EP1830337A1 - Method for forming a movable matrix image and device for a light-emitting-diode running letters - Google Patents

Abstract

The invention relates to display technology and may be used for the display of color, alphanumeric and graphical information for designing and developing various information presentation means on interior and exterior objects. The invention makes it possible to improve the quality of the displayed data, to increase the reliability of the function and to reduce the cost of the device due to the possibility of adjusting the resolution within the columns of the displayed video field image, the optimal arrangement of light emitting diodes within the pixel of the luminous circuit and the general purpose Reduction in the number of light emitting diodes to achieve. The elements of the scrolling device consist of two adjacent pixels having a common light-emitting diode, and the arrangement of these diodes in one pixel makes it possible to adjust the image resolution.

Description

The invention relates to display technology and can be used in the development of visual display device technology for advertising and other informational messages to indoor and outdoor installations. It can be implemented as a light-emitting diode device for color rendering alphanumeric and graphic information as well as moving images with a range of color shades.

A method of generating a dot matrix image and a display device using the so-called "residual image" effect are known. This effect occurs in the human eye during rapid adjustments of the display device, which is manufactured using LED technology (see information source [1], back).

The disadvantage of this known method for generating a dot matrix image and the display device is that this method does not allow to develop a device for displaying, for example, an information ticker.

There are known a method for generating a movable dot matrix image and a display device implemented by means of display bars. These indicator bars consist of light emitting diodes, which bring about the aforementioned "residual image" effect in the presentation of information [2].

Among the disadvantages of this known method for generating a movable dot matrix image and the display device is that the same method also generates further line elements and a series of the moving image by means of black-and-white (non-color) light-emitting diodes in the display device; therefore the information is presented monotonously.

The closest approach to the purpose of generating a movable dot matrix image in a display device is as follows. The display device consists of n display bars. The indicator bars contain pixels and are arranged in parallel. The distance between the display bars is at least as large as the width of a display bar. According to this method, a movable dot matrix image is generated by the display bars. Each element of the image line in the display bar is generated by means of a pixel of three light-emitting diodes, namely red, blue and green. These LEDs are arranged sequentially along the width of the display bar. Each element of the image series is generated by means of the adjacent pixels which are arranged along the length of the display bar [3].

The drawback of this prototype selected method for generating the moving dot matrix image is that this method produces the row and row elements in the moving dot matrix image by means of color pixels that are not optimized with respect to the light emitting diode array. However, this fact prevents increasing the resolution of the data presented and hence the quality of the moving dot matrix image.

The device closest to the invention according to its intended purpose is also one which consists of n display bars arranged parallel to one another. These indicator bars share a common power supply. The columns of the movable dot matrix image with the "residual image" effect within the video field of the displayed information are formed by means of display bars. Each indicator bar contains line illuminators. Each cluster is executed using color pixels. The color pixels consist of light emitting diodes of the red, blue and green luminous colors and are arranged linearly along the row of rows. The pixel length coincides with the width of the luminous column of the indicator bar [3].

The disadvantage of this known as a prototype device for displaying alphanumeric and graphical data is that the display bars in this device contain color display elements that consist of one pixel of three color LEDs. The light-emitting diodes are arranged in series along the line of the displayed image. The elements that make up the columns of the video field image are not optimized by design. This does not allow to increase the resolution of the displayed data and thus also the quality of the video field of the displayed image.

The disadvantage of this known as a prototype device for displaying alphanumeric and graphical data is that the display bars in this device contain color display elements that consist of one pixel of three color LEDs. The light-emitting diodes are arranged in series along the line of the displayed image. The elements that make up the columns of the image of the video field are not optimized by design. This does not make it possible to increase the resolution of the displayed data and thus also the quality of the displayed image of the video field in the display device.

The essence of the invention consists in the following: The invention solves the tasks associated with the development of a method for generating the movable Dot matrix image and the device of the light-emitting diode display for displaying alphanumeric and graphic data. The device consists of n parallel display bars that shape the columns of the image.

In the practice of the invention, the following uniform technical result can be achieved: an improvement in the quality of the displayed data, an increase in functional reliability, and a cost reduction of the device thanks to the ability to adjust the resolution within the columns of the displayed video field image; LEDs within the pixel of the Leuchtkluster and the general reduction in the number of LEDs.

The specified technical result is achieved as follows. The known method for generating a movable dot matrix image requires the use of a display device. The display device consists of n display bars which contain a plurality of pixels and are arranged parallel to one another. The distance between the display bars is at least as large as the width of a display bar. The method is to create a moving dot matrix image through these display bars with a "residual image" effect. In this display bar, the line item of the image is generated by means of a pixel. The pixel consists of three LEDs, red, blue and green, which are serially arranged along the width of the indicator bar. The element of the image row is generated by adjacent pixels which are arranged along the length of the display bar. The display bars of the image row serve to generate the movable dot matrix image. Therein, the line element of the image is generated by means of two adjacent pixels. In these pixels, the LEDs are arranged one below the other in the form of triangles. At the corner of the minor angle of these triangles, a common LED is arranged with one of the three luminous colors. The triangles form secondary pixels along the lines. The sides of the triangles run parallel to the width of the indicator bar of the image rows. In the corners of these pages LEDs are arranged with the same color. The triangles, their sides with the length of the indicator bar of the image row run parallel, have in the angles formed by these pages light emitting diodes with different luminous colors and subpixels along the lines or along the image row. The distance between the display bars of the image rows is set to be divisible by the total length of the adjacent pixels along the row element. Within the line element of the image, the neighboring pixels are in the shape of an equilateral triangle. Within two adjacent pixels, a common light emitting diode with blue light color is installed. Within two adjacent pixels, a common green LED light emitting diode will be installed. Within two adjacent pixels a common light emitting diode with red light color is installed. The generation of the movable dot matrix image by the display bars of each individual line element, which is formed by two adjacent pixels with a common light-emitting diode, makes it possible to reduce the number of light-emitting diodes in the display bar of the image row.

The arrangement of the light emitting diodes within the pixels, forming triangles, and provided that a common light emitting diode is incorporated at the vertex of the fog angles of those triangles, allows the adjacent pixels having different configurations of the light emitting diode array within the pixel with respect to rows and rows form. This allows the display bars to generate a moving dot matrix image and also ensures the possibility of tracking the resolution of the displayed data. The possibility of incorporating a common light-emitting diode with different fluorescent colors on the neighboring pixels of a display element allows it to be very different

To display information.

• die Pixel durch den gemeinsamen Eckpunkt benachbart sind,
• in diesem Eckpunkt die gemeinsame Leuchtdiode eingebaut ist,
• und bei der Anordnung der Leuchtdioden mit unterschiedlichen Leuchtfarben in den Winkeln der Dreieckseiten, die der Länge des Anzeigebalkens parallel verlaufen,

ermöglicht es, die Auflösung des dargestellten Bilds des Videofelds nachzustellen und den Abstand zwischen den Anzeigebalken zu optimieren, um die erforderliche Stufe der Leuchtdichte zu erreichen. Dadurch wird die Detaillierung des Bilds verbessert und die Möglichkeit der Glättung der Farbabtönungen des Bilds eröffnet.The stated technical result is achieved in the practice of the invention in connection with its object, the light-emitting diode device for displaying alphanumeric and graphic data according to a first embodiment, as follows. The Leuchtdiodenlaufschrift the known device for displaying alphanumeric and graphical data consists of n parallel to each other arranged display bar with a common power supply. The columns of the moving dot matrix image with the "residual image" effect within the video field of the displayed information are formed by the display bars. Each indicator bar contains lines of light illuminators. Each cluster is executed as a color pixel. Each pixel consists of light emitting diodes with red, green and blue light colors. The light-emitting diodes are arranged linearly along the image row line. The length of the pixel coincides with the width of the luminous column of the indicator bar. In the display bar each luminous line of the line is geometrically designed as a rectangle. The length of the diagonal of this rectangle is twice the length of the shortest side of the rectangle that runs parallel to the length of the column's column. The intersection of the diagonals within the rectangle forms equilateral, adjacent triangles. At the angles of these triangles, color LEDs are arranged. The light-emitting diodes serve to form two neighboring pixels of the lighthouse of the image line. In this case, a common light-emitting diode with one of the three luminous colors is installed at the neighboring angles of the triangles of the color pixels. The width of the lighthouse coincides with the shortest sides of the rectangle. The Leuchtkluster are arranged along the display bar. The Klusterabstand corresponds to the width of the Leuchtklusters. The display bar parallel sides of the rectangle of the light-emitting diode contain light emitting diodes with red and green light color. The common LED of the neighboring pixels has a blue luminous color. The display bar parallel sides of the rectangle of the light-emitting diode contain light emitting diodes with blue and green light color. The common LED of the neighboring pixels has a red light color. The display bar parallel sides of the rectangle of the light-emitting diode contain light emitting diodes with red and blue luminescent color. The common LED of the neighboring pixels has a green light color. The distance between the display bars of the image columns is divisible by the width of the luminous bar of the display bar. The row luminous slits of the display bar of the column are in the form of a square. In the center of this square, a light-emitting diode with one of the luminous colors, red, green or blue, is arranged. At the corners of the square light emitting diodes are installed with other luminous colors. In the display bar of the device of the light-emitting diode according to the invention, the luminous clusters are formed as neighboring pixels of light-emitting diodes with different luminous colors. The arrangement of light emitting diodes within the Pixels in the form of an equilateral triangle, where

• the pixels are adjacent by the common vertex,
• in this corner, the common LED is installed,
• and in the arrangement of the light emitting diodes with different luminous colors in the angles of the triangle sides, which run parallel to the length of the display bar,

allows to adjust the resolution of the displayed image of the video field and to optimize the distance between the display bars to achieve the required level of luminance. This improves the detailing of the image and opens the possibility of smoothing the color tones of the image.

wobei
R der Abstand zwischen den Anzeigebalken und;
L die Länge des Leuchtklusters ist.The stated technical result is achieved in the practice of the invention in connection with its subject matter, the light-emitting diode device for displaying alphanumeric and graphic data according to a second embodiment, as follows. The Leuchtdiodenlaufschrift the known device for displaying alphanumeric and graphical data consists of n parallel to each other arranged display bar with a common power supply. The columns of the movable dot matrix image with the "residual image" effect within the video field of the displayed information are formed by the display bars. Each indicator bar contains luminous clusters. The clusters are executed as color pixels. Each pixel consists of light emitting diodes with red, green and blue light colors. The light-emitting diodes are arranged linearly along the image row line. The length of the pixel coincides with the width of the luminous column of the indicator bar. The distance between the display bars of the columns within the video field of the displayed information is determined by the following ratio: $$R=\left(5-15\right){\mathrm{<figure-callout\; id="1"\; label="L"\; filenames="imgf0003.png"\; state="\{\{state\}\}">L</figure-callout>}}_1$$

in which
R is the distance between the display bars and;
L is the length of the lighthouse.

wobei

S

die Länge des Anzeigebalkens der Spalte,

L

die Länge des Leuchtklusters und

m

die Anzahl der Leuchtkluster im Anzeigebalken der Spalte des Videofelds ist.

The length of the indicator bar of the column is selected by the following ratio: $$S=L\times m.$$

in which

S

the length of the indicator bar of the column,

L

the length of the lighthouse and

m

the number of luminous cycles in the display bar is the column of the video field.

wobei

Lp

die Breite des Anzeigebalkens und

L

die Länge des Leuchtklusters ist.

The width of the indicator bar is determined by the following ratio: $$L\mathrm{p}=\left(2-4\right)<figure-callout\; id="1"\; label="\; L"\; filenames="imgf0003.png"\; state="\{\{state\}\}">\; </figure-callout>L_{}{}_1$$

in which

Lp

the width of the indicator bar and

L

the length of the lighthouse is.

The video field of the displayed data is made up of 72 display bars. The display bars are grouped in groups of 9 display bars each. The display bars of the columns of each group are connected to a separate power supply. To ensure the input of incoming data signals, the indicator bars are connected in series with each other in the direction of image scanning in the video field. In this case, the input of the signals of the indicator bar of the first column at the beginning of the image scan is connected to the output of a control unit. The input of the control unit is connected to a flash memory card.

The proposed choice of the spacing between the display bars taking into account the length of the color display element allows to ensure the required brightness of the video field. The chosen display bar length taking into account the width of the color element of the display bar ensures optimum resolution of the displayed image and dimensions necessary for viewing the video display displayed data is required by the viewer at any distance. In addition, the display device is designed with a reduced number of elements, whereby the device costs are reduced. Combining the indicator bars in a group with a separate power supply reduces the amplitude size of the current steps within the supply lines of the light emitting diodes of the device. This reduces the probability of disturbing tendencies in the control circuits of the LEDs and increases the functional and control reliability of the device for the light-emitting diode drive.

In order to check the conformity of the invention with the requirements of the invention, a follow-up search was made with respect to known solutions. The objective of this follow-up research was to determine the features that coincide with the characteristic features of the present invention in terms of the chosen prototype. The results of the research show that each variant of the invention for a person skilled in the art is not obvious from the known state of the art, because no technical solutions have been found in which the light-emitting diode device with the "residual image" effect by means of display bars with color representation elements were realized. The display bars are formed of two neighboring pixels with a common light-emitting diode with one of the three fluorescent colors. The light-emitting diodes of the pixels are arranged in the form of an equilateral triangle. This allows the pixels to adjust the resolution depending on the type of data displayed and to increase the luminance.

Fig. 1

ein Pixel eines Darstellungselements eines Anzeigebalkens in der Spalte eines Prototyp-Bilds,

Fig. 2

das Darstellungselement des Anzeigebalkens in Form eines Klusters in der vorgeschlagenen Leuchtdiodenlaufschrift-Vorrichtung zur Darstellung von alphanumerischen und grafischen Daten, wobei das Videofeld des Bilds durch die Anzeigebalken der Spalten mit unterschiedlichen Ausführungsgeometrien der Leuchtkluster ausgebildet wird und die Leuchtdioden-Pixel darin unterschiedlich angeordnet sein können, und

Fig. 3

ein Strukturdiagramm der Vorrichtung der Leuchtdiodenlaufschrift zur Darstellung von alphanumerischen und grafischen Daten, wobei die Anzeigebalken stromversorgungsmäßig in Gruppen vereinigt sind.

The proposed light-emitting diode diagramm for the representation of alphanumeric and graphic data will be explained in more detail on the basis of exemplary embodiments and the following figures. Show it:

Fig. 1

a pixel of a display element of a display bar in the column of a prototype image,

Fig. 2

the display element of the display bar in the form of a cluster in the proposed light-emitting diode device for displaying alphanumeric and graphic data, the video field of the image being formed by the display bars of the columns having different design geometries of the luminous clusters and the light-emitting diode pixels being arranged differently therein, and

Fig. 3

a structural diagram of the device of the light-emitting diode display for displaying alphanumeric and graphical data, the display bars are power supply grouped in groups.

The generation of a moving image with the "residual image" effect is realized in the prototype on the basis of the display device with a limited video field of the image 1 (FIG. 1). It consists of n display bars of the image columns 2 ₁ , 2 ₂ and 2 _n . Each indicator bar of the image column 2 having a length S contains color representation elements of the lines 3 with a length L, each pixel consisting of three color LEDs, red - R, green - G and blue - B arranged horizontally along the line.

The display bars of the image column 2 in the display device of the video panel 1 are arranged in parallel. The distance R therebetween is at least as long as the length L of the luminous character of the line 3 of the display bar of the image column 2.

FIG. 2a shows the video field of the image with limits 1 of the proposed light-emitting diode script for displaying alphanumeric and graphic data. The video field is formed from n display bars of columns 2. The distance R between the display bars is selected so that this size is divisible by the length L of the luminescent code of the line 3 from the ratio RIL = 1,2,3, ... m. The maximum value m is determined by the level of required brightness of the entire image field.

Fig. 2b shows a luminous switch 3. This cluster has the shape of a rectangle in which the length of each diagonal is equal to the length of the shortest side. By overlapping the diagonals within the rectangle, equilateral triangles are formed. At the angles of these triangles color light emitting diodes B, G, R are arranged. These are the equilateral triangle RBG clockwise and the equilateral triangle BRG. These equilateral triangles form two neighboring pixels 4 and 5 with a common light-emitting diode B. This luminaire allows the resolution of the image within columns horizontally and change vertically.

FIGS. 2c, 2d, 2e and 2f show examples of the luminous circuit 3 of the display bars 2 with different arrangement variants in the neighboring pixels of the color light-emitting diodes. In Fig. 2g is executed in the form of a square Leuchtkluster shown.

FIG. 3 shows a construction diagram of the light-emitting diode drive for displaying alphanumeric data.

The operation of the LED trace for displaying alphanumeric and graphic data is based on the method of generating the movable dot matrix image with "residual image" effect. This effect is determined by the particularity of the human eye to keep the image and superimpose the retained image on the currently displayed image. The human eye tracks the image, superimposing the current image on the previous one, and ultimately, the illusion of a connected image is achieved, although in reality it consists of a certain number of individual fragments. The fragment is composed of row and row elements. These row and row elements are formed by data strings. FIG. 2a shows the imaginary element of the line 6 between the display bars of the image rows 2.

The device according to the invention is realized in the product "LED Diagram" for the color representation of alphanumeric and graphic data in the "INCOTEX display system" LOR CLO-1024x54-16-00. The structure diagram is shown in Fig. 3, wherein each indicator bar (Fig. 2) has a length L of 16 mm of the luminous key, a width of the indicator bar of 3.54 mm in accordance with the ratio Lp = (2-4) L and a Length S of 1024 mm calculated in accordance with the ratio S = L x m = 16 x 64 = 1024 mm, where 64 is the number of luminous clusters.

From the construction scheme of the light-emitting diode display for the representation of alphanumeric Data (Figure 3) shows that it consists of 72 indicator bars 2 of the image columns forming the video field. The display bars are grouped into 8 groups. Each group contains 9 indicator bars of type CLO-1024-54-16. Each group of indicator bars is connected to a power supply Sv (1 to 8). The distance R between the display bars of the columns and between the display bar groups has been selected to be 176 mm and corresponds to the ratio R = (5-15) L. The ratio 11 corresponds to the selected distance R = 176 mm. The display bars after the input of the data signal are connected in series from right to left (Figure 3). In the first display bar St1, the input of the data signal is connected to the signal output of the control unit, which is connected to the flash memory card. The information transmission rate over the video field is about 5m / s.

Thus, the present invention reduces the number of light-emitting diodes, thereby generally reducing the cost of the overall information display device while allowing a high-quality moving picture to be produced with a color gamut of 64 to 4096 color shades.

REFERENCES

1. 1. US Patent 5670971 , Kl. G09G, 3/20 dated 23.09.1997
2. Second US Patent 6069595 , Kl. G09G, 3/06 dated 30.05.2000
3. Third US Patent 6072446 , Kl. G09G, 3/20 of 06.06.2000

Claims (13)

A method for generating a moving dot matrix image in a display device consisting of pixel-containing, n display bars of image rows in which the display bars are arranged in parallel at a distance at least as large as the bar width and further in the minimum width of the display bar of the image row coincides with the pixel length, and the method of generating the movable dot matrix image with the "residual image" effect by display bars of the image rows, wherein the line item of the image is generated within the display bars by means of a pixel consisting of three series along the width of the display bar consists of the image row arranged color light emitting diodes, and the image row is generated by the Bildreihenpixel,
characterized,
in that the display bars of the image row form a movable dot matrix image in which the line element of the image is generated by two adjacent pixels, in these neighboring pixels the light emitting diodes are arranged one below the other in the form of triangles, and at the vertex of the minor angles of these triangles a common light emitting diode with one of the three luminous colors is arranged, wherein the triangles whose sides are parallel to the width of the display bar of the image row and in the corners of which LEDs are arranged with the same luminous color, have neighboring pixels along the lines and the sides of the triangles with the length of the display bar of the image series run, arranged in the angles of the sides of the triangle light-emitting diodes with different luminous colors, these LEDs generate adjacent pixels along the lines or the image rows and the distance between the display bar of the image rows is set so that it is determined by the total length of the adjacent rten pixels along the line element is divisible. Method according to claim 1,
characterized,
that the neighboring pixels within the line element of the image are the geometry an equilateral triangle. Method according to claim 1 or 2,
characterized,
that a common light-emitting diode with blue luminous color is installed within two adjacent pixels. Method according to claim 1 or 2,
characterized,
in that within two adjacent pixels a common light emitting diode with green light color is installed. Method according to claim 1 or 2,
characterized,
that a common LED with red light color is installed within two adjacent pixels. A light-emitting diode device for displaying alphanumeric and graphic data consisting of n display bars arranged parallel to each other and provided with a common power supply within the video field of the displayed information, wherein the columns of the mobile dot matrix image with the "residual image" effect formed by the display bars each display bar has line luminescent, each cluster is designed as a color pixel consisting of light emitting diodes each having red, green and blue luminescent color, the LEDs are arranged linearly along the image row line and the length of the pixel coincides with the width of the luminous column of the indicator bar
characterized,
that each luminous line of the line in the display bar is geometrically designed as a rectangle, that the length of the diagonal of this rectangle is twice as long as the length of the shortest side of the rectangle which is parallel to the length of the column, that is due to the overlap the diagonal within the rectangle are formed equilateral triangles adjacent to each other, that at the angles of these triangles color LEDs are arranged, which form two neighboring pixels of the luminous line of the line,
wherein at the neighboring angles of the triangles of the color pixels, a common light-emitting diode with one of the three luminous colors is installed, that the width of the luminaire coincides with the shortest sides of the rectangle, that the luminous clusters are arranged along the display bar and that the cluster distance corresponds to the width of the luminous clasp. Light-emitting diode device according to claim 6,
characterized,
in that the sides of the rectangle of the light-emitting device which run parallel to the length of the display bar contain light-emitting diodes with red and green luminous color, and the common light-emitting diode of the neighboring pixels has a blue luminous color. Light-emitting diode device according to claim 6,
characterized,
in that the sides of the rectangle of the light-emitting device parallel to the length of the display bar contain light-emitting diodes with blue and green luminescent color, and the common light-emitting diode of the neighboring pixels has a red luminescent color. Light-emitting diode device according to claim 6,
characterized,
in that the sides of the rectangle of the light-emitting device which run parallel to the length of the display bar contain light-emitting diodes with red and blue light color, and the common light-emitting diode of the neighboring pixels has a green light color. Light-emitting diode device according to claim 6,
characterized,
in that the distance between the display bars of the image columns is divisible by the width of the luminous bar of the display bar. Light-emitting diode device according to claim 6,
characterized,
in that the line lighthouses of the indicator bar of the column are in the form of a square, in the center of which a light-emitting diode with one of the luminous colors, red, green or blue, is arranged, and in that the light-emitting diodes with other luminous colors are installed at the angles of the square. A light-emitting diode device for displaying alphanumeric and graphic data consisting of n display bars arranged in parallel and provided with a common power supply within the video field of the displayed information, in which the columns of the moving dot matrix image with the "residual image" effect through the display bars each cluster is constructed as a color pixel consisting of light emitting diodes each having red, green and blue luminous color, the LEDs are arranged linearly along the image row line and the length of the pixel coincides with the width of the luminous column of the indicator bar;
characterized,
in that the distance between the display bars of the columns within the video field of the displayed information is determined by the ratio R = (5-15) L, where
R is the distance between the display bars and
L is the length of the lighter,
wherein the length of the display bar of the column is selected according to the ratio S = L xm, wherein
S is the length of the indicator bar of the column,
L is the length of the lighthouse and
m is the number of luminous keys in the display bar of the column of the video field, and the width of the indicator bar is set by the ratio Lp = (2-4) L is, where
Lp the width of the indicator bar and
L is the length of the lighthouse. Light-emitting diode device according to claim 12,
characterized,
in that the video field of the displayed data is formed of 72 display bars united in groups of 9 display bars each, that the display bars of the columns of each group are connected to a separate power supply, the display bars serially toward each other in order to ensure the input of the incoming data signals the image scan are connected in the video field, wherein the input of the signals of the display bar of the first column at the beginning of the image scan is connected to the output of the control unit, and that the input of the control unit is connected to a flash memory card.

Images