DE3837313A1 - Point matrix LED indicator unit for large display - has CPU with software programmed for cyclic scanning through N-rows - Google Patents

Abstract

The dot matrix LED indication plate contains mxn LED points, each contg. at least one monochromatic LED chip. An associated control circuit has an input connected to a computer. A data shift circuit corresponds to the in columns of the matrix and a data scanning drive circuit corresponds to the n rows. A CPU contains software programmed for cyclic scanning through the n rows. The cooresp. information is transferred from the computer to the LED points via the data shift circuit. The control circuit contains an output connection and an address device in which an identification code is stored. The output connection can be structurally connected to the input connection and is connected to the lines between the input and CPU. The identification code coincides with a specific computer memory address, software of which causes data display when the data are transferred with an address signal coinciding with the code. ADVANTAGE - Size of large display can be increased or reduced at will without requiring new circuit design.

Description

The invention relates to a dot matrix LED on display unit, more specifically on a multicolor dot matrix LED display unit, arbitrarily in any number to a large dot matrix LED display device each desired size can be combined. It is about thereby for the partial continuation registration of the US application with the serial no. 07/1 09 517.

LED displays are widely used these days det. Any type of colored image can be used a number of LED points in an LED point matrix  be fathered. One LED spot can have three LED chips for under different monochromatic light, especially red, Green and blue included. Because through these three primary chro all types of light can be generated it is possible to use any such LED points Color by mixing different proportions of the three pri generate chromatic types of light.

(Note: At present only red and green LED chips can be manufactured cheaply, while the blue LED chip is still very expensive to manufacture. For economic reasons, most of the commercially used LED displays are therefore only available with red and equipped with green LED chips and not with blue. With the red and green LED chips many so-called "warm colors" such as yellow, orange, yellow-green and a number of intermediate colors can be generated. The so-called "cold colors" such as magenta, cyan, violet or indigo, however, cannot be made without the blue component, Figure 9 shows an LED dot ( D ) with a red (R) and a green (G) LED chip.) are present Large colored, dynamic, dot matrix LED displays are available which produce a template stored in a computer in accordance with the template dynamically displayed on the monitor of the computer. (The phrase "dynamic" means that the representation on the display changes over time, like the pictures on a television screen. It therefore has the opposite meaning of the term "static", which means a picture on a display that is different does not change depending on the time, as applies, for example, to a photograph). Fig. 11 shows a large dynamic dot matrix LED display device ( L ) with a series of dot matrix LED display fields. (For reasons of clarity, only nine fields ( P 11 ) to ( P 33 ) are shown in the illustrated example. In actual use, the number of fields arranged in a large LED display device is generally significantly greater than nine. In fact If the resolution of nine fields (only 24 × 24 = 576 dots) is not removed, it is capable of depicting the displayed character "Bugs Bunny".)

The fields are standardized dot matrix LED display elements. Each field contains 8 × 8 = 64 LED points ( D ). Each dot can contain two (red and green, as shown in FIG. 9) or three (red, green and blue) LED chips. The generation of the image on the large LED display device ( L ) is achieved by cyclically scanning all LED points in the large LED display device from top to bottom. The scanning of the large LED display device differs from the scanning of the TV screen mes in that in the first case rows are scanned point by point in the second case. Since scanning is a well-known technique, its detailed explanation is unnecessary.

Since the computer signals ( C ) are not suitable for transmission over a relatively long distance from the computer ( C ) to the large LED display device ( L ), an interface ( I ) must be interposed which converts the computer signals into a form which is suitable for transmission in a relatively long line. The "template" in the computer is analyzed as a "halftone" map created by a number (in the example 24x24 = 576) dots. The color (colourfulness) and the brightness (luminance) of each point correspond to the values of the corresponding point on the template and depend on the brightness of the LED chips (R) (G) . The brightness of an LED chip can be divided from very dark to very bright in, for example, eight classes, namely O, L , M , N , P , Q , R and S. The brightness of a chip depends on its power supply. As the power supply increases, the brightness of the chip will increase. If the brightness of the red LED chip ( R ) corresponds to an LED point of the M class and the brightness of its green LED chip ( G ) corresponds to the P class at a certain moment, the result is a color brightness of the MP Be great. With the distinction into eight brightness levels, 8 × 8 = 64 different classes of color brightness can be defined. (Note: In this case the term "color brightness" must be used instead of "color" to describe the 64 different classes, since it cannot be said that there are 64 different colors. Because the corresponding color tint of the chromatic light Based solely on the ratios of the primary monochromatic light types, the same color (yellow) occurs in the LL class and the RR class, but with different brightness.) The color brightness of the LED points is determined by Color brightness signals (data) controlled, which are passed to the corresponding points via a data shift circuit (DS) . The scanning of the rows is controlled by row scanning signals which activate the corresponding row via a scan drive circuit (SC) . The row scan signals sequentially activate the 24 rows of LED dots on the large LED display from the top row ( R 1 ) to the bottom row ( R 24 ), and then repeat the process. If a certain row (eg the first row of dots of the LED board ( P 21 ), ( P 22 ), ( P 23 ), ie the 9th row ( R 9 ) of the large LED display device ( L )) is activated, the data of the corresponding LED points in this row (ie the color brightness signals of these points) are transmitted to the 24 LED points of this row ( R 9 ). The control of the scanning and the transmission of data is carried out via the software of a central processing unit (CPU). The output of the CPU is connected via a buffer ( B 1 ) to the data shift circuit ( DS) and to a random access memory (RAM), the output of which is connected to a scanning drive circuit (SC) via a further buffer ( B 2 ) . The components represented in the area defined by the broken line (ie the CPU, RAM, data shift circuit ( DS) , scan drive circuit (SC) and buffers ( B 1 ) (B 2 )) form the control circuit (CC ) the large LED display device and can be arranged on a single circuit board. The power supply to the control circuit is carried out via a current stabilizer ( S ). All of the above elements are known in the computer industry, making their detailed description unnecessary.

The software in the CPU must be programmed so that the 24 rows of points sequentially in a specific period be scanned and that if a row of dots from the Scanning drive circuit is sampled, which correspond  the data (i.e. the color-brightness signals) of the LED dots this row to the corresponding LED points will.

Despite the fact that such a large LED display device tion is increasingly used in wide areas, it has a number of disadvantages. The first night part is that their size cannot be changed.

Since the large LED display device is scanned with a defined number of rows and columns of dots, it cannot be enlarged or reduced by adding or removing certain dot matrix LED display panels without the hardware and software of the control circuit (CC) must be changed. For example, increase the scale of the large LED display ( L ) to a 32 × 32 = 1024 dot matrix panel (ie with 4 × 4 = 16 fields) or its scale to a 16 × 16 = 252 dot matrix panel (ie with 2 × 2 = 4 fields), the resulting new large LED display device becomes compatible with the original control circuit (CC) . The reason for this is simple. A television receiver of the NTSC system cannot be used to cover the program of a television station with a SECAM system, since the number of columns and rows (scanning standard) of the two systems is different. Accordingly, it is also impossible to use a control circuit (CC) specially designed for a 24 × 24 dot matrix to control a large LED display device with a 32 × 32 or 16 × 16 dot matrix. For this reason, if the scale of the large LED display device ( L ) is to be extended to 32 × 32 dots, the buffers ( B 1 ), ( B 2 ), the data shift circuit ( DS) and the scan drive circuit ( SC) must be changed to correspond to the dots arranged in 32 rows and 32 columns in the enlarged LED display, and the software in the CPU must be reprogrammed so that a scan cycle now spans 32 rows instead of 24. Furthermore, the circuit board, which carries the elements ( B 1 ), ( B 2 ), (DS), (SC) , RAM and CPU must be redesigned. This makes it impossible to economically change the size of the large LED display device ( L ).

For this reason, the large LED display device is missing with regard to their size and specification Flexibility. If a certain size is small number is produced, the unit price becomes very high. Therefore are large LED display devices only in the market few specific standard sizes available.  

In addition to the impossibility of resizing them, another disadvantage of the conventional dynamic dot matrix LED displays is that they need the LED display panels to match to the greatest extent and that it is impossible to match the color brightness of a specific one Zone (or a specific LED display panel) to change in a large LED display device ( L ). For the manufacturers in the LED industry there is a technical difficulty, which has not yet been solved even today, in that the quality of an LED display panel cannot be controlled in such a way that its color brightness is accurate to a defined value (or in a very high degree area) is set during the manufacture of the LED display panel. Therefore, the color brightness of the dots of an LED display panel ( P 11 ) can differ from that of another LED display panel ( P 12 ) (lighter or darker than the last one, or red or greener than the last one), even if both LED display fields are supplied with the same voltage and the same current. The uneven color brightness of the LED display fields can cause unsightly optical effects on the LED display. For example, if the color brightness of the dots in field ( P 11 ) is darker and red than that on field ( P 13 ), the right ear of the Bugs Bunny rabbit will appear darker and red for no reason than its left ear. As stated above, it is impossible to control the resulting quality of an LED display panel during its production; therefore you cannot definitely make an LED display panel whose color brightness meets our requirements. Only one LED display field can be selected from a number of finished LED display fields in order to obtain the desired color brightness. The manufacturers of LED display panels generally divide their products into different grades (e.g. ten) according to their color brightness when energized with a standardized voltage. Large LED display manufacturers (who purchase the panels) must select panels of the same grade (e.g., grade 5) to build a large LED display device. Since all fields must strictly correspond to the same degree, it can happen that the manufacturers of the large LED displays become unwelcome customers of the field manufacturers, since the first buy only a specific degree of the products of the latter. The field manufacturers must therefore increase the price for the specific type of product, which is relatively low in the warehouse. Furthermore, the manufacturers of the large LED display devices often have to reckon with a shortage of the desired specific field degrees.

Furthermore, even if all fields ( P 11 ) to ( P 33 ) were strictly selected so that they have the same degree of color brightness, the entire area of the resulting large LED display still cannot have a uniform, uniform color brightness if energized with same tension, which is due to some unpredictable factors. For example, the field ( P 11 ) can be slightly darker than the field ( P 13 ) if both are mounted in a large LED display device, even if they were originally classified in the same color brightness class. In this case, it is necessary to set the brightness of the individual fields. However, the separate setting of individual fields is impossible since the entire large LED display device (all fields) is scanned as a whole. Therefore, only the color brightness of the entire large LED display device ( L ) can be adjusted. In other words, only all nine fields ( P 11 ) to ( P 33 ) can be changed together in terms of their color brightness at the same time, since the entire large LED display ( L ) is scanned as a whole.

Accordingly, there is a very strong interest in egg ner large LED display device that arbitrarily on egg ne size can be enlarged or reduced can, without redesigning the switching arrangement  is necessary. It is also desirable that the color brightness of the different parts in one large LED display device can be set separately can, so the fields are not all the same degree of color must have brightness and that the local unequal color brightness in the large LED display device in a certain area by a locally limited Setting can be compensated.

In order to solve this problem, the conventional large LED display device must be renewed in principle. It is the principle that all points of the LED display fields ( P 11 ) to ( P 33 ) are scanned as a whole, which leads to the flexibility of the large LED display device in relation to its size. Furthermore, the principle that the whole large LED display device ( L ) is driven by a single control circuit (CC) is responsible for the fact that the local adjustment in terms of color and brightness is impossible. Therefore, the principles of the conventional large dynamic dot matrix LED display device must be abandoned.

According to the invention, a large LED display device is formed by combining a number of the same units. Each unit can contain N standard 8 x 8 LED dot matrix fields, where N is a small positive integer. The number N is preferably chosen neither too large nor too small (the reason for this will be explained later). For example, N = 8 if a unit contains 2 × 4 = 8 fields and the resulting unit is a 16 × 32 = 512 dot matrix. The essence of the invention is that each unit has its own control circuit with an input and an output terminal. Two units can be connected in series (ie the output of one unit is connected to the input of the other unit or can be connected in parallel (ie the input connections of both units are connected to each other. This way, any number of units can be connected to each other to form a large LED display device of desired size. Each unit is scanned as a whole (in other words, with a unit of 16 × 32 dots, the 16 rows are sequentially moved from the top row (first) to the bottom row Row (16th row) is scanned and then the scanning process is started again from the first row.) Since all units in the large LED display device are separately scanned, the size of the large LED display device can be arbitrarily sized by adding or removing its units can be changed without causing the problem of incompatibility.

Since each unit is independently scanned as a whole, the control circuitry of each unit must contain the same elements that the control circuit known from the prior art contains. Therefore, the control circuit of each unit such as the control circuit (CC) of the conventional large LED display device must contain a CPU, a RAM, a scan drive circuit, a data shift circuit and the necessary buffers. (Accordingly, a unit according to the invention can be regarded as a miniaturized conventional large LED display device ( L ) according to Fig. 10.) The power supply of each control circuit is done by a current source (or a current stabilizer). The scan drive circuit cyclically scans the 16 rows with the data shift circuit transmitting the data (color brightness signals) to the 32 points of each corresponding row. The software in the CPU is especially programmed for a 16 × 32 dot matrix. If the unit contains a different number of fields (eg 4 fields instead of 8), the software in the CPU must be reprogrammed accordingly to comply with this "scanning standard".

To adjust the color and brightness of the unit is the control circuit of each unit continues with one  Color brightness switching scheme provided. Because one unit ins is scanned overall, the individual units can ner large LED display device separately adjusted However, the 8 squares of a unit become the same Time adjusted and cannot be adjusted separately. In practice, the color brightness switching scheme contains meh rere ON / OFF switch, the position of which different Corresponds to degrees of color brightness.

Because the individual units in the large LED display direction can be regulated differently, it is not necessary that all fields of the large LED display direction correspond to the same degree. Only the 8th Fields of a unit must have the same degree in order the uniformity in terms of color and brightness in ensure each unit. Furthermore, if be parts of the large LED display are inconsistent, the units of these parts are regulated separately make them consistent with the rest of the parts.

One problem with a large LED display made up of such units is how one unit selectively receives the data destined for it from the computer and rejects the data from the other units. A conventional large LED display device ( L ) in Fig. 10 contains only one unit (in other words, the entire large LED display device ( L ) is a "unit"), so this problem does not exist there. However, in the case of the present invention, each unit must be able to receive the data destined for it and reject the data of the other units. Assuming with reference to Fig. 1A that a large LED display device ( L 1 ) in accordance with the invention of 4 × 2 = 8 units ( U 1 ) to ( U 8 ) (see sub-picture) by parallel or Series connection of the units is formed, then the data transmitted from the computer to the unit ( U 6 ) can be sent to all units. (For example, you can go through (U 1 ), ( U 2 ) to ( U 6 ), or (U 1 ), ( U 3 ) and ( U 7 ) to ( U 8 ).) The data can only be unit ( U 6 ) received since the remaining units reject the data that is not intended for them. For this purpose, a unit must be able to recognize whether or not the transmitted data are intended for it. Therefore, each unit has an "identification code" and the transmitted data is accompanied by an "addressing signal". If the identification code matches the addressing signal, a unit accepts the transmitted information. Otherwise, the information is rejected and passed on. So the data intended for unit ( U 6 ) pass through the unit ( U 1 ) without being accepted there and then bifurcate into the units ( U 2 ), ( U 3 ) and ( U 4 ) Where the data are not accepted are forwarded to (U 5 ), ( U 6 ), ( U 7 ) and ( U 8 ), of which only unit ( U 6 ) receives the data.

Before the eight units ( U 1 ) to ( U 8 ) are installed in their position on the large LED display device ( L 1 ), the positions of these units must be assigned to the corresponding addresses in the memory of the computer, so that the data for a unit can be generated correctly in the relevant position. Assuming the eight positions of the large LED display ( L 1 ) in the sub-drawing of Fig. 1A, the eight addresses 000 , 001 , 010 , 011 , 100 , 101 , 110 and 111 in the memory ( M ) of the computer are then assigned The data determined for each unit must first be assigned to an address. For example, the data for unit ( U 6 ) must be linked to address 101 . (The assignment of the data of the eight units to the eight addresses can be referred to as an “assignment plan”.) That is, when the data of the unit ( U 6 ) are transmitted, an “addressing signal” corresponding to the address 101 is transmitted simultaneously.

To ensure that the transmitted data are accepted by the corresponding unit, each unit must be provided with a respective identification code that corresponds to an address. For example, the unit ( U 6 ) must receive the identification code 101 so that the unit ( U 6 ) can receive the data with the addressing signal of the address 101 .

It is worth noting that the "allocation plan" is only determined by the positions of the units on the large LED display device ( L 1 ) and the codes of the units, but the wiring of the units has no influence on this. If, for example, the cabling of the units is converted into a series connection of U 1 - U 2 - U 3 - U 4 - U 5 - U 6 - U 7 - U 8 , the "allocation plan" in the memory ( M ) of the computer changes not as long as the positions of the units on (L 2 ) remain the same and the codes are not changed. On the other hand, who changes the positions or the coding of the units also changes the "allocation plan", even if the cabling of the units remains unchanged.

The "mapping plan" can be outlined in a "mapping program" run. After entering the data intended for the units and the data relating to the position of the units on (L 1 ) in the computer, only one (and only a single) run of the "mapping program" has to be carried out, so that the Computer assigns the data for each unit to the corresponding address. (In other words, an "allocation plan" outlined in its memory.) After the "allocation plan", the data of a unit are accompanied by a corresponding addressing signal, which enables a unit to recognize whether or not the Data is intended for them.

In the event that the user changes the size of the large LED display device ( L 1 ) by adding or removing some units or only changes the positions of the units in (L 1 ) without adding or removing units, or only the encodings changed for these units, the assignment changes and the user can no longer use the old assignment plan to generate the data in the correct units. Therefore, he must enter the data of the new units and the data for the positions of the units and run the mapping program again to outline a new mapping plan. This gives the units the property of selectively accepting or rejecting the data transmitted by the computer.

The "mapping program" is not absolutely necessary. If a "mapping plan" of the units in advance the computer memory can be entered, is unnecessary a mapping program. Such an "assignment plan" However, it must be changed accordingly by another "assignment plan "to be replaced when arranging the units is changed.

(Note: In fact, the "allocation plan" is a pro gram that the assignment of the intended for the units Data and the corresponding addresses. This "Plan program" must not be combined with the "mapping program" be confused. The mapping program does not exist special assignment between the units and the addresses sen. "Mapping" does not mean a plan, but the fa ability to draw a plan. It enables the computer the "allocation plan" of the allocation of the units to the Sketch addresses of the computer. When running through the "Mapping program," the computer outlines a "plan program "of the units in its memory. The" allocation plan "must be changed when the assignment of the one the addresses of the computer that is changing "Mapping program", however, does not have to change the assignment can be changed.)  

In practice, the "identification code" of each unit corresponds to the state of an address switching scheme with several manually operated ON / OFF switches. If the address switching scheme of each unit contains three ON / OFF switches, there are eight different binary codes, namely 000, 001, 010, 011, 100, 101, 110 and 111 , each of which is a unit ( U 1 ) to ( U 8 ) correspond. Needless to say that an "overlap" or "collision" of the codes is not allowed. In other words, two units must not have the same coding, unless they are designed to always reproduce the same pattern. Because of this, all units must each receive a different identification code. If the address switching scheme contains eight ON / OFF switches, (2) ⁸ = 256 different eight-bit encodings are available. That is, the large LED display device can contain up to 256 units.

If more than 256 units are needed, the number of possible encodings can easily be increased by increasing the number of switches in the address switching scheme. If, for example, the number of switches is increased from eight to ten, (2) ¹⁰ = 1024 different ten-bit codes are available. However, this is not a preferred embodiment, since a circuit diagram with ten switches is not available on the market. An eight-switch element is available. For cost reasons, the available eight-switch type is preferred. In order to use the available circuit diagram with 8 switches for more than 256 units, the number of output connections on the interface is increased. Each interface output is connected to a group of 256 (or less than 256) units. If a large LED display device ( L 2 ) with 1024 units ( U 1 ) to ( U 1024 ) is to be formed with reference to FIG. 1B, the units can be divided into four groups ( G 1 ), ( G 2 ), ( G 3 ) and ( G 4 ) who divided, each containing 256 units, namely (U 1 ) to (U 256 ), ( U 257 ) to ( U 512 ), ( U 513 ) to ( U 768 ) and ( U 769 ) to ( U 1024 ). The number of output ports on the interface must be increased to four. The delivery points ( g 1 ), ( g 2 ), ( g 3 ) and ( g 4 ) are each connected to a group ( G 1 ), ( G 2 ), ( G 3 ) and ( G 4 ). The computer must be programmed in such a way that it transmits the information applicable to a group (for example, (G 2 )) to the group ( G 2 ) via the appropriate output connection ( g 2 ). The interface ( I 1 ) in Fig. 1B differs from the interface ( I ) in Fig. 10 and in Fig. 1 only in that the number of its output ports can be increased. Theoretically, the number of issuing offices can be increased infinitely. Therefore, the number of units of a large LED display device ( L 1 ) can be increased to any practical number desired using the conventional eight-switch element.

As mentioned above, the number N of fields in a unit is preferably chosen neither too large nor too small. The reason for this is now given. Since each unit must be provided with a corresponding control circuit, which contains a CPU, a RAM, a data shift circuit, a scan drive circuit, an address switching scheme as well as a color-brightness switching scheme, if N is too small (e.g. N = 1, ie each unit contains only a single 8 × 8 dot array), in the event that a large LED display device with 64 × 64 dots is to be formed, 8 × 8 = 64 control circuits and thus 64 element sets are required (although the structure of some elements , such as the buffer, the data shift circuit and the scan drive circuit become simpler when N is smaller). The resulting increase in costs is remarkable. Furthermore, a lot of time is required to set the address switching scheme so that each of the 64 units receives a corresponding identification code and they are connected to each other. However, if N is too large (eg N = 32), the possibilities of the combination are largely reduced. For example, if a unit contains 2 × 4 = 8 fields, the large LED display device can easily be enlarged to a scale of 64 × 64 to 96 × 80 dots by adding 7 such units containing eight fields. If N = 32, such a size cannot be achieved. Furthermore, the fields of a unit must have the same degree, since the color brightness of the N fields of a unit cannot be adjusted separately.

That is, the larger the value for N , the more difficult it will be to find N fields with the same degree and the more difficult it will still be to make a "local adjustment". Therefore, the choice of an optimal value for N is a compromise between the costs and the possibilities of achieving a size that can be put together and the possibility of local adjustment. Taking all of these factors into account, N = 8 appears as the optimal value.

The invention can be more easily understood if it is in Reading the accompanying drawings, in which:

Brief description of the drawings

Fig. 1A is a graph showing the connection of a large LED display device with eight units according to the invention and a computer with the allocation plan of the units sketched in its memory; the sub-figure shows the positions of the eight units in the large LED display device;

Fig. 1B shows a graph showing the connection of the large LED display device with four groups of units with an interface with four outputs;

Fig. 1C is a graph showing the connection of a series of circuit boards on the interface;

Fig. 2 is a perspective view of a unit with eight 8 × 8 dot matrix LED display panels according to the invention;

Fig. 3 is a perspective view showing a large LED display device consisting of eight of the units shown in Fig. 2 and their connection to a computer;

Fig. 4 is a brief block diagram of the control circuit of one of the units of Fig. 2;

Fig. 5 is a graph showing the connection of the outputs and inputs of the units of Fig. 1A;

Fig. 6 is a detailed circuit diagram showing a part of the control circuit with the address switching scheme and the color-brightness switching scheme;

Fig. 7 is a circuit diagram showing in detail the wiring of the eight panels of a unit;

Fig. 8 is a circuit diagram of the data shift circuit;

Fig. 9 is a perspective view showing an LED dot having a red and a green LED chip;

Fig. 10 shows a block diagram of a conventional large dynamic dot matrix LED display device consisting of nine 8 x 8 dot matrix arrays;

Fig. 11 shows a perspective view of the large LED display device of Fig. 10 and its connection to a computer.

Detailed description of the preferred embodiment

With reference to FIG. 2, a unit according to the invention ( U ) contains an LED display plate ( 27 ) consisting of eight dot matrix LED fields ( P 11 ) to ( P 24 ), and a control circuit (CC 1 ) consists. A current stabilizer ( S ) supplies the required current. Generally, several units (e.g. ten) can use a common current stabilizer. As noted above, the unit has an input port ( 1 ) and an output port ( 1 ') through which a number of the same units can be connected together to form a large LED display device. Fig. 3 shows a large LED display device ( L 1 ), which is formed from eight units ( U 1 ) to ( U 8 ) and with a computer ( C ) via an interface ( I ) connected to the interface ( I ) in Fig. 11 corresponds.

Fig. 4 shows that the control circuit (CC1) of a unit A CPU ( 21 ), a RAM ( 22 ), buffer ( 23 ) and ( 24 ), a data moving circuit ( 25 ) (or DS 1 ) and a scan drive circuit ( 26th ) (or SC 1 ) contains. A current stabilizer ( S ) feeds the control circuit (CC 1 ). Since these elements correspond to the corresponding elements from the prior art in FIG. 10, their description is reduced to a minimum in the following.

As mentioned above, the control circuit of a unit further includes an address switching scheme ( 31 ) and a color-brightness switching scheme ( 32 ). These are each connected to the CPU via buffers ( 311 ) and ( 321 ). The buffers ( 311 ) and ( 321 ) are each connected to a control gate circuit ( 33 ). This receives the signals from the CPU to control the transfer of the buffers ( 311 ) and ( 321 ) in order to allow the corresponding signals to pass.

In Fig. 4, the input point ( 1 ) is connected to the computer via an interface ( I ). The output of the input terminal ( 1 ) contains a data transmission line ( 11 ), an address transmission line ( 12 ) and a control transmission line ( 13 ) which are connected to the input of the transmission buffer ( 23 ).

The transmission lines ( 111 ), ( 131 ) from the transmission buffer ( 23 ) are connected to the CPU ( 21 ), while the transmission line ( 121 ) is connected to a buffer ( 24 ), the output ( 121 ) of which continues to be connected to the buffers ( 311 ), ( 321 ) and the RAM ( 22 ) is connected. The three transmission lines ( 111 ), ( 112 ), ( 113 ) are each divided into two and branch to the output connection ( 1 '). If the transmitted data is not intended for this unit, it does not reach the core of the unit, but goes sideways through the output connection ( 1 ') to the input connection ( 1 ) of the next unit. Since the data pass through a buffer ( 23 ) with an amplifier function, the signal of the data does not become weaker when passing through a number of units, even if many units have to be passed. A control transmission line ( 132 ) and a data transmission line ( 133 ) connect the CPU ( 21 ) and the RAM ( 22 ). A transmission line ( 112 ) leads from the CPU ( 21 ) to the data shift circuit ( 25 ). The data shift circuit ( 25 ) sends the data from the transmission line ( 112 ) to the corresponding rows of points on the LED display panel ( 27 ). The scanning of the rows of the LED display ( 26 ) is effected by the scanning drive circuit board ( 27 ) via the upper scanning transmission line ( 281 ) and the lower scanning transmission line ( 291 ). The scan transmission lines ( 28 ) and ( 29 ) lead from the RAM ( 22 ) to the scan drive circuit. The row scan signals are transmitted from the CPU ( 21 ) through the RAM ( 22 ) via the scan transmission lines ( 28 , 29 ), the scan drive circuit ( 26 ) and the scan transmission lines ( 281 , 289 ) to the LED display plate ( 27 ) to scan its sixteen rows.

Fig. 5 shows in detail the connection of the connections ( 1 , 1 ') of the units shown in Fig. 1.

With reference to Fig. 6 it is clear that both the address switching scheme ( 31 ) and the color-brightness switching scheme ( 32 ) each contain eight ON / OFF switches. With the eight ON / OFF switches of the addressing circuit diagram ( 31 ) 256 different binary codes can be achieved. That is, a large LED display device can be composed of at most 256 such units. Four of the eight switches of the color-brightness switching scheme ( 32 ) control the brightness of the red chips in the points of this unit, the remaining four switches control the brightness of the green chips. With the four switches (2) ⁴ = 16 different brightness levels can be set. The hue can also be controlled by changing the ratio of the red to the green light. Assuming, for example, the brightness of the red chip corresponds to the 9th degree and that of the green chip to the 8th degree, in the event that the brightness produced is satisfactory, but the color tone is a little too red, the red chip can be on the 8th degree and the green chip are set to the 9th degree. This does not change the brightness, but the hue is corrected.

The data transmission lines ( 112 ) from the CPU ( 21 ) to the data shift circuit ( 25 ) includes a red light data transmission line ( 1121 ), a green light data transmission line ( 1122 ), a timer data transmission line ( 1123 ) and a scan data transmission line ( 1124 ). The red and green light transmission lines ( 1121 ), ( 1122 ) pass the information on the red and green components. The scanning signal enables the information about the red or green component to be transmitted to the corresponding points when the appropriate row is scanned.

From Fig. 7 it is clear that the scan transmission lines ( 281 ), ( 291 ) from the scan drive circuit ( 26 ) to the LED display panel ( 27 ) each with the points of the four upper fields ( P 11 ) to ( P 14 ) and the points of the four lower fields ( P 21 ) to ( P 24 ) are connected to control the scanning of the LED display ( 27 ).

Fig. 8 shows that the four data transmission lines ( 1121 ) to ( 1124 ) are connected to the data shift circuit ( 25 ). The shift circuit ( 25 ) contains eight shift registers (SR 1 ) to (SR 4 ) and (SR 1 ′) to (SR 4 ′) and eight drive stages ( D 1 ) to ( D 4 ) (red drive stages) and (D 1 ′) to (D 4 ′) (green driving stages). The red light data transmission line ( 1121 ) is only connected to the four shift registers (SR 1 ) to (SR 4 ), which in turn are connected to the red chips of the plate ( 27 ), while the green light transmission line ( 1122 ) is only connected to the four shift registers ( SR 1 ') to (SR 4 ') is connected, which in turn are connected to the green chips on the plate ( 27 ). Each driver stage has eight outputs, each of which is connected to a column of the LED display plate ( 27 ). Since the description made in the preceding three paragraphs relates to known technical processes and is not part of the invention, further details may be omitted.

The brightness of the LED chip is controlled by the pulse duration. As mentioned above, the brightness of an LED chip depends on its power supply. Since the average current is directly related to the pulse duration that energizes the LED chip, the brightness can be adjusted by changing the pulse duration. The CPU ( 21 ) is able to determine the state of the color-brightness switching scheme and to transmit pulses with a corresponding duration via the red light transmission line ( 1121 ) and the green light transmission line ( 1122 ) to the red and green LED chips, so that in the desired level of color brightness is generated.

In the preferred embodiment, the on setting the color brightness gradually. With others Words, the brightness of the LED chips will be in sixteen un different grades divided. A stepless entry However, it is also possible to use different versions cher conventional devices.

It is worth noting that the units are theoretically in un finite number can be connected in series. If however, they should be connected in parallel should the number of the units connected in parallel at one point do not exceed ten since that is from the computer de signal for each branch of the parallel circuit will split and can thus become weaker. If the If the number of branches exceeds ten, the signal can go as far weakened that an operation is no longer possible is.

In order to build a large LED display device with 256 units, different codes must first be assigned to the 256 units by setting the addressing circuit diagram ( 31 ) and then connected to their connections in order to form a closed circuit. Then the large LED display device formed must be connected to the computer via an interface.

Then a "mapping plan" must be entered into the computer will. The "plan" can be entered by entering a "plan program mes "are generated in the memory of the computer or alternatively by running a "mapping program", which, as mentioned above, outlines a "plan" in the computer graces.

In order to increase or decrease the scale of a large LED display device ( L '), a selected number of units can be added to the original large LED display device ( L ') (or a selected number of units thereof) are removed) and the added units are assigned the respective identification code. (If necessary, the identification codes of the old units in the original large LED display device must also be changed.) Then the units of the new large LED display device can be reassigned to the addresses of the computer and the "assignment plan" can be renewed. in the computer by replacing the "old plan" with a new or another run of the "mapping program". The modified large LED display device can then be used.

As mentioned above, the number of output ports of the interface can be increased if more than 256 units are required and the available eight-switch element is used. Fig. LC shows that a circuit board ( W ) of the interface can hold eight output connections ( g 1 ) to ( g 8 ), each of which is connected to a group ( g 1 ) to ( g 8 ) with 256 units. Each circuit board ( W ) has an input end ( X ) and an output end ( Y ). This means that any number of circuit boards ( W ) can be connected in series. Of course, the data of a given group, for example the third group ( G 3 ) of the first circuit board ( W ), can only be transmitted to the relevant output connection ( g 3 ) of the first circuit board ( W ) and not to the other output connections. This is controlled by the computer. By connecting three such circuit boards, 24 output connections can be provided. This means that 24 groups or 256 x 24 = 6144 units can be incorporated in one large LED display device.

The present invention provides numerous advantages in Comparison with conventional dynamic dot matrix LED Show. Since the unit can be standardized, their price will be minimized. The units can be in combine any desired number to form a large LED-on to form a pointing device of any desired size,  without the redesign of the circuit or the software must be reprogrammed in the CPU would. Because the degree of color brightness of each individual Unit can be set separately is the requirement The equality of the fields is not critical, as with conventional LED displays and the slightest inequality in terms of brightness or hue in any location of the right resulting large LED display device can be locally adjustments are eliminated. There is no two fel that this invention was a revolutionary breakthrough in LED display manufacturing.

Claims (8)

1. A dot matrix LED display unit for constructing a large dot matrix LED display device which reproduces the original information stored in a computer, with a dot matrix LED display panel and a control circuit, the dot -Matrix LED display plate contains m × n LED dots and n and m are positive integers and each of the LED dots contains at least one LED chip for monochromatic light, and the control circuitry can be connected to the computer The input port includes, with a CPU connected to the input port, memory devices connected to the CPU, a plurality of buffer devices, a data shifter circuit corresponding to the m columns of the LED dots on the disk, and a scan drive circuit which corresponds to the n rows of the LED points on the plate, the CPU containing software programmed in such a way that the scan drive circuitry performs a cyclic scan by the n- series from the first to the n- th series and the data shift circuit transmits the corresponding information from the computer to the LED points of a corresponding series which is scanned by the scanning drive circuit, characterized in that the control circuit with an off is provided port and an addressing device in which an identification code is stored, the output port is structurally connectable to the input port and connected to the connecting lines between the input port and the CPU, and wherein the identification code with a specific address of the memory of the computer over agrees, the software is such that when data are transmitted with an addressing signal from the computer and the addressing signal matches the identification code, the unit allows an image of the data on the LED display plate. 2. Dot matrix LED display unit according to claim 1, wherein each of the LED dots has at least two LED chips each because it contains different monochromatic light. 3. The dot matrix LED display unit according to claim 2 with furthermore an adjustment device to the Hellig of the respective LED chips for different things adjust monochromatic light. 4. Large dot matrix LED display device, made of a plurality of the dot matrix LED display units  according to claim 1, characterized in that the one connecting at least one unit to the computer is connected and the input port of each of the ver permanent units with at least one of the input and output ports of at least one other input unit and each of the units has its own Identification code. 5. The dot matrix LED display unit according to claim 1, at which the addressing device has a plurality of ON / OFF Contains switches and the identification code through the Position of the switch is formed. 6. The dot matrix LED display unit according to claim 3, at the control device has several ON / OFF switches contains and the different degrees of brightness of the LED chips correspond to the positions of the switches. 7. The dot matrix LED display unit according to claim 1, wherein m = 16 and n = 32. 8. The dot matrix LED display unit according to claim 1, at which the dot matrix LED display panel by 2 × 4 = 8 Fields with an 8 × 8 LED dot matrix is formed.