LT4356B - Telephone set - Google Patents

Abstract

The telephone set (1) has an ear piece (14) and first and second switches (6,7) by means of which the telephone set (1) is connected to a telephone exchange (5) via two lines (2,3). When the switches (6,7) are closed the telephone set (1) is supplied with electric energy via the lines (2,3) from the exchange (14). The telephone set (1) also has a circuit component (10). The first switch (6), the component (10) and the second switch (7) are electrically connected in series. The switches (6,7) are actuated via the ear piece (14). A first coil (8) is connected between the first switch (6) and the circuit component (10). A second coil (9) is connected between the component (10) and the second switch (7). The two coils (8,9) are wound in opposite senses around a body (12) of magnetic material. This body (12) has an arrangement (11,13) to generate an alternating magnetic field in the magnetic body (12). The time differential of the magnetic induction in the body (12) is measured. A signal to open the switches (6,7) is generated when the measured differential satisfies predetermined criteria.

Description

The invention relates to the field of telecommunications and describes a telephone station as described in the preamble of claim 1.

The object of the invention is a telephone station having a security device which prevents fraudulent use of the telephone free of charge.

The European patent no. EP0310371 discloses a telephone apparatus having a device for canceling a call when it is determined that a telephone is fraudulently intended to be used. A similar telephone set with a free-of-charge security system is also described in U.S. Pat. 5150403.

This object of the present invention is achieved by the features listed in claims 1 and 7.

The embodiment of the invention is described below in more detail with reference to the drawings, in which:

Fig.1 is an electrical diagram of a telephone station connected to a telephone switch;

Figure 2 is a diagram of measurement;

Figure 3 shows the magnetization curve and waveforms;

Figure 4 shows a magnetization curve and configurations of currents and voltages;

Fig. 5 shows a measuring scheme for measuring the impedance of a transformer inlet.

Fig. 1 is a schematic diagram of a public telephone exchange 1, connected by three lines 2, 3 and 4 to a telephone switch 5. It has two switches 6 and 7, first and second coils 8 and 9, circuit element 10, measuring coil 11, magnetic element 12 and measuring circuit 13. Switch 6, first coil 8, circuit element 10, second coil 9 and switch 7 are connected sequentially. The outputs of the switches 6 and 7 are connected to the lines 2 and 3, the switches 6 and 7 are controlled by the manipulator 1 14. They are switched off when the manipulator 14 is depressed and activated when the inverter 14 is raised. The circuit element 10 has two connections connected to line 4 through respective resistors 15 and 16. The circuit element 10 is the core of the telephone station 1, which creates an impedance

Ζτ. Other details of the construction of the schematic element are not relevant to the understanding of the invention and will not be described.

The first line 2 inside the telephone switch 5 is connected via a coil 17 to a grounded point m, to a line 4 which acts as a grounding line and to the positive terminals of the direct current voltage source 18. The second line 3 is connected via coil 19 to the negative outputs of the direct current voltage source 18. The telephone switch 5 comprises a grounded circuit 20 with a coil 21 and an alternating current generator 22, which further modulates the charging of pulses for telephone services on lines 2 and 3.

The charge accounting pulses are alternating signals with a frequency of mostly 50 Hz. The tax accounting pulses are received by the circuit element 10 of the telephone station 1 and are used, for example, for the direct debiting of credit received through the insertion of coins or similar means of payment. Alternatively, the telephone station 1 first aggregates the tax accounting impulses and then uses them for credit or e-card payment or other non-cash payment.

The electrical circuit 23 is connected to the telephone station 1 for fraudulent use of the telephone. The first power cord 24 of the circuit 23 is connected to the outlet A of the telephone station 1, which is between the circuit element 10 and the second coil 9. The second power cord 25 of the circuit 23 is connected to a grounding m _f . Circuit 23 generates an impedance Z _f between the two power wires 24 and 25. Depending on the type of fraud, circuit 23 may be a telephone or circuitry attenuating tax accounting impulses.

When the manipulator 14 is raised, the dc circuit is connected: dc first flows 2 from dc output 18 of dc voltage source 18 through circuit element 10 to duct A, dc ₂ flows second line 3 from dc output jj and the direct current l ₃ continues to flow directly from line 18 from positive source 18 to j of A. The dependence between direct currents is expressed as: l ₂ = h + l ₃ . The magnitudes of the direct currents h and l ₂ are about 100 mA. The direct current l ₃ is very low compared to the currents h and l ₂ , since the impedances 15 and 16 are significantly higher than the impedance Ζτ of the circuit element 10. In this way, power to the telephone exchange 1 can be supplied from the telephone switch 5 by lines 2 and 3.

The tax accounting pulses consist of alternating current pulses hi and h ₂ that exit the telephone switch 5 through lines 2 and 3 parallel to the telephone station 1 and are grounded by line 4 passing through impedances 15 and 16. Current impulses hi and h ₂ typically have a power of several or several tens of microamperes, so it is very small compared to the direct current H and l ₂ .

If no foreign circuit 23 is not connected to the output A, and then both of the dc and a ₂ h are nearly equal. However, if the extension telephone is connected in the same way as circuit 23, the current l ₄ flows from the ground point nit via impedance Zf j to terminal A and further to the negative terminal 18 of the DC voltage source. According to the node point rule the following dependency is formed: l ₂ = 11 + 1 ₃ + L.

The coils 8 and 9, the measuring coil 11, the magnetic element 12 and the measuring circuit 13 form a device to prevent unauthorized use of the telephone 23.

As can be seen in Fig. 1, the coils 8 and 9 are wound around the magnetic element 12 in opposite directions and have the same number of turns N _b. The element 12 is in the form of a ring. The DC currents h and l ₂ flowing through the coils 8 and 9 create a magnetic field Η _Λ ι in the ring 12 that is proportional to the difference between the DC currents Δ1 = hl ₂ and the number of turns Nf Η _ή ι ~ Δ1 * Νι. The measuring coil 11 is also wound around the ring 12.

Fig. 2 shows a first measuring circuit 13, which includes a measuring circuit. an alternating current source connected to the two terminals of the measuring coil 11 and consisting of a series connected alternating current voltage source 26 and a resistance 27, a voltmeter 28 for measuring the voltage between the terminals of the coil 11, and a reference circuit 29. V which the comparator circuit 29 compares with a predetermined threshold value V _o . The comparator circuit at output 29 sends a binary signal which may correspond to the values "0" and "1". A value of "0" means that the DC voltage V is greater than the value Vo and the value Ί means that the voltage V is less than the value V _o . The output signals of the comparator circuit 29 are so coordinated with the switches 6 and 7 that the signal "0" does not change the positions of the switches 6 and 7 and the signal "1" disables them.

When switches 6 and 7 are off, the power to the telephone exchange 1 from the telephone switch 5 is interrupted. In the event of a power failure, switches 6 and 7 do not connect simply by raising the manipulator 14. It must be depressed and then raised again, i.e. switches 6 and 7 are two-position switches, such as two-position relays. If the telephone 23 is still connected after raising the manipulator 14, the measuring circuit 13 immediately switches off the switches 6 and 7 again.

On the one hand, the measuring coil 11 together with the AC source 26, 27 generates in the ring 12 an alternating magnetic field Ημ (ϊ) covering the magnetic field Η _ά ι generated by direct currents h and l ₂ . On the other hand, measuring coil 11 measures the time deviation of magnetic induction B (t) that occurs in ring 12 based on the magnetization curve B (H). These two functions can also be performed by two measuring coils.

According to the first embodiment (Fig. 1), the ring 12 consists of a soft magnetic material having a magnetization curve B (H) of Fig. 3. For magnetic fields H, the absolute value of which is below the value Hk>, the magnetic induction B (H) is proportional to H and the inclination angle in dB / dH, i.e., the magnetic permeability μ _χ , is greater than the unit: μ _χ >> 1. The inclination angle dB / dH of magnetic fields H, the absolute value of which is above the value H _K , is significantly smaller. The magnetic material becomes saturated: the magnetic permeability μ _χ approaches 1. In the field Hk, the magnetization curve B (H) has a refractive point K. The number of coils 8 and 9 of the coil Ni is set to Ni = 25 such that the current difference Δ = 2 mA a field H_m lower than the field Hk, and thus prevents the ring 12 from being saturated magnetically, and the difference in currents ΔΙ = 4 mA creates a magnetic field Η _Δ ι that is significantly larger than the Hk field and saturates the ring 12. The feature that the transition from high penetration to low penetration occurs at a value of Δ that is relatively low with respect to the value of Hk: ΔΗ << Ηκ, so that the maximum allowable current difference Als that is not yet interpreted as an attempt to dishonestly use the telephone. In jargon, this was called a sharp breakthrough.

The AC voltage source 26 generates an AC voltage at an ohmic frequency within the range of 5-100 kHz and the impedance 27 has a magnitude of about 10 kD. This value is significant because it depends on the magnitude of the impedance of measuring coil 11 at frequency ω _,, so that a predetermined relatively low amplitude alternating current l _M (t) flows through measuring coil 11. The alternating current l _M (t) generates in the ring 12 a measuring field H _M (t) which covers the magnetic field Η _Δ ι. The measuring field Ημ (ϊ) is proportional to the number of alternating current l _M (t) and the number of turns of the measuring coil 11 N ₂ , which is about N ₂ = 250. Due to the large number of turns N ₂ , a relatively strong measuring field H _M (t) is created at relatively low alternating current l _M (t) of only a few μΑ, so the measuring circuit 13 consumes very little energy. When the magnitude of the alternating current l _M (t) is 10μΑ, the measuring field Ημ (ϊ) is approximately 20 times smaller than the magnetic field Η _Δ ι, with a difference of currents Δ1 = 2 mA. The voltmeter 28 measures the voltage U (t) on the measuring coil 11 which is proportional to the time deviation <In> (t) of the magnetic flux through the measuring coil 11 and thus also proportional to the magnetic induction B (t) produced by the magnetic field H ( t) = Hii + H _M (t) in ring 12, for time deviation.

In addition to the behavioral magnetization curves B (H) and Β (Δ1), Fig. 3 also shows the magnetic fields Ηι (ϊ) = Η _Δ ι, ι + Ημ (ϊ) and H ₂ (t) = H _A i, ₂ + HM (t) and the corresponding voltages U (t) = Ui (t) and U (t) = U ₂ (t), where the difference in currents is ΔΙι = 2 mA in the first case and ΔΙ ₂ = 4 mA. The magnitudes of the magnetic field Ημ (ϊ) and the voltages lh (t) and U ₂ (t) are shown at magnification. The form of the alternating current that excites the measuring coil 11 is of no particular significance. Saw alternating current can be easily generated.

The magnetic field Hi (t) is still not saturated by ring 12 (Fig. 1), so the time change of magnetic induction B (t) in ring 12 corresponding to the high inclination angle dB / dH of the magnetization curve B (H) against the refractive point K in measuring coil 11 a relatively high amplitude voltage Ui (t). However, the magnetic field H ₂ (t), which has a constant field component H _A i, ₂ , magnetically saturates the ring 12, so that the field B (t) corresponding to the inclination angle dB / dH of the magnetization curve B (H) slight changes over time. Therefore, the voltages U ₂ (t). the amplitude is extinct. The voltages U, (t) and U ₂ (t) are alternating and have no DC component.

In the first case, that is, at a voltage Ui (t), the voltmeter 28 produces a DC voltage V having a value greater than V _o . In the second case, that is, at voltage U2 (t), the value of DC voltage V is less than V _o . The difference ΔΙ between the two dc currents h and l ₂ , which is greater than the predetermined threshold value Ais, causes the switches 6 and 7 to be switched off. In this way, the telephone station 1 is adapted to detect the telephone 23 connected to the telephone station 1 as described above. and forbid him to call,

The magnetization curve B (H) in Fig. 3 corresponds to the ideal case. In fact, any ferromagnetic material has the properties of hysteresis in the form of a limited residual magnetization B _x and a limited coercive field strength H _c . In order for the meter to automatically return to satisfactory operation after an interrupted attempt to unauthorized use of the telephone, it is necessary that the magnetic magnetization, B _x, is sufficiently low. In this case, the low residual magnetization B _x means that the magnetic field B in the ring 12 acquires a value well below the saturation value B (H _K ) as soon as the difference ΔΙ between the currents It and L ₂ disappears and, at the same time, these currents create a magnetic field Η _Δ ι. Due to the high permeability μ _χ , the low residual magnetization B _x also implies a low coercive field strength H _c . The materials corresponding to the ideal magnetization curve B (H) are, for example, metallised glass masses, ie amorphous ferromagnetic materials. With a low residual magnetization B _x and a low coercive field strength H _c , the glass mass is known as VITROVAC 6025 F. The glass mass has a transverse anisotropy that affects the so-called F-loop characteristic of the magnetization curve B (H).

In a second embodiment, the measuring circuit 13 (FIG. 2) controls the measuring coil 11 as a so-called Fluxgate Sensor. The AC source 26, 27 is of different size, the voltmeter 28 has a bandpass filter 30, and the comparator circuit 29 has an inverter connected below it in the direction of current flow. The current source formed by the AC voltage source 26 and the impedance 27 supplies, ideally, a saw ac current l _{F at a} fundamental frequency co _F whose amplitude and number of turns N ₂ of the measuring coil 11 are such that the magnetic field H _F generated by the alternating current l _F and measuring coil

11, periodically saturates the ring 12, i.e., the amplitude of the alternating current If produces a magnetic field H larger than the field Ηκ · The bandpass filter 30 passes at least one even harmonic at a fundamental frequency of, ideally the first even harmonic at 2 * ofFig.4 illustrates the configuration times for magnetic fields H _F (t) = HFi (t) and H _F (t) = HF2 (t) and voltages U (t) = U _F i (t) and U (t) = UF2 (t) in measuring coil 11. In the first case, the measured current difference ΔΙ is zero. In this way, the magnetic field H _F i (t) has no constant field component. The voltage Upi (t), which is again proportional to the change in magnetic flux φ (ΐ) over time, and thus proportional to the change in magnetic field B (t) over time, acquires a configuration formed from positive to negative rectangular pulses. voltage U _F i (t) is positive and negative rectangular pulses are uniform characteristic, and the voltage U _F i (t) is the frequency spectrum has only odd harmonics. The dc dc voltage V is detected at the output of the voltmeter 28 and the comparator circuit 29 emits a signal “1. As the current difference ΔΙ increases, the constant field component of the magnetic field H _F 2 (t) increases. Because ring 12 is magnetically saturated, positive and negative rectangular pulses change length and position along the time axis, and the frequency spectrum of voltage U _F 2 (t) also has even harmonics. By means of the bandpass filter 30 arranged in the direction of current flow, the voltmeter 28 measures the strength of the second harmonic. The DC voltage V increases with increasing current difference ΔΙ. If the DC voltage V exceeds the value Vo, the comparator circuit 29 issues a signal "0". Thanks to the value V _o , it is possible to control the threshold value Als at which the output level of the comparator circuit 29 changes. The inverter which is connected to the output of the comparator circuit 29 changes the signal so that switches 6 and 7 can be switched as described above,

With this second chain, the ring 12 can be manufactured not from magnetic glass, but from ferromagnetic material with known hysteresis properties, such as Permalloy. Then, the voltages UFi (t) and UF2 (t) do not have the rectangular pulses shown in Fig. 4, but the measurement principles remain unchanged. Further details on the Fluxgate Sensor can be found, for example, in Fluxgale Sensor in Planar Microtechnology (Thomas Seitz, 1990, LA21-A23, pp. 799-802).

In yet another measuring circuit 13, the measuring coil 11 is connected in series or in parallel, depending on a capacitor having a capacitance C, as part of the LC-resonant circuit. The measuring circuit 13 consists of an electronic circuit which resonantly controls the resonant circuit and generates a signal proportional to the resonant frequency cor at which the resonant circuit oscillates. If the difference in currents ΔΙ is very small, the ring 12 is unsaturated and the measuring coil 11 has a high inductance Li. If the difference in currents Δ pakankamai is large enough, the ring 12 is magnetically saturated and the measuring coil acts as an air coil having an inductance L = Lib, which is significantly reduced with respect to L = Li. Since the resonant frequency is normally or = oi = iNLiC or © r = coib = 1 / VLibC, in the case of an unauthorized use of the telephone, this test can be readily recognized, Measuring circuit 13 is intended to signal the switching off of switches 6 and 7 the resonant frequency or exceeds a predetermined value. Since the resonant frequency or, at a predetermined fixed capacitance value C, depends only on the impedance L of the measuring coil 11, this method of measurement corresponds to the measurement of the impedance.

The above solutions for barring a telephone connected to a telephone station 1 (FIG. 1) as a circuit 23 are based on the use of a magnetic material whose magnetization curve is not linear in relation to the measured current difference ΔΙ and exhibits saturation characteristics that can be adapted, e.g. , terminate the connection of the illegally connected telephone as described above. The following will describe how to prohibit making telephone calls if circuit 23 is a suppressive tax accounting circuit.

The coils 8 and 9 are wound in opposite directions so that the currents h and l ₂ produce a magnetic time H in the ring 12, which, as mentioned above, is proportional to the difference between the currents h and l ₂ , the currents h and l ₂ being indicated by arrows. In this case it is irrelevant whether the currents h and l ₂ are constant or alternating. The total inductance L _to t = O of both coils 8 and 9. The alternating current pulse hi (FIG. 1) has the same direction as the direct current H, and the direction of the alternating current pulse h ₂ is opposite to the direction of direct current l ₂ . Therefore, the coils and 9 retain non-extinguishing inductance with respect to the tax accounting pulses formed by alternating current pulses hi and h ₂ . The coils 8 and 9, the ring 12 and the measuring coil 11 act as a transformer with respect to the AC pulses hi and h ₂ . To answer the question whether the circuit 23 that attenuates or even suppresses the tax accounting impulses connects output A to ground m, the transformer impedance conversion feature is used: the measuring circuit 13 is used to determine the impedance of the measuring coil 11, which in this case is the transformer input impedance. Ζτθ. The transformer input impedance θτθ depends on the transformer output impedance Z _la , which is determined by the transformer charge. In this way, the input impedance Ζτθ depends on whether the circuit 23 is connected or not.

The transformer input impedance measuring circuit 13 is shown in FIG. It consists of an AC voltage generator 31, a resistance 32, a voltmeter 31 and an evaluation circuit. The alternating voltage generator 31 generating a voltage of a predetermined size and frequency ωτ and the impedance 32 are connected in series, the magnitude of the impedance 32 associated with the input impedance Ζτθ being large, so that a predetermined variable current flows through the measuring coil 11. The frequency ωτ is chosen to be approximately equal to the frequency of the alternating current pulses hi and h ₂ and reaches about 50 Hz. The voltmeter 28 measures the ac voltage on the measuring coil 11 and supplies a dc voltage V which is proportional to the input impedance Ζτθ of the transformer input circuit 34. As can be seen in FIG. 1, the ring 12 of the transformer consisting of coils 8, 9.

z ·. coils · .11, the output impedance Zt ₃ also depends on the impedance on the telephone switch lines 2 and 3. Therefore, at best, the telephone station 1 is dedicated to its switching moment and periodically to set the input impedance Ζτθ and store it in the rating circuit 34 as reikšτθ. Then, during the operation of the telephone station 1, when switches 6 and 7 are on, the rating circuit 34 determines the input impedance Ζτθ at regular intervals or at any time intervals and compares it with the stored value Z _Te , for the norm -τθ-Ζτθ. at a predetermined value, the rating circuit 34 issues a signal that turns off switches 6 and 7.

Here are the principal facts which are necessary to understand the present invention. The measuring circuit of Fig. 2 and the measuring circuit of Fig. 5 may be connected in any manner known to the person skilled in the art so that the telephone station can recognize and prohibit various types of violations.

Claims (10)

DEFINITION OF INVENTION A telephone station (1) having a manipulator (14), first and second switches (6, 7), by means of which the telephone station (1) is connected via a dual line (2, 3) to a telephone switch (5) controlled by a telephone station (1). 1) a manipulator (14) such that when the switches (6, 7) are actuated, the telephone station (1) is supplied with electricity from the telephone switch lines (2, 3), in addition to the circuit element (10), the first switch (10); 6), the circuit element (10) and the second switch (7) are electrically connected in series, characterized in that a first coil (8) is provided between the first switch (6) and the circuit element (10) and between the circuit element (10). and the second switch (7) is provided with a second coil (8), both coils (8, 9) being wound in opposite directions about the magnetic material element (12), the telephone station (1) having means (11, 13; 11, 26, 27). ) to create a variable magnetic field (Ημ (ϊ); Hp (t)) in the element (12), means (11, 13; 11, 28 , 29; 11, 28, 29, 30) means for measuring the time deviation dB / dt of magnetic induction B (t) occurring in the element (12) and means (13; 29) generate a signal that turns off the switches (6, 7) if the measured deviation dB / dt exceeds a predetermined value. A telephone station as claimed in claim 1, wherein the magnetization of the magnetic material is represented by a magnetization curve B (H) having a high magnetic permeability (μ _χ ) per unit when the magnitude of the magnetic field H is ³ H ³ lower than HK, and the magnetic permeability (μχ) is low when the magnitude of the magnetic field H is ³ H ³ greater than the value HK, and the transition range from high permeability (μ _χ ) j to low ΔΗ is small relative to H _K and the residual j magnetization B _r is low relative to the saturation value B (H _K ). 3. A telephone station as claimed in claim 2, wherein the magnetic material is metallized glass. 4. Telephone exchange according to claim 2 or 3, wherein the means for varying the magnetic field (H _M (t)) to create a variable current source is composed of an AC voltage generator (26) and a resistance (27) to which is connected the measuring coil (11) is wound around the element (12) and the amplitude of the magnetic field (H _M (t)) is low relative to the value H _K. 5. A telephone exchange according to claims 1-3, wherein the means for generating an alternating magnetic field (Hp (t)) is an AC source consisting of an AC voltage generator (26) and a resistor (27) to which is wound. about the element (12), the measuring coil (11), furthermore, the amplitude of the variable magnetic field (Hp (t)) is so large that a magnetic saturation effect is produced in the element (12). 6. A telephone station as claimed in claim 5, characterized in that the current frequency of the current flowing through the measuring coil (11) is (of) and that the means (11, 13; 11,28, 29, 30) have a deviation in dB / dt. the measurement consists of a voltmeter (38) and a bandpass filter (30) transmitting a second harmonic at a frequency (2 * g> f). A telephone station (1) having a manipulator (14), first and second switches (6, 7), by means of which the telephone station (1) is connected by two lines (2, 3) to a telephone switch (5) controlled by a telephone station (5). 1) a manipulator (14) such that, when the switches (6, 7) are turned on, the telephone station (1) is supplied with electricity from the telephone switch lines (2, 3), in addition to the first element of the circuit element (10). (6), the circuit element (10) and the second switch (7) are electrically connected in series, characterized in that a first coil (8) is provided between the first switch (6) and the circuit element (10), between the circuit element (10). and the second switch (7) is provided with a second coil (8), both coils (8, 9) being wound in opposite directions about the magnetic material element (12), a third measuring coil (11) is wound around the element (12) and the signal is off. the switches (6, 7) can be created depending on the measurement mo coils (11) impedance (L). 8. A telephone station as claimed in claim 7, characterized in that the measuring coil (11) is arranged in a resonant circuit having a means (13) which controls the measuring coil (11) resonantly and determines the resonant frequency (cor), the resonant frequency (co _R ). depends on the impedance (L) of the measuring coil (11), the signal turns off the switches (6, 7) when the resonant frequency (cor) exceeds a predetermined value. 9. The telephone station of claim 7, further comprising a circuit (31, 32, 33, 34) for determining the impedance (L) of the measuring coil (11) at the frequency of the accounting pulses (cor). 10. A telephone station as claimed in any one of claims 1 to 9, wherein the magnetic element (12) is a ring.