KR101940731B1 - System for reducing power in OLED - Google Patents

Abstract

The present invention relates to a power reduction system through individual correction of a GUI object in playing an image of an organic light emitting diode display. According to one embodiment of the present invention, the power reduction system comprises: an OLED display panel comprising a plurality of OLED modules; a power supplier supplying power to each OELD module in the OLED display panel; a camera photographing OLED images displayed in the OELD display panel; an individual correction luminance value calculator extracting GUI object images displayed in the OLED images in order to calculate individual correction luminance values which make luminance of each of the extracted GUI object images have a predetermined individual reference luminance; and an OLED image controller controlling each of power supplying values of the OLED modules displaying GUI object images in the OLED images in order to have the luminance of GUI object images applied with the individual correction luminance values wherein the OLED image controller provides image data for the OLED display panel and controls power supply of the power supplier. The present invention can reduce power consumption through luminance correction by using individual reference luminance aligned for each GUI object.

Description

[0001] The present invention relates to a system for reducing power in an organic light emitting diode (OLED) display,

The present invention relates to a power reduction system through individual correction of GUI objects upon image reproduction of an organic light emitting diode display.

In recent years, high-definition broadcasting (HDTV) has been commercialized due to the development of video technology and semiconductor technology, and LED display boards have become popular. As a result, OLEDs have been developed and applied to OLED display panels in full- Anger is going on rapidly. However, there is a demand for a digital image processing technique for realizing a technique for displaying a video image close to natural color and an image without smearing, as well as the development of a technique for simply displaying an image.

In order to meet such a demand, an error detection device and a correction technique have been implemented. For example, a display panel system in which resolution is improved by various image sources, scaling processing and dynamic interpolation scanning is proposed in Korean Patent No. 468209.

However, in the case of a large-size OLED, several tens to millions of OLED modules are combined. However, since the brightness or color of each OLED module is not uniform, the entire display panel There still existed limitations such as occurrence of minute unevenness in the display of the electric sign board.

Accordingly, techniques for measuring and correcting luminance and chromaticity individually for each OLED module are proposed at the time of product shipment in order to realize high image quality in an OLED electronic billboard including tens to millions of OLED modules.

However, only technologies for correcting brightness and chromaticity for OLED modules for high image quality are presented, and luminance correction means for power reduction at the time of shipment of OLED display panels are not proposed.

Korea Patent No. 468209

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electric power reduction means through individual correction of a GUI object during image reproduction of an organic light emitting diode display.

An embodiment of the present invention relates to an OLED display panel comprising a plurality of OLED modules; A power supply for supplying power to each OLED module in the OLED display panel; A camera for photographing the OLED image displayed on the OLED display panel; An individual correction luminance value calculator for extracting GUI object images displayed on the OLED image and calculating an individual correction luminance value such that the luminance of each of the extracted GUI object images has a predetermined reference standard luminance; And a power supply of the OLED module for displaying the GUI object image in the OLED image so that the brightness of the GUI object image to which the individual correction luminance value is applied is provided to the OLED display panel, And an OLED image controller for separately controlling supply values.

And a power saving request button which is requested by the user to control the power supply value of the power supply so that the OLED image is output with the individual correction luminance value, The power supply value can be controlled so that the GUI object in the LED image is output as the individual correction luminance value in the case of a power saving request.

Wherein the power reduction system includes an individual reference luminance assignment database in which individual reference luminances are assigned to respective GUI object image shapes, and the individual correction luminance value calculator calculates a GUI object image An individual correction luminance value can be calculated using the individual reference luminance assigned to the shape.

The individual reference luminance allocation database is allocated and set to a value at which the individual reference luminance becomes lower as the size of the GUI object image is larger.

Wherein the individual reference luminance assigning database assigns individual reference brightnesses for each color of the GUI object image, and the individual correction brightness value calculator identifies the color of the extracted GUI object image, It is possible to calculate the individual corrected brightness value.

The individual reference luminance allocation database may be assigned and set to a value such that the individual standardized luminance decreases as the color of the GUI object becomes darker.

According to the embodiment of the present invention, it is possible to reduce the power consumption through the brightness value correction using the individual reference brightness assigned to each GUI object.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic block diagram showing the configuration of a measurement system for conventional LED module luminance and chromaticity correction; FIG.
FIG. 2 is a block diagram of a power reduction system through individual correction of a GUI object upon image reproduction of an OLED display according to an embodiment of the present invention; FIG.
3 is a block diagram of the configuration of a power reduction system through individual correction of GUI objects upon image reproduction of an OLED display in accordance with an embodiment of the present invention.
4 is a flowchart illustrating power reduction processes by individual correction of a GUI object during image reproduction of an OLED display according to an exemplary embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to achieve them, will be apparent from the following detailed description of embodiments thereof taken in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the exemplary embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete and will fully convey the concept of the invention to those skilled in the art. And the present invention is only defined by the scope of the claims. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a schematic block diagram showing the configuration of a conventional measurement system for luminance and chrominance correction. FIG. 2 is a schematic diagram illustrating a power reduction through individual correction of a GUI object in an image reproduction of an OLED display according to an embodiment of the present invention. FIG. 3 is a block diagram of a power reduction system through individual correction of a GUI object upon image reproduction of an OLED display according to an embodiment of the present invention. Referring to FIG.

An existing measurement system for luminance and chromaticity correction of an individual light source module of a display panel includes a measurement sample 10, a measurement device 20, and a measurement sample controller 30. The measurement sample 10 includes a display panel 10, And a flash memory 13, which is a nonvolatile memory. The display panel 11 includes a light emitting element such as a light emitting diode (LED) The measuring instrument 20 may include a camera 21 for photographing the display panel 11 and a measurement value processor 23 for extracting measurement values such as luminance and / or chromaticity data from the data photographed by the camera 21 have. The measurement sample controller 30 includes a correction processing unit 31 for receiving measured values of luminance and chromaticity from the measurement value processing unit 23 and outputting correction data and control data of luminance and chroma to a predetermined reference value and a correction processing unit 31 And a lighting controller 33 which can turn on the display panel 11 of the measurement sample in accordance with the correction data and the control data from the controller 31. [ The lighting controller 33 can store the correction data received from the correction processing section 31 in the flash memory 13 of the measurement sample 10. [

The configuration of the measurement and correction system of the conventional light source module as shown is a measurement system separate from the display system. In this case, after the measurement, the correction data, that is, the coefficient data, is stored in the memory 13 of the measurement sample 10. This memory 13 is held as a nonvolatile memory without losing data once it has been restored.

In the conventional system, the correction operation of the display panel is performed by a control unit of the display panel, when the display panel is set up, from the memory of the light source module to the correction coefficient data stored in the nonvolatile memory of the light source module, And then calibrating the entire display panel after correcting the readout.

However, in the conventional system, the luminance and chromaticity are corrected individually for the OLED module for high image quality implementation, and the luminance correction means for reducing the power is not proposed.

Accordingly, the present invention is intended to provide luminance correction means for power reduction.

Referring to FIG. 2, a power reduction system through individual correction of a GUI object upon image reproduction of an OLED display of the present invention includes an OLED display panel 100, a power supply 200, a camera 300, A display 410, and an OLED image controller 420. In addition, it may further include an individual reference luminance allocation database 430. The individual correction luminance value calculator 410, the OLED image controller 420 and the individual reference luminance allocation database 430 may be implemented within a single calculation device such as the desktop PC 400. [

The OLED display panel 100 is a display device composed of a plurality of OLED modules. Therefore, the OLED display panel 100 may include all kinds of OLED display devices such as an OLED display panel. For reference, organic light emitting diodes (OLEDs) are organic light emitting diodes that emit light using organic compounds and are flat panel displays whose image quality is 1000 times faster than LCD. OLED uses three fluorescent organic compounds, red, green, and blue, which have self-luminous functions, and belong to an emissive display. Organic EL using the phenomenon that electrons injected from cathode and anode and positively charged particles combine in organic material and emit light by itself are light emitting type products, and therefore, there is no need for backlight (backlight device) that lowers color. OLEDs have faster data response times than TFT-LCDs and have a viewing angle of 170 °, which is more than 10 ° wider than TFT-LCDs, so they can experience the same image quality in either direction.

The power supply 200 is a device that is provided in the OLED display panel 100 and supplies power to each OLED module in the OLED display panel 100. A DC-DC converter, an FET switching device, a PWM modulator, and the like, and individually supplies driving power to each OLED module constituting the OLED display panel 100.

The camera 300 is an imaging device that captures an OLED image displayed on the OLED display panel 100. [ And is an element for picking up the OLED display panel 100 before it is shipped and sold for correction for power saving of the OLED product.

For reference, the camera 300 may include a lens assembly, a filter, a photoelectric conversion module, and an analog / digital conversion module. The lens assembly includes a zoom lens, a focus lens, and a compensation lens. The focus distance of the lens can be shifted under the control of the focus motor MF. The filters include an optical low pass filter and an optical low pass filter. And may include an Infra-Red Cut Filter. An optical low-pass filter removes the high-frequency component of optical noise, while the Infra-Red cut filter blocks the infrared component of incident light. The photoelectric conversion module may include an image pickup device such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal-Oxide-Semiconductor). The photoelectric conversion module converts light from the optical system (OPS) into an electrical analog signal. The analog / digital conversion module may include a CDS-ADC (Correlation Double Sampler and Analog-to-Digital Converter) device. An analog / digital conversion module (not shown) processes an analog signal from the photoelectric conversion module OEC, removes the high-frequency noise, adjusts the amplitude, and converts the analog signal into a digital signal.

The individual correction brightness value calculator 410 extracts GUI object images displayed on the OLED image. Here, the GUI object image refers to an image of a graphical user interface (GUI). For example, in the case of an OLED display panel, an environment setting GUI object image, a menu selection GUI object image, and the like may be applied.

The individual correction luminance value calculator 410 also calculates an individual correction luminance value such that the luminance of each of the extracted GUI object images has a predetermined individual reference luminance. The individual reference luminance is the standard luminance value of the GUI object image displayed on the OLED display panel 100. [

For example, assuming that the individual reference luminance is 40 [cd / m ² ], when the measured luminance of the environment setting GUI object image displayed by driving the OLED display panel 100 is 50 [cd / m ² ] , And the individual correction luminance value of the environment setting GUI object image is -10 [cd / m ² ].

Similarly, when the measured luminance of the menu selection GUI object image displayed by driving the OLED display panel 100 is 65 [cd / m ² ], assuming that the individual reference luminance is 40 [cd / m ² ] The individual correction luminance value of the setting GUI object image is -25 [cd / m ² ].

The OLED image controller 420 is a device that provides image data to the OLED display panel 100 and controls the power supply of the power supply 200.

The OLED display panel 100 is designed such that it is output at an individual reference luminance at the time of power supply operation. However, in many cases, the OLED display panel 100 outputs a luminance higher than the individual reference luminance due to OLED characteristics, panel plate characteristics, , To display the corrected luminance value before the sale of the OLED product, thereby preventing unnecessary power consumption.

To this end, the OLED image controller 420 of the present invention controls the driving power of the light source module such that the luminance of the GUI object image to which the individual correction luminance value is applied is the luminance of the GUI object image.

For example, assuming that the configuration GUI object image is measured at 50 [cd / m < ² >] when power to the first light source module outputting the environment setting GUI object image in the OLED image is provided at 5A, When the individual correction luminance value of the setting GUI object image is calculated as -10 [cd / m ² ], the power to be driven to the light source module for outputting the environment setting GUI object image in the OLED image is reduced to 4 A, ² ] brightness.

Assuming that the menu selection GUI object image is measured at 65 [cd / m ² ] when the power to be supplied to the second light source module outputting the menu selection GUI object image in the OLED image is 7 A, If the individual corrected luminance value of the object image is calculated as -25 [cd / m ^2], by reducing the power to the light source driving module which outputs a configuration GUI object image in the image to the OLED 5A 40 [cd / m ^2] So that the luminance is obtained.

Therefore, the power consumption can be reduced because the minimum power required for achieving the individual reference brightness is consumed.

Meanwhile, the power reduction system may include a power saving request button that is requested by the user to control the power supply value of the power supply 200 so that the OLED image is output with the individual correction luminance value.

The LED image controller controls the power supply value so that the GUI object in the LED image is output as the individual correction luminance value when there is a power saving request through the power saving request button. Therefore, when there is no power saving request, it is controlled without brightness correction, and brightness correction for power saving can be performed only when power saving is requested.

On the other hand, the power reduction system may include a separate reference brightness allocation database 430 in which individual reference brightnesses are assigned to GUI object image shapes, respectively. Here, the database may be a hard disk drive, an SSD drive (Solid State Drive), a flash memory, a CF card, an SD card (Secure Digital card), a SM card ), An MMC card (Multi-Media Card), a memory stick, and the like, or may be provided in a separate device.

Furthermore, the individual reference brightness can be assigned and set to a value that increases as the size of the GUI object image shape increases.

The individual correction luminance value calculator 410 can calculate the individual correction luminance value using the extracted individual reference luminance values assigned to the GUI object image shapes by grasping the extracted GUI object image shapes. Therefore, different individual correction luminance values can be calculated using the different reference luminance assigned differently according to the shape of each GUI object image.

Further, as the size of the GUI object image shape is larger, the individual reference brightness can be assigned and set to a value at which the individual reference brightness is lowered. This is because the larger the size of the GUI object image is, the better the GUI object can be identified even if the luminance is low. Therefore, even if the individual reference luminance is set low, the visibility is not significantly problematic. Thus, the power saving can be further increased.

In addition, individual reference brightnesses may be assigned to each GUI object image color in the individual reference brightness assignment database 430. The individual correction brightness value calculator 410 may grasp the color of the extracted GUI object image and grasp The individual correction luminance values can be calculated using the individual reference luminances assigned to the GUI object image colors. Therefore, different individual correction luminance values can be calculated using the individual reference luminance assigned differently according to each GUI object image color.

Furthermore, as the color of the GUI object becomes darker, it is possible to assign and set a value such that the individual opening luminance becomes lower. This is because the visibility of the GUI object does not vary much even if the brightness of the GUI object image is low, and visibility is not a problem even if the individual reference brightness is set low. Thus, the power saving can be further increased.

FIG. 4 is a flowchart illustrating power reduction processes through individual correction of a GUI object during image reproduction of an OLED display according to an exemplary embodiment of the present invention.

The power reduction method through individual correction of the GUI object during the image reproduction of the OLED display of the present invention includes the OLED image capturing process S410, the individual correction brightness value calculation process S420, and the OLED image control process S430 .

The OLED image capturing process S410 is a process of capturing an OLED image displayed on the OLED display panel 100 using the camera 300. [ The OLED display panel 100 before being sold is photographed to acquire an OLED image in order to calibrate for the OLED power saving of the product.

The individual correction luminance value calculation process S420 is a process of extracting GUI object images displayed on the OLED image and calculating an individual correction luminance value such that the luminance of each extracted GUI object image has a predetermined reference standard luminance . Here, the GUI object image refers to an image of a graphical user interface (GUI).

Also, an individual correction luminance value is calculated so that the luminance of each extracted GUI object image has a predetermined reference luminance. For example, assuming that the individual reference luminance is 40 [cd / m ² ] The individual correction luminance value of the environment setting GUI object image becomes -10 [cd / m ² ] when the measured luminance of the environment setting GUI object image displayed by driving the display device 100 is 50 [cd / m ² ]. Similarly, when the measured luminance of the menu selection GUI object image displayed by driving the OLED display panel 100 is 65 [cd / m ² ], assuming that the individual reference luminance is 40 [cd / m ² ] The individual correction luminance value of the setting GUI object image is -25 [cd / m ² ].

The OLED image control process S430 is a process for individually controlling the power supply value of the OLED module for displaying the GUI object image in the OLED image so that the luminance of the GUI object image to which the individual correction luminance value is applied is controlled.

The OLED display panel 100 is designed such that it is output at an individual reference luminance at the time of power supply operation. However, in many cases, the OLED display panel 100 outputs a luminance higher than the individual reference luminance due to OLED characteristics, panel plate characteristics, , To display the corrected luminance value before the sale of the OLED product, thereby preventing unnecessary power consumption. To this end, the OLED image controller 420 of the present invention controls the driving power of the light source module such that the luminance of the GUI object image to which the individual correction luminance value is applied is the luminance of the GUI object image.

For example, assuming that the configuration GUI object image is measured at 50 [cd / m < ² >] when power to the first light source module outputting the environment setting GUI object image in the OLED image is provided at 5A, When the individual correction luminance value of the setting GUI object image is calculated as -10 [cd / m ² ], the power to be driven to the light source module for outputting the environment setting GUI object image in the OLED image is reduced to 4 A, ² ] brightness.

The embodiments of the present invention described above are selected and presented in order to facilitate the understanding of those skilled in the art from a variety of possible examples. The technical idea of the present invention is not necessarily limited to or limited to these embodiments Various changes, modifications, and other equivalent embodiments are possible without departing from the spirit of the present invention.

100: OLED display panel
200; power supply
300: camera
410: Individual correction luminance value calculator
420: OLED image controller
430: individual reference luminance assignment database

Claims (6)

An OLED display panel comprising a plurality of OLED modules;
A power supply for supplying power to each OLED module in the OLED display panel;
A camera for photographing the OLED image displayed on the OLED display panel;
An individual correction luminance value calculator for extracting GUI object images displayed on the OLED image and calculating an individual correction luminance value such that the luminance of each of the extracted GUI object images has a predetermined reference standard luminance;
A power supply of an OLED module for displaying a GUI object image in an OLED image so that the luminance of the GUI object image to which the individual correction luminance value is applied is supplied to the OLED display panel, An OLED image controller for individually controlling the values; And
And an individual reference luminance assignment database to which individual reference luminances are assigned for each GUI object image shape,
The individual correction luminance value calculator calculates the individual correction luminance value by using the individual reference luminance assigned to the GUI object image shape obtained by grasping the extracted GUI object image shape,
Wherein the individual reference luminance assignment database comprises:
Wherein the OLED display is assigned and set to a value such that the individual reference brightness decreases as the size of the GUI object image increases.
The system of claim 1,
And a power saving request button which is requested by the user to control the power supply value of the power supply so that the OLED image is output with the individual correction luminance value,
Wherein the OLED image controller controls a power supply value so that a GUI object in the OLED image is output as the individual correction luminance value when there is a power saving request through the power saving request button. Power reduction system through individual compensation of objects.
delete delete The method according to claim 1,
In the individual reference luminance allocation database, individual reference brightnesses are allocated to each GUI object image color,
Wherein the individual correction luminance value calculator calculates the individual correction luminance value by using the individual reference luminance assigned to the identified GUI object image color by grasping the color of the extracted GUI object image, The power reduction system with individual compensation of.
6. The apparatus of claim 5,
Wherein the brightness of the GUI object is set to a value that decreases as the color of the GUI object becomes darker.

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