KR910001083Y1 - Line interface circuit in automatic answering system - Google Patents

Abstract

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Description

Line interface circuit of answering machine

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

3 and 4 are operational waveform diagrams of FIG.

* Explanation of symbols for main parts of the drawings

100: discharge tube 101,102: fuse coil

103,111: relay contact switch 104: transformer

106,115,119: Capacitor 108,110,112,114,116,118,130: Resistor

109: bridge diode 121, 122: zener diode

113,117: diode 120: comparator

124 microprocessor

The present invention relates to a line interface circuit of an answering machine, and more particularly to a circuit for easily detecting a ring signal and a message interrupt signal input to a line interface. will be.

The answering machine is connected to the telephone line and detects the ring signal inputted to the telephone line when the user is absent, sends the user's OUT Going Message to the caller, and the caller's input message (IN Comming). Refers to an additional device of the telephone which stores a message) in an internal recording unit.

Unlike the answering phone, the answering device described above is used in parallel with an existing phone, and thus detects a ring signal of 1 second per second and a second signal sent from the switching center, and a ring signal arrives or While the answering machine is in operation, when the user picks up the handset of the telephone connected in parallel, it should have a function to detect the message and stop the operation of the answering machine.

The ring detection function and the message interrupt detection function as described above are connected to the telephone line of the switch and a line processor circuit for interfacing the input / output signals with the answering machine and the microprocessor for controlling the answering machine system (Microprocessor (hereinafter referred to as MPU)). It is controlled by a circuit whose circuit is shown in FIG.

1 is a conventional line interface circuit diagram, which is connected to both ends of telephone lines L1 and L2 to prevent surge, and is connected in series to the telephone lines L1 and L2, respectively. A fuse coil (2) (3) and a fuse coil (2) (3) for blocking the overcurrent inlet are input to the primary winding (Na), and the organic winding is output to the secondary winding (Nc) at the same time. A transformer 3 having a primary winding Nb to which the primary winding Na and one side are connected, and the other side is connected to the capacitor 5, one end of the fuse coil 2 and the transformer 3 The relay contact switch S1 connected between one side of the primary winding Na of the switch and switched by predetermined control, and the common contact terminal COM2 are connected to the fuse coil 3, and the Normal open (NO) (NO2) is connected to the connection point of the primary winding (Na) (Nb), and a capacitor for AC passing through the other end of the primary winding (Nb) (5) and a normally closed contact (Normal Close: NC) NC2 is connected, and the relay contact switch S2 in which the contact point NO2 (NC2) is switched by a predetermined control, and the relay contact switch ( A resistor 6 and a zener diode connected in series between the contact point NC2 of S2 and the telephone line L1 to emit light in response to an input of a ring signal limited to a predetermined level and limited to a predetermined level. 7) (8), a resistor (9), an anode is connected to the light emitting diode of the bidirectional photocoupler 10 and the telephone line L1, and a cathode is connected to the zener diode 8 and the resistor (9). And a plurality of constant current source diodes 12 connected to a series connection point with a plurality of constant current source diodes 12 and a plurality of constant current source diodes 11 connected in a reverse direction to the plurality of constant current source diodes 12 and light emitting states of the light emitting diodes. The phototransistor of the bidirectional photocoupler 10 and the photocoupler 10 It is connected between the to transistor emitter and the ground and outputs the signal through the emitter resistor 13 and the capacitor 14 and the resistor 17 which outputs the output as a signal of a predetermined level, and the emitter is grounded to the base. A ring signal detection circuit 18 composed of a transistor 16 which drives the phototransistor output when the phototransistor output is input as a predetermined signal from the connected base resistor 15, and connected to both ends of the primary winding Na of the transformer 3; When the relay contact switch (S1) (S2) is switched to the normal open terminal (NO1) (NO2), a predetermined voltage through the bridge diode 19 and the resistor (29) for full-wave rectification of the voltage (L1) (L2) Is input to the collector, and the emitter is connected to the positive voltage output terminal of the transistor 28 and the bridge diode 19 for outputting a signal in response to the signal through the base resistor 27 with the emitter grounded. Is the base resistance A transistor 24 connected to (27) and switched by a base input signal to drive the transistor 28 and the DC voltage output both ends of the bridge diode 29 (+) (-) and at the same time the transistor 24 Is composed of diodes 21, 25, resistors 22, 26, and capacitors 23 for driving the transistor 24 when the output voltage of the bridge diode 19 suddenly changes. A transistor of the analog switch 31 and the ring signal detection signal 18 connected to the interrupt detection circuit 30 and the secondary side winding (NC) output line of the transformer 3 and switched by a predetermined control signal. The relay drive signal is outputted to the relay driver 32, 33 by the ring detection signal outputted from 16, and the system is controlled. The message interrupt signal detection circuit 30 and the relay driver 32, 33 are controlled. By blocking the relay drive signal It is composed of the MPU 50 for stopping the operation of the system.

Looking at the operation of the circuit configured as described above, the MPU 50 initially outputs a signal of "low" to the relay driver 32, 33, so that the relay contact switch (S1) (S2) is normally closed terminal (NC1) (NC2).

In the state where the relay contact switches S1 and S2 are connected to the normal cross terminals NC1 and NC2, ring signals (approximately 20 HZ) of 1 second and 2 seconds are sent from the switching station on the lines L1 and L2. When it arrives, it is a photocoupler in which the signal of the AC component is connected in both directions to the resistor 6 and the zener diodes 7 and 8 and the resistor 9 through the relay contacts COM2 NC2 and the capacitor 5 in both directions. Input to a series circuit of two light emitting diodes (10).

At this time, the ring signal of the 1 second speed and 2 seconds short state input to the series circuit is set to a predetermined level by the Zener diode 7-8, whereby the light emitting diode of the photocoupler 10 is the ring signal of the 1 second speed state. Is emitted upon input.

The light emitting diode light emission in the photocoupler 10 "turns on" the port transistor, whereby the transistor 16 is "turned on" and the ring signal detection signal in the "low" state is input to the MPU 50.

The microcomputer 50 counts the ring detection signal output from the transistor 16 until a predetermined number of times and outputs a relay driving signal to the relay driving units 32 and 33 when the predetermined number of times is reached. After outputting the enable signal to the switching via 51) and outputs the system operation drive signal to the bus (53).

Accordingly, the relay contact switches S1 and S2 of the relay driving units 32 and 33 are connected to the normal open terminals NO1 and NO2, and the analog switches 31 for inputting the control signal of the MPU 50 are connected. Is “on”.

Thereafter, an output message deck (not shown) is driven by a signal output from the bus 53 of the MPU 50 to enable a user message through a line 31b. It sends out to the line 31a of the secondary winding NC of the transformer 3 through the analog switch 31. FIG.

The input signal of the secondary winding of the transformer 3 is induced to the primary winding Na and outputs on the lines L1 and L2 through the relay contact switches S1 and S2.

On the other hand, as described above, the line voltage (constant DC voltage output from the exchanger) and the audio signal in the state where the output message OGM, which is the user's record, are output on the lines L1 and L2, and the audio signal of the bridge diode 19 It is input to AC signal input terminal.

Therefore, after rectifying to a constant DC voltage by the operation of the bridge diode 19, it is input to the emitter of the transistor 24, input to the diode 21, the resistor 22, the capacitor 23 is input to the capacitor 23 The transistor 24 is " turned off " by charging a predetermined voltage.

By the " turning off " of the transistor 24, the transistor 28 continues to input the signal of the " high " state to the MPU 50 via the line 52.

At this time, if a hook-off of a telephone (not shown) connected in parallel to the telephone lines L1 and L2 is carried out, the voltage of the telephone lines L1 and L2 is reduced to the operation of the telephone connected in parallel. The resistance is reduced as a result of the parallel connection to the operating resistance caused by the action of the automatic response device.

The DC output voltage of the bridge diode 19 drops due to the line voltage down of the lines L1 and L2, and the diodes 21, 25, resistors 22, 26, and Rb are capacitors. The operation by (23) causes the transistor 24 to be " turned on " to input the positive voltage output of the bridge diode 19, which is input to the emitter, via the resistor 27 to the base of the transistor 28. . Transistor 28 is thus " turned on " so that the voltage on line 52 drops to " low " by passing a predetermined voltage through resistor 29 to ground through the collector-emitter.

Due to the voltage logic of the line 52, the MPU 50, which is monitoring the message interrupt function, transitions from "high" to "low" so that the telephone connected in parallel to the lines L1 and L2 is hooked. It is recognized that the "off" and outputs a predetermined control signal to the bus 53 to stop the transmission of the output message, and then interrupt the relay drive signal of the relay drive unit 32 (33) to stop the automatic response function.

At this time, the user can make a call using a parallel-connected telephone.

However, the conventional circuit operated as described above has been a cost increase factor due to the increase of man-hours by separately configuring circuits for detecting message interrupts of ring signals.

Accordingly, an object of the present invention is to detect a ring signal as a comparison result when the ring signal voltage is superimposed on a second voltage of a comparator for comparing and outputting a predetermined first voltage and a second voltage having different voltage levels in a predetermined state. It is to provide a circuit for causing the first voltage to change suddenly during the drop and detect the message interrupt as a result of the comparison.

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

2 is a circuit diagram according to the present invention, which is connected in series with both ends of telephone lines L1 and L2 to prevent surge and the telephone lines L1 and L2, respectively, in series to connect over current. A transformer for preventing the fuse coils 101 and 102 and the fuse coils 101 and 102 through the primary coil and outputting the signal to the secondary side, and organically outputting the signal induced to the secondary side to the primary side. It has a perm 104 and a normal cross terminal NC10, a common terminal COM10 is connected to the fuse coil 101, and a normal open terminal NO10 is connected to one end of the primary side of the transformer 104. The signal of the line L1 is connected to the relay contact switch 103 which contacts and switches the closed terminal NO10 (NC10), and the normal open terminal NO10 of the relay contact switch 103, and the signal is predetermined. Serial connection to limiting resistor 108 and normal cross terminal NC10 And a bridge for inputting the capacitor 106 and the resistor 107 for limiting only the AC signal components, the pass signals of the resistors 107 and 108 and the signal of the telephone line L2 to the AC input terminal for full-wave rectification and output. The resistor 110 connected in series across the output of the diode 109 and the bridge diode 109 and the rectified voltage through the resistor 110 are input to the normal open terminal NO11 and a predetermined operating voltage VCC is input. A relay contact switch 111 for inputting to the normal cross terminal NC11 and outputting only one of the two voltages to the common terminal COM11 according to a predetermined control, and a normal open terminal NO11 of the relay contact switch 111; A zener diode 121, a resistor 130, a zener diode 122 and a relay connected between the grounds to make the voltage of the bridge diode 109 a predetermined first voltage V1 and a second voltage V2; Connected between the common terminal COM11 of the contact switch 111 and the ground Is connected between the resistor 112, the one-way diode 113, the resistor 114, and the common connection node of the zener diode 122 and the resistor 114 and the ground to divide the voltage to output the third voltage VB. A resistor 116 and a diode connected in series between the timing capacitor 115 for charging and discharging a predetermined voltage, the common terminal COM11 of the relay contact switch 111, and the ground to output a predetermined fourth voltage VA. 117 and a resistor 118, a capacitor 119 connected in parallel with the resistor 118 to charge and discharge the fourth voltage, and the third voltage VB and the fourth voltage VA are non-inverted. The comparator 120 inputs (+) and compares the inverting terminal (-) and outputs a detection signal according to the result, and the relay drive signal, the switching enable signal, and the system control according to the detection signal of the comparator 120. An MPU 124 for outputting a signal, a relay drive signal, a switching enable signal, and a system control signal of the MPU 124; Transistors 125 for inputting a predetermined power source by inputting the MPU 124 and the relay driving signal of the MPU 124 as a base, respectively, and passing the current of the relay coil RY connected to the collector. ) And an analog switch 126 connected between the secondary output lines of the transformer 100 and switched by a switching enable signal of the MPU 124.

3 is a ring detection operation waveform diagram of FIG. 2 according to the present invention, (a) is an input waveform diagram of a ring signal, (b) is a waveform diagram of third and fourth voltages, and (c) is a Ring signal detection waveform.

4 is a waveform diagram of the message interrupt detection operation of FIG. 2 according to the present invention, (a) is a voltage fluctuation waveform diagram of lines L1 and L2, (b) a fluctuation waveform diagram of third and fourth voltages, (c) is a message interrupt detection waveform diagram of a comparator.

Hereinafter, the operation example of FIG. 2 according to the present invention will be described with reference to the operation waveform diagrams of FIGS. 3 and 4.

In the initial state, all signals of the MPU 124 output the normal state signal, so that the transistor 125 is "turned off", the analog switch 126 is disabled, and the operation of the triggering machine is stopped. To be.

Accordingly, the relay contact switches 103 and 111 switched by the operation of the transistor 125 are in a state in which each common terminal COM10 and COM11 are connected to each normal cross terminal NC10 and N C11. Will be.

In the above state, the line voltage signals at both ends of the telephone lines L1 and L2 are connected to the normal cross terminal NC10 and the bridge diode 109 of the relay contact switch 103 through each fuse coil 101 and 102. It is input at one end of AC input.

In addition, the power supply voltage VCC of the common contact terminal COM11 of the relay contact switch 111 in which the power supply voltage VCC input to the normal cross terminal NC11 is switched to the common terminal COM 11 is connected to the resistor 112. The zener diode 122, the capacitor 115, and the resistor 114 are inputted to the node point N2 connected in parallel through the one-way diode 113, and the ON resistance of the resistor 112 and the diode 113 is increased. Resistance 114.

The third voltage VB due to the resistance partial voltage is charged in the capacitor 115, which is input to the non-inverting terminal (+) of the comparator 120.

In addition, the power supply voltage VCC of the common connection terminal COM11 is input to the node point N3 to which the resistor 118 and the capacitor 119 are connected through the resistor 116 and the one-way diode 117. As described above, the fourth voltage VA due to the on-resistance of the resistor 116 and the diode 117 and the divided voltage of the resistor 118 is charged in the capacitor 119, which is the inverting terminal (−) of the comparator 120. Is entered.

At this time, the magnitudes of the resistors 112, 114, 116, 118 and the capacitors 115, 119 are set as follows, and in the normal state, the output of the comparator 120 is in the "low" state. Output the signal of.

Resistor 112 = Resistor 116, Resistor 114 <Resistor 118 Capacitor 115> Capacitor 119 Therefore, in the state where the magnitude of the resistor is set as described above, the "low" signal is always line 131. It is input to the port (port) of the MPU 124 through.

As described above, when the output signal of the comparator 120 outputs a signal of "low", when the ring signal 80Vrms 20HZ of 2 seconds per second is input to the lines L1 and L2 as shown in FIG. Likewise, the normal cross terminal NC10 of the relay contact switch 103 is input to one end of an AC input of the bridge diode 109.

The signal input to the normal cross terminal NC10 of the relay contact switch 103 is limited to only an AC signal component by a capacitor 106 and a resistor 107 connected in series to the other end of the bridge diode 109. It is input to AC input terminal.

Therefore, in the current output terminal (+) (-) of the bridge diode 109, the positive DC voltage (+) rectified by the ring signal input through the lines (L1) (L2) is connected through the resistor 110 having one side grounded. It is input to the normal open terminal NO11 of the relay contact switch 111.

The rectified voltage input to the normal open terminal NO11 is limited by the zener diode 121, the resistor 130, and the zener diode 122 to the first voltage V1, and the zener diode 122 is limited. A voltage lower than the first voltage V1 level is output to the node point N1 due to the Zener voltage of and overlaps the node point N2 to which the third voltage VB is output.

Therefore, when the ring signal as shown in FIG. 3a is input at the point P1 of FIG. 3, the third voltage VB is raised by the second voltage V2 as shown in FIG. 3b rather than the fourth voltage VA to compare the two inputs. The comparator 120 outputs a ring detection pulse in a “high” state for a period T1 and a signal having a “low” signal for a period of T2 as shown in (131a) of FIG. 3C through the line 131. Output to

At this time, the MPU 124 counts the ring signal detection signal input through the line 131 a predetermined number of times and outputs a relay driving signal to the base of the transistor 125 when the predetermined number of times is reached, and the analog switch 126. ) Outputs a switch enable signal through line 125 and switches it, and bus 126 drives an OGM deck (not shown) to output an output message (OUT Going Message: OGM) of the user to line 127. To be loaded.

On the other hand, the transistor 125 which inputs the relay driving signal of the MPU 124 is turned on and passes the current of the relay coil RY connected to the collector to ground through the collector-emitter.

At this time, the relay contact switches 103 and 111 are switched from normal cross terminals NC10 and NC11 to normal open terminals NO10 and NO11 by the current flow of the relay coil RY.

The DC voltage loaded on the telephone lines L1 and L2 by the switching of the relay contact switches 103 and 111 forms a trunk line loop by the primary coil of the transformer 104 and simultaneously through the resistor 108. It is input to both ends of the AC input of the bridge rectifier 109 and rectified and output.

The rectifier output of the bridge rectifier 109 is clipped to the first voltage V1 (150) of FIG. 4A by the circuit of the zener diode 121, the resistor 130, and the zener diode 122 as described above. It is output to the common terminal COM11 of the relay contact switch 111.

Therefore, according to the above conditions, the magnitude relationship between the third and fourth voltages VB and VA of the node points N2 and N3 is input to the input terminal (+) (-) of the comparator 120 as VA> VB. do.

As described above, the relay switches 103 and 111 are switched to the normal open terminals NO10 and NO11 so that the output messages of the line 127 are “on” of the analog switch 126 and the transformer 10 4. When the handset of the telephone (not shown) connected in parallel to the telephone lines L1 and L2 is hooked off in the state of being output through the secondary and primary windings and the relay contact switch 103, as shown in FIG. The voltages of the lines L1 and L2 that were maintained at the same state as 150 are dropped as shown at 151 in FIG. 4A.

That is, the line voltage 150 of the telephone lines L1 and L2 results in the parallel connection of the DC operating resistance of the telephones connected in parallel and the operating DC resistance of the present system in parallel. And the output of the bridge rectifier 109 is also reduced.

At this time, the third voltage VB and the fourth voltage VA of the node points N2 and N3 outputting the voltage division of the line voltage 150 to a predetermined level and outputted as shown in FIG. 4B also fall. The capacitor 115 and the capacitor 119 connected to 118, respectively, are set by the capacitor 115> capacitor 119 as described above, so that the fourth voltage VA becomes the third voltage VB as shown in FIG. 4b. It falls sharply faster than).

Accordingly, the comparator 120 comparing and outputting the third voltage VB and the fourth voltage VA transmits a message interrupt detection signal having a high state for a predetermined time T3 through the line 131 as shown in FIG. Input to the microprocessor 124.

The MPU 124 which inputs the single message interrupt detection signal input in the "high" state during T3 of FIG. 4C outputs the "low" signal to the transistor 125 and the analog switch 126, and relay contact switch. (103) (111) is switched to the normal open terminal (NO1 0) (NO11) and the output line of the secondary winding of the transformer 104 is cut off.

In addition, the MPU 124 blocks the drive signal of the output message deck output to the bus 126.

Therefore, the output message OGM sent to the lines L1 and L2 is cut off, and the voice of the parallel connection telephone is output on the lines L1 and L2.

As described above, the present invention has an advantage that a circuit of a line interface can be simply configured by detecting a ring signal and a message interrupt input using only a simple switching circuit and a voltage comparison circuit according to another state.

Claims (1)

In a line interface circuit of an answering machine using a microprocessor that outputs a predetermined switching control signal in response to input of a predetermined detection signal, the secondary side by inputting the signals of telephone lines L1 and L2 to both ends of the primary winding. A transformer 104 for organically outputting a winding, rectifying means for rectifying and outputting a signal through the input path with a direct current input path and a direct current input path as a direct current, and the telephone connected to one end of the transformer 104. A first switch 103 connected to the middle of the line to form an AC input path of the rectifying means and switched to a DC input path by a switching control signal of the microprocessor to form a DC path; A first voltage generating means for outputting a voltage to the first and second voltages having a predetermined level difference, and an output voltage of the rectifying means is input to the first contact point; And a second switch 111 for selectively outputting the rectified voltage in a state in which a predetermined operating voltage is input to a second contact and switched by the same switching control signal of the first switch 103 to output a predetermined voltage to a common contact. ) And a third voltage of a predetermined level connected between the common contact of the second switch 111 and the ground and inputting the first voltage output of the first voltage generating means as an output node, the common contact having a predetermined time constant. Second voltage generating means for outputting the third voltage generating means connected between the common contact and the ground of the second switch 111 and outputting the voltage of the common contact as a fourth voltage having a predetermined time constant; And comparing the third voltage output from the second and third voltage generating means with the fourth voltage level, detecting a different ring signal and a message interrupt input signal, and inputting the same to the microprocessor. Circuit characterized in that the adapted 120.