KR100241703B1 - Subscriber line status control circuit for full-electronic exchange - Google Patents

Abstract

The present invention relates to a multiplexing subscriber line state control of a full-duplex switching system, and more particularly, to a subscriber line state control circuit in a full-duplex switching system in which a subscriber board for controlling a subscriber line state on an individual channel basis is suitable for multi- .

It is an object of the present invention to provide a subscriber line matching circuit of a demultiplexing scheme in which a control logic for notifying a hook state of each subscriber to an exchange through an enable signal according to a subscriber hook- The state control circuit enables a multiplexing scheme so that the design of a highly integrated exchange subscriber board is economically feasible.

Accordingly, multiplexing-type subscriber line control becomes possible by connecting a circuit for processing an enable signal to a subscriber line matching circuit of a demultiplexing scheme, so that an in-use signal is directly used for improving the integration and reliability of the entire electronic exchanger There is a very economical effect on the circuit configuration as compared with the multiplexing method.

Description

The subscriber line state control circuit

The present invention relates to a multiplexing subscriber line state control of a full-duplex switching system, and more particularly, to a subscriber line state control circuit in a full-duplex switching system in which a subscriber board for controlling a subscriber line state on an individual channel basis is suitable for multi- .

In the conventional exchanger, since the state of the subscriber line is processed in the individual channel unit through the demultiplexing line, the control between the subscriber channels is not required.

However, when outputting the subscriber line status in a multiplexing manner, an enable signal which is a subscriber line status output control signal for displaying an individual channel unit in the subscriber line status is required. Here, the demultiplexing is a method of one-to-one control of a hook state signal output from one subscriber line matching circuit. Multiplexing is a method of controlling several of the hook state signals output from several subscriber line matching circuits in units of several units to be.

The subscriber line state control circuit according to the demultiplexing scheme and the multiplexing scheme will be described with reference to FIG.

Here, FIG. 1A is a subscriber line state control circuit according to a demultiplexing scheme, and FIG. 1B is a subscriber line state control circuit according to a multiplexing scheme.

That is, according to FIG. 1A, since it is a subscriber line state control circuit according to a demultiplexing scheme, a subscriber line and a subscriber line matching circuit 10 are one-to-one associated with each other without requiring a separate in- do.

As shown in FIG. 1B, when the subscriber line state control circuit according to the multiplexing scheme is hooked off by any one of several subscribers in the switchboard, the subscriber line state control circuit is controlled by the subscriber line matching circuits 20-1 to 20-4, The hook status information of the subscriber detected by the subscriber can be outputted so that the hook status of all subscribers in the exchange can be confirmed. At this time, only four subscribers are shown in the drawing.

For example, if there are 32 subscribers, multiplexing them two-to-one will reduce the subscriber's hook status signal line to 16.

Hook state information of each subscriber is multiplexed together with address information of the subscriber in the multiplexers 30-1 and 30-2 and transmitted to the exchange side.

The exchange then processes the 16 signals to determine which subscriber line is in the hook-off state.

Here, the hook state signal is outputted as 'low' only in the subscriber line matching circuit which detects the hook-off by the generation of the enable signal.

That is, when an enable signal is generated in the hook-off detector 21 through the input terminal E of the enable signal, the hook state information detected by the hook-off detector 21 is transmitted to the subscriber through the first control logic 22, And output as 'low' or 'high' to the line state output terminal (/ DET).

However, although the multiplexing process can be performed by the subscriber line state control circuit of the multiplexing scheme as described above, the cost of the subscriber line state control circuit of the demultiplexing scheme is somewhat higher than that of the demultiplexing scheme because of the configuration of the control logic according to the enable signal process.

In addition, when the subscriber line control circuit according to the demultiplexing scheme can not perform the multiplexing process, the number of patterns to be routed in the subscriber board increases when several subscriber lines are added, which affects the reliability of the subscriber board design.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a subscriber line matching circuit of a demultiplexing scheme, Logic is added to the subscriber line state control circuit of the demultiplexing scheme, thereby enabling a multiplexing scheme to economically design a highly integrated switching subscriber board.

According to another aspect of the present invention, there is provided a subscriber line state control circuit for a subscriber line state control circuit, the subscriber line state control circuit comprising: a subscriber line matching circuit of a demultiplexing scheme for subscriber individual channel processing, And the voltage state applied through the collector resistance is changed according to the signal state of the subscriber line state output terminal of the subscriber line matching circuit when the on state is on, And a control logic including a transistor for outputting the status signal as a status signal to enable multi-channel control of the subscriber line.

1A is a schematic diagram of a subscriber line state control circuit according to a general demultiplexing scheme,

1B is a schematic diagram of a subscriber line state control circuit according to a general multiplexing scheme,

2 is a configuration diagram of a subscriber line state control circuit according to the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

10, 20-1 to 20-4: Subscriber line matching circuit 21: Hook-off detector

22,40: Control logic R1: Base resistance

R2: Collector resistance Q1: Transistor

Hereinafter, an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

2 is a configuration diagram of a subscriber line state control circuit in the electronic exchanger according to the present invention.

The configuration includes a subscriber line matching circuit 10 and a second control logic 40 including a base resistor R1 and a collector resistor R2 and a transistor Q1.

The subscriber line matching circuit 10 is a demultiplexing subscriber line matching circuit shown in FIG. 1A. That is, no circuit capable of processing the enable signal is provided.

The second control logic 40 includes a transistor Q1 for performing a switching operation by an enable signal generated in an exchange that senses a hook-off by a subscriber, and a transistor Q1 for turning on and off the transistor Q1 And resistors R1 and R2 for determining the magnitude of the base current I1 and the collector current I2, respectively.

At this time, the emitter terminal of the transistor Q1 is connected to the subscriber line state output terminal (/ DET) of the subscriber line matching circuit 10.

The operation of the present invention having the above configuration is as follows.

When a hook-off occurs by any one subscriber, the enable signal is brought to a high state and applied to the base end of the transistor Q1 of the second control logic 40. [

Accordingly, the transistor Q1 performs a switching operation. At this time, if the subscriber is in a hook-on state, the signal of the subscriber line state output terminal (/ DET) of the subscriber circuit line matching circuit 10 becomes a high state.

As a result, the transistor Q1 in such a case can not perform the switching operation in the 'high' state of the emitter.

As a result, the hook state signal output from the collector terminal becomes a high impedance state and becomes a signal irrespective of hook-on and hook-off.

On the other hand, when the corresponding subscriber is in the hook-off state, the signal of the subscriber line state output terminal (/ DET) of the subscriber circuit line matching circuit 10 becomes a low state and the switching operation of the transistor Q1 becomes possible.

That is, a 'low' signal is outputted as a hook state signal.

Thus, the hook state of the subscriber is detected as a hook-off state.

Table 1 shows the state of the in-ear signal and the hook state signal according to the signal state of the subscriber's line state output terminal (/ DET) in truth table.

Hook state signal value according to the signal state of the enable signal and the subscriber line state output terminal The enable signal / DET Hook status signal H H Z L L L X Z X Z

(H: high state, L: low state, Z: high impedance, X: not related)

Hereinafter, the optimal resistance value of each of the resistors R1 and R2 for enabling the switching operation of the transistor Q1 when the transistor Q1 is a 2N2222A NPN transistor will be described.

At this time, the collector input voltage Vcc is 5 V and the collector resistance R2 is 4.7 k ?.

For the 2N2222A NPN transistor, And its minimum value is '75'.

At this point, when the transistor Q1 is turned on, the transistor Q1 has a collector current I2 of about 1 mA.

Therefore, if the transistor Q1 has a base current I1 of 0.0133 mA, the minimum value? Of the transistor Q1 can be 75, so that the truth table shown in Table 1 can be obtained.

The optimum value of the base resistance (R1) is obtained by using the following equation.

Here, E ₀ is 2 V as the minimum value of the input voltage when the enable signal is in a high state.

At this time, when the base resistor R1 is small, the base current I1 is actually generated more than necessary. Therefore, when the most optimal value is specified within the allowable range, 95 k?

Accordingly, the truth table as shown in Table 1 satisfies the most optimal state with the 2N2222A NPN transistor, the base resistance R1 of 95 k? And the second control logic 40 of the collector resistance R2 of 4.7 k? do.

As described above, according to the present invention, it is possible to control a subscriber line in a multiplexing scheme by connecting a circuit for processing an enable signal to a subscriber line matching circuit of a demultiplexing scheme, thereby improving the integration degree and reliability of the entire electronic exchanger There is a very economical effect on the circuit configuration as compared with the multiplexing method in which the in-use signal is directly used.

Claims (1)

1. An all-electronic exchanger having a subscriber line matching circuit of a demultiplexing type for subscriber individual channel processing, And an on / off operation is performed by inputting an enable signal generated from the exchange according to a subscriber hook-off through a base resistor, and when the on state is on, a collector resistance is determined according to a signal state of a subscriber line state output terminal of the subscriber line matching circuit And a control logic including a transistor for outputting a voltage state applied to the subscriber line as a hook state signal so as to enable multi-channel control of the subscriber line.