KR910000018Y1 - Rear-view mirror - Google Patents

Abstract

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Description

Power Consumption Circuit of LCD Rear View Driving Circuit Using Relay

1 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

PD: photodiode R1-R5: resistor

C1: Capacitor OP1: Comparator

RY1: relay 10: light sensing unit

20: power supply control circuit 30: light quantity comparison unit

40: oscillator 50: liquid crystal drive voltage generator

60: liquid crystal endoscope

The present invention relates to a power consumption saving circuit of the liquid crystal rearview driving circuit, and more particularly, to a power consumption saving circuit of the liquid crystal driving circuit which supplies power to the liquid crystal rearview driving circuit only when the amount of light incident is a certain amount or more.

In the conventional liquid crystal rearview circuit, when the headlight light of a car coming from the rearview liquid crystal is strongly incident, the photodiode sensing the light quantity is received and inputs the received light quantity to the comparator in which the reference light quantity is set. In this case, the comparator compares the reference amount with the received amount of light output from the photodiode and drives the liquid crystal rearview mirror when the amount of light sensed is greater than or equal to the reference value.

However, the conventional liquid crystal rearview driving circuit operated as described above uses the comparator and other liquid crystals when the photodiode sensing the amount of light senses the amount of the reference light amount or less than the reference light amount so that the liquid crystal viewoscope is ″ off ″. Current flows through all circuits that drive.

Therefore, there has been a problem of power consumption even when the liquid crystal viewing mirror is turned off.

Therefore, the object of the present invention is to cut off the supply of the supply voltage when the photodiode receiving the light amount of the rear vehicle headlight is lower than the predetermined reference light intensity, and supply the supply voltage only when the light receiving amount is higher than the predetermined reference light intensity to drive the liquid crystal rearview mirror. The present invention provides a power consumption saving circuit of the liquid crystal rearview driving circuit.

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

1 is a circuit diagram according to the present invention, the photodiode PD and the resistors R1 and R2 are connected in series between a power supply voltage and a ground to output an optical sensing voltage according to the amount of light received. And a relay Q1 and Q2 driven to an output of the light sensing unit 10 are connected to a Darlington and driven by a collector output of the transistors Q1 to Q2 to control the power supply voltage. A power supply control circuit 20 composed of a diode D1 connected in parallel with the relay RY1 and the relay RY1 to prevent a surge voltage, and by dividing the power supply voltage, a signal corresponding to the reference light quantity is supplied. The resistor R3-R5, the noise bypass capacitor C1, and the comparator CP1 are inputted to input an operating power source driven by the relay RY1 to compare the light sensing voltage with a predetermined reference voltage. The light quantity comparison unit 30 for outputting the comparison voltage and the phase When the comparator OP1 of the conventional light amount comparator 30 outputs the light sensing comparison voltage, the oscillation unit 40 oscillates and outputs a square wave of a predetermined period in response to this, and is operated by the driving voltage of the relay RY1. The liquid crystal drive voltage generator 50 outputs the oscillation signal output from the oscillator 40 to the liquid crystal drive voltages of which phases are opposite to each other, and the drive signal outputted from the liquid crystal rearview voltage generator 50 in phases different from each other. It consists of a liquid crystal rearview mirror 60 that is driven by and scatters incident light. Reference numeral CV _DD is a power source of an automobile.

Now, the headlights of the car following from the rear of the photodiode (PD), the cathode (Cathode) of the diode (D1) and the power supply voltage (CV _DD ) are input to one end of the coil of the relay (RY1), the liquid crystal display When incident to 60), the photodiode PD installed in the liquid crystal viewing mirror 60 detects the amount of light of the headlight light emitted from the rear vehicle and converts it into an electrical signal.

At this time, if the electrical signal conversion current is large, the voltage of the anode of the photodiode PD increases, and this voltage is immediately divided by the resistors R1 and R2 and input to the base of the transistor Q1. The non-inverting terminal (+) of the comparator CP1 is input.

As the amount of light received by the photodiode PD increases, the resistance divided voltage by the resistors R1 and R2 increases, which causes the base-emitter voltage of the Darlington connected transistor Q1 to be forwarded. do. Therefore, when the light reception amount of the photodiode PD is large, the transistors Q1 and Q2 are continuously saturated, so that the relay RY1 is driven so that the contact switch So is ″ ON ″ in the off state. (ON: closed)

By the above operation, the power supply voltage CV _DD of the vehicle is controlled through the contact switch So of the relay RY1 and the power supply line 31, and the comparator CP1, the oscillator 40, and the liquid crystal driving voltage generator ( 50 is inputted to the operating power supply voltage.

On the other hand, the comparator CP1, which inputs the power supply voltage CV _DD through the contact switch So of the relay RY1, divides the power supply voltage V _DD by the resistors R3-R4 to divide the inverting terminal (-). The reference voltage is input, and the photodiode PD senses and divides the optical sensing voltage divided by the resistors R1 and R2 into the non-inverting terminal (+) and outputs the result.

At this time, the reference voltage input to the inverting terminal (-) of the comparator CP1 becomes a voltage for determining the reference light quantity value. Accordingly, the comparator CP1 is in a ″ high ″ state when the light emitted from the headlight of the rear vehicle is sensed by the photodiode PD and the light sensing voltage output from the light sensing unit 10 is higher than the reference light intensity voltage. Outputs a logic signal to the oscillator 40.

That is, when the conversion output of the electrical signal output from the photodiode PD is large, the relay RY1 is driven so that the vehicle power supply voltage V _DD is supplied to the power input terminal of the comparator CP1. The transistor of the internal output stage is saturated by the resistor R5 connected to the power supply voltage line 31 to output a ″ low ″ signal, and then to the non-inverting terminal (+) with a resistor R3 and a resistor. When a light amount sensing voltage greater than the reference light quantity value voltage by (R4) is input, the output transistor of the comparator CP1 is cut off, so that the ″ high ″ level light sensing voltage by the resistor R5 is generated. Input to the operating power of (40).

The oscillator 40 inputs the output of the comparator CP1 oscillates a spherical frequency having a predetermined period and outputs it to the liquid crystal driving voltage generator 50.

At this time, the liquid crystal driving voltage generator 50, which inputs a square wave signal of a predetermined period, divides the frequency of the square wave by two to generate liquid crystal driving voltages having different phases, and outputs the liquid crystal driving voltage to the liquid crystal rearview mirror 60. ) Is operated only when the photodiode (PD) light receiving amount receives more than the reference light amount.

Therefore, when the base bias voltage of the transistor Q1 is adjusted to the resistor R2 and designed to be higher than the reference voltage due to the divided voltages of the resistors R3 and R4, the light having the reference light quantity value is greater than the photodiode PD. The relay RY1 which intercepts the power only when received by the light is operated to control the power so that the power supply voltage is supplied to each circuit only when the headlight light of the vehicle following is strong, thereby driving the liquid crystal rearview mirror 60.

On the other hand, when the light amount of the light of the headlight shining from the rear vehicle decreases, the voltages caused by the resistors R1 and R2 also decrease so that the transistors Q1 and Q2 are in the " off " state. As described above, when the transistors Q1 and Q2 are in the " off " state, the current does not flow through the coil of the relay RY, so that the contact switch So is turned off.

Therefore, when the light emitted to the rear vehicle is weak, the power supply voltage CV _DD of the vehicle is not applied to the power supply line 31, thereby reducing power consumption.

As described above, the present invention is a relay which is driven by the light sensing voltage by the electrical conversion of the photodiode of the photodiode and controls the power supply of the liquid crystal rearview driving circuit so that the liquid crystal only when the rear headlight of the car is above the reference value. By supplying the operating power of the rearview driving circuit has the advantage that can reduce the power consumption of the car battery.

Claims (1)

An oscillator 40 for oscillating and outputting a square wave of a predetermined period by inputting a light quantity comparison voltage and a square wave connected to an output terminal of the oscillator 40 are divided by a power supply voltage input and divided into two phases. The liquid crystal rear view mirror which is connected to the liquid crystal driving voltage generation unit 50 for generating a liquid crystal driving voltage and the output terminal of the liquid crystal driving voltage generation unit 50 and is driven by the generated liquid crystal driving voltage to scatter the incident light. In the power consumption saving circuit of a liquid crystal rearview driving circuit using a relay provided with a relay (60), a photodiode (PD) and a resistor (R1) (R2) are connected in series between a power supply voltage and a ground, so that the photodiode (PD) is connected. The light sensing unit 10 for dividing the amount of light received by the light into the resistors R1 and R2 and outputting the light sensing voltage, and the base of the transistors Q1 to Q2 connected to the darling tone are light sensing. Output terminal of the unit 10 A relay connected between a power supply voltage and a collector of the transistor Q1 to switch the power supply voltage to the power supply voltage line 31 by an output of the transistor Q2 and to provide the power supply voltage to the respective circuit portions. A power supply control circuit 20 composed of RY1, a resistor R3-R5, a capacitor C1, and a comparator CP1, and the power supply voltage line 31 is driven by driving the relay RY1. And a light quantity comparator 30 for outputting a light quantity comparison voltage to the oscillator 40 by comparing the light sensing voltage with a reference voltage set by the resistors R3-R4 by inputting an operating power input to the light source. Power-saving circuit of liquid crystal rearview driving circuit using relay.