KR20070081816A - Apparatus for controlling flash led of digital camera - Google Patents

Abstract

A device for controlling a flash LED of a digital camera is provided to control the flash LED by using a frame synchronization signal outputted from a camera sensor part, thereby keeping brightness for a long time without increasing the size of the flash LED. A device for controlling a flash LED of a digital camera includes a transistor(TR) having a collector connected to a gate terminal of a FET(Field Effect Transistor) in parallel, and a base applied with a frame synchronization signal(VSYNC), which is applied from a camera sensor part(10) to a back-end chip set part(20) so that the transistor is turned off in the frame synchronization signal section of a low level for turning on the FET by applying a flash short enable signal output from the back-end chip set part to a gate of the FET without a change. In a synchronization signal section of a high level(HSYNC), the transistor is turned on and applied with the flash short enable signal at a ground of an emitter thereof, thereby turning off the FET.

Description

Flash LED control device of digital camera {APPARATUS FOR CONTROLLING FLASH LED OF DIGITAL CAMERA}

1 is a flash LED control circuit diagram of a conventional mobile phone camera.

Figure 2 is a flash LED control timing diagram of a conventional mobile phone camera.

Figure 3 is a view showing the configuration of a flash LED control device of a digital camera according to an embodiment of the present invention.

4a and 4b is a flash LED control timing diagram of a mobile phone camera according to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

10. Camera sensor part, 20. Backend chipset part, 30. DC / DC converter

The present invention relates to a flash LED control device of a digital camera, and more particularly, to a flash LED control device of a digital camera to control the flash LED using a frame synchronization signal output from the camera.

In general, a digital camera or a mobile phone camera mounted on a mobile communication terminal has a built-in flash to provide the amount of light required for night imaging. The brightness of the flash LED is controlled by the current flowing through the LED. The more current flows, the brighter the LED.

However, when a large amount of current is continuously flowed for a long time and the flash LED emits bright light, the LED is inevitably damaged, and in order to keep the LED turned on for a long time, a lower current flows to control the brightness lower.

As described above, in order to emit light for a long time, an appropriate current must be flowed, and for this purpose, the brightness value according to the current is limited.

That is, in the related art, in order to obtain brighter brightness required for capturing at the time of capturing, the flash LED is turned on brighter than the capturing frame in shorter time.

1 is a flash LED control circuit diagram of a conventional mobile phone camera. Power is supplied to a flash LED through a flash enable signal, and the brightness of the flash LED is changed according to the voltage value Vf and the resistance value R1 applied to the flash LED1. Is determined. When determining the brightness value of the flash LED, it is considered that the flash LED is continuously turned on, and it is used when it is used as a lantern function (a function of continuously emitting the flash LED by a video shooting light). When you take a picture, you need a brighter brightness value momentarily, and by turning on the FET by giving the FET a flash short enable signal, more current flows through the flash LED as R1 and R2 are connected in parallel. The LED can turn on brighter momentarily.

In more detail, when the flash LED is emitted by the resistance value of R1 is called 'case 1', and when the FET is turned on and the flash LED is emitted by the resistance values of R1 and R2, it is called 'case 2'. When the brightness of the LED is measured at a distance of 1m, 'case 1' is about 100LUX, and in 'case 2', the instantaneous brightness of about 400LUX is measured.

2 is a flash LED control timing diagram of a conventional mobile phone camera. In FIG. 2, the VSYNC and HSYNC waveforms are synchronization signals of an image input from a camera sensor unit (signal input unit) to a backend chipset unit (signal processing and control unit). In accordance with VSYNC, the video signal is inputted to the backend chipset, and the number of frames per second and the number of VSYNC waveforms coincide with each other. Therefore, the VSYNC signal may be referred to as a frame synchronization signal of an image. The HSYNC signal is a synchronization signal of one horizontal line signal of each video frame.

For example, a 200 million pixel camera has 1600 × 1200 pixels and 1600 pixels are formed in 1200 rows vertically. In this case, 1200 HSYNCs per VSYNC are output from the camera sensor.

In FIG. 2, when VSYNC is low, an image is an input section, and an image is not input in a high interval section. (On the contrary, an image may be input when VSYNC is high and an image may not be input when it is low. The former is taken as an example)

As described above, in the related art, a large amount of current flows instantaneously through the flash LED to produce bright light, but there is a problem in that the brightness value is limited in order to be continuously turned on. In order to solve this problem, a large size LED may be used. However, when a large size LED is used, the size of the terminal increases, and the unit price increases due to the price of the large size flash LED.

Accordingly, there is a need for a method of continuously realizing brighter brightness using the same flash LED without using a large LED.

The present invention has been made in view of the above-described necessity. Since an image signal does not enter in a section in which the frame sync signal VSYNC is high, the flash LED can be controlled using the frame sync signal VSYNC output from the camera sensor. The purpose is to provide a flash LED control device of a digital camera.

In the flash LED control apparatus of the digital camera according to an embodiment of the present invention for achieving the above object, the image signal is applied to the back-end chipset unit in accordance with the frame sync signal (VSYNC), the frame sync signal is a low level section A camera sensor unit for applying an image signal to the backend chipset unit only during the operation, a power supply unit for applying an LED driving voltage to a flash LED according to a flash enable signal applied from the backend chipset unit, and a flash short applied from the backend chipset unit. Turned on according to the enable signal, one end is connected in series with the drain terminal, the other end is connected in parallel with the output terminal of the flash LED, and one end is connected in parallel with the source terminal, and the other end is connected in series with the output terminal of the flash LED. A second resistor connected to the output terminal of the flash LED in parallel to maximize the flash LED. In the flash LED control device of the digital camera comprising a FET to brighten the large brightness value, the collector terminal is connected in parallel to the gate terminal of the FET, and receives a frame synchronization signal applied from the camera sensor unit to the back-end chipset unit The FET is turned on by applying a flash short enable signal outputted from the back end chipset unit to the FET as it is in the low level frame sync signal section, and turned on in the high level frame sync signal section. It is preferable to further include a transistor for applying a flash short enable signal output from the negative terminal through a collector terminal to a ground terminal connected to the emitter to turn off the FET.

Hereinafter, a flash LED control apparatus of a digital camera according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a road, a camera sensor unit 10, a back end chipset unit 20, a DC / DC converter 30, a flash LED, and a FET showing the configuration of a flash LED control device of a digital camera according to an embodiment of the present invention. And R1, R2, transistor TR, and R3.

In such a configuration, the camera sensor unit 10 applies an image signal to the back end chipset unit 20 in accordance with the frame synchronization signal VSYNC, but the back end chipset unit (VSYNC) during the period in which the frame synchronization signal VSYNC is at a low level. 20, the video signal is applied, and the video signal is not applied to the backend chipset unit 20 during the period in which the frame sync signal VSYNC is at a high level.

The back end chipset unit 20 processes an image signal applied from the camera sensor unit 10 and outputs a control signal for driving a flash LED.

That is, when the back end chipset unit 20 needs to drive the flash LED according to the night photography, the back end chipset unit 20 applies the flash enable signal back and forth to the DC / DC converter 30 in accordance with the capture time and simultaneously enables the flash short enable by the FET. Apply a signal.

When the flash LED needs to be driven according to the video recording, the flash enable signal is applied to the DC / DC converter 30 and the flash short enable signal is applied to the FET while the video recording is in progress.

As described above, according to the present invention, the flash short enable signal is also applied to the FET, unlike the conventional case in which only the flash enable signal is applied to the DC / DC converter 30 at the time of video recording.

Meanwhile, the DC / DC converter 30 applies the LED driving voltage to the flash LED based on the flash enable signal applied from the back end chipset unit 20.

The flash LED emits light based on the voltage applied from the DC / DC converter 30, but the brightness of the light varies according to the resistance applied to the output terminal.

The FET is turned on / off by receiving a flash short enable signal output from the back end chipset unit 20 through R3 through a gate stage, and when a high level signal is applied, the FET is turned on and connected to the drain stage in series and the other stage. Current flows through R1, which is connected in parallel to the output of the flash LED, and current flows through R2, which is connected in parallel with the source and one end, into the ground of the source. . When a low level signal is applied, only the current flowing through R1 is turned off to the ground terminal of the source terminal.

Accordingly, when the FET is turned on, R1 and R2 are connected in parallel to the output terminal of the flash LED, and a large amount of current flows through the flash LED, resulting in bright light. On the other hand, when the FET is turned off, the current flows only to R2, which emits weak light.

The transistor TR is connected in parallel between the collector terminal R3 and the gate terminal of the FET, and receives the frame synchronization signal VSYNC applied from the camera sensor unit 10 to the back end chipset unit 20 through the base terminal. In the low level signal section in which the image is applied from the camera sensor unit 10 to the back end chipset unit 20, the high level flash short enable signal output from the back end chipset unit 20 is output through the R3. In the high level signal section in which the FET is turned on and the image is not applied to the back end chipset unit 20 so as to be applied to the gate end, the high level flash short enable signal output from the back end chipset unit 20 is converted to R3. By applying it to the ground terminal of the emitter terminal of the transistor, a low level signal is applied to the gate terminal of the FET, thereby turning off the FET.

4A and 4B are flash LED control timing diagrams of a mobile phone camera according to the present invention, FIG. 4A is a flash LED control timing diagram at the time of video recording, and FIG. 4B is a flash LED control timing diagram at the time of photographing.

First, during video shooting, as shown in FIG. 4A, the back end chipset unit 20 outputs a flash enable signal and a flash short enable signal while video recording is in progress, and the camera sensor unit 10 outputs the back end signal. The high level flash short enable signal is applied to the gate terminal of the FET during the low level period of the frame sync signal VSYNC to which the image signal is applied to the chipset unit 20, thereby making the brightness of the flash LED brighter.

Meanwhile, as shown in FIG. 4B, the back end chipset unit 20 outputs a flash enable signal and a flash short enable signal back and forth in accordance with a gap time, and the camera sensor unit 10 outputs the back enable chipset. Since the high level flash short enable signal is applied to the gate terminal of the FET only during the low level period of the frame synchronization signal VSYNC to which the image signal is applied to the negative signal 20, the flash LED is set to the maximum brightness value only in the gap period. You can shoot.

Hereinafter, the operation of the flash LED control device of the digital camera according to the present invention will be described with reference to FIGS. 3 and 4.

First, the back end chipset unit 20 applies a flash enable signal to the DC / DC converter 30 to illuminate the flash LED at the maximum brightness value in order to provide the amount of light required for night imaging during the night video recording. A flash short enable signal is applied to the FET side.

Meanwhile, the camera sensor unit 10 applies an image signal to the back end chipset unit 20 according to the frame synchronization signal VSYNC, and the back end chipset unit 20 only during a period in which the frame synchronization signal SYNC is at a low level. The video signal is applied.

As described above, the frame synchronization signal VSYNC applied from the camera sensor unit 10 to the back end chipset unit 20 is also applied to the base terminal of the transistor TR, and the frame synchronization signal SYNC through the base terminal. Transistor TR is turned on / off according to the frame sync signal VSYNC.

That is, it is turned off while the low level frame synchronization signal SYNC is applied, and is turned on while the high level frame synchronization signal SYNC is applied.

As described above, the transistor TR is turned off in a section in which the frame synchronizing signal SYNC that applies the image signal from the camera sensor unit 10 to the back end chipset unit 20 is at a low level, and thus the back end chipset unit 20 is turned off. ) Is applied to the gate end of the FET as it is.

Accordingly, the FET is turned on, and R2 connected to the drain terminal of the FET and R1 connected to the source terminal are connected in parallel to the output terminal of the flash LED, so that more current flows in the flash LED, and the flash LED turns on brighter momentarily.

On the other hand, the transistor TR is turned on in a section in which the frame synchronization signal SYNC in which the image signal is not applied from the camera sensor unit 10 to the back end chipset unit 20 is at a high level, so that the back end chipset unit 20 is FET. The high level flash short enable signal applied to the side flows through the transistor TR to the ground terminal.

Accordingly, a low level signal is applied to the gate of the FET, the FET is turned off, and only the R1 is connected to the output of the flash LED, and the flash LED transmits an image signal from the camera sensor unit 10 to the back end chipset unit 20. When applied, it is turned on by a weaker light.

On the other hand, the operation during the night photographing is different only in the section of outputting the flash enable signal and the flash short enable signal at a high level from the back-end chipset unit 20, the operation is the same as the night video recording, so The description will be omitted.

The flash LED control device of the digital camera of the present invention is not limited to the above-described embodiment, and may be variously modified and implemented within the range permitted by the technical idea of the present invention.

According to the flash LED control device of the digital camera of the present invention as described above, by controlling the flash LED using the frame sync signal (VSYNC) output from the camera sensor, the same flash LED without using a large flash LED By using it, you can maintain brighter brightness for a long time.

Claims (1)

A camera sensor unit applying an image signal to a back end chipset unit in accordance with a frame sync signal VSYNC, and applying a video signal to the back end chipset unit only during a period in which the frame sync signal is at a low level, and a flash in applied from a back end chipset unit. A power supply for applying the LED driving voltage to the flash LED according to the enable signal and a flash short enable signal applied from the back-end chipset unit are turned on, one end is connected in series to the drain terminal and the other end is connected to the output terminal of the flash LED. The first resistor connected in parallel and one end is connected in parallel to the source terminal and the other end is connected in parallel to the output terminal of the flash LED to the second resistor connected in series to the output terminal of the flash LED to illuminate the flash LED to the maximum brightness value In the flash LED control device of a digital camera comprising a FET, The collector terminal is connected in parallel with the gate terminal of the FET, and receives a frame synchronization signal applied from the camera sensor unit to the back end chipset unit, and is turned off in a low level frame synchronization signal section to be output from the back end chipset unit. The short enable signal is applied to the FET as it is, and the FET is turned on. In the frame synchronization signal section of the high level, the FET is turned on to receive a flash short enable signal output from the back end chipset unit through a collector stage and connected to the emitter. And a transistor configured to be applied to the ground terminal to turn off the FET.

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