WO2000060562A1 - High resolution display screen for an led screen - Google Patents

Abstract

The invention relates to a device enabling the number of pixels to be multiplied by 6 in comparison with a conventional system for the same number of LEDs. The inventive device comprises a panel on which the LEDs are disposed in such a way as to enable each LED to participate, either successively or simultaneously, in 6 different pixels, and an adapted electronic control system.

Description

Haunting resolution display system for LED screen. The present invention relates to LED screens (or display boards) (light emitting diodes). LED screens have been designed to meet the need to present images in places where the intensity of ambient light is high (usually outdoors in daylight, or indoors in bright places).

This equipment consists on the one hand of a panel whose frontage of black color is equipped with a very large quantity of LED, allowing to make appear the image, and on the other hand of an electronic control system which receives d 'a source (video recorder for example) information concerning the image to be reproduced. The electronic system transforms the image information it receives into an electrical intensity emission intended for each LED, allowing it to light up with the desired intensity. Thus each LED at each instant T (for example 120 instructions per second when the system frequency is 120 Hertz) lights up with such intensity, allowing, taking into account the intensity received by its neighboring LEDs associated in the same pixel, obtain the image point of the desired color and intensity. White is obtained by switching on all the LEDs with high intensity, and black is obtained by switching off all the LEDs.

In the current state of the art, each pixel (image point) consists of a set of red (R), green (G = green) and blue (B) LEDs. The technique now makes it possible to constitute a pixel with only 1 red LED + 1 green LED + 1 blue LED. Each LED being definitively assigned to a pixel, we thus obtain in the best case 1 Pixel = 1 red LED + 1 green LED + 1 blue LED, that is to say 1 Pixel for 3 LEDs.

The disadvantage of these LED screens is that they give an image whose definition is poor because of the small amount of pixels. It is therefore necessary to distance the screen from the spectators, and consequently to produce screens only of large dimensions, therefore very expensive. The pixel density can be increased by reducing the size of the LEDs and / or by bringing them as close as possible to each other. In this case, we are technically limited by the minimum size of an LED and its attachment to the screen. more, such an approach would generate a considerable increase in the price of such a screen

The main object of the present invention therefore is to remedy these drawbacks and to do this, it has for ob] βt a system which is essentially characterized in that it comprises on the one hand a panel on which the LEDs are arranged a particular way, and on the other hand a particular LED control system The LEDs used have characteristics such that they make it possible to form a pixel when the centers of the LEDs of a tri-color trio form an equilateral triangle

LED arrangement on the panel

The LEDs according to the present invention are arranged according to the following principle as illustrated in FIG. 1 on each horizontal line, the LEDs appear in the following order

RGBRGBRGB, etc (or RBGRBGRBG, etc), in which "R" = red LED, "G" = green LED, "B" = blue LED, and with a constant mterval between two neighboring LEDs Each line is arranged relative to the previous line so that each LED is located exactly below the middle of the interval which separates the two LEDs of complementary colors from the top line Each line is also arranged in relation to the previous line so that the vertical distance which separates the horizontal axes of two consecutive lines is equal to the horizontal distance which separates the centers of two neighboring LEDs located on the same line multiplied by the square root half of three, a value very close to 0.866 So, thanks to this particular arrangement of the LEDs on the screen, each LED is close to 6 pairs of LEDs of the two complementary colors and each LED is equidistant from each of its color neighbors different rs, thus making it possible to form 6 different pixels around an LED, as illustrated on the figure 1 This LED arrangement is applied to the entire LED control screen

The electronic LED control system according to the present invention is designed such that each LED is controlled according to the pixel or pixels which it is necessary to actuate. This system is programmed to scan the image in a precise order of appearance of pixels Depending on the frequency used, the most appropriate sequence will be chosen, allowing all the pixels to be actuated with the same frequency Each pixel must be actuated with a frequency at least equal to 24 Hertz (minimum frequency allowing, thanks to persistence of the retina, eliminating flickering phenomena in the image in a dimly lit environment (this threshold increases with the level of ambient light)

Thus each LED can intervene in 6 different pixels. Given this particular arrangement of LEDs, several different pixel control sequences are possible. They influence the resolution and the luminance, and each require a specific frequency.

Numerous sequences are possible Certain sequences are to be avoided because they allow the formation of parasitic pixels constituted by only two contiguous LEDs belonging to two different pixels II thus forms between these two LEDs a pixel whose color and light intensity are inconsistent with the image to be reproduced Among the possible sequences, the most interesting (because they avoid the formation of spurious pixels) are the following - Sequence 15 In this sequence, the different pixels are actuated successively in a precise order (Figure 3) Each pixel is activated one time out of 15 The pixel control frequency is therefore 15 times higher than the minimum basic frequency of a traditional LED screen. At any time t, the active pixels are sufficiently distant from each other so that there is no interference between them The resolution of the image thus produced is therefore maximum At each instant t, 40% of the LEDs are activated, which causes a decrease in luminance of the screen compared to the luminance of a traditional LED screen. This decrease in luminance can be compensated for by using more powerful LEDs if necessary.

- Sequence 6 In this sequence, the different pixels are actuated successively in a precise order (Figure 4) Each pixel is actuated one time out of 6 The pixel control frequency is therefore 6 times higher than the minimum basic frequency of one traditional LED screen

At each instant t, the active pixels are close enough to each other that there is formed between them non-controlled interpixels The color and the brightness of each mter-pixel thus formed results from the average of the colors and brightness of the controlled pixels which are contiguous to it Thus these uncontrolled mter-pixels are automatically consistent with the image to be reproduced The resolution of the image thus produced is therefore slightly lower than in sequence 15, but much higher than that of a traditional screen A at each instant t, 100% of the LEDs are actuated, which does not cause any drop in luminance of the screen compared to the luminance of a traditional LED screen

- Sequence 2 In this sequence the different pixels are actuated successively in a precise order (Figure 5) Each pixel is actuated every second time The pixel command frequency is therefore twice as high as the minimum base frequency of a screen a traditional LED Each LED, belonging simultaneously to three different pixels, must be controlled so that it displays an intensity equal to the average of the values controlled by each of these three pixels

At each instant t the active pixels are close enough to each other so that non-controlled interpixels are formed between them. The color and the brightness of each mter-pixel thus formed results from the average of the colors and brightness of the controlled pixels which they are contiguous thus allowing them to be consistent with 1 image to be reproduced The resolution of 1 image thus produced is therefore slightly more weak than in sequence 15, but much higher than that of a traditional screen

At all times t 100% of the LEDs are activated, which does not cause any drop in luminance of the screen compared to the luminance of a traditional LED screen

- Sequence 1 In this sequence, all the pixels are actuated simultaneously (figure 6) The pixel control frequency is therefore identical to the minimum basic frequency of a traditional LED screen

Each LED, belonging simultaneously to six different pixels, must be controlled so that it displays an intensity equal to the average of the values controlled by each of these six pixels.

The resolution of the image thus produced is therefore slightly lower than in sequence 15, but much higher than that of a traditional screen.

At any time t, 100% of the LEDs are activated, which does not cause any drop in luminance of the screen compared to the luminance of a traditional LED screen

One can also choose, by a specific programming of the control system, to use only part of the series of available pixels

We thus obtain, compared to a conventional system (in which a pixel is formed by 3 LEDs which are permanently assigned to it, and therefore in which we obtain as many pixels as there are LEDs of a given color) possibility to create 6 times more pixels for the same number of LEDs We therefore increase the pixel density without increasing the number of LEDs

It is thus easily understood that, by comparison with a conventional system, such a system makes it possible to considerably improve the quality of the broadcast image (resolution and filling of the image) for a very low additional manufacturing cost. Also, it is also easy to imagine that such a system makes it possible, at equivalent image quality, to obtain very reduced manufacturing costs.

Claims

1) Device for producing LED screens or display panels intended for broadcasting fixed or animated images, characterized in that it is equipped with LEDs whose characteristics make it possible to constitute a pixel with only three LEDs (one red + one green + one blue) and that it has a particular arrangement of LEDs allowing each of them to be close to six pairs of LEDs of complementary colors making it possible to form around each LED of a given color, six three-color trios 2) Device according to claim 1 characterized in that on the same line of LEDs, the LEDs are arranged in a precise order (red, green, blue, red, green, blue etc. for example, or red, blue, green red, blue green, etc), and two consecutive LED lines are arranged so that each LED is located exactly below the middle of the mterval which separates the two LEDs of complementary colors from the top line, and each line is arranged with respect to the previous line so that the vertical distance between the horizontal axes of two consecutive lines is equal to the horizontal distance between the centers of two neighboring LEDs located on the same line multiplied by the square root of three , a value very close to 0 866 3) Device according to claim 1 or claim 2 characterized in that the electronic control system is designed to control successively (in a pre-established order) or simultaneously certain pixels or all the pixels 4) Device according to any one of the preceding claims, characterized in that different configurations of the control system are possible, each generating different characteristics of 1 image obtained (resolution and luminance) 5) Device according to 1 any one of the preceding claims characterized in that in certain configurations of the control system the same LED which can mtevenir in the constitution of several pixels adjacent commands will controlled so that it displays an intensity equal to the average of the values controlled by each of these pixels. 6) Device according to any one of the preceding claims, characterized in that in certain configurations of the control system, coherent inter-pixels, which participate in the quality of the resolution of the image, are created automatically. 7) Device according to any one of the preceding claims, characterized in that the system makes it possible, according to certain particular configuration of the electronic control system, to use only part of the series of pixels available. AMENDED CLAIMS [received by the International Bureau on July 28, 2000 (07/28.00); claims 1, 2 and 3 replaced by new claim 1 other claims unchanged (1 page)] CLAIMS: 1) Device for producing LED screens or display panels intended for broadcasting fixed or animated images, characterized in that it is equipped with LEDs whose characteristics make it possible to constitute a pixel with only three LEDs (one red + one green + one blue), that it includes a particular arrangement of LEDs allowing each of them to be close to six pairs of LEDs of complementary colors making it possible to form around each LED of a given color, six tri-color trios, and that the electronic control system is designed to control successively (in a pre-established order) or simultaneously certain pixels or all the pixels. 2) Device according to claim 1 characterized in that different configurations of the control system are possible, each generating different characteristics of the image obtained (resolution and luminance). 3) Device according to any one of the preceding claims, characterized in that in certain configurations of the control system, the same LED which can intervene in the constitution of several contiguous controlled pixels, will be controlled so that it displays an equal intensity the average of the values controlled by each of these pixels. 4) Device according to any one of the preceding claims, characterized in that in certain configurations of the control system, coherent inter-pixels, which participate in the quality of the resolution of the image, are created automatically. 5) Device according to any one of the preceding claims, characterized in that the system makes it possible, according to certain particular configuration of the electronic control system, to use only part of the series of pixels available.