KR890000849Y1 - Record shielding circuit of automatic responser - Google Patents

Abstract

No content.

Description

Recording cutoff circuit of answering machine

1 is a circuit diagram of the present invention.

2 is a waveform diagram of each part of the present invention.

* Explanation of symbols for main parts of the drawings

1: Input terminal 2: Output terminal

3: flip-flop N ₁ -N ₄ : NAND gate

I ₁ : Inverter Q ₁ , Q ₂ : Transistor

C ₁ -C ₄ : Capacitor R ₁ -R ₁₂ : Resistance

VR ₆ : Variable resistor Vcc: Power

The present invention automatically cuts off the telephone line when the talker stops talking for more than a certain time when the talker's words are recorded on the telephone line through the telephone line. It relates to a recording cutoff circuit of an answering machine.

In the conventional answering machine, if the talker does not speak for a certain time (about 7 seconds) during the call, the signal is input to the microcomputer to cut off the telephone line, and the recording operation is blocked at the microcomputer. The talker's words were not recorded.

Therefore, a certain time (approximately 7 seconds) is fixed after the talker is disconnected, and thus the recording signal may be cut off too early or too late due to different habits and personalities of the talker.

As such, if the recording signal is cut off too early, the speaker may not be able to record enough words. If the recording is too late, no signal may be recorded and the recording tape is consumed.

In consideration of this, the present invention uses a simple circuit instead of hanging up a call if there is no signal for a fixed period of time (about 7 seconds). 12 sec.) It is a recording cut-off circuit of an answering machine that amplifies the input signal through a transistor, and then inputs a waveform by the time constant of the capacitor and the variable resistor to the NAND gate depending on whether the switching transistor is connected. It is configured to control the recording operation by applying the output of NAND gate to micom.

When described in detail by the accompanying drawings as follows.

FIG. 1 is a circuit diagram of the present invention, in which an input signal of an input terminal 1 is distributed to a resistor R ₁ (R ₂ ) and a transistor Q having an overvoltage protection resistor R ₄ connected through a coupling capacitor C ₁ . ₁ ) is applied to the base side of the transistor, and the collector output of the transistor Q ₁ is charged and discharged through the capacitor C ₂ and then the NAND gate N ₁ of the flip-flop 3 via the overvoltage protection resistor R ₃ . It is configured to be applied to one side. The output of the NAND gate N ₁ is applied to one side of the NAND gate N ₂ through the charge / discharge capacitor C ₄ , the resistor R ₁₂ , and the reverse current prevention diode D ₁ , and the NAND gate N ₂ . The other side is connected to the cathode side of the reverse current prevention diode D ₁ , and the output of the NAND gate N ₂ is configured to be applied to the other side of the NAND gate N ₁ and _one side of the NAND gate N ₃ .

In addition, the other side of the NAND gate N ₃ to which the power supply Vcc is applied via the overvoltage protection resistor R ₅ is configured so that the recording signal waveform is applied, and then the output of the NAND gate N ₃ is the resistor R ₈ (R). ₉₎ in the side of the collector of being applied to the base shaft of the transistor (Q ₂₎ transistors (Q ₂₎ distributed resistance (R ₁₀₎ (a NAND gate to which is applied the power (Vcc) at a side through R ₁₁₎ (N ₄₎ connected to the other side Sikkim and at the same time the resistance (R ₇₎ and recording-off time variable resistors set (VR ₆₎ and a capacitor (C ₃₎ configured to be connected to, and a burner, the output of the NAND gate (N ₄₎ (I ₁ It is configured to be output to the output terminal (2) through.

At this time, the waveform output to the output terminal (2) is applied to the microcomputer to control the output of the recording signal waveform in the microcomputer and at the same time to control the output for driving a known telephone line blocking relay.

The effect of the present invention configured as described above will be described in detail with reference to the waveform diagram of FIG. That is, in the present invention, when a voice signal such as (a) of FIG. 2 is input to the input terminal 1 in the circuit diagram of the present invention, the bias is biased to the resistor R ₁ (R ₂ ) through the coupling capacitor C ₁ . The inverted amplifying transistor Q ₁ is turned on so that the collector-side output of the transistor Q ₁ becomes a waveform as shown in FIG. 2B by the charge / discharge operation of the capacitor C ₂ .

That is, in the answering machine, the voice signal of the caller is applied as shown in (a) of FIG. 2 and the time after the voice signal is applied through the transistor Q ₁ and the condenser C ₂ is shown in FIG. As in (b), it is applied to the flip-flop 3 at a low level.

The waveform (b) of FIG. 2 is input to one side of the NAND gate N ₁ operating as the flip-flop 3 through the overvoltage protection resistor R ₃ to charge / discharge resistor R ₁₂ and the capacitor C _4. ) And the reverse current prevention diode D ₁ are output to the output side of the NAND gate N ₂ as shown in FIG. 2C.

At this time, the resistor R ₁₂ and the capacitor C ₄ perform the charge / discharge function, and the diode D ₁ operates to prevent reverse current, and the NAND gate N ₁ at the low level portion of the waveform (b) of FIG. The output of is high level and this high level output is applied to the input side of the NAND gate (N ₂ ) and simultaneously charged to the capacitor (C ₄ ) to the NAND gate (N ₂ ) connected to the cathode of the diode (D ₁ ) The other input side is also high level, and the output of the NAND gate N ₂ is output at the low level as shown in (c) of FIG. 2, and when the waveform of (b) of FIG. 2 is changed from the low level to the high level, the NAND The output of the gate N ₁ becomes low level and is input to the NAND gate N ₂ , and at the same time, the capacitor C ₄ discharges so that the input of the NAND gate N ₂ to which the diode D ₁ is connected becomes low level. the output of the NAND gate (N ₂₎ is output to the high level as in the second degree (c) It is presented.

That is, the waveform as shown in (b) of FIG. 2 shows the charge and discharge function of the resistor R ₁₂ and the capacitor C ₄ connected to the flip-flop 3 and the reverse current prevention of the diode D ₁ . It is output as square wave as in c).

The waveform (c) of FIG. 2 is applied to one side of the NAND gate N ₃ to which the power supply Vcc is applied via the protection resistor R ₅ , and the recording of the answering machine to the other side of the NAND gate N ₃ . The recording signal waveform as shown in (d) of FIG. 2 generated when the deck motor is rotated is input.

At this time, the recording signal waveform as shown in (d) of FIG. 2 is generated by the rotation of the motor driven by the recording deck driving signal since the transmission signal is immediately transmitted after the transmission signal is recognized by the microcomputer. It is controlled by the microcomputer and such a recording signal is output at a high level while the recording deck is being driven.

Therefore, in the NAND gate N _{3 to} which the waveforms of (c) and (d) of FIG. 2 are applied, the transistor is output through the resistor R ₈ (R ₉ ) by outputting the waveform as shown in (e) of FIG. 2 to the output side. (Q ₂₎ there is a walking donor bias of the reverse surface at a high level output waveforms, as shown in the second degree (e) a transistor (Q ₂₎ is the "on" and a low level, the transistor (Q ₂₎ is "off".

Therefore, when the transistor Q ₂ is turned “on”, the collector-side output of the other transistor Q ₂ is at a low level, so the power supply Vcc is applied to only one terminal of the NAND gate N ₄ and the voltage across the capacitor C ₃ is applied. Is discharged so that a low level is input to the other terminal of the NAND gate N ₄ .

However, in FIG. 2E, when the output waveform is low level and the transistor Q ₂ is “off”, the collector-side output of the transistor Q ₂ becomes high level, and the power supply Vcc is variable with the resistor R ₇ . Since the capacitor C ₃ is charged by the resistor VR ₆ , the waveform as shown in FIG. 2F is input to the other terminal of the NAND gate N ₄ .

Therefore, if the voice signal is continuously input to the input terminal 1, the period (a) part is changed several times in a short time as shown in (f) of FIG. 2, and the NAND gate N ₄ is not recognized as a high level state, but it is not fixed. by the input terminal (1) If a speech signal is input to a second-degree (f) of the period (b) resistance (R ₇₎ and a variable resistor (VR _6), the input side of the NAND gate (N ₄₎ as in the capacitor The waveform shown in (f) of FIG. 2 is input by the time constant filled in (C ₃ ).

At this time period (b) in the second degree (f) is a period of time when the voice signal of the calling party is being input, and a variable resistor (VR ₆₎ can be adjusted to be constant by adjusting a variable resistor (VR ₆₎ up to the resistance When the value is set, the waveform of the period (b) rises in (f) of FIG. 2 within a minimum time, and the NAND gate N ₄ is recognized as a high level state, and the variable resistor VR ₆ is set to the minimum resistance value (0Ω). If a long time passes, it is recognized as a high level state.

By so if no signal from the answering machine functions on behalf disconnected the phone owner you want to "certain time" time (about 3-12 seconds) with a variable resistor (VR ₆ talker during a certain period of time (about 7 seconds) You can change this by changing). That is, when the talker continues to input the voice signal, the capacitor C ₃ is charged and discharged as in the period (a), but when the voice signal is not input for a predetermined time, the charge charge of the capacitor (C ₃ ) increases as in the period (b). Therefore, the NAND gate N ₄ is recognized as a high level.

Therefore, in the NAND gate N ₄ , when the charge charge of the capacitor C ₃ rises and recognizes the high level as in the period b, the low level is output to the output side, and the output of the NAND gate N ₄ is the inverter I _1. After inverting through), the output terminal 2 is applied to the microcomputer at a high level as shown in (g) of FIG.

In this way, when the talker speaks, the output terminal 2 applies the low level to the micom, and if the talker does not speak the correction time, the high level is applied to the micom.

In addition, the microcomputer executes an internal program after the high level recognition, and outputs a signal to cut off the driving of the recording deck so that the low level recording signal (see (d) in FIG. 2) is applied to the input side of the NAND gate N ₃ . At the same time, by outputting a cutoff signal to a known telephone line cutoff relay, the telephone line is cut off so that the talker's words are no longer recorded.

As described above, the present invention stops recording tech and cuts off the telephone line when the voice signal of the caller is not applied for a certain time in an automatic telephone answering machine. By varying the length of time from 3 to 12 seconds, the phone line is blocked even when the talker is not finished. You can eliminate the disadvantages.

Claims (1)

The audio signal is detected by the transistor Q ₁ connected to the capacitor C ₂ and outputted as a square wave through the flip-flop 3 connected to the resistor R ₁₂ , the capacitor C ₄ , and the diode D ₁ . And the square wave signal of the flip-flop 3 is configured to control the driving of the transistor Q ₂ through the NAND gate N ₃ together with the recording signal controlled by the microcomputer. The transistor Q ₂ controls the capacitor C ₃ whose time constant is changed by the resistor R ₇ and the variable resistor VR ₆ to change the output of the NAND gate N ₄ , and then the inverter I ₁ . Recording cut-off circuit of answering machine configured to be output to micom through.