JPH1185104A - Eliminating method for fixed pattern noise of large screen led display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate a fixed pattern noise by which luminance difference of individual LED causes luminance unevenness in a large screen LED display device. SOLUTION: A picture display screen 1 of a large screen LED display device is divided into plural blocks, all LEDs included in them are successively lighted with an equal signal level, LEDs successively lighted are photographed by a CCD camera 2 provided with a telephoto lens which can look simultaneously one block, a luminance compensation coefficient of a LED is calculated based on a luminance level of an obtained picture signal, that result is stored in a compensation coefficient memory 3, after storing of a luminance compensation coefficient of each LED of all blocks is finished, a compensation coefficient is read out from the compensation coefficient memory 3 when picture display is performed, a picture signal with which respective LED is luminance-modulated or a picture signal gammer-compensated which is multiplied by that picture signal, the signal level of these resultant output signals are converted to quantity of current, and respective corresponding LEDs are luminance-modulated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large-size image display apparatus for displaying a high-definition image or the like on a large-screen image display device using light-emitting diodes (LEDs). The present invention relates to a method for removing fixed pattern noise of a screen LED display device.

[0002]

In an image display device using LEDs as light-emitting pixels, the luminance difference between the individual LEDs results in luminance unevenness of the display screen as it is. This is called fixed pattern noise. Fixed pattern noise is always a problem in image display devices and the like in which a large number of pixels are arranged in a matrix, and some solution has been taken.

At present, many large-screen image display devices which are arranged outdoors for displaying advertisements or the like to display a color image often use a light bulb or a gas-filled light bulb as a light emitting element. However, when displaying a high-definition image such as a high-definition image, it is necessary to arrange small light-emitting elements at a high density.
D is promising.

A large screen display device using an LED is largely different from a large screen display device using a light bulb or the like in terms of the size of the light emitting element itself, the density of element arrangement (accordingly, the number of elements used), and Of the light-emitting element.

It is an object of the present invention to provide a light emitting device having a small size,
Large screen LE with a huge number of light emitting elements arranged at high density
An object of the present invention is to provide a fixed pattern noise removing method for a large-screen LED display device, which is configured to be most suitable for removing the fixed pattern noise in the D image display device.

[0006]

In order to achieve the above object, a fixed pattern noise elimination method for a large-screen LED display device according to the present invention comprises dividing an image display surface of a large-screen LED display device into a plurality of blocks. A CC equipped with a telescope or a telephoto lens capable of simultaneously illuminating all of the LEDs included in the divided blocks one by one at the same signal level and simultaneously putting one of the blocks into the field of view.
The LED sequentially lit is photographed by a D camera, a luminance correction coefficient of the sequentially lit LED is calculated based on the luminance level of the obtained image signal, and the calculation result is written into a correction coefficient memory. After the writing of the luminance correction coefficient of each LED of the block is completed, when the LED display device performs image display, the correction coefficient is read from the correction coefficient memory for each LED, and the read correction coefficient is Multiplying the corresponding LED by a luminance-modulated image signal or a gamma-corrected image signal, converting the signal level of the multiplied output signal into a current amount, and performing luminance modulation on the corresponding LED. It is characterized by being in.

Further, the method of removing fixed pattern noise of a large-screen LED display device according to the present invention comprises the steps of:
Is taken with the CCD camera fixed so that the block including the lit LED is within the image frame of the photographed output of the CCD camera.
When photographing of the ED is completed, the direction of the CCD camera is changed so as to move to photographing of another block.

Further, in the method for removing fixed pattern noise of a large-screen LED display device according to the present invention, an equatorial mount is used to change the direction of the CCD camera.

Further, the fixed pattern noise removing method for a large-screen LED display device according to the present invention comprises the step of:
The calculation of the brightness correction coefficient K _x of

(Equation 2) It is characterized by being performed based on.

In the fixed pattern noise elimination method for a large-screen LED display device according to the present invention, the output signal level resulting from the multiplication is converted into a current amount. The amplitude-modulated current level is maintained for a predetermined period.

Further, in the fixed pattern noise elimination method for a large-screen LED display device according to the present invention, the predetermined period may be set to the LE.
When the D display device displays Hi-Vision line by line, the display time is 29.6 μsec.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on embodiments of the present invention with reference to the accompanying drawings. FIG.
4 conceptually illustrates a method for removing fixed pattern noise of a large-screen LED display device according to the present invention. In FIG.
Reference numeral 1 denotes an image display surface of a large-screen LED display device, and 2 denotes a CCD camera having a telescope or a telephoto lens for photographing the image display surface 1 from a distance (this is a CCD with a super telephoto lens).
A calculation storage system including a memory for calculating a luminance correction coefficient of each LED based on an image signal captured by the CCD camera 2 and writing the result (correction coefficient); Reads a correction coefficient from the memory of the calculation storage system 3 for each LED, multiplies the image signal which is gamma-corrected as necessary and modulates the brightness of each LED, and outputs the signal level of the multiplied output signal as a current. This is a drive circuit for the image display surface 1 which is configured to convert the amount into an amount and to perform luminance modulation on the corresponding LED.

Now, in the fixed pattern noise elimination method according to the present invention, the size of the image display surface 1 of the target large-screen LED display device is, for example, assuming that each LED is driven by a Hi-Vision signal, the LED is 1,920. × 1,080
= 2,073,600 pieces are required. Assuming that these LEDs are arranged at an interval of 1 cm in length and width, as shown in FIG.
X 10.8m, 9.6m x 5.4m even at 5mm intervals
And a huge image display surface.

Next, the measurement of the luminance level of the light emission luminance of each LED will be described with reference to FIG. Originally, since the light emission luminance of the LED is extremely high, it is not necessary to strictly block external light, and the measurement may be performed while paying attention to cloudy weather, night of a new moon, light of an external light, and the like. The measurement position was set at a position 5 times ahead of the height (10.8 m) of the display surface 1 (i.e., 54 m) from the midpoint of the image display surface. It may be a position.

Specifically, the measurement of the brightness level of each LED is performed by sequentially lighting the LEDs one by one at the same signal level, and setting the CCD camera 2 mounted on a telescope (for example, an astronomical telescope).
To measure the emission luminance. Now, assuming that the viewing angle of the astronomical telescope is 2 degrees (about 1,000 mm on the image display surface), the viewing angle in the horizontal direction of the display surface is 20 degrees. Has a viewing angle of 11.42 degrees, so that the entire display surface can be covered by six measurement angle movements. That is, the movement of the measurement angle for the measurement is a total of 60 times. For the movement of the measurement angle, for example, an equatorial mount for astronomical observation can be used.

An image photographed by lighting (an image using an LED as a subject) is subjected to A / D conversion, and, for example, an average pixel value until the signal is reduced by 3 dB from the maximum value is measured as a signal output. The viewing angle between adjacent LEDs is 0.0
Since it is 1 degree, the viewing angle of the astronomical telescope is 2 degrees, that is,
200 x 200 = 40,000 pixels in one measurement block
In order to display a color image, each pixel is composed of three LEDs of red (R), green (G) and blue (B), so that 120,000 LEDs are included.

The time required for measuring the luminance level of the LEDs on all display surfaces (total measurement time) is: total measurement time = [{(LED emission time + calculation processing time + data storage time) × number of LEDs in one block} + ｛ Block moving time｝] × number of blocks Each element time in this equation is as follows. LED emission time: 1 field (1 out of 16 ms)
(Horizontal scanning period: 29.6μsec) ・ Calculation processing time: Processing in the same field ・ Data storage time: Processing in the same field ・ Block movement time: 2 seconds Therefore, the total measurement time = (16 ÷ 1,000 × 120,000 + 2) ×
60 = 115,320 seconds (32 hours).

At 32 hours, it is not possible to complete the measurement at dark nights. If it is absolutely necessary to complete within 6 hours, it will take about 11 hours to measure only one color (for example, red (R)) a day,
This is not an overnight measurement. Therefore, it is conceivable that the measurement of one color is performed in two systems, completed in 5.5 hours per night, and completed in three nights.

Next, one method for obtaining a correction coefficient performed in the calculation storage system 3 (see FIG. 1) will be described below. Maximum Lmax LED brightness showing luminance, minimum when the Lmin the luminance of the LED indicating the luminance, the correction coefficient K _x of the LED indicating the luminance L _x may be obtained by the following equation.

(Equation 3)

The individual LEs read from the calculation storage system 3
Correction coefficient K _x of D is sent to the drive system 4, where each L
The ED is multiplied by an image signal for luminance modulation, and converted into a current having a level corresponding to the result of the multiplication.

As described above, the method according to the present invention employs the current driving method depending on the signal strength. Lighting of individual LED, when displaying high-definition video,
Its horizontal scanning period is 29.6 μs and its duty cycle is 30 Hz. FIG. 3 shows an embodiment of the drive circuit 4 (see FIG. 1).

In FIG. 3, 5-R, 5-G and 5-
B denotes a correction coefficient memory included in the calculation storage system 3 (see FIG. 1) shown in FIG. 1, and has a total of 1,920 × 1,080 × 3 bits of 8 bits in parallel, that is, a capacity of approximately 6 Mbytes. Then, the above-described correction coefficient _Kx is stored.

On the other hand, red (R), green (G), and blue (B) signals (shown at the left end in FIG. 3) input to drive the image display surface 1 of the large-screen LED display device are respectively Gamma correction is performed by gamma correction circuits 6-R, 6-G, and 6-B (this gamma correction may be omitted at times), and then correspondingly performed by multiplication circuits 7-R, 7-G, and 7-B, respectively. Is multiplied by the correction coefficient of the color to be changed.

The corrected R, G, and B color signals are written into the 8-bit parallel 1,920-stage shift registers 8-R, 8-G, and 8-B at the HDTV clock rate (74.25 MHz). It is. When a signal for one horizontal scanning period is written in these shift registers, the written contents are transferred to the display buffer 9.

The output data from the display buffer 9 is 1,92
The signal is sent to the 0 × 3 bit DA converter 10 and converted into an analog voltage level. This voltage level is further converted by the current converter 11 into a current amount that is amplitude-modulated in accordance with the voltage level, and this is converted into one horizontal scan of each LED 1 (1,920 × 3 per scan line) in the vertical direction. Supplied at the same level during the period. The cathode side of the LED is
Scanning is performed by a vertical scanning signal from a vertical scanning circuit (not shown), and each horizontal line is connected to the ground, and LED1 on the corresponding scanning line is activated. As a result, the light emission luminance of the LED at an arbitrary pixel point correctly reproduces the level of the image signal at the corresponding pixel point.

In the above embodiment of the present invention, the LED
To drive the image display surface of the display device, the analog voltage level of the DA converter output is converted to a current corresponding to the level (amplitude modulation of the current amount) and supplied for one horizontal scanning period. . This is compared with other conceivable methods, for example, when changing the lighting time of the LED while keeping the amplitude of the current constant according to the analog voltage level (time width modulation of the lighting time). This is because the response frequency of the LED display device can be reduced, and the price of the LED display device can be reduced.

In the case of Hi-Vision display, one horizontal scanning period Th is 29.6 μsec. In the case of time width modulation, in order to correctly reproduce luminance corresponding to a time width of 1/256 of this, a circuit of the circuit is required. It is necessary to set the response frequency to 8.64 MHz.
3.75 kHz may be used. FIG. 4 shows drive current waveforms of both the amplitude modulation method and the time width modulation method as waveforms (a) and (b), respectively.

[0028]

According to the fixed pattern noise elimination method according to the present invention, the following remarkable effects can be obtained. Since the individual differences between the individual LEDs are corrected, it is not necessary to strictly adjust the characteristics of the individual LEDs, and therefore, the device is inexpensive. If the LED drive circuit that performs the amplitude modulation of the current amount described above is employed, the frequency response required for the drive circuit is low, so that an inexpensive circuit element can be used and the error based on the time element is small. It is also possible to easily correct uneven brightness of the LED due to aging.

[Brief description of the drawings]

FIG. 1 conceptually shows a fixed pattern noise removing method according to the present invention.

FIG. 2 is a diagram illustrating a scale of an image display surface of a large-screen LED display device and measurement of a luminance level of emission luminance of each LED.

FIG. 3 shows details of an image display surface, a part of a calculation storage system, and a driving circuit in FIG.

FIGS. 4A and 4B show drive current waveforms of both the amplitude modulation method and the time width modulation method, respectively.

[Explanation of symbols]

Reference Signs List 1 image display surface 2 CCD camera 3 calculation storage system 4 drive circuit 5-R, 5-G, 5-B correction coefficient memory included in calculation storage system 6-R, 6-G, 6-B gamma correction circuit (γ 7-R, 7-G, 7-B Multiplication circuit 8-R, 8-G, 8-B shift register 9 Display buffer 10 DA converter 11 Current converter

Claims (6)

[Claims] 1. An image display surface of a large-screen LED display device is divided into a plurality of blocks, and all of the LEDs included in the divided blocks are sequentially turned on one by one at the same signal level, and one of the blocks is turned on. C with a telescope or telephoto lens that allows one to enter the field of view at the same time
The sequentially lit LEDs are photographed by a CD camera, the brightness correction coefficient of the sequentially lit LEDs is calculated based on the brightness level of the obtained image signal, and the calculation result is written to a correction coefficient memory. After the writing of the brightness correction coefficient of each LED of the block is completed, when the LED display device performs image display, the correction coefficient is stored in the correction coefficient memory from each LED.
Each time, and the read out correction coefficients are
Multiplying the corresponding LED by a luminance-modulated image signal or a gamma-corrected image signal, converting the signal level of the multiplied output signal into a current amount, and performing luminance modulation on the corresponding LED. A method for removing fixed pattern noise of a large-screen LED display device. 2. The method according to claim 1, wherein the photographing of the sequentially lit LEDs is performed such that the block including the lit LEDs is within an image frame of a photographing output of the CCD camera. The large-screen LED display device is fixed in that the camera is fixed and the direction of the CCD camera is changed so as to shift to the shooting of another block when the shooting of the LED in the block is completed. Pattern noise removal method. 3. The method of claim 2, wherein said CC
A fixed pattern noise removing method for a large-screen LED display device, wherein an equatorial mount is used to change the direction of the D camera. 4. The method according to claim 1, wherein the calculation of the luminance correction coefficient K _x of the sequentially lit LEDs is represented by the following _equation : A fixed pattern noise removing method for a large-screen LED display device, wherein the method is performed based on: 5. The method according to claim 1, wherein the current amount is amplitude-modulated corresponding to the output signal level to convert the multiplied output signal level into a current amount. A fixed pattern noise removing method for a large-screen LED display device, wherein the fixed current level is maintained for a predetermined period. 6. The method according to claim 4, wherein the predetermined period is 29.6 μsec when the LED display device displays a high definition image on a line-by-line basis. Pattern noise removal method.