KR880002353A - Subscriber circuit - Google Patents

Abstract

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Description

Subscriber circuit

As this is a public information case, the full text was not included.

1A and 1B are circuit diagrams for explaining a hybrid function of a subscriber circuit.

2 is a block diagram for explaining the principle of the subscriber circuit according to the first embodiment of the present invention.

3 is a block diagram showing a configuration of a subscriber circuit according to a first embodiment of the present invention.

Claims (9)

A subscriber circuit connected to a subscriber end and a switchboard, the subscriber circuit for connecting the subscriber end and the switchboard, comprising: a pair of subscriber nodes for coupling the subscriber circuit to the subscriber end via a subscriber line; A pair of receiving nodes and a pair of transmitting nodes for coupling the subscriber circuit to the switchboard via one receiving line and one transmitting line; Power supply means for supplying a DC current to the subscriber end via the subscriber nodes and for regulating the DC current; First adder means for adding a voltage between the pair of subscriber nodes and a voltage supplied between the pair of receiving nodes; First impedance means having an impedance corresponding to a real multiple of the impedance between the subscriber nodes observed from the subscriber lines, and receiving an output voltage of the first adder means; Inverting amplifier means for receiving an output of the actual first impedance means; Second impedance means having an impedance corresponding to a real multiple of impedances of the subscriber line and the subscriber end observed from the subscriber node, and inserted into the feedback path of the inverting amplifier means; Feedback means for supplying a signal corresponding to a current flowing through the first impedance means to the power supply means as a control signal; Second adder means for adding an output voltage of the inverting amplifier means, an output voltage of the first adder means and a voltage supplied between the pair of receiving nodes, and as a result, supplying the voltage to the pair of transmitting nodes; And a subscriber circuit. A subscriber circuit as claimed in claim 1, wherein said feedback means comprises direct detection means for detecting a current flowing through said first impedance means. 3. The subscriber circuit as claimed in claim 2, wherein the direct detection means includes a resistance element coupled in series with the first impedance means, and a potential difference detection means for detecting a voltage drop by the resistance element. . The said feedback means is provided with indirect detection means for detecting the electric current which flows through the said 2nd impedance element, The said electric current corresponds to the electric current which flows through the said 1st impedance element. Subscriber circuit. 5. The indirect detecting means according to claim 4, characterized in that the indirect detecting means is provided with an output portion of the inverting amplifier means and includes current generating means for providing a current signal corresponding to the current flowing through the second impedance means. Subscriber circuit. A subscriber circuit connected to a subscriber end and a switchboard, the subscriber circuit for connecting the subscriber end and the switchboard, comprising: a pair of subscriber nodes for coupling the subscriber circuit to the subscriber end via a subscriber line; A pair of receiving nodes and a pair of transmitting nodes for coupling the subscriber circuit to the switchboard via one receiving line and one transmitting line; Power supply means for supplying a DC current to the subscriber end via the subscriber nodes and for regulating the DC current; First adder means for adding a voltage between the pair of subscriber nodes and a voltage supplied between the pair of receiving nodes; First impedance means having an impedance corresponding to a real multiple of the impedance between the subscriber nodes observed from the subscriber lines, and receiving an output voltage of the first adder means; Inverting amplifier means for receiving an output of said first impedance means; Second impedance means having an impedance corresponding to a real multiple of impedances of the subscriber line and the subscriber end observed from the subscriber node, and inserted into a feedback path of the power generation amplifier means; Feedback means for detecting a current flowing through said second impedance means to provide a detection signal, and for supplying said detection signal to said power supply means as a control signal; Second adder means for adding an output voltage of the inverting amplifier means, an output voltage of the first adder means and a voltage supplied between the pair of receiving nodes, and as a result, supplying the voltage to the pair of transmitting nodes; And a subscriber circuit. 7. The terminal of claim 6, wherein the first adder means has its inverting input terminal coupled via resistors to one of the subscriber nodes and to one of the receiving nodes, the non-inverting input terminal being connected via the resistor to the other subscriber node. And a buffer amplifier means coupled to the subscriber circuit. 7. The subscriber circuit of claim 6 wherein the second adder means comprises one buffer amplifier and is a weighting adder circuit. A subscriber circuit connected to a subscriber end and a switchboard, the subscriber circuit for connecting the subscriber end and the switchboard, comprising: a pair of subscriber nodes L ₁ , L ₂ for coupling the subscriber circuit to the subscriber end via a subscriber line; A pair of receiving nodes and a pair of transmitting nodes for coupling said subscriber circuit to said switchboard via one receiving line and one transmitting line; First means for adding a voltage V ₀ and a received voltage V _RX between the pair of subscriber nodes L ₁ and L ₂ ; A load R ₁ + NZ _{T to} which the voltage obtained by the first means is applied; Second means for amplifying the voltage obtained by the first means by a coefficient of NZ _B / (R ₁ + NZ _T ), and subtracting V _RX from the voltage V ₀ and the received voltage V _RX from the subtraction; Third means for calculating a difference between a result and the amplification result and providing a transmission voltage V _TX ; A fourth stage for amplifying the difference between the potential difference appearing across the load R ₁ , that is, the sum of the voltages V ₀ and V _RX calculated in NZ _T by the coefficient of A ₀ ; Fifth and sixth means for converting currents flowing through the subscriber nodes L ₁ and L ₂ into voltages using loads R ₂ and R ₃ , respectively; Seventh means for adding the voltages obtained by the fifth and sixth means; Eighth means for adding the voltage obtained by the seventh means and the reference voltage for determining the voltage and the DC power supply current obtained by the fourth means, and amplifying the voltage by the coefficient of A _{1 as} a result; And a ninth means for supplying the voltages obtained by the eighth means to the loads R ₂ and R ₃ . ※ Note: The disclosure is based on the initial application.