KR910008171Y1 - First and end checking circuit of video tape - Google Patents

Abstract

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Description

First and end detection circuit of video tape

1 is a detailed circuit diagram showing an embodiment of the first and second detection circuit of the present invention.

2A to 2G are waveform diagrams of respective parts of FIG.

Figure 3 is a signal flow diagram showing the operation of the microprocessor used in the first and last detection circuit of the present invention.

4 is a conventional first and end detection circuit diagram.

* Explanation of symbols for main parts of the drawings

10 microcomputer 20 light source unit

30: ledger F: integrator

PD: photodiode PT: phototransistor

Q: transistor

The present invention relates to a first and end detection circuit of a video tape for detecting the first and end of a video tape embedded in a deck portion in a video tape recorder.

In general, a video tape recorder automatically stops the current operation mode and rewinds the video tape when the video tape is terminated in the state of performing constant speed playback, forward high speed search, and fast forward, and rewinds the video tape. When it is in the ultra short position from the state, it provides service operation such as stopping the rewind automatically.

In order to provide such a service operation, it is necessary to detect the beginning and end of a video tape. In a conventional video tape recorder, as shown in FIG. 4, the light output from the photodiode PD is located at the beginning and end positions of the video tape. The phototransistor PT is turned on as it enters the phototransistor PT through the transparent lead tape, and a high-potential control signal is input to the system control microcomputer (hereinafter, abbreviated as "microcomputer"). .

That is, a lead tape through which light can pass is attached to the first and second ends of the video tape. In the conventional first and end detection circuits for detecting the lead tape, light of the photodiode PD passes through the lead tape and The phototransistor PT turns on as it enters the transistor PT, and outputs a high potential to its emitter. The output high potential is input to the microcomputer so that the microcomputer recognizes the beginning and end of the video tape. .

However, the conventional ultra-short and end detection circuits described above operate the phototransistor PT by external light other than the light of the photodiode PD, that is, for example, complete assembly in a production line of a video tape recorder. In case of testing, or if the case is separated for troubleshooting the video tape recorder, external light is incident on the photo transistor (PT), and high potential is input to the microcomputer to recognize it as the first and end of the video tape. There was a malfunction.

In order to prevent such a malfunction, a housing is installed around the photo transistor PT to block external light from being incident on the photo transistor PT. However, this is necessary to secure a space for installing a separate housing. There were problems such as a lot of problems in miniaturization and thinning of the.

Therefore, an object of the present invention is to provide a first and end detection circuit for accurately detecting the first and end of a video tape by distinguishing the light output from the photodiode and the external light.

In order to achieve the above object, the first and second end detection circuits of the present invention allow a photodiode to output light at regular intervals by a pulse signal and to enter the phototransistor. The output signal of the phototransistor is integrated, and the transistor is turned on and off in accordance with the level of the integrated signal to input the detection signal to the microcomputer.

In addition, the microcomputer used in the present invention outputs a pulse signal of a certain period to cause the photodiode to emit light at a predetermined period, and inputs a detection signal of the phototransistor after a predetermined time after the pulse signal is output, so that the end and end of the video tape are terminated. To determine.

Hereinafter, with reference to the accompanying drawings 1 to 3 illustrating a preferred embodiment of the present invention will be described in detail.

1 is a detailed circuit diagram showing a preferred embodiment of the first and second end detection circuits of the present invention, as shown therein. ) Is connected to the photodiode PD through a current amplifier A that amplifies and inverts a current and a resistor R ₁ in order to configure the light source unit 20.

In addition, the emitter of the phototransistor PT, which receives the light of the photodiode PD, is connected to the resistor R ₂ and through the integrator F formed of the resistor R ₃ and the capacitor C. The light receiving unit 30 was configured by connecting to the base of Q) and connecting to the collector of the transistor Q and the sensor input terminal SENSOR IN of the microcomputer 10 through the resistor R ₄ .

In the drawing description of FIG. 1, reference numeral Vcc denotes a power supply terminal to which an operating power supply is applied.

The first and second end detection circuits of the present invention configured as described above have the sensor on terminal ( ) Outputs a low potential pulse signal having a constant period as shown by the waveform (a) of FIG.

Sensor on terminal ( The low-potential pulse signal outputted by the A) is amplified and inverted through the current amplifier A of the light source unit 20 and outputted as shown in the waveform (b) of FIG. 2, and amplified and inverted through the current amplifier A. As shown in the waveform (b) of FIG. 2, the output signal of the current amplifier A is applied to the photodiode PD through the resistor R ₁ , so that the photodiode PD emits light at a predetermined period. .

In this case, if the video tape is not at the first end or the end of the video tape, the light output by the photodiode PD is blocked by the opaque video tape and cannot be incident to the photo transistor PT. The low potential is applied to the sensor on terminal of the microcomputer 10 so that the microcomputer 10 recognizes that it is not the first and end of the video tape. do.

In this case, when the first end or the end of the video tape is positioned so that the light of the photodiode PD enters the photo transistor PT of the light receiving unit 30 through the transparent lead tape at the first end and the end of the video tape, the photo transistor PT ) Is turned on.

Therefore, the phototransistor PT outputs a high potential pulse signal to its emitter, as shown in the waveform (c) of FIG. 2, and the output high potential pulse signal is condensed through the resistor R ₂ of the integrator F. (C) is applied to the base of the transistor Q while being charged and discharged as shown by the waveform f in FIG.

Here, when the photo transistor PT outputs a high-potential pulse signal to its emitter, the resistance R ₃ of the integrator F such that an operating point thereof, that is, a bias voltage or less is applied to the base of the transistor Q. And the time constant of the condenser (C).

Then, the transistor Q is continuously turned off during the time that the photo transistor PT outputs a high potential pulse signal, so that the photopotential PT outputs a high potential pulse sinusoidal resistor R ₄ output to its emitter. Through the sensor input terminal (SENSOR IN) of the microcomputer 10 through the microprocessor 10 recognizes that the first and end of the video tape.

Here, the identification operation by the charging and discharging time constants of the integrator F for charging and discharging the output signal waveforms c and d of the photo transistor PT will be described in more detail.

When the values of the resistor R ₃ and the capacitor C are set such that the time constant of the integrator F becomes a waveform (c) <(R ₃ C time constant) <waveform (d), the photodiode PD When light is not incident on the photo transistor PT and the photo transistor PT outputs the waveform d, the high potential of the waveform d is continuously charged in the capacitor C to turn on the transistor Q. The transistor Q remains on and the low potential is input to the microcomputer 10.

In addition, when the light of the photodiode PD enters the phototransistor Q through the lead tape and the phototransistor PT outputs the waveform c, the capacitor (D) during the high potential period Ton of the waveform c is used. Since C) is not charged with sufficient potential to turn on the transistor Q, and the charge potential of the capacitor C is discharged during the low potential period Torr, the transistor Q is kept off and the waveform c ) Is input to the microcomputer 10 through the resistor R ₄ to recognize the beginning and end of the video tape.

When the external light is incident on the photo transistor PT, the photo transistor PT remains on, and thus the photo transistor PT continuously outputs a high potential as shown by the waveform d of FIG. The above is charged through the resistor R ₃ of the integrator F as shown by the waveform g of FIG. 2 to continuously apply high potential to the base of the transistor Q.

Then, the transistor Q is continuously turned on, and thus the low potential is continuously applied to the sensor terminal SENSOR IN of the microcomputer 10 as shown by the waveform e in FIG. It is recognized that it is not the beginning and end of.

3 is a signal flow diagram illustrating the operation of the microcomputer 10 by the first and second end detection circuits of the present invention. As shown in the drawing, the microprocessor 10 sets the sensor state low in the sensor check routine, and the memory. After clearing the sensor on terminal ( After outputting the low potential to the photodiode (PD) to emit light, delay a predetermined time (T _H ), and determines the sensor signal input to the sensor IN (SENSOR IN).

At this time, if the input sensor signal is not high potential, it is recognized as not the first end and the end of the video tape and returns.

If the sensor signal is at high potential, the built-in memory (N) ㅇ, ㄹ '1' is added to the sensor on terminal ( ) To obtain the output high potential photodiode (PD) is to be turned off, and the memory (in a certain period of time (T _L) if the value of N) is not a constant value (NM) to determine whether more than a predetermined value (NM) the Sensor on terminal after delay Repeat the operation of outputting and detecting the low potential again.

If the high potential is input to the sensor input terminal repeatedly until the value of the memory N becomes the constant value NM repeatedly for a predetermined number of times, the microcomputer 10 recognizes that the video tape is at the beginning and end. After returning sensor state to high.

As described in detail above, the first and second end detection circuits of the present invention do not malfunction even when external light is incident on the light-receiving unit, and accurately detects the first and second ends of the video tape, thereby easily testing and troubleshooting a video tape recorder. In addition, the size of the housing can be reduced to the extent that it can protect the light-receiving unit from external light, which not only contributes to the miniaturization and thinning of the device, but also reduces the power consumption by repeatedly blinking without continuing to operate the light source unit. Has the effect of.

Claims (1)

A photodiode (PD) for emitting light and a phototransistor (PT) for receiving the light emitted from the photodiode (PD) and passing through the lead tape of the video tape to input a detection signal to the microcomputer (10). In the first and second end detection circuits of the provided video tape, a pulse signal output from the microcomputer 10 is applied to the photodiode PD, and the emitter of the phototransistor PT is an integrator F. First and end detection of a video tape, which are connected to the base of the transistor Q and connected to the collector side of the transistor Q and the sensor input terminal SENSOR IN of the microcomputer 10. Circuit.