KR890004724B1 - Anti-close veiwsight protecting circuit for television - Google Patents

Abstract

The circuit detects a TV viewer proximity to control the feedings power. The generator(3) transmits the fixed-frequency infra-red to the TV viewer reflecting the infra-red signals which are sensed at the detector(6). The frequency discriminator(10) empolys the amplifier magniying the leveled infrared signals, the phase discriminator(11) generating the trigger pulses by comparing the amplified signals and the signals generated by the local oscillator(12). When the reflected infra-red signals are detected, the warning sounds are produced in the alarm signal generator(15) and the relay driver(16) cuts off the feeding power after elapsing predetermined time.

Description

Television eye protection circuit

1 is a block diagram of the present invention.

2 is an exemplary circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply part 2: oscillation part

3: infrared generator 4: transmission

5 receiver 6 infrared receiver

7: Buffer 8: Automatic Gain Control Circuit

9 low frequency amplifier 10 frequency discrimination circuit

11 phase comparison unit 12 frequency oscillator

13 trigger pulse generator 14 delay unit

15: alarm sound generating unit 16: relay driving unit

SP: Speaker CP: Differential Amplifier

GA: gyrator A ₁ : amplifier

OP ₁ , OP ₂ , OP ₃ , OP ₄ : OP amplifier 19: Gain control unit

Q ₁ , Q ₂ , Q ₃ , Q ₄ . Transistor 20: oscillator

The present invention relates to a vision protection circuit of a television that can protect the vision of the viewer by shutting off the power of the TV after the alarm when the viewer approaches a distance that can impair vision when watching television. In general, the viewing distance that can cause obstacles when watching TV is not known to the viewers, so it is often seen within the viewing distance of the TV. It was to be the main cause. Therefore, it is necessary to watch TV while maintaining a certain distance so as not to be influenced by X-rays, but in general, simply configure the light emitting unit and the light receiving unit such as a controller (automatic door opener and alarm) to adjust the voltage applied to the light receiving unit. In comparison, there was a difficulty in maintaining the viewing distance.

In other words, home appliances such as televisions are mobile from the point of sale, and because the user's position of use is easily changed, they cannot be fixed like alarms and door-opening devices, and they cannot be installed with light emitting and receiving parts facing each other. It could not be prevented from malfunctioning due to generated radio waves.

SUMMARY OF THE INVENTION An object of the present invention is to provide a viewing distance maintaining circuit of a television which can cut off the power supplied to the television circuit while outputting an alarm sound when the television is watched within a viewing distance, which impairs vision. When detecting that the viewer is approaching within the viewing distance of the television, the infrared receiver to prevent the malfunction caused by the electromagnetic wave and external noise and optical noise generated in the CRT and the frequency discrimination circuit to accurately detect the reception frequency of the reflected infrared ray Providing that the viewer can accurately detect whether the viewer has approached within the viewing distance to prevent near-field viewing. The infrared signal is generated by controlling the infrared generator as the status signal of the oscillator, and the infrared rays reflected from the infrared receiver are detected. In the circuit for controlling the power of the output side of the circuit, the output of the infrared receiver is configured to be applied to the automatic gain control circuit through the buffer, and the received frequency applied to the phase comparator through the low frequency amplifier is phased with a fixed integer multiple of the frequency signal of the frequency oscillator. Compared by the comparator, the frequency discrimination circuit is configured to drive the trigger pulse generator, and then the relay driver and the alarm sound generator are controlled through the delay unit.

This will be described in detail with reference to the accompanying drawings. 1 is a block diagram of the present invention, wherein the power source Bt of the power supply unit 1 is applied to the oscillator 2 so that the infrared oscillation frequency can be continuously transmitted through the optical diode of the infrared generator 3. ) And the receiver 5 is configured to apply the reflected infrared signal received by the light receiving diode of the infrared receiver 6 to the automatic gain control circuit 8 through the buffer 7 to irregularly input the received infrared signal. It is configured to prevent the malfunction of the output side.

The infrared frequency signal applied through the low frequency amplifier 9 of the frequency discrimination circuit 10 is applied to the phase comparator 11 and the output of the frequency oscillator 12 is applied to the phase comparator 11. By comparing the oscillation frequency of an integer multiple of the reception frequency generated by the frequency oscillator 12 and the reception frequency of the low frequency amplifier 9 to prevent malfunction caused by an external noise signal, the trigger pulse generator 13 is driven. The relay driver 16 is configured to be controlled through the alarm sound generator 15 and the delay circuit 14. 2 is an implementation circuit diagram of the present invention, in which an alternating current (AC) power supply is supplied to a television circuit connected to a terminal (P ₃ ) (P ₄ ) via a relay switch (LS) at a primary side of a transformer (T) of a power supply unit (1). The power source which is configured to be secondary to the transformer (T) secondary side is rectified through the diode (D ₁ -D ₄ ), and then the transistor (Q ₁ ), the diode (D ₅ ), the zener diode (ZD), and the capacitor (C _1- ). The set is configured to be supplied to each circuit as the driving power source Bt through the constant voltage consisting of C ₃ ). When the power source Bt is applied, the oscillator 2 supplies the monostable multivibrator MT ₁ to the resistor R ₂ and the capacitor. By oscillating with the time constant of (C ₄ ), the transistors Q ₂ and Q ₃ are configured to be driven to output to the photodiodes LD ₁ and LD _{2 of} the infrared ray generating unit 3.

That is, when the power supply Bt supplied from the normal power supply unit 1 is applied, the ballast unit 2 is operated so that the photodiode LD ₁ (LD ₂ ) of the infrared generating unit 3 located at the front of the set is operated. Infrared radiation is continuously generated according to the frequency of the oscillation unit 2 through.

The infrared receiver 6, which is installed at the front of the set and receives infrared rays reflected by a viewer or another object located within a viewing distance, has a gyrator (GA) through a differential amplifier (CP) on a light receiving diode (LD ₃ ). And the received infrared signal is applied to the buffer (7), and the resistors (R _3- R ₆ ) and capacitors (C ₆ -C ₉ ) are respectively applied to the four stages of the OP amplifiers (OP _1- OP ₄ ). After configuring the automatic gain control circuit 8 so that the output of the feedback control unit 19 fed back to each of the OP amplifiers OP _{1 to} OP ₃ maintains the received signal input level constant, the frequency discrimination circuit And the frequency discrimination circuit 10 is configured to apply the amplified received signal output of the low frequency amplifier 9 composed of the amplifier A ₁ to the phase comparator 11. ₁ ) and the output of the oscillator 12, which is connected to the condenser C ₁₁ , has a low frequency amplifier 9 through a divider 17. In the phase comparator 11, the frequency division frequency f ₂ becomes n times the reception frequency f ₂ . The trigger generator 13 is driven through the capacitor C ₁₂ by outputting the level signal f ₃ of the level. In addition, the transistor Q ₄ (Q ₅ ) is configured to be “turned on” by the low level pulse of the trigger generator 13, thereby connecting the warning speaker SP connected to the transistor Q ₆ through the oscillator 20. At the same time, the delay unit 14 is constituted by the monostable multivibrator MT ₂ connected to the resistor R ₁₃ and the capacitor C ₁₃ to excite the excitation coil L for controlling the power supply of the television, thereby providing a relay switch ( The relay driver 16 is configured such that LS is opened.

In the present invention configured as described above, when the AC power source AC is applied to the terminals P ₁ and P ₂ , the relay switch LS is connected in the normal state in which the viewing distance is maintained at the primary side of the transformer T (normally). Power supply (AC) is supplied to the television circuit connected to the terminals (P ₃ ) and (P ₄ ), and the induced power on the secondary side of the transformer (T) is rectified through the diodes (D ₁ -D ₄ ). after transfection registry constant power (Bt) to the oscillating region (2), the transistor (Q ₁₎ to be supplied to each circuit including a zener diode (ZD _1), a condenser (C ₁ -C ₃₎ through (Q _1), The diode D ₅ constitutes an electrostatic source circuit so that a constant power source Bt is output. In this way, when the power source Bt is supplied from the power supply unit ₁ and applied to the monostable multivibrator MT ₁ of the oscillation unit 2, a square wave generated by the time constant of the resistor R ₂ and the condenser C ₄ is generated to generate infrared rays. The photodiode LD ₁ (LD ₂ ) for generation is abutted at the oscillation frequency of the oscillation unit 2.

That is, when AC power is supplied to the power supply unit 1, it is supplied to the television circuit connected to the terminals P ₃ and P ₄ , and at the same time, the electrostatic source Bt is supplied to each part of the circuit so that the oscillation unit 2 is oscillated at a constant frequency. The oscillation frequency is emitted through the transistor Q ₂ and Q ₃ and then through the photodiode LD ₁ and LD ₂ for infrared generation. As a result, when the power source Bt of the power source 1 is supplied, the infrared generating unit 3 installed on the front of the set continuously generates infrared rays having a frequency by the oscillating unit 2. The infrared signal is reflected by the human body and the object within the viewing distance, and then applied to the light receiving diode LD ₃ of the infrared receiver 6 located in front of the set. Will detect a certain distance from the.

When a viewer or another object approaches within the viewing distance of the TV, the infrared rays of the infrared ray generating unit 3 are reflected by the viewer or the other object and then applied to the infrared receiver 6 and there is no viewer or other object within the viewing distance. In this case, when the infrared ray reflected by the infrared ray receiver 6 is not applied to the infrared ray receiver 6, the infrared ray reflected by the infrared ray receiver 6 is judged to be a viewer or other object within the viewing distance and generates an alarm sound. Together, they shut off the TV. That is, when the viewer or other object approaches the infrared receiver 6 within the viewing distance, the infrared ray of the infrared generating unit 3 is received. At this time, the viewer and the other object cannot be detected by distinguishing the viewer and the other object. Will only detect the presence of. In this way, a differential amplifier CP is formed on the anode and cathode side of the light receiving diode LD ₃ of the infrared receiver 6 receiving the infrared signal, and the infrared signal reflected by the viewer or other object is received. By comparing the signal of the wood with the signal of the wood, the noise generated in phase with the infrared reception frequency (reflected infrared ray) can be eliminated, and the gyrator (GA) is spoken in parallel to the output side to reverse the Since the noise generated when the phase is removed, the state signal applied to the buffer 7 is applied with a stable infrared reception frequency without the frequency variation caused by the load variation.

That is, when the viewer approaches or the other object is placed within the viewing distance, the infrared ray of the infrared ray generator 3 is reflected from the other object of the viewer and applied to the infrared ray receiver 6, and the infrared ray receiver 6 receives the received infrared signal. The frequency is stabilized and applied to the buffer 7. In addition, the output of the buffer 7 which minimizes the variation of the received infrared frequency caused by the load fluctuation is output through the four stages of the OP amplifiers OP _{1 to} OP ₂ . The irregular reception signal input level of the transmission wave is kept constant with respect to the signal (the amount of reflected infrared light). That is, the output of the gain adjusting unit 19 to which the output of the OP imp OP ₄ is fed back is applied to each of the OP amps OP _{1 to} OP ₃ to adjust the respective resistances R ₃ (R). ₄ ) By comparing the voltage difference between both ends due to (R ₅ ) and (R ₆ ), you get a subdivided output and at the same time output a square wave. Capacitors (C ₆ -C ₉ ) prevent oscillation of high frequency signal. Done.

As a result, the automatic gain control circuit 8 converts and outputs a signal having a constant gain level with respect to the irregular infrared reception frequency applied from the infrared receiver 6, and the output of the automatic gain control circuit 8 is a condenser C ₁₀ . After the DC component is cut off through the low frequency amplification amplifier (A ₁ ) is amplified in the phase comparator 11 is applied to the receiving frequency (f ₁ ).

At this time, since the frequency f ₁ output from the low frequency amplifier 9 is an infrared reception signal reflected by the viewer and other objects within the viewing distance, the frequency f ₁ is the same as the frequency generated by the infrared generator 3. If the infrared ray of the infrared ray generator 3 is reflected by the viewer within the viewing distance and is not applied to the infrared ray receiver 6, the electromagnetic wave or television transmission signal of external noise and CRT is transmitted to the infrared ray receiver 6 When applied, the frequency f ₁ is not output from the low frequency amplifier 9. That is, the low frequency amplifier 9 generates a frequency f ₁ and applies it to the phase comparator 11 only when the infrared rays of the infrared ray generator 3 are reflected from the viewer within the viewing distance and then applied to the infrared receiver 6. It is to let.

The oscillation frequency of the oscillation unit 12 whose oscillation frequency is adjusted by the variable resistor VR ₁ and the condenser C ₁₁ is a frequency comparator 11 divided at a constant frequency f ₂ through the divider 17. Will be applied to. At this time, the frequency f ₂ divided by the divider 17 is fixed to be an integer multiple (n times) of the frequency f ₁ output from the low frequency amplifier 9, that is, the frequency generated by the infrared ray generator 3. Will be applied.

In other words, the output frequency f ₂ of the fountain 17 is n times higher than the output frequency f ₁ of the low frequency amplifier 9.

Therefore, in the phase comparator 11, when the frequency f ₂ of the frequency divider 17 is compared with the frequency f ₁ of the differential amplifier 9, the frequency f ₂ becomes n times the frequency f ₁ ( f ₂ = n × f ₁ : This means that the infrared rays of the infrared ray generator 3 are reflected by the viewer located within the viewing distance and then normally applied to the infrared receiver 6 so that the differential amplifier 9 has the same frequency as the infrared frequency. Outputs a high level status signal f ₃ , and when the frequency f ₂ does not become n times the frequency f ₁ (that is, the infrared rays of the infrared generating unit 3 are It is reflected and not applied to the infrared receiver 6, but means that electromagnetic waves or external noise is applied to the infrared receiver 6.) outputs a state signal f ₃ of low level.

The reason why the phase comparator 11 compares the frequencies f ₁ and f ₂ and outputs the status signal f ₃ is that the infrared rays generated by the infrared generating unit 3 are directed to the viewer or other object within the viewing distance. This is to determine whether it is applied to the infrared receiver 6 after being reflected, thereby eliminating malfunctions that may be caused by electromagnetic waves or external noise of the CRT. That is, the phase comparator 11 outputs a high level status signal f ₃ when the frequency f ₂ becomes n times the frequency f ₁ (in the normal operation of the present invention), and otherwise (external electronics). When a plate and noise are received and malfunction, the low level status signal f ₃ is output.

The state signal f ₃ of the phase comparator 11 is applied to the trigger generator 13 through the condenser C ₁₂ , and the state signal f ₃ is applied at a high level in the trigger generator 13. Only generates a negative trigger pulse to " turn on " transistor Q ₄ (Q ₅ ). When transistor Q ₄ (Q ₅ ) is “turned on” (viewer or other object approaches within viewing distance), oscillator 20 is operated to drive transistor Q ₆ at a constant frequency to alert speaker SP. It raises a warning to the viewer, while being applied to the monostable multivibrator MT ₂ of the delay unit 14, and delayed by the time constants of the resistor R ₁₃ and the capacitor C ₁₃ to excite the excitation coil L. The relay switch LS is cut off to cut off the AC power supplied to the terminal P ₃ and P ₄ to cut off the power applied to the television circuit.

That is, when another viewer approaches the viewing distance wife, the state signal f ₃ of the phase comparator 11 is output at a high level, so that the transistor Q ₄ (Q ₅ ) is turned on through the trigger generator 13. By turning on, the oscillator 20 operates to generate a warning sound from the speaker SP, and if the state signal f ₃ of the high level is continuously outputted until a certain time is delayed in the monostable multivibrator MT ₂ , the relay driver The relay switch LS of 16 is cut off to cut off the AC power supplied to the television from the terminals P ₃ and P ₄ to protect the viewer's eyesight.

In this case, the reason why the delay unit 14 is delayed for a predetermined time is to prevent the power of the television from being cut off when the channel of the television is changed or passed in front of it. That is, when the viewer or another object approaches within the viewing distance for a predetermined time set by the resistor R ₁₃ and the condenser C ₁₃ , the AC power supplied to the television is blocked to protect the viewer's eyesight. As described above, the present invention removes in-phase noise from the differential amplifier CP of the infrared receiver 6 and anti-phase noise from the gyrator GA, and automatically removes the infrared state signal applied through the buffer 7. Since the gain control circuit 8 outputs the received frequency at a constant level, the irregular level and noise of the reflected infrared light are removed to draw the desired infrared reception frequency, and the frequency discrimination circuit 10 receives the desired frequency. Compared to the frequency multiplied by, it is possible to detect and output the infrared reflection frequency that is accurately reflected and applied, so that the alarm sound is generated when watching TV in close proximity and always cut off the power (AC) applied to the television circuit after a few seconds. Eyesight protection on television that can protect your eyesight by maintaining a constant viewing distance That number will be provided.

Claims (3)

In a circuit for generating an infrared signal from the infrared generator 3 at the oscillation frequency of the oscillator 2 and controlling the power supply of the television to the relay driver 16, within the predetermined distance from the infrared generator 3 An infrared receiver 6 for receiving the infrared signal reflected from the viewer, a buffer 7 for reducing the frequency variation of the infrared signal received by the infrared receiver 6, and an output signal level of the buffer 7 are fixed. The automatic gain control circuit 8, the low frequency amplifier 9 for amplifying the output signal of the automatic gain control circuit 8 so as to enable signal processing, and the reception frequency of the low frequency amplifier 9; The frequency discrimination circuit 10 for controlling the driving of the trigger pulse generator 13 by comparing the oscillation frequency of the frequency oscillator 12 with the phase comparator 11 and the output of the trigger pulse generator 13 are driven.Warning sound generating section which control 15, the trigger pulse generating unit 13 outputs the delay unit 14 of the television eye protection consisting of a circuit for controlling the relay drive unit 16. After a predetermined time delay. 2. The infrared receiver (6) according to claim 1, wherein the infrared receiver (6) configures a differential amplifier (CP) on the anode and cathode sides of the light receiving diode (LD ₃ ), and then the gyrator in parallel on the output side of the differential amplifier (CP). A vision protection circuit of a television which is connected (GA). The frequency discriminator circuit 10 applies the phase comparator 11 after the output of the oscillator 12 to which the variable resistor VR ₁ and the condenser C ₁₁ are connected is relieved in the frequency divider 17. A television configured to drive the trigger pulse generator 13 when the frequency comparator frequency f _{2 of the} frequency divider 17 becomes an integer multiple of the reception frequency f ₁ of the low frequency amplifier 9 in the phase comparator 11. Eye protection circuit.

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