FR2500241A1 - BATTERY POWER CIRCUIT FOR TELEPHONE INSTALLATION - Google Patents

Abstract

THE INVENTION CONCERNS POWER SUPPLY CIRCUITS USED IN TELEPHONY. THE CONTINUOUS CURRENT FLOWING THROUGH EACH CONDUCTOR OF A TWO-WIRE TELECOMMUNICATIONS LANE IS GENERATED BY A TWO-WAY CURRENT SOURCE 103, 104 WHICH RECEIVES ONE OF THE SIGNALS OF A COMPLEMENTARY PAIR OF FIRST SIGNALS OF

Description

The present invention relates to a food circuit

  battery for a two-way communication channel

  lar. A battery power supply circuit provides DC power to a telecommunication equipment

  munications through a two-wire transmission channel which

  Also typically mines a bidirectional voice or data signal. This power supply is

  balanced, that is to say that each transmission wire

  gives a current which is equal in absolute value but of sense

opposite to that of the other wire.

  In telecommunications applications, the

  length of a two-wire transmission path varies

  ably. As a result, the feed circuit

  The battery must be designed to provide the current

  required power supply over a range of

  resistances of the way. The transmission routes are also

  likely to capture fashion-induced signals

  common or longitudinal, for example a signal of

  50 Hz, which can be turned into noise.

  It is therefore necessary that the battery supply circuit minimizes the transformation of such signals.

longitudinal noise.

  Various kinds of food circuits have been developed.

  battery powered. These circuits can usually be brought into one of two classes, depending on their

  battery power profile, that is, the relationship between

  between the supply DC current and the voltage at the terminals of the two-wire transmission channel, and the

  way they treat the longitudinal signals

  nal. The first class of battery power circuits, such as, for example, U.S. Patent 4,004,109, produces a linear battery power pattern and has a low common mode impedance for the longitudinal signals. This first class of circuits achieves only moderate success in reducing the noise that longitudinal signals induce in the two-wire transmission path. In addition, although these circuits operate satisfactorily in many applications, the use of a linear battery power profile dissipates excessive power on short two-wire transmission paths. The second class of battery power circuits, in accordance with the

  description made in a document entitled: "A Floating

  Low-Power Line Subscriber Interface "by L. Freimanis and D. Smith, ISSCC Digest, 1980, pages 180, 181, provides a nonlinear battery power profile that limits the power supply current on the transmission paths

  short two-wire The noise induced by long signals

  is minimized by the existence of a high common mode impedance, thanks to the use of

  insulation, such as transformers or opto-

  isolators. However, these devices are expensive and bulky.

  The problem is solved in a food circuit.

  battery circuit according to the invention, wherein the battery supply circuit comprises first and second bidirectional power sources which are

  respectively connected to first and second conductors

  channel, a first feedback circuit for generating a first control signal and its complement, by controlling the differential mode voltage across the channel, and a second feedback circuit for generating a second control signal by controlling the common mode voltage across the terminals of the flight, and the first source generates a first direct current under the effect of the first signal

  command, the second source generates a second current con-

  tinu of equal absolute value but opposite direction to the first DC current, under the effect of the complement of the first comumande signal, and the first and second sources also vsr- the first and second currents of equal value under the effect of the second control signal,

  to maintain a constant difference between them.

  According to the invention, a feed stream

  Battery operation, which is a balanced direct current, is generated in a two-wire telecommunication pathway. The continuous current flowing in each conductor of the

  two-wire path is generated by a two-phase

  -directional. Each current source is regulated by one of the signals of a complementary pair of first control signals, as well as by a second control signal. Current sources generate a power profile through

  non-linear battery under the effect of the complementary pair

  re of first control signals. This pair of control signals is generated by a feedback circuit that controls the differential mode voltage across the channel. A low common mode impedance with respect to the longitudinal signals is established by a second feedback circuit which controls the common mode voltage across the terminals.

  of the two-wire pathway and which generates from this

  the second control signal. This second control signal varies by an equal value the current of each bidirectional current source, so as to maintain a constant difference between the DC currents in each conductor. The induced noise in longitudinal mode is therefore

reduced to a minimum.

  The invention will be better understood on reading the

  description that will follow of embodiments and by

  Referring to the accompanying drawings in which: Figure 1 is a block diagram of a battery power circuit according to the invention;

  Figure 2 is a graph of the food profile.

  non-linear battery delivery provided by the invention; FIG. 3 is a detailed diagram of the circuit of FIG. 1 FIG. 4 represents a modified version of the linear reaction circuit 105 represented in FIG.

  2, which is coupled with additional circuits for furnishing

  several features that are required in many telecommunications applications; and Figure 5, which is on the same plate as Figure 2, is a graph of power profiles

  non-linear battery that can be obtained with the cir-

cooked from Figure 4.

  Figure 1 shows an example of application

  of the invention to telecommunications. A telecom route

  two-wire communication means consisting of metal conductors 101 and 102, transmits voice or bidirectional data signals between a subscriber unit 120 and a

  traditional 4-wire interface in a central office.

  Such a two-wire telecommunications path constitutes this

  commonly referred to as a subscriber loop and the conductors

  101 and 102 are respectively called peak conductor and ring conductor. The length, and therefore the resistance, of the peak and ring conductors from the central office to the subscriber station may vary

  considerably from one subscriber to another. We understand

  However, the two-wire telecommunications path can be connected to a two-wire switch instead of being connected to a subscriber station. In such cases, the two-wire telecommunications path is so-called

a junction.

  A direct supply current directed to the subscriber station 120 is generated by a bidirectional power source 103 connected to the peak conductor via a protection resistor 113 and by

  a bidirectional power source 104 which is connected

  to the ringing conductor by a protection resistor

  114. These protective resistances are necessary to prevent deterioration of the

  by battery under the effect of transients due to lightning.

  Each protection resistor has a characteristic value

  than 100 ohms. Each power source receives a potential

  continuous negative, VBAT, and the potential of the mass.

  By convention, the DC supply current flows from the tip conductor to the ring conductor. This flow direction of the supply current corresponds to

  what is also called normal battery power

  male (NB). In addition, the supply current, ITR 'is balanced, that is, the currents flowing in the tip and ring conductors have the same value.

  absolute but move in opposite directions.

  The absolute value of the supply current is regulated by a differential mode feedback circuit 105 which is connected to the tip and ring conductors via leads 106 and 107. The differential mode feedback circuit 105 controls the voltage. differential mode, VTR, between the peak and ring conductors, and generates control signals S1 and S which are transmitted by conductors 115 and 116 to sources 103 and 104. The control signals S1 and S1 are complementary signals, i.e. they have equal absolute values but opposite polarities, and they are non-linear functions of VTR. This relationship advantageously reduces the power consumed by providing a non-linear battery power supply profile which limits the power supply current over short lengths

  peak and ring conductors.

  FIG. 2 represents the normal nonlinear battery power supply profile provided by the control signals S1 and S.

  value of VTR falls between V1 and V2 and the feed current

  tation follows the right segment A. For weaker

  values of VTR between V3 and V2, the feed current

  Normal battery operation is governed by the segment

  B and it varies between IX and IMAX. The straight line C world

  The value of the supply current is limited to IMAX 'independently of any decrease in VTR below V3. In built models, IMAX was 42 mA and IX was 32 mA. The slopes of the straight segments A, B and C respectively had the following values: 300

  ohms, 2600 ohms and more than 30000 ohms.

  It is well known that longitudinal currents

  may be induced by various sources in the con-

  edge and ring conductors. FIG. 1 shows a characteristic longitudinal source at 50 Hz which is designated 108. The common mode source 108 induces a longitudinal current, IL, which flows through the

  same sense in both advanced drivers and sonne-

  series. The total current in the peak conductor, ITe is equal to the difference between ITR and IL. The total current in the ringing conductor, IR, is equal to the sum of ITR and IL. Since the absolute value of IL may exceed that of ITR, it is possible to create a total current inversion in either of the peak or ring conductors. Since the current sources 103 and 104 are bidirectional and linear when the current reverses, i.e. they have linear characteristics that pass through the origin, this inversion of

  current does not create noise. Any different mode voltage

  created by the longitudinal current IL is a parasitic noise. Measuring the ability of a circuit to minimize

  such noise is what is commonly referred to as the equi-

  longitudinal free of the circuit. Longitudinally induced noise can be minimized by creating low and equal common mode impedances in

tip and ring.

  In the invention, a low common mode impedance is established in the tip and ring conductors by means of a mode reaction path

  common to current sources 103 and 104.

  As will be considered, equal common mode impedances are obtained in the tip and ring conductors by matching the transconductances of the current source.

103 and the current source 104.

  The common mode reaction path includes

  resistors! is of equal value, conductive

  117, 118 and a common-mode feedback circuit 109. The circuit 109, descrambled by T, controls any variation in the average or common-mode voltage at the node resulting from the presence of longitudinal signals.

  and it generates a control signal S2. The signal of com-

  S2, transmitted by the conductor 117 to the power sources 103 and 104, drives each current source to

  compensate for any current that a long-term source

  longitudinal circulation in advanced conductors and

  this technique is called the long-term cancellation

  gitudinale. Therefore, we maintain a difference

  constant between the supply currents in the

tip and ringers.

  We will now look at Figure 3. The

  This current 103 comprises a differential operational amplifier 301 and resistors 302, 303, 304, 305 and 306. The values of the input resistors 303 and 304 are equal and the values of the feedback resistors 302 and 305

  are equal. The control signals S1 and S2 are respectively

  applied to the positive and negative inputs of the

  differential plifier 301. The use of the amplifica-

  Differential converter 301 advantageously allows to apply to the protection resistor 113 an output current having one or the other of two possible directions. The value of this output current is equal to the product of the difference

  between the control signals S1 and S2 by the transconduc-

  tance of the power source. This transconductance is equal to the resistance value 302 (r-resistance 304) (resistance 306),

  The current source 104 includes an amplification

  Differential Operator 310 and resistors 311, 312, 313, 314 and 315. Each resistor of current source 104 has the same value as its equivalent in current source 103. Control signals S1 and S2

  are respectively applied to the positive and negative inputs

  differential operational amplifier 310.

  fact that the structure of the current source 104 is identical

  to that of the current source 103, the output current of the current source 104 may also have

  one or the other of two possible meanings, and the transcon-

  The currents of the current sources 103 and 104 are equal.

  The output current of the source 104 has a value equal to 1 S2) times the value of <resistor 313) (resistor 33511 In the absence of longitudinal signals, the application of S1 to the current source 103 generates a preselected current which travels towards the peak driver.

  the application of the control signal S1 to the source of cou-

  rant 104 circulates an equal current from the

  ringing station to VBAT, via the

  of the differential amplifier 310.

  The control signals S1 and S1 are generated by the differential mode feedback circuit 105. The positive input of the differential operational amplifier 320, which is part of the circuit 105,. is connected to the tip conductor by the conductor 106, and its negative input is

  connected to the ringing conductor by the driver 107.

  The values of the input resistors 322 and 323 are equal.

  The values of resistors 321 and 324 are also

  equal. The differential amplifier 320 provides a voltage

  output voltage equal to the product of the differential mode voltage between the tip and ring conductors, VTR, by the resistance value 322 The output voltage of the differential amplifier 320 represents both the DC voltage generated by the currents output of current sources 103 and 104, and any alternating voltage

  representing voice or data signals on the con-

  edge and ring conductors. This output voltage is applied to the transmit side of a 4-wire interface, in which the DC voltage is blocked, so that

  allow only the emission of the alternative component

  tive. The output signal of the differential amplifier 320 is also transmitted by the resistor 329, at the input

  negative of the differential amplifier 325.

  The differential amplifier 325 provides a gain from three different gains, depending on the value of

  the output voltage of the differential amplifier 320.

  -The variation of gain modifies the gain of the circuit 105 in

  function of the VTR and, therefore, the value of the

  S1 and S1, to give the feed profile by

  non-linear battery which is shown in FIG.

  The value of the slopes of the line segments A, B and C, in ohms, is equal to the inverse of the product of the transconductance of the current source 103 or 104 by half the gain of the circuit 105. The segment of A right when the gain of the differential resistor amplifier 328 325 is equal to the resistor value 329 The power profile follows the line segment B when the gain of the amplifier 325 is equal to the value of:

  resistance 328 + resistance 327> resistance 329.

  Finally, a gain of the amplifier 325 equal to the value of 1 + 1 + 1i) resistor 329 resistor 328 + resistor 327 resistor 326 provides the substantially horizontal straight segment C, the negative input of the differential amplifier 325 is also connected to the current source 350 which determines the point of intersection with the axis VTR, ie Vit

  in Figure 2. The current source 350 is selected judiciously.

  to give an intersection point whose value is less than a certain threshold voltage, VTH,

  at the battery voltage VBAT. This ensures that the amplifiers

  301 and 310 remain correctly polarized,

  that is to say, do not reach saturation, when a cir-

  baked open appears between the peak conductors and

  ringing and when no power supply is gener-

  re. As a result, the longitudinal cancellation as well as

  transmission of voice and data signals are now

  regardless of the presence or absence of a

power supply.

  A filter 360, comprising a resistor 361 and a capacitor 330, removes any AC voice or data voltage component in the output voltage and the differential amplifier 325. A

  filter time constant of 200 ms gave results

satisfactory conditions.

  It should be noted that the output voltage S0 of the amplifier

  The differential encoder 325 is referenced to ground while the control signals S1 and S are referenced to VBATI 2BT. The current source, 331, the resistors 332, 333, 338, 339, the emitter coupling transistors 334, 335 and the differential amplifiers 336 and 337 provide an offset of the voltage reference point to -2AT. The level of IMAX shown in FIG. 2 is directly proportional to the current supplied by the current source 331. It is therefore possible to set IIAX er. varying

  the current provided by the current source 331.

  Transistors 343, 344, current source 340 and resistors 341 and 342 transmit to amplifiers

  differential factors 336 and 337 all the alternating

  voice or data originals represent incoming or receiving signals. Therefore, these alternative signals are also transmitted by the conductors 115 and 116 to the power sources 103 and 104, and

  then to the tip and ring conductors.

  The common mode feedback circuit 109 com

  takes a 350 difference amplifier and resistors

  351 and 352. The positive input of the difference amplifier

  Rence 350 controls the common mode voltage on the node while the negative input of the VBAT amplifier 350 is referenced a. The common mode impedance in the peak conductor, in ohms, is equal to: resistor 351 (1 + resistor 352 103 denoting by G103 the transconductance of the current source 103. The common mode impedance of the ring conductor is equal to: resistor 351 (1 + Irsistance 3) denoting by G104 the transconductance of the current source 104. Advantageously, the values of the common mode impedances of the peak and ring conductors are chosen so that they are respectively equal to the sum of the values of the resistors 113 and 306 and to the sum of the values of the resistors 114 and 315. This choice

  gives a constant output voltage for the amplifiers

  301 and 310 different, regardless of value

  of any longitudinal current. Thus, the excursion of

  in the two different amplifiers

  301 and 30 are not reduced by the value of longitudinal currents. Longitudinal cancellation is not

-O 24 1

  limited only by the permissible voltage excursion at the output of the differential amplifier 350 and by the output current that can be provided by the differential amplifiers 301 and 310. As a result, the longitudinal cancellation can be performed for induced currents having

  much higher value than the supply current.

  A common mode impedance of low value is obtained by choosing the ratio of the resistors 351 and 352. The longitudinal equilibrium is achieved by matching the transconductances of the current sources 103 and 104. Since these current sources can advantageously be realized in Using integrated circuits, this pairing can easily be done by adjusting the value of the corresponding resistors to make them equal. It should be noted in this regard that the resistors 113 and 114 do not affect the common mode impedance of the tip or ring conductors. Therefore,

  the matching of the resistances 113 and 114 is not neces-

  for the longitudinal balance. This feature is particularly advantageous because the matching of the resistors, which must withstand transients due to lightning, is considerably more expensive than the resistance matching incorporated in

current sources 103 and 104.

  Looking at Figure 4, we note that the cir-

  The above described battery power cooker can conveniently be adapted to provide a number of features that are required in telecommunications applications. The differential mode circuit 405 is identical to the circuit 105, except for the addition of a switch 406 and a current source 407. The switch 406, which is shown by way of example in the form of a mechanical switch is controlled either by the supply current cutoff control signal (FS) or by the battery reversal control signal (RB). These two signals are two-level logic signals that are generated in the signaling equipment that is connected to the 4-wire interface. A predetermined state

- 2500241

  (eg logic state "0") of the two control signals RB and FS switches the switch 406 to the terminal 1 so as to connect the current source 350 to the negative input of the differential amplifier 325. As envisaged, this gives the normal battery profile which is shown in FIG. 2. A logic RB control signal "1" switches the switch 406 to terminal 3, so as to connect the current source 407 to the negative input of the differential amplifier 325. The current source 407 is identical to the current source 350, with the exception

reverse polarity.

  The connection of the current source 407 reverses the polarity of the control signals S1 and S1. As a result, the normal flow of battery current from the tip wire to the ring wire is reversed. The inverted battery power (RB) profile, shown in Fig. 5, is equal to and opposite to the NB profile that is normally established. An inverted battery power profile

  is necessary for signaling when the conductors

  bifilar wires 101 and 102 are conductors of

  They are connected to a two-wire switch or PBX instead of being connected to the subscriber unit 120. In other applications at trunks, the supply current is not necessary. In such cases, a control signal FS at logic state "1" controls the switch 406 so as to place it on the

  terminal 2 and apply an open circuit to the negative input

  Differential amplifier 425. The cutoff profile

  The resulting power supply is shown in FIG.

  During the power failure, the longitudinal balance is maintained because the operation of the circuit of

  common mode reaction 109 is not affected.

  The loop closure signal (LO) is another two-level logic signal that is required by other telecommunications equipment connected to

  the 4-wire interface. A change in the state of the logical signal

  that LC is generated by a predetermined change in the value of VT. This predetermined change, which is typically 3 V, is representative of the pulse dialing and / or off-hook of the subscriber unit 120. A particular state, for example the logic state 1 ", the logic signal LC may conveniently be generated by the addition of a loop closure detector 408. The detector 408 comprises a comparator which generates a signal LC at the logic state" 1 "when the output signal of the differential amplifier 325 exceeds a

threshold set.

  A switch 409 and a switch control circuit 410 may also be advantageously employed with the generation of the loop close signal and the battery invert signal. The switch 409, connected in parallel with the filter 360, is momentarily closed (for a nominal duration of 16 ms) at the time of detection of a signal state change.

  LC or signal RB, by the switch control circuit.

  410. Momentary closing of switch 409

  establishes a derivation from the 360 filter to

  distortion and delay during the issuance of

  numbering or during transitions between

  normal and reverse battery power.

  It goes without saying that many modifications can be made to the device described and represented,

  without departing from the scope of the invention.

REVE1NDIOCATIONS

  A battery power circuit for a two-wire communication path, characterized in that it comprises: first (103) and second (104) bidirectional power sources;

  which are respectively intended to be connected to a first conductor (101) and a second conductor (102) of the track; a first reaction circuit (105) which comprises

  a circuit (320-329, 350) responsive to the different mode voltage

  (VR) at the track terminals by generating a signal

  control circuit (So), and a second feedback circuit (109) of

  to generate a second control signal by controlling the common mode voltage across the channel; and in that the first source (103) generates a first direct current (ITR) under the effect of the control signal, the second source generates a second direct current of absolute value equal to that of the first direct current and of opposite direction, under the effect of the control signal, and the first and second sources also vary the first and second currents by an equal value under the effect of the second control signal (S2) in a manner,

  to maintain a constant difference between them.

  2. Battery supply circuit according to the

  claim 1, characterized in that the first circuit of

  reaction (105) further comprises circlait (332-344) which

  to the control signal (So) by generating a signal

  control (SI) and> ncomplement of the first control signal

  of; the first source (105) generates the first continuous stream

  under the effect of the first control signal (S1) and the se-

  source (104) generates a second direct current of absolute value equal to that of the first direct current, and of direction

  opposite, under the effect of the complement of the first com-

mande.

  3. Battery supply circuit according to the

  v1, characterized in that the first reaction circuit polari.zse the first and second bidirectional current sources (103, 104) so as to avoid saturation

  when an open circuit is present in the first and second

conductive conductors (101, 102).

  4. Battery power circuit according to the

I 0 2 4 1

  claim 1, characterized in that the first feedback circuit comprises a circuit (406, 407) responsive to a predetermined state of an applied control signal (RB)

  to reverse the direction of the first and second currents.

  A battery power circuit according to Claim 3, characterized in that the first feedback circuit (105) comprises a circuit (406, 407) responsive to a predetermined state of an applied control signal (RB )

  in order to reverse the direction of the first and second currents.

* 6. Battery supply circuit according to the

  claim 4, characterized in that the first circuit of

  reaction (105) comprises a device (406, terminal 2) which

  git to a predetermined state of a second control signal

  plicated (FS) so as to pocket the generation of the first and

second currents.

  7. Battery supply circuit according to the

  5, characterized in that the first circuit of

  reaction (105) comprises a device (406, terminal 2) which

  git to a predetermined state of a second control signal

  plicated (FS) so as to pocket the generation of the first and

second currents.

  8. Battery supply circuit according to the

  claim 1, characterized in that the first feedback circuit (105) comprises a detector (408) for detecting a predetermined change in the mode voltage

  differential across the track.

  9. Battery supply circuit according to the

  claim 3, characterized in that the first feedback circuit (105) comprises a detector (408) for detecting a predetermined change in the mode voltage

  differential across the track.

  1 C. Battery supply circuit according to the

  claim 4, characterized in that the first reaction circuit (105) comprises a detector (408) for detecting

  a predetermined change in the differential mode voltage

tiel at the terminals of the track.

  11. Battery supply circuit according to the

  claim 5, characterized in that the first circuit of -0241

  reaction (105) comprises a detector (408) for de-

  detect a predetermined change in the mode voltage

  differential across the track.

  12. Battery supply circuit according to

  claims 6, characterized in that the first circuit

  (105) comprises a detector (408) for detecting a predetermined change in the voltage of

  differential mode at the terminals of the track.

  Battery supply circuit according to claim 7, characterized in that the first feedback circuit (105) comprises a detector (408) for detecting a predetermined change in the voltage of the battery.

  differential mode at the terminals of the track.

  14. Battery supply circuit according to one

  any of claims 10 to 13, characterized in that

  the first feedback circuit (105) comprises switching means (409, 410) responsive to detecting the predetermined change in the differential mode voltage, or a change in the state of the applied control signal, establishing a derivative with respect to a filter (360) belonging to the first reaction circuit, for a predetermined duration.