NL8800475A - Telephone subscriber line interface circuit - has level shifting function which makes it transparent to speech frequencies - Google Patents

Abstract

The interface circuit has four cascaded bi-directional amplifiers (1,2,3,4). The subscriber's appts. (Zsub) is connected in parallel to two amplifiers (1,3), one (3) of which provides a high impedance shunt to high frequencies and a low impedance, e.g. 300 ohms, shunt to low frequencies. The other amplifier (1) connects to the intermediate circuit (2,4). The intermediate circuit has three amplifier (1,2,4) terminal pairs in parallel. One is the other side of that (1) connected to the subscriber, another is the one (2) connected to the PABX switch matrix (Zpabx). The third amplifier supplies a frequency-dependent shunt impedance. The level shift function of the circuit makes it transparent to speech frequencies, i.e. 300 to 3400 Hz, but also enables detection of on/off hook conditions.

Description

t. ) i N.0. 35034 1%

Telephone line interface Circuit Inventors: Ernst Hugo Nordholt and

Petrus Adrianus Marie van der Caranen both in Berkel and Rodenrijs.

The invention relates to a speech connection between a switching matrix and the associated device interface circuits, as used in PABX circuits.

A levelshift function has been realized here, while the system is transparent for the speech signals in the band from 300 Hz to 3400 Hz. In the chosen approach it is easy to break this connection.

Furthermore, it is possible to use part of this circuit for applying the bell voltage.

It is also possible to carry out detection of loop currents in order to be able to detect the resting and speaking state of the device (on-hook / off-hook condition).

15 The bidirectional amplifier principle:

Figure 1 shows the symbol for a bidrectional amplifier circuit. For this circuit holds: U1 = r1 *! 2 20 U2 = ^ 2 * ^ 1 h = U ^ / Ii = - (RpR2) / Z0 U2 / Ui = -Z0 / Ri Igrli = R2 / Z0 25 Figure 2 gives a block diagram of a bidirectional amplifier circuit.

The connection between switching matrix and device lines:

Figure 3 shows the concept symbolically. The cascade of bidirectional amplifier 1 and bidirectional amplifier 2 guarantees a completely transparent system. After all, the impedance Z2 seen in the left side of bi-directional amplifier circuit 2 is equal to 30k.50 / Z switch, matr1x.

The impedance on the left side of bidirectional amplifier 1 is: 30k * 150 / Z2 = zSchakelmatrix * So ool (the 1mPedantl'e zo 35 will be equal to Ztoestel ·

To realize the galvanic isolation, bidirectional amplifier 4 has been added. For low frequencies, the impedance at the output terminals of the bi-directional amplifier is 4: 600k.

The impedance Z4, which can be seen on the other side of bidirectional amplifier 40, is then 15k.600 / 600k = 15 ohms. There is therefore almost a short circuit for DC between terminals a .8800475 \ ί 2 and b, which means that the DC impedance Z-j and Z0 at the input and output is very high (300k).

In addition, an inductive character is added to the impedance Zj which can be seen between the subscriber lines. This is effected by bidirectional amplifier 3.

For low frequencies, the impedance Z3 at the input of bidirectional amplifier 3 is equal to 30k.l50 / 15k = 300 ohms.

For high frequency, the output of bidirectional amplifier 3 is short-circuited, so the impedance Z3 is high.

The parallel connection of the 15 kohm resistor and the 3.3 uF capacitor is converted to a series connection of a 300 ohm resistor and an inductance of 14.85 H.

The parallel connection at the output of bidirectional amplifier 15 4 of 600 kohm and 33uF is converted into a series connection of 15 ohm and 297H. (The resistance and capacitance values are chosen quite randomly).

8800475

Claims (5)

1. Telephone line interface circuit, provided with two colors, whether or not connected by cable to the device and two terminals, which are connected to the switching matrix, whereby a transparent connection can be switched on or off for speech signals, supplying a line voltage or ring voltage to the terminals of the device of choice only, characterized in that the speech connection is established by means of two electronically implemented, cascaded, two-way amplifiers, the cascade acting as an accurate one-to-one transformer for speech signals; furthermore, a third bi-directional amplifier with a gate is connected in parallel to the common gate of said bi-directional amplifiers and the other gate is terminated with an impedance, thereby obtaining a DC decoupling between device and switching matrix terminals. 2. Interface circuit according to claim 1, characterized in that a fourth on and off switchable bidirectional amplifier with one port is connected in parallel to the device terminals and the other port is terminated with an impedance, whereby a defined impedance is connected in parallel the device terminals, and that a DC voltage or DC current can be supplied to a suitable addition point in one of the bidirectional amplifiers, which device can supply the device with the desired supply voltage. Interface circuit according to claims 1 and 2, characterized in that an alternating voltage or alternating current which can supply the device with the desired bell voltage can be supplied to a suitable addition point in one of the bidirectional amplifiers. Interface circuit according to claims 1 and 2, characterized in that an alternating voltage and / or alternating current can be supplied to a suitable addition point in one of the bidirectional amplifiers, through which an audio signal can be superimposed on the line connection. Interface circuit according to claims 1, 2 and 3, characterized in that the magnitude of the voltage over and / or the current through the device can be measured for detection purposes by measuring the current and / or voltage at the the device connected port of the bi-directional amplifier 1 or 3. 40 ++++++++++ ----- ^ .8800475