KR940005499Y1 - Light control circuit of led - Google Patents

Abstract

No content.

Description

Brightness Control Circuit of Light Emitting Diode

1 is a brightness control circuit diagram of the present invention.

2 (a) to 2 (c) are waveform diagrams showing driving pulse signals outputted by the microcomputer of FIG.

3 is a signal flow diagram showing the operation of the microcomputer of FIG.

* Explanation of symbols for main parts of the drawings

1: micom 2: illuminance detection unit

3: drive control unit 4: display unit

LD ₁ -LD _N : Light Emitting Diode

The present invention relates to a brightness control circuit of a light emitting diode for controlling the brightness of the light emitting diode used as a display device in various electronic devices, including home appliances according to the ambient illumination.

In general, various electronic devices use LEDs to indicate operating states.

That is, for example, in an audio device, the light emitting diode is flickering according to the output level of the audio signal, and in the television receiver, the light emitting diode is displayed in the voice multicasting state.

As described above, in displaying various operation states and the like using the light emitting diodes, a driving signal is applied to the light emitting diodes regardless of the illuminance of the surroundings so as to light them.

Therefore, when the ambient light is bright, such as during the day, the light of the light emitting diode is relatively dark, so that the user cannot accurately determine the operating state of the device, and when the ambient light is dark, such as at night or at bedtime, The light of the light emitting diode is very bright to dare the user's eyes, even disturb the bed, there is a problem such that a lot of power consumption without need.

The present invention has been devised to solve the above-mentioned conventional problems, and detects ambient illumination and adjusts the duty ratio of the driving pulse signal of the light emitting diode according to the detected illumination. Accordingly, an object of the present invention is to provide a brightness control circuit for varying the brightness of light emitting diodes, which will be described in detail with reference to the accompanying drawings.

1 is a brightness control circuit diagram of the present invention, as shown here, the microcomputer 1 for controlling the overall operation of the system, and the photoconductive element CdS and the resistors R1 and R2 in series with the power supply Vcc. The illuminance detector 2 connected to detect and illuminate peripheral illumination to the microcomputer 1, and a resistor R3 for outputting a driving current according to a driving pulse signal output by the microcomputer 1 to the output terminal DR. The driving control section 3 consisting of -R5 and the transistor Q1, the collector of the transistor Q1 which is the output terminal of the driving control section 3, and the output terminals OT ₁ -OT _N of the microcomputer 1; The light emitting diodes (LD ₁ -LD _N ) and the resistors (R ₅₁ -R _5N ) are connected in series to each other, and the light emitting diodes (LD ₁ -LD _N ) are output in accordance with a driving signal output to the output terminals (OT ₁ -OT _N ). It consisted of the display part 4 which lights up.

In the brightness control circuit of the present invention configured as described above, the illuminance detection unit 2 detects the illuminance of the surroundings and inputs the detected illuminance to the microcomputer 1 while the power supply Vcc is applied.

That is, the photoconductive element Cds detects the ambient illuminance, and when the illuminance is dark, its resistance value increases, and as the illuminance becomes bright, the resistance value decreases, so that the illuminance detector 2 outputs it when the illuminance is dark. The lower the level of the detection signal and the brighter the level, the higher the level of the detection signal output from the illuminance detection unit 2, and the output detection signal is input to the input terminal IN of the microcomputer 1.

When the detection signal output from the illuminance detection unit 2 is input to the input terminal IN of the microcomputer 1, the microcomputer 1 determines the illuminance according to the level of the input detection signal and then the second (a) As shown in FIG. 2 (c), the driving pulse signals T1 to T3 having different high potential and low potential duty are selectively output.

That is, for example, when the peripheral illuminance is high and the level of the detection signal output by the illuminance detection unit 2 is high, as shown in the second (a) diagram of the microcomputer 1, the driving pulse signal having a long low potential period is shown. When the T1 is output and the peripheral illuminance is about medium, and the level of the detection signal output by the illuminance detection unit 1 is about medium, as shown in FIG. 2 (b), a driving pulse having a low potential period is medium. When the signal T2 is output and the level of the detection signal output by the illuminance detection unit 1 is low because the ambient illuminance is dark, the driving pulse signal T3 having a short low potential period is as shown in FIG. 2 (c). )

As described above, the driving pulse signal T1-T3 outputted by the microcomputer 1 to the output terminal DR is applied to the base through the resistor R4 of the driving control unit 3, so that the driving pulse signal T1 -1 is applied. The transistor Q1 is turned on during the low potential period of T3, and the power supply Vcc is output through the transistor Q1 to supply the driving current to the display unit 4.

In this state, when the microcomputer 1 outputs a low potential drive signal to the output terminals OT _{1 to} OT _N according to the operation state of the device, the drive current output from the drive control unit 3 is displayed on the display unit 4. The low potential drive signal flows through the light-emitting diode (LD ₁ -LD _N ) and the resistor (R ₆₁ -R _6N ) to the output terminal (OT ₁ -OT _N ) where the low potential drive signal is output. The light emitting diodes LD ₁ -LD _N connected to the terminals OT ₁ -OT _N side are selectively lit.

At this time, when the peripheral illuminance is bright and the low potential period of the driving pulse signal outputted by the microcomputer 1 is long, the time for which the transistor Q1 is turned on is long, so that the driving current flows through the light emitting diodes LD ₁ -LD _N. Since the light emitting diodes LD ₁ to LD _N are turned on very brightly, and when the peripheral illuminance is about medium and the low potential period of the driving pulse signal is about medium, the on time of the transistor Q1 is about medium, and thus the light emitting diodes are medium. (LD ₁ -LD _N ) is lighted with a medium brightness, and when the low illumination period of the driving pulse signal is short due to dark ambient light, the on time of the transistor Q1 is short and the light emitting diode LD ₁ -LD _N is short. Lights up dimly.

3 is a signal flowchart showing the operation of the microcomputer 1 by the brightness control circuit of the present invention.

As shown in FIG. 10, the illuminance detection signal applied to the input terminal IN is input in step 10, and the level of the illuminance detection signal input in steps 11 and 12 is set to the preset values Y1 and Y2. Compare.

At this time, when the illuminance is very bright and the level of the illuminance detection signal is smaller than the set value Y1, the driving pulse signal T1 having a long low potential period is output to the output terminal DR in step 13, and the illuminance is about medium. When the level of the illuminance detection signal is greater than the set value Y1 and smaller than the set value Y2, the driving pulse signal T2 having a low potential length is medium is output in step 14, and the illuminance detection signal is dark because the illuminance is dark. If the level is larger than the set value (Y2), the driving pulse signal T3 having a short low potential period is output in step 15, and then in step 16, the output terminals OT ₁ -OT according to the current state of the device. _N ) outputs a low-potential driving signal so that the light emitting diodes LD ₁ -LD _N are turned on at a predetermined brightness according to the ambient illuminance.

In the above description, the brightness of the light emitting diodes LD ₁ to LD _N is adjusted in three steps according to the ambient illumination. However, in the present invention, the illumination detection signal is compared with a plurality of setting values, and According to the comparison result, the brightness of the light emitting diodes LD ₁ -LD _N may be adjusted in several stages.

As described in detail above, the brightness control circuit of the present invention illuminates the light emitting diode brightly when the ambient light is bright, and lights up the light emitting diode darkly when the ambient light is dark, thereby making the display state of the light emitting diode clear regardless of the ambient light intensity. In addition, it is possible not only does not disturb the bedtime at bedtime, but also has an effect of preventing unnecessary power consumption.

Claims (1)

The illuminance detecting unit 2 for detecting peripheral illuminance, the microcomputer 1 for outputting a driving pulse signal having a shorter duty ratio as the illuminance for determining the peripheral illuminance with the illuminance detection signal of the illuminance detecting unit 2, and The drive control unit 3 supplies the drive current according to the drive pulse signal output from the microcomputer 1, and the drive current supplied from the drive control unit 3 is used as a power source. And a display unit (4) for selectively lighting the light emitting diodes (LD ₁ -LD _N ).