator 11 is connected to the integrator.

Description

Loop detection device in internal or external ringing mode
The invention relates to the detection of the subscriber loop in the ringing phase, whether the ringing is internal to a subscriber terminal, or external to it.

We know from French patent application 2531 296,
"Method and device for loop detection in ringing phase", a device allowing loop detection in internal ringing mode, that is to say an internal ringing at the trunk, the detection being made by measuring the duty cycle of the current in the subscriber line. To this end, the ring phase detection device consists of a zero crossing detector, an integrator circuit and two comparators.

 The zero crossing detector comprises hysteresis means defining two thresholds, one positive and the other negative, in order to obtain correct operation despite the presence of zero current stages in the line alternating current.

 On the other hand, since there may be a leakage current in the line, the duty cycle of the line current in ringing phase is not in this case 50% before the handset is picked up by the subscriber but slightly higher, for example 50.45% for a leakage current of 0.625 mA. The cyclic ratio not being 50%, the detector delivers a non-zero average current to the integrator; to compensate for this average current, due to the leakage current, the integrator includes means for compensating for the leakage current.

 In the case of ringing external to the trunk, the ringer signal is delivered to the subscriber line, and the trunk is then connected to each wire of the line by a high-value resistor in order to minimize the energy dissipated; the signal at the input of the trunk is weaker than in the case of an internal buzzer, and the device described in the French application cited above cannot ensure detection.

 The object of the invention is to detect a loop in internal or external ringing mode by the same device, the loop detection being made by measuring the duty cycle of the current in the trunk.

 The subject of the invention is a loop detection device in ringing mode, internal or external, comprising an input circuit delivering a voltage signal proportional to the current in a subscriber line, a detector for zero crossings of the current. in the line, an integrator and two comparators, characterized in that it also comprises a control circuit, that the detector comprises a comparator, a first current generator, a hysteresis resistor, means for short-circuiting the hysteresis resistance in external ringing mode and means for circulating a current in said hysteresis resistance, that the comparator has a negative input connected by a compensation resistance at the output of the input circuit and an output connected to the integrator and to said means for circulating a current, that the first current generator is connected on the one hand to a negative voltage from a first power source, and on the other hand by means s switching to the negative input of the comparator in internal ringing mode to compensate for a leakage current in the line, and to ground in external ringing mode, that the hysteresis resistor is connected on the one hand to a positive input of the comparator and to said means for circulating a current, and on the other hand to ground, and that said switching means and said means for short-circuiting the hysteresis resistance are controlled by the control circuit to which they are connected, said control circuit receiving a signal for selecting the ringing mode.

 The invention will be described using an embodiment illustrated by the appended figures in which - FIG. 1 is a diagram representing the connection of a subscriber line to an electronic trunk and to an external buzzer, FIG. 2 schematically represents the loop detection device of the invention, FIG. 3 represents a zero crossing detector and an integrator of the devices of FIG. 2.

 In FIG. 1, two wires A and B of a subscriber line are connected, by contacts sl and s2 in the rest position of a ringing relay Rs, to two wires a and b themselves connected to an electronic trunk J.

Two resistors Ra and Rb, of the same value, connect the wires A and a and B and b, respectively, these resistors being short-circuited by the contacts sl and s2 in the rest position.

 A circuit, comprising a battery BAT, in series with two ringing sources S1 and S2, and two injection resistors R is connected to the wires A and B by the contacts s1 and s2 in the working position.

 The ringing sources S1 and S2 are for example two secondary windings of a transformer having a primary winding supplied by a ringing generator, as is well known to those skilled in the art. The positive polarity of the battery is connected to ground; the trunk J is itself connected to the ground and to the polarity -VB of the battery.

The contacts sl and s2 are only in the working position when it is necessary to send a ring signal by the external ring; as soon as the subscriber connected to wires A and B of the line picks up his handset and the off-hook is detected, the relay Rs is no longer supplied and the contacts s1 and s2 resume the rest position; in internal ringing the contacts sl and s2 remain in the rest position, even after lifting the handset, the ringing signal being suppressed. In the absence of any ringing signal, the contacts sî and s2 are in the resting position and the J circuit breaker supplies line ; the wire b is at a voltage -Vd1 relative to the ground and the wire a is at a voltage Vd2 relative to the potential -VB of the battery; the voltage between wires a and b is
VB - (Vd1 + Vd2) = VB - Vd with Vd = Vd1 + Vd2; Vd is called waste voltage.

 In external ringing the contacts sl and s2 are in the working position and a current flows in the wires A and B of the subscriber line whose impedance before off-hook is Z.

 Continuously, this impedance has a value Zc and the average voltage between the wires A and B is equal to VB - 2Ri, i being the average current.

When this average voltage is greater than VB - Vd, the trunk acts as a receiver, and when this average voltage is lower the trunk acts as a generator. The average current is from which the trunk becomes generator is given by the equation
VB - 2Ris = VB - Vd hence Vd
is Vd is is called detection threshold current.

The trunk J will detect the loop closure, that is to say the off-hook of the telephone handset by the called subscriber, as of the off-hook since the current in the line then increases, the impedance of the line becoming lower than Z and its continuous value then being less than Zc. It is noted that the smaller the waste voltage Vd, the lower the injection resistances R. The impedance Zc corresponding to the threshold current is
2R = 2R (VB - Vd)
Zc: Vd
Instead of having injection resistors R, it is possible to use complex impedances for which the continuous value is R and the alternating value is low in order to have a greater detection sensitivity and more losses. weak for the alternative ring signal.

 FIG. 2 represents a ring detection loop device of the invention, comprising a zero crossing detector 2, a control circuit 3, an integrator 4 and two comparators 5 and 6. The control circuit 3 receives a TS signal indicating the type of ring, internal or external, and is connected to the zero crossing detector 2. Comparator 5 has a positive input connected to the output of the integrator 4 and a negative input connected to a reference voltage + Vr ; comparator 6 has a negative input connected to the output of integrator 4 and a positive input connected to a reference voltage -Vr. The comparators 5 and 6 deliver signals C1 and C2, respectively, which are used to give the indication relating to the loop detection.

 The loop detection device is obviously part of the trunk J, Figure 1; it is connected at the output of an input circuit i also forming part of the trunk and connected to the wires a and b; the input circuit 1 is of any known type, for example of the type shown in French patent 2531296 already cited; this input circuit delivers a voltage U = KI proportional to the current I in the subscriber line.

On ringing, the zero crossings detector 2 detects the zero crossings of the voltage U, therefore of the line current; the detector 2 comprises means for compensating for the leakage current in the line and hysteresis means which are used for internal ringing, and inhibited for external ringing, by command by the control circuit. The integrator 4 does not include means for compensating for the leakage current in the subscriber line, since these means are in the zero crossing detector.

 FIG. 3 represents the zero crossing detector 2 and the integrator 4 of FIG. 2.

 The detector comprises at the input a comparator 71 having a negative input connected on the one hand to a current generator 10 via a contact tl, and on the other hand to the output of the input circuit 1 by a resistor Rcf, and a positive input connected to ground by a hysteresis resistor RH. A current generator 12 is connected to a current generator 13 on the one hand by a bias resistor Rp allowing the current generators to deliver a current I, and on the other hand by a bridge of four diodes D1, D2, D3 , D4.

 The current generators and the diode bridge make it possible to circulate the current I in the hysteresis resistor RH, the diodes D1 and D3 on the one hand, the diodes D2 and D4 on the other hand being in series between the two generators current. The output of comparator 11 is connected to a point P common to the diodes D1 and D3. A point Q common to the diodes D2 and D4 is also common to the positive input of the comparator 11 and to the hysteresis resistance RH. A follower amplifier 14 has its output and a negative input connected to point Q, a positive input connected to ground and a control input connected by a contact t2 to a potential -5V from a power source. The current generator 12 is connected to a + 5V potential from a power source and the current generators 10 and 13 are connected to the -5V potential.

 The integrator 4 is constituted by an amplifier 15 having a negative input connected on the one hand to the point P of the detector by a resistor Ri and on the other hand to the output of the amplifier by a capacitor Ci, and a positive input connected to ground; the output of the amplifier 15 is connected to the comparators 5 and 6 of FIG. 2.

 The contacts tl and t2 are for example contacts of a relay, the supply of which is controlled by the signal TS, FIG. 2; the relay and its contacts ti and t2 constitute the control circuit 3 of FIG. 2. Of course the contacts tl and t2 can advantageously be electronic switches whose on or off state is controlled by the control circuit; in this case the switches are preferably located in detector 2.

 In internal ringing mode the contact t1 connects the current generator 10 to the negative input of the comparator 11, and the contact t2 is open.

 In external ringing mode, the contact tl connects the current generator 10 to ground and the contact t2 is closed and connects the control input of the follower amplifier 14 to the negative voltage -5V the follower amplifier is thus switched on service and a virtual mass is brought back to point Q, which short-circuits the RH hysteresis resistance.

The current generator 10 delivers a current Icf for compensation of the leakage current in the line in internal ringing; this current Icf flows through the resistor Rcf, as an internal buzzer, and the voltage at the negative input of the comparator 11 is: Ve = U - Rcf.Icf,
U being the voltage at the output of the input circuit 1. In internal ringing, before the handset is picked up by the subscriber, the voltage Ve consists of positive and negative alternations at the frequency of the ringing signal. The hysteresis resistance RH and the current I of the current generators 12 and 13 have values such that the product RH.I is small compared to a voltage of - + 5V, for example of the order of 100mV.

 For a positive voltage Ve greater than 100 mV, the voltage at point P, at the output of comparator 11 has a value of the order of -5V, the diodes D1 and D4 are conducting, the diodes D2 and D3 are blocked, and the hysteresis resistance RH is traversed by a current I in the mass direction point Q; the voltage at point Q is negative with respect to ground and we have 'VQ = -RH.I. At the next alternation Ve is negative and the comparator 11 delivers a voltage of the order of + 5V when the voltage Ve becomes lower than the voltage on the positive input of the comparator 11, that is to say when Ve < -RH.I.

 The diodes D2 and D3 are then conducting, the diodes D1 and D4 being blocked, and a current I flows in the hysteresis resistance RH in the direction point Q ground, that is to say in the opposite direction to that which 'he had previously. The voltage at point Q is then VQ = + RH.I. At the next positive alternation, the amplifier 11 delivers a voltage of the order of -5V when the voltage Ve is less than the voltage on the positive input of the comparator 11, that is to say when Ve> + RH.I . Two thresholds + RH.I and -RH.I are thus obtained for the positive and negative alternations of the ringing signal.

 In external ringing, the current generator 10 being connected to ground by the contact t1, the current Icf no longer flows in the resistor Rcf, and the contact t2 being closed the follower amplifier 14 brings a virtual ground to the point Q; in external ringing, the compensation of the leakage current and the hysteresis resistance are therefore eliminated, and the voltage at point -P changes sign at the same time as the alternations of the ringing signal.

 In internal or external ringing, the voltage signal at point P consists of alternately positive and negative slots which are applied to the input of the integrator 4 which outputs a triangular signal. This triangular signal is applied to the two comparators 5 and 6 of FIG. 2, and compared to the reference voltage + Vr in the comparator 5 and to the reference voltage -Vr in the comparator 6. Before dropping out, the voltage slots delivered by the comparator 11 are equal, the duty cycle being equal to 1, and the signal at the output of the integrator 4 is between two values less than + Vr and -Vr; after dropping out the duty cycle is greater than 1 and the signal at the output of the integrator reaches a positive value greater than + Vr.

Claims (4)

1 / Ring or loop detection device, internal or external, comprising an input circuit (1) delivering a voltage signal proportional to the current in a subscriber line, a detector (2) of zero crossings of the current in the line, an integrator (4) and two comparators (5, 6), characterized in that it also comprises a control circuit (3), that the detector (2) comprises a comparator (11), a first generator current (10), a hysteresis resistance (RH), means for short-circuiting the hysteresis resistance in external ringing mode and means for circulating a current in said hysteresis resistance, that the comparator (11 ) has a negative input connected by a compensation resistor (Rcf) at the output of the input circuit (1) and an output connected to the integrator (4) and to said means for circulating a current, as the first current generator is connected on the one hand to a negative voltage (-5V) of a first source of ali ment, and on the other hand by switching means (tif) at the negative input of the comparator in internal ringing mode to compensate for a leakage current in the line, and to ground in external ringing mode, that the hysteresis resistor is connected on the one hand to a positive input of the comparator (11) and to said means for circulating a current, and on the other hand to ground, and that said switching means and said means for short- circuit hysteresis resistance are controlled by the control circuit (3) to which they are connected, said control circuit receiving a selection signal (TS) of the ringing mode. 2 / loop detection device according to claim 1, characterized in that the means for short-circuiting the hysteresis resistance consist of a follower amplifier (14) having a positive input connected to ground, an output and a negative input connected to the hysteresis resistance and a control input connected by a control means to the negative voltage of the first power source, said control means being controlled by the control circuit (3) to which it is connected . 3 / loop detection device according to claim 1, characterized in that the means for circulating a current in the hysteresis resistor (RH) are constituted by a second (12) and a third (13) current generators and a diode bridge, the second current generator (12) being connected to a positive voltage (+ 5V) from a second power source, the third current generator (13) being connected to the negative voltage (-5V ) from the first power source, the second and third current generators being connected, on the one hand by a bias resistor (Rp) and on the other hand by the diode bridge, said diode bridge having a first ( D1) a second (D2) a third (D3) and a fourth (D4) diodes, the first and third diodes being in series and forming a first branch, the second and fourth diodes being in series and forming a second branch in parallel with the first branch, a first dot com mun (P) with the first and third diodes being connected to the output of the comparator (11), a second common point (Q) with the second and fourth diodes being connected to the hysteresis resistor (RH). 4 / loop detection device according to claim 2, characterized in that said switching means (t1) and said control means (t2) are electronic switches.