KR900004748Y1 - Modulating circuit in rear-view mirror - Google Patents

Abstract

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Description

Reflectance Control Circuit of LCD Rearview Mirror

1 is a circuit diagram according to the present invention.

2 is a voltage waveform diagram across the liquid crystal according to the duty ratio adjustment.

* Explanation of symbols for main parts of the drawings

10: light quantity detection circuit 20: light quantity comparison unit

30: oscillation circuit 40: monostable multivibrator

100: AND gate UNT1: negative logic inverter

BUF1-BUF2: Buffer VF: Half and Half Voltage Poller

The present invention relates to a reflectance control circuit of a liquid crystal rearview mirror, and more particularly, to a circuit for adjusting a reflectance of a liquid crystal to suit a surrounding environment by a user adjusting the driving voltage of the liquid crystal rearview mirror.

In general, the liquid crystal rearview mirror is attached to the vehicle like a general rear-view mirror to play the role of the rearview mirror. When the headlight of the car coming from the rear is too strong, it is driven by the rear light. It is an endoscope that has the function of attenuating the light of a losing headlight.

The liquid crystal viewing mirror as described above has been filed by the applicant of the Utility Model Registration Application No. 86-16623 dated October 30, 1986.

In general, the response characteristics of the liquid crystal rearview mirror and the liquid crystal shutter of the general-purpose liquid crystal display device are proportional to the driving voltage applied between the two electrodes.

For example, if the root mean square value of the driving voltage applied between the two transparent electrodes is large, the response speed of the liquid crystal shutter is high, and if the effective value of the driving voltage is small, the response speed of the liquid crystal shutter is slow.

If the effective value of the driving voltage applied to the liquid crystal viewing mirror, such as Utility Model Registration No. 86-16623, is large, the reflectance of incident light is large, and if the effective voltage is small, the response speed is slow and the reflectance of incident light is small. You lose.

The conventional liquid crystal rearview driving circuit for driving the liquid crystal rearview mirror is a utility model registration application No. 86-16624 dated October 30, 1986 by the present applicant. However, the liquid crystal rearview driving circuit of the application No. 86-11624 has a rear end by an output of a sensing circuit that outputs a predetermined signal according to the amount of headlight light of the vehicle when the headlight light of the vehicle coming from the rear is more than a reference value. The driving voltage that can block the headlights of the coming cars is input to the liquid crystal rearview mirror to block the headlights of the rear vehicle, thereby reducing the reflectance of the light incident to the driver.

However, the liquid crystal viewing goggles operated by the above circuits do not play the role of the backsight at all when the weather is cloudy or when the clock is poor. Has been.

Accordingly, an object of the present invention is to provide a circuit that allows the driver to arbitrarily adjust the reflectance to suit the surrounding environment in response to the current weather.

The present invention for achieving the above object is to detect the intensity of the headlight light of the following car, and outputs the light sensing voltage according to the intensity, and compares the output light sensing voltage with a predetermined reference voltage A liquid crystal comparator having an optical logic comparator for outputting the comparative logic signal and an oscillator circuit for oscillating and outputting a square wave of a predetermined period by the comparative logic signal outputted after the output to the optical comparator is determined to be greater than a predetermined reference voltage. 1. A reflectance control circuit of a visual periphery, comprising: a gate circuit that gates and outputs a pulse of an oscillation output as a clock pulse when an output of a negative logic gate for generating and outputting a predetermined signal and a predetermined power supply voltage and an oscillation output of the oscillation circuit are the same Is triggered by the output clock pulse, and the predetermined time is determined by the RC time constant value according to the adjustment of the capacitor C and the variable resistor VR. And by the monostable multi-vibrator ray other for outputting a signal, the end turn at the same time that the output buffer for stable multi-vibrator output ray rudder is characterized in that it consists of an output means for outputting the buffer.

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

FIG. 1 is a circuit diagram of the present invention, and includes a light amount sensing circuit 10 that senses and outputs an amount of light of a headlight of a vehicle coming from the rear, and a light amount sensing signal sensed and output by the light quantity sensing circuit 10. A light quantity comparator 20 for outputting a comparison logic signal compared to a reference voltage, an oscillation circuit 30 for inputting a comparison logic signal output from the light quantity comparator 20 to oscillate and output a pulse of a predetermined period; The negative logic inverter UIN1 for inverting and outputting the ground potential of the ground, the oscillation circuit when the output of the oscillation circuit 30 and the output of the negative logic inverter UIN1 and a predetermined voltage are both high. The gate circuit 100 for outputting the oscillating pulse signal of 30 as a clock pulse and the output of the gate circuit 100 are rising edges to be triggered by the external capacitor C and the variable resistor VR. Duty due to RC time constant A monostable multivibrator 40 for outputting a predetermined pulse having a ratio, a buffer BUF1 for buffering and outputting the output of the monostable multivibrator 40, and a monostable multivibrator ( 40 is composed of an inverted voltage follower VF and a buffer BUF2 that inverts the output of the buffer 40 and buffers the output thereof.

In the above configuration, the buffer BUF1, the buffer BUF2, and the voltage cleaner VF correspond to the buffer means.

In addition, the terminal 101 of the structure of FIG. 1 is a terminal which outputs a predetermined voltage to a liquid-crystal backsight (not shown) 1st electrode, and the terminal 102 is a predetermined voltage to the 2nd electrode of the said liquid-crystal backscopy. Is a terminal for outputting the first and second electrodes.

2 is a waveform diagram in which a predetermined period of clock pulses has a predetermined duty ratio upon input and a waveform diagram of a driving voltage of the liquid crystal.

Hereinafter, an operation example of FIG. 1 according to the present invention will be described with reference to the waveform diagram of FIG. 2.

When the light of a strong headlight of a vehicle following now enters the light quantity detecting circuit 10 of FIG. 1, the light quantity detecting circuit 10 receives incident light through a light receiving element, such as a photo diode, to receive light. Outputs a light sensing voltage corresponding to. That is, the light quantity detecting circuit 10 detects the light quantity of the headlight light emitted from the rear vehicle and inputs the light quantity detecting signal voltage to the light quantity comparator 20.

The light intensity comparator 20 inputs the light intensity detection signal voltage sensed by the light intensity sensing circuit 10 compares it with a predetermined reference voltage set at a level of a predetermined light quantity and outputs a comparison logic to the oscillation circuit 30. .

At this time, the light quantity detecting circuit 10 outputs a "high" signal as the oscillation control signal of the oscillation circuit 30 when the light quantity detecting signal is greater than the predetermined reference voltage, and the light quantity detecting signal is less than the reference voltage. Outputs a low signal.

When the comparison logic signal output from the light intensity inverse furnace 20 is a "high" signal, the oscillation circuit 30 oscillates a pulse as shown in FIG. 2a at a predetermined period and inputs it to the gate circuit 100, and the comparison logic signal is "low". "If it does not oscillate.

On the other hand, the gate circuit 100 inputs the output of the negative logic inverter UIN1 and the power supply voltage Vcc which inverts the state of the ground GND and outputs it as a "high" signal, and all of the input signals are "high". In this case, the oscillation circuit 30 gates and outputs the pulse signal oscillated and output to the clock terminal CK of the monostable multivibrator 40 as shown in FIG.

The gate circuit 100 described above may use a normal AND gate. In this case, it can be seen that the gate circuit 100 and the multivibrator 40 are disabled and reset when the power supply voltage Vcc is "low".

When the gate circuit 100 gates the output of the oscillation circuit 30 and outputs a pulse of a rising edge as shown in (1) of FIG. 2a to the clock terminal of the monostable multivibrator 40, the monostable multivibration is performed. The rater 40 is triggered by the clock pulse of the edge.

The monostable multivibrator 40 triggered by the output of the gate circuit 100 outputs a predetermined pulse having a duty ratio determined by an RC time constant by an external capacitor C and a variable resistor VR. do.

When the variable resistor VR is minimized, the duty ratio of the output pulse is reduced so that a signal having a duration as shown in (2) of FIG. 2B is output from the output terminal Q of the monostable multivibrator 40 and buffered. It is output to the first electrode of the liquid crystal rearview mirror (not shown) through the BUF1.

In addition, the waveform (2) of FIG. 2b output from the output terminal Q is inputted to the inverting terminal (-) of the inverted bogie follower (VF) to be inverted as shown in FIG. 2c and the terminal (BF1) is inverted through the buffer BUF1. 102 is input to the second electrode of the liquid crystal rearview mirror.

Therefore, the voltage applied to both the second electrode and the second electrode of the liquid crystal viewing mirror is the root-mean square bale (rms) of the driving pulse voltage as shown in FIGS. 2b and 2c. The effective voltage applied to the light bulb is shown in a waveform diagram and is shown in FIG. 2D.

On the other hand, when the variable resistance VR of the monostable multivibrator 40 is increased to increase the RC time constant, the duty of the pulse output from the output terminal Q is also increased, and thus is output from the output terminal Q. The signal is output as shown by (2 ') in FIG. 2E.

At this time, the signal output from the output terminal Q of the monostable multivibrator 40, such as (2 ') of FIG. 2e, is buffered by the above-described buffer BUF1, and then the liquid crystal is passed through the terminal 101. The first electrode of the colonoscope is input. On the other hand, the output of the monostable multivibrator 40 as shown in (2 ') of FIG. 2e is input to the inverting terminal (-) of the inverted voltage follower (VF) so that the signal of FIG. 2e is inverted as shown in FIG. 2f. Then, the buffer BUF2 acts as a buffer and is input to the second electrode of the liquid crystal rearview mirror through the terminal 102.

Accordingly, the voltage applied to both ends of the first and second electrodes of the liquid crystal display mirror is a signal in which the 'on' duty is increased by adjusting the variable resistor VR of the monostable multivibrator 40, that is, the high duration period is increased. It can be seen that the increased signal is input to each other. In this case, the waveform of the effective voltage across the first and second electrodes is equal to the second g degree.

Therefore, the effective voltage of the driving voltage applied to the liquid crystal rearview mirror is increased by adjusting the variable resistance VR of the monostable multivibrator 40, so that the response speed of the liquid crystal in the liquid crystal rearview mirror is changed and the reflectance is also changed.

As described above, the output voltage of the monostable multivibrator 40 may be adjusted by adjusting the variable resistance VR, and the effective value of the driving voltage applied to the liquid crystal display mirror may be adjusted.

Therefore, it can be seen that the reflectance is greater when the voltage having the effective value of 2g is input than the driving voltage having the effective value of 2d degree is applied between the first and second electrodes of the liquid crystal rearview mirror 40.

As described above, the present invention adjusts the duty ratio of the driving voltage of the liquid crystal display goggles to easily adjust the reflectance of the headlight light of the following car according to the weather conditions and environmental changes, thereby promoting safe operation even on a high weather change day. There is an advantage to this.

Claims (1)

Light amount sensing unit 10 for detecting the intensity of light of the headlight of the vehicle following the output and outputs the light sensing voltage according to the intensity, and outputs a predetermined comparison signal by comparing the output light sensing voltage with a predetermined reference voltage The liquid crystal rearview mirror having an optical beam comparator 20, an oscillation circuit 30 for oscillating and outputting a pulse signal of a predetermined period by the comparison signal output from the optical beam comparator 20, and first and second electrodes. In the reflectance control circuit of the liquid crystal rearview mirror provided with an output, the output of the negative logic inverter UIN1 for inverting and outputting the state potential of the ground and the oscillation output of the predetermined voltage Vcc and the oscillation circuit 30 are the same. The gate circuit 100 outputs the pulse of the oscillation output as a clock pulse, and is triggered by the clock pulse output from the gate circuit 100 to have a predetermined duty according to the adjustment of the capacitor C and the variable resistor VR. Output pulse Is a monostable multivibrator 40 and the output of the monostable multivibrator 40 is buffered and output to the first electrode voltage of the liquid crystal rearview mirror and inverted to the second of the liquid crystal rearview mirror A buffer means 200 for buffering and outputting an electrode voltage to adjust the effective voltage provided between two electrodes of the liquid crystal rearview mirror by adjusting a duty ratio of an output pulse of the monostable multivibrator 40. Reflectance control circuit of the liquid crystal rearview mirror characterized in that for adjusting the reflectance of the backoscope.