KR920002625Y1 - Drive circuit of liquid crystal anti-glare mirror using cds cell - Google Patents

Abstract

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Description

LCD antiglare mirror driving circuit using cds

1 is a schematic diagram of the present invention,

2 is a detailed circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

10: light detection unit 20: comparison unit

30: oscillation unit 40: liquid crystal display mirror driving unit

50: stabilization unit

The present invention relates to a liquid crystal anti-glare mirror driving circuit using cds.

The present invention reduces the reflectance of incident light by absorbing a part of the amount of light irradiated to the rearview mirror from the outside in order to prevent the occupant's view from being blurred due to the strong reflected light generated when a strong light source is irradiated to the rear-mirror of the vehicle. It is to let.

In other words, the present invention uses a liquid crystal display mirror driving circuit using cds, which is a utility model (application number 88-9266) of a linear axis, which operates a liquid crystal display mirror that widens the rear end of the rider, protects eyesight, and provides a comfortable ride. It was devised to fix water.

The liquid crystal anti-glare mirror driving circuit using the pre-applied cds directly drives the liquid crystal panel through a flip-flop, so the fan-out is small and noise is generated when driving for a long time. There was a potential for anxiety.

Therefore, the present invention compensates for the above conventional defects, and adds a stabilizing part to the output part to increase the pen and out, thereby making it possible to use the liquid crystal glare mirror for a long time, and to obtain a stable output by removing noise and protecting the circuit. The purpose is to provide.

Another object of the present invention is that the load resistance value of the front roughness sensing photoelectric conversion element is a predetermined multiple of the load resistance value of the rear roughness sensing photoelectric conversion element, resulting in the same effect as amplifying the front roughness voltage n times. In the conventional circuit, the present invention is described in detail together with the accompanying drawings as designed to remove the amplifier for amplifying the front roughness voltage.

1 is a schematic view of the present invention, the photodetector 10 detects the front roughness and the rear roughness of the vehicle using the photoelectric conversion element cds to convert each illuminance into a predetermined voltage, and the comparison unit 20 The back illumination is compared by comparing the two voltages based on the output voltage of the photoelectric conversion element for detecting the front roughness and the output voltage of the photoelectric conversion element for detecting the back roughness provided by the photodetector 10. The enable signal is provided to the enable terminal of the liquid crystal antiglare mirror driver 40 only when the sensing photoelectric conversion element output voltage is large.

In addition, the oscillator 30 generates a synchronization signal of a predetermined frequency necessary for synchronization of the liquid crystal antiglare mirror driver 40, and the liquid crystal antiglare mirror driver 40 is synchronized with the synchronization signal provided by the oscillator 30. The control signal, which is enabled by the signal provided from the comparator 20 and controls the incident light absorption of the love anti-glare mirror, is provided to the common terminal and the segment terminal of the liquid crystal panel through the stabilizer 50.

The stabilization unit 50 protects the output end of the liquid crystal antiglare mirror driving unit 40 and prevents the occurrence of noise to obtain a stable output to prevent the malfunction of the antiglare mirror.

2 shows a detailed view of the present invention.

The photodetector 10 uses the characteristics of the photoelectric device cds whose resistance value changes according to the amount of incident light, so that the load resistance R _A value is applied to the photoelectric conversion device cds ₁ for detecting the surface roughness and the photoelectric conversion device cds ₂ for detecting the back illumination. It was set at 1.1-1.5 times this R _B value.

Front illumination detection photoelectric conversion element output voltage of cds ₁ side of the load resistor R _A of the output voltage V _A and the back photoelectric conversion element cds illuminance sensing portion ₂ side of the resistor R and _B for V _B are represented as follows.

Here, R ₁ and R ₂ are internal resistances applied to the photoelectric conversion elements cds ₁ and cds ₂ , respectively.

If the load resistance (R _A , R _B ) is configured to be much smaller than the resistance (R ₁ , R ₂ ) value of the photoelectric conversion element when the front roughness and the back roughness is the same as the above formula (1) and formula (2) since the denominator in is substantially equal to the load resistance of the output voltage at (R _a, R _B) (V _a, V _B) is the formula (1) and (2) numerator, that is the load resistance ((R _a in , R _B ), the resistance (R _A ) of these load resistance is set to 1.1 to 1.5 times the value of the other resistance (R _B ) as described above, so the load resistance (R _A ) The output voltage of V _A is n (1.1 ~ 1.5) times of the output voltage (V _B ) of the load resistor R _B , which has the same effect as amplifying the front roughness voltage by n (1.1 ~ 1.5) times under the above conditions. You will get

On the other hand, the comparator comprises an operational amplifier OP ₁ having an inverting end (-) connected to the load resistance R _A and a non-inverting end (+) connected to the other load resistance R _B. output voltage (V _B) this is greater, i.e., the rear illumination of the vehicle, such as when a strong light in the rear view mirror from the back of the vehicle enters the night the front of the (R _a) output voltage load resistor (R _B) than (V _a) of If you are moving n (1.1 ~ 1.5) times of illuminance and feel the glare of the occupant, the resistance (R ₂ ) of the rear illuminance sensing photoelectric element (cds ₂ ) is the resistance of the front illuminance sensing photoelectric element (cds ₁ ). R ₁₎ it is lower than a value, in the end load resistance (R ₂₎ the output voltage (V _B) is a high level from the comparator operational amplifier (OP ₁₎ for higher than the output voltage (V _a) of the load resistor (R ₁₎ of the Immediately after the signal is output, the flip flop FF of the driver connected to the comparator is enabled.

The oscillator 30 includes an operational amplifier including a resistor and a condenser, and the liquid crystal anti-glare mirror driver 40 generates a control signal to be provided to the segment terminal and the common terminal of the liquid crystal panel through the stabilizer 50. It consists of an FF call.

The operational amplifier OP ₂ of the oscillator 30 oscillates twice the frequency of the liquid crystal panel driving frequency and provides it to the sync terminal CP of the flip-flop FF of the liquid crystal antiglare mirror driver 40, and synchronized with the oscillator 30. The flip-flop FF of the liquid crystal display mirror driving unit 40 is enabled by the comparator 20 when the rear roughness of the vehicle is larger than the front roughness to drive the liquid crystal panel to absorb a part of the light incident on the rearview mirror. A control signal of a drive frequency having a desired AC characteristic is generated.

On the other hand, in the past, the LCD panel was driven by directly connecting the power terminal (Vcc) and the LCD panel to the output terminal of the flip-flop device 40, but in this case, when the output terminal of the flip-flop device 40 is low level, the power supply terminal Since the voltage of (VDD) is directly applied thereto, the flip-flop element 40 which is sensitive to voltage fluctuation may be burned out, and in this structure, the second, third or more at the output terminal of the flip-flop element 40 may be damaged. When the common terminal or segment is connected, the voltage variation increased by the increased number of these terminals is directly applied to the output terminal of the flip-flop element, thereby greatly limiting the fan-out which can increase the number of connected terminals.

The present invention can solve the conventional problem that the voltage of the power supply stage directly affects the output stage by configuring a buffer stage consisting of a resistor and an inverting gate at the output terminal of the flip-flop device 40 to act as a buffer. In addition, it is possible to increase the fan-out by connecting the second, third or more terminals through the buffer stage to drive them simultaneously.

As described above, the present invention not only has a simpler configuration than the conventional circuit, but also increases the fan-out by adding a stabilization unit 50, thereby increasing the use time of the antiglare mirror and removing noise to prevent liquid crystals. This prevents the mirror from malfunctioning and prevents damage to the circuit.

Claims (1)

_A photodetector in which load resistors R _A and R _B are connected in series to the front illuminance detecting photoelectric conversion element Cds ₁ and the rear illuminance detecting photoelectric conversion element Cds ₂ , and the load resistors R _A , R _B ), which is connected to the output voltage of these load resistors (R _A , R _B ) for comparison, an oscillator for generating a pulse signal for dongling, and an oscillator and a comparator, connected to the liquid crystal display mirror A liquid crystal display mirror driving circuit using a Cds, comprising: a liquid crystal display mirror driving unit for generating a control signal for adjusting the absorption rate of incident light; and a stabilizing unit connected to an output terminal of the driving unit;