JP2004062115A - Distribution processing unit for picture display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a distribution processing unit that enables a display unit structure to be arbitrarily designed. <P>SOLUTION: The distribution processing unit for a picture display device receives data from a picture data source concerning a picture to be displayed in a display section which is structured by connecting a plurality of display units and, on the basis of the data received, transfers necessary data to the display section of the picture display device. The distribution processing unit is provided with an interface 20 for the purpose of performing data communication by connecting a plurality of distribution processing units, and also provided with an interface 21 for the display unit for the purpose of transferring data to the driving circuit 6 of a light emitting element comprising the display section of the picture display device. The interface 20 for the distribution processing unit has a capability of transferring data faster than the interface 21 for the display unit. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a distribution processing device for an image display device.
[0002]
[Prior art]
Today, high-luminance light-emitting elements such as light-emitting diodes (hereinafter, also referred to as “LEDs”) have been developed for each of the three primary colors of light, red (Red), green (Green), and blue (Blue). As a result, large self-luminous full-color displays have been manufactured. Above all, LED displays have features such as lightness, thinness, and low power consumption, and the demand for large displays that can be used outdoors is rapidly increasing. A large LED display having a large size uses a large number of LEDs. For example, in the case of 300 × 400, a total of 120,000 LED groups are used.
[0003]
Generally, a dynamic driving method is used as a driving method of the LED display. For example, as shown in FIG. 1, in the case of an LED display configured by a dot matrix of M rows × N columns, the anode terminals of the LEDs 11a, which are the light emitting elements located in each row, are commonly connected to one common source line 12. The cathode terminals of the LEDs located in each column are commonly connected to the current line 13 in that column. Each of the current lines 13 is connected to a constant current source 14a. The M rows of common source lines 12 are sequentially turned on at a predetermined cycle, and the LED drive current is supplied to the N columns of current lines 13 according to the image data corresponding to the turned-on lines. As a result, an LED drive current corresponding to the image data is applied to the LED 11a of each pixel, and an image is displayed.
[0004]
A large-sized LED display to be installed outdoors is generally configured by combining a plurality of LED units. In each of the LED units, light emitting diodes each having a set of RGB are arranged in a dot matrix on a substrate, and each LED unit performs the same operation as the above-described LED display. When a plurality of LED units are combined to form one flat display as a whole, each part of the displayed screen information is displayed on each LED unit.
[0005]
When an LED display is configured by combining a plurality of such LED units, a controller for transferring necessary image data from an external image data source is required for a drive circuit of each LED unit. Such an apparatus is called a terminal adapter (hereinafter, referred to as a "distribution processing apparatus").
[0006]
FIG. 2 shows an example of the distribution processing device. The distribution processing device 1 shown in this figure includes a long-distance receiving device 1A and a distribution unit 1B. The long-distance receiving device 1A includes an input-side interface 2 for connecting to the display control device 10, and an output-side interface 3 for transmitting to the distribution unit 1B. The display control device 10 acquires information such as an image to be displayed on the image display device from an external image data source or the like, converts this data into a format that can be processed inside the distribution processing device, and sends it to the distribution processing device 1. . The display control device 10 and the long-distance receiving device 1A are connected by a coaxial cable 4, and the long-distance receiving device 1A and the distribution unit 1B are connected by a flat cable 15. The long-distance receiving device 1A receives the data converted by the display control device 10 in serial, converts the data into parallel, and sends it to the distribution unit 1B. Each distributing section 1B is connected to a driving circuit 6 of the LED unit 5 for lighting and driving each LED unit 5 based on parallel data from the long distance receiving device 1A. The distribution unit 1B can connect a plurality of distribution units 1B in series, and includes an interface for connecting to the next-stage distribution unit 1B. Each of the plurality of connected distribution units 1B drives the driving circuit 6 of the LED unit 5 connected thereto based on the data received by the long distance receiving device 1A. The drive circuit 6 performs double-speed display or the like in order to display the corresponding image data on the LED unit 5, and as a result, a desired image is displayed on the entire LED display.
[0007]
[Problems to be solved by the invention]
However, in this type of distribution processing apparatus, the distribution unit 1B needs to temporarily store the image data to be displayed in the memory and distribute the image data to the LED units 5 connected to the distribution unit 1B. As the number of LED units 5 increases, the amount of image data to be stored increases by that amount, and there is a problem that a large-capacity memory is required. The larger the capacity of the memory, the more expensive it is. Therefore, if a large number of LED units 5 are connected to form a large-screen LED display, there is a disadvantage that the manufacturing cost is increased.
[0008]
Further, in this type of distribution processing apparatus, there is a problem that the form of connection between units is limited. As an interface between the LED units, a low-speed interface generally connected in parallel by a flat cable or the like is used. In the case of a ribbon-shaped flat cable, the wiring length is limited, and it cannot be set to a long distance of, for example, 50 cm or more. For this reason, it is necessary to arrange the units close to each other to some extent, and there is a problem that the arrangement conditions of the units are limited by the restriction of the cable length.
[0009]
On the other hand, as shown in FIG. 3, a circuit configuration of an image display device in which units are connected to each other with a coaxial cable 4 so that the units can be separated from each other has been developed. The circuit board of the distribution processing apparatus 1 shown in FIG. 1 includes input and output interfaces 7 and 8 for performing data communication between boards that are spaced apart from each other. Using these interfaces 7 and 8, the boards can be connected to each other with a coaxial cable 4 to perform data communication. The interface between each circuit board 1C and the LED unit 5 of the distribution processing apparatus 1 includes three output ports 16 as an LED unit control interface so that the circuit board 1C can be directly connected to the LED unit 5. When this substrate is used, four rows of LED units 5 are connected in three stages on one substrate, and a total of 12 LED unit blocks can be configured.
[0010]
However, even in this circuit configuration, since it is necessary to temporarily store the image data assigned to each circuit board 1C in a memory, there is a problem that memory for the number of units connected to the circuit board 1C is required for each circuit board 1C. . For example, in order to connect 12 LED units 5, it is necessary to provide a large-capacity memory corresponding to 12 × (the number of pixels per LED unit) × 3 colors on the circuit board 1C. For this reason, there is a problem that the cost of the memory becomes high, the driver circuit 9 for driving the memory becomes complicated, and the manufacturing cost of the circuit becomes high. Further, the number of connectable LED units is limited by the number of output ports 16 of the circuit board 1C. In other words, the inability to connect more LED units 5 than the number of output ports limits the circuit design, and there is a disadvantage that the LED units per block cannot be expanded. In addition, there is a disadvantage that an interface for connecting the coaxial cable 4 for connecting the circuit boards 1C is expensive.
[0011]
The present invention has been developed to overcome these disadvantages. A main object of the present invention is to provide a distribution processing device of an image display device that can be freely designed with an inexpensive circuit configuration.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, a distribution processing device of an image display device according to claim 1 of the present invention provides an image display device configured to connect a plurality of display units to each other with an image data source. And transfers necessary data based on the received data to the display unit of the image display device. The distribution processing device includes a distribution processing device interface for connecting a plurality of distribution processing devices to each other to perform data communication, and a transfer processing device for transferring data to a driving circuit of a light emitting element constituting a display unit of the image display device. It has a display unit interface, and the distribution processing device interface enables higher-speed data transfer than the display unit interface.
[0013]
As the display unit, for example, one in which a plurality of light emitting elements are arranged in a matrix can be used, and includes an LED unit and the like. This distribution processing device can be used for a drive circuit of an image display device that forms a larger display screen by combining a plurality of display units in a unit type.
[0014]
According to a second aspect of the present invention, there is provided a distribution processing apparatus for an image display device, wherein one or more distribution processing apparatuses are connected to each other to form one distribution processing apparatus aggregate. And each distribution processing unit aggregate has an aggregate interface for transferring data to other distribution processing unit aggregates, and each unit is given a unique identification information and is performed in a packet format. It is characterized by.
[0015]
The aggregation interface is provided in at least one of the distribution processing devices constituting the distribution processing device aggregate. Preferably, it is provided in the distribution processing devices located at both ends, but it may be provided in all the distribution processing devices, or an external interface for an aggregate may be separately provided for each distribution processing device aggregate. As the data to be transferred, in addition to the image data alone, data to which control data is added in addition to the image data may be used.
[0016]
According to a third aspect of the present invention, in addition to the features described in the first or second aspect, the distribution processing device of the image display device has a configuration in which the distribution processing devices are connected in parallel to each other and one distribution is performed. It is characterized in that the distribution processing devices constituting the processing device aggregate can be arbitrarily added or deleted.
[0017]
With a configuration in which the distribution processing device can be added, the number of display units that can be connected to the distribution processing device aggregate can be increased or decreased. Further, since the distribution processing devices can be separated from each other by the distribution processing device interface, each distribution processing device can be arranged according to the arrangement of the display units.
[0018]
Still further, the distribution processing device of the image display device according to the present invention may further include a parallel connection unit that connects the distribution processing devices constituting the distribution processing device aggregate with a serial connection unit that connects the distribution processing device aggregates. It is also possible to make the transfer speed faster and the connection length longer. For this purpose, for example, a high-speed transmission method using an LVDS signal level or the like can be adopted.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiment described below exemplifies a distribution processing device of an image display device for embodying the technical idea of the present invention, and the present invention relates to a distribution processing device of the image display device as follows. Not specific to
[0020]
Further, in this specification, in order to easily understand the claims, the numbers corresponding to the members described in the embodiments are added to the members indicated in the column of “Means for Solving the Problems”. . However, the members described in the claims are not limited to the members of the embodiments. Further, the size, positional relationship, and the like of the members illustrated in the drawings may be exaggerated for clarity of description. Further, each element constituting the present invention may be configured such that a plurality of elements are formed of the same member and one member also serves as the plurality of elements.
[0021]
[Example 1]
FIG. 4 shows an example of configuring an LED flat panel using the distribution processing device 1 according to one embodiment of the present invention. The apparatus shown in this figure shows a state in which a plurality of distribution processing apparatuses 1a, 1b,. The display unit 18 is connected to the distribution processing device assembly 17. The display unit 18 connects a plurality of LED units 5 to each other to form one flat panel display.
[0022]
The distribution processing device 1a shown in FIG. 4 includes three types of interfaces: an assembly interface 19, a distribution processing device interface 20, and a display unit interface 21. The aggregation interface 19 is for receiving data from the display control device 10, performing necessary processing, and then transferring the processed data to the next-stage distribution processing device 1b. Necessary processing includes, for example, processing for serial-parallel conversion of data. Similarly, the next-stage distribution processing device 1b transfers the data to the next-stage distribution processing device (not shown), and thus sequentially transfers the data. In the case of one-way communication, data is returned from the last-stage distribution processing device to the display control device 10, but in the example of FIG. 4, the last-stage distribution processing device transmits data to the display control device 10 by employing bidirectional communication. Need not be returned. In this way, data communication is performed between the entire distribution processing device assembly 17 and the display control device 10. The transfer speed of data communication is performed at high speed by serial transfer, and data is transmitted in a packet format.
[0023]
The display control device 10 is an LED display control device that connects a source of image data and converts the image data into a format that can be processed inside the distribution processing device. The source of the image data connects an external device such as a video playback device to the display control device 10. Alternatively, the display control device 10 may include a source of image data. The function of converting the format of the image data may be provided to the display control device 10 or may be provided to the distribution processing device.
[0024]
The aggregate interface 19 is composed of an input terminal and an output terminal for the distribution processing device, and is fixed so as to be exposed from an end of a substrate constituting the distribution processing device 1. In the LED panel shown in FIG. 4, the distribution processing device 1 located at the end is in charge of the transfer of external data, and sends out the decoded data to the distribution processing device 1 connected to the next and subsequent stages. In other words, the distribution processing apparatus 1a uses the aggregate interface 19, but the distribution processing apparatus 1b and thereafter do not need the aggregate interface 19. However, the same type as the distribution processing apparatus 1a may be used for all subsequent steps. Although not shown, an assembly interface may be provided only in the distribution processing device 1 located at an end or a specific portion. In this case, the aggregate interface may be input only or output only.
[0025]
In this embodiment, the connector of the aggregate interface 19 has a high transfer rate of several hundred Mb class, and realizes a sufficient speed for serially transferring packet data. By using a general-purpose interface connector, a normal LAN twisted cable can be used as a cable for connecting them, which contributes to a reduction in manufacturing cost.
[0026]
The aggregate interface 19 is connected to the decryption processing unit. This circuit decodes the transferred packet data and converts the packet data to a predetermined transfer rate for sending to the LED drive circuit 6. This transfer speed is generally lower than the transfer speed between the distribution processing devices.
[0027]
The distribution processor 1a receives its own data and sends the original data from the distribution processor interface 20 to the next-stage distribution processor 1b. The received data is decrypted by the decryption processing unit and transmitted to the display unit interface 21. The packet data may be decoded by the distribution processing device 1a that receives the data, and the decoded data may be transmitted to the next distribution processing device 1b. It is also possible to adopt a configuration in which each processing unit performs decoding.
[0028]
The distribution processing device interface 20 is a parallel port, and transmits a plurality of data strings in parallel. Among the received data, the distribution processing device 1b extracts data corresponding to the LED unit 5 in charge of the distribution processing device 1b, and sends the data to the next-stage distribution processing device 1c.
[0029]
In the example of FIG. 4, the distribution processing apparatuses 1 are directly connected to each other by the substrate-substrate connector of the interface 20 for the distribution processing apparatus. The connector is formed in a shape that can be fitted or locked to each other, for example, one of which is a male type and the other is a female type, so that the adjacent distribution processing devices 1 can be connected to each other. Each protrudes from both sides of the processing apparatus 1. The distribution processing devices 1 having male and female connectors protruding on both sides, respectively, can be connected to adjacent distribution processing devices 1 sequentially to increase the number of distribution processing devices 1 to be added. As described above, the connector is provided with not only the connection of the electric signal between the distribution processing apparatuses 1 but also the physical connection function.
[0030]
In the example described above, each substrate is provided with a high-speed interface. However, the present invention is not limited to this configuration, and a high-speed interface may be provided only on the substrate located at the end of one unit of the distribution processing apparatus. In this configuration, a high-speed interface is provided only on the input stage substrate and the output stage substrate, and the intermediate portion substrate is a substrate having only a low-speed parallel port. Can be reduced at low cost. If the input and output stages use the same type of substrate, each having an input / output interface, the number of types of substrates can be reduced to two, so that they can be conveniently used without being confused. Can be used. Alternatively, a substrate having only input ports may be used for the input stage, and a substrate having only output ports may be used for the output stage.
[0031]
Data such as image information and control information is transmitted in a packet format. The data in the packet format has identification information indicating a transfer destination, so-called ID information, in addition to the data. One ID number is assigned to the distribution processing device 1 in advance as a whole unit, and the distribution processing device aggregate 17 selects packet data to which an ID matching the ID number is added and selects the data addressed to itself. To get. Note that the ID assigned to the distribution processing device assembly 17 can be assigned in hardware at the design stage, but is preferably assigned arbitrarily in software. In the former method, a predetermined ID number is set by switching an ID setting dip switch provided on each substrate. On the other hand, in the latter method, when a display panel that can be disassembled and assembled is used, a predetermined ID number can be automatically given each time a display is installed. Therefore, compared to the method of assigning ID numbers by hardware, the method of assigning IDs by software does not need to be constructed according to the number of each panel, so that it can be used conveniently and each panel has the same specifications. There is an advantage that it can be used for general purposes.
[0032]
Instead of assigning an ID to each distribution processing device 1, a distribution processing device aggregate 17 which is an aggregate of the distribution processing devices 1 is treated as if it were one distribution processing device 1, and one ID is assigned thereto. In this method, the distribution processing device 1 can be freely combined and designed according to the purpose of use or application, and can be handled as one distribution processing device 1 in an appropriate form according to the configuration, and the circuit configuration is flexible. Contributes to sex. The packet data is transmitted for each frame constituting the image data to be displayed.
[0033]
The distribution processing device 1b and below are provided with two types of interfaces in which the aggregation interface is omitted from the distribution processing device 1a. However, the same type as the distribution processing apparatus 1a may be used.
[0034]
As described above, the method of transferring image data to one distribution processing apparatus 1 in which a plurality of distribution processing apparatuses 1 are connected to each other by using a LAN cable or the like is based on a method in which an aggregate of the plurality of distribution processing apparatuses 1 is processed as if a large distribution processing apparatus 1 It provides a high degree of freedom that it can be handled as the device 1 and can be easily designed according to the scale of the display.
[0035]
The distribution processing device interface 20 serves as a connector for connecting the adjacent distribution processing devices 1 and exchanges data. The data obtained from the aggregation interface 19 is subjected to a decoding process to extract image data to be displayed on the display unit, and is sent from the display unit interface 21 to the display unit in each distribution processing device 1. The display unit interface 21 is connected to the distribution processing device 1 and the LED unit 5 constituting the display unit. Parallel or serial connection can be used for the connection form. Thus, the image display device is configured.
[0036]
The display unit is configured by interconnecting a plurality of display units. In this example, an LED is employed as a light emitting element. One set of LEDs is configured with one set of RGB as one pixel, and an LED unit 5 which is a group of LEDs arranged in a dot matrix form as a display unit. A single flat panel display is configured by combining a plurality of LED units 5. Combination methods include a flat panel type full-color display as a VGA type with a vertical and horizontal aspect ratio of 3: 4, as well as a guide plate or a copy belt shape extending in one direction vertically and horizontally, depending on the usage situation. By changing the configuration of the LED display, the shape and size of the display unit can be arbitrarily designed. The expression method is not limited to a full-color display, but may be a single-color display using a single-color LED, a two-color display, a three-color display, or information in which the arrangement of light emitting elements is arranged in a character pattern such as a specific character, numeral, or symbol. It can also be applied as a display panel.
[0037]
The display unit 1 has a plurality of light emitting elements 11 arranged in a matrix of M rows × N columns on a substrate on which a conductive pattern is formed. As the light emitting element 11, an LED or the like is used. In this embodiment, three light emitting diodes each capable of emitting light of RGB are arranged at a predetermined pitch in units of one pixel to form a display surface. An LED with RGB adjacent to each pixel can realize full-color display. However, the present invention is not limited to this configuration, and two colors can be arranged close to each other, or two or more LEDs can be arranged for one color. In this way, the distribution processing device aggregate 17 to which the plurality of distribution processing devices 1 are connected distributes the image data acquired from the display control device 10.
[0038]
Furthermore, as shown in FIG. 4, the distribution processing device aggregates 17 are also connected to each other so that data communication is possible. Each of the distribution processing device aggregates 17 is connected in a ring shape including the display control device 10, and data transferred from the display control device 10 loops through each distribution processing device assembly 17 and finally reaches the display control device 10. Configured to return. The interface connecting the distribution processing device aggregates 17 is an aggregation interface 19, which receives image data via the aggregation interface 19, performs necessary processing, and transfers the image data to the next-stage distribution processing device aggregate 17. I do. The next-stage distribution unit aggregate 17 similarly transfers the data to the next-stage distribution unit aggregate 17. In this way, the data is sequentially transferred, and the distribution processor aggregate 17 at the final stage returns the data to the display controller 10. This transfer speed is extremely high, and data is transferred in a packet format. In the case of bidirectional communication, it is not necessary to connect in a ring.
[0039]
[Example 2]
FIG. 5 shows a configuration example of a distribution processing apparatus aggregate according to the second embodiment of the present invention. In the example shown in FIG. 5, the distribution processing device interface 20 is connected to a flat cable. In the conventional example of FIG. 4, the width of the LED unit 5 in the vertical direction in the figure is not so large as compared with the width of the distribution processing device 1, so that the distribution processing devices 1 can be arranged close to each other. On the other hand, when the width of the LED unit 5 in the vertical direction is large as in the example of FIG. 5, it is necessary to arrange the distribution processing device 1 apart. In such a case, a connection mode in which the distribution processing apparatuses 1 are arranged apart from each other as shown in FIG. 5 is used. Even a connection via a flat cable can be used without any difference from the direct attachment of the distribution processing device 1 in terms of data transfer speed and the like. As described above, the connection mode between the distribution processing apparatuses 1 is appropriately selected according to the mode of the LED unit 5 to be connected and the state of use.
[0040]
[Example 3]
FIG. 6 shows a configuration example of a distribution processing apparatus aggregate according to the third embodiment of the present invention. In the example shown in FIG. 6, the distribution processing device aggregates 17 are connected to each other by an aggregate interface 19. In this drawing, the distribution processing device aggregate 17 is composed of only one distribution processing device 1, but it goes without saying that a distribution processing device aggregate in which a plurality of distribution processing devices are connected can be used. .
[0041]
A distribution processing device connection cable 22 is connected to the aggregate interface 19, and the distribution processing devices are connected to each other by the distribution processing device connection cable. The aggregation interface 19 employs an interface for high-speed transmission such as an LVDS signal level. LVDS is a low-voltage differential signal, which is a signal level used for communication having a low voltage of about several hundred mV and a data transfer rate of several hundred Mb. A general-purpose LAN cable such as a shielded category 5 can be used as the distribution processing device connection cable 22. The use of a shielded cable shields signals from external noise, so that electromagnetic radiation noise (EMI) can be significantly reduced. In addition, data can be transferred at high speed by serial transfer, and the transmission rate increases. As the serial transfer method, IEEE 1394, RS-232C, RS-422, USB, serial ATA, or the like can be adopted. Further, in the embodiment of the present invention, not only a wired connection using a physical cable or the like but also a communication using radio waves such as a wireless LAN and Bluetooth, and a wireless connection using an infrared communication, an optical communication, and the like are used. it can.
[0042]
When connecting with a ribbon-shaped flat cable as shown in FIG. 5, there is a limit to the connection length of the cable due to the limitations of CMOS and TTL used for the interface circuit. On the other hand, as shown in FIG. 6, the method of connecting by adopting the LVDS signal level or the like is a stable high-speed connection that can be connected even at a long distance that cannot be connected with a flat cable or the like and is resistant to external noise. Data communication can be realized relatively inexpensively.
[0043]
As described above, in the embodiment of the present invention, any of the connection as shown in FIG. 5 and the connection as shown in FIG. 6 can be adopted depending on the use status of the image display device. This is because the distribution processing device 1 according to the embodiment of the present invention has a high-speed interface and a low-speed interface. In the embodiment of the present invention, an appropriate connection form according to the distance and arrangement between the distribution processing apparatuses 1 can be adopted. This is an effect that cannot be achieved by the conventional distribution processing apparatus 1.
[0044]
In addition to this, the number of LED units that can be connected and displayed can be changed by appropriately adding the distribution processing device 1, and the usability when constructing a display panel combining a plurality of LED units 5 is dramatically improved. To improve. That is, the feature that the distribution processing device 1 can be optimally connected according to the number and arrangement of the LED units 5 is realized.
[0045]
That is, when the LED unit 5 itself is small, the distribution processing devices 1 are directly connected to each other without using a flat cable or the like as shown in FIG. On the other hand, when the size of the LED unit 5 is large as shown in FIG. 5, the distribution processing devices 1 can be arranged so as to be appropriately separated from each other. Further, depending on the usage of the LED unit 5, the display itself may be arranged apart. Even in such an embodiment, the distribution processing device 1 can be arranged at an appropriate position by using the aggregate interface 19 as shown in FIG. Further, by changing the number of connected LED units 5, the area and shape of the display unit can be freely changed. The number of connected LED units 5 is determined by the number of ports of the display unit interface 21 provided in the distribution processing device 1. In the embodiment of the present invention, the number of ports is limited because the number of connected LED units 5 can be increased. The number of connected units can be set freely without any need. In particular, when the display unit is used as an LED display for outdoor display that can be assembled into a desired configuration when the LED unit 5 is disassembled for moving or transporting and installed outdoors or the like, a great degree of freedom in arrangement of the display is provided. Is provided, and the convenience can be improved. Furthermore, a flexible wiring structure of the distribution processing apparatus 1 is possible, and a low-cost and compact circuit board can be configured. As described above, in the embodiment of the present invention, the versatility of the distribution processing device 1 corresponding to the LED unit 5 enhances the versatility of the LED unit itself used for the display unit.
[0046]
Further, in this embodiment, a bidirectional bus is realized at the LVDS signal level. By the two-way communication, it is also possible to cause the LED unit 5 to detect an abnormality or the like. Further, instead of transferring only image data using a one-way bus as in the related art, a bidirectional bus can be used to transfer control data in addition to image data.
[0047]
When a coaxial cable is used as a connection cable for a distribution processing device as in the related art, there is a problem that the cable itself is thick and difficult to handle. However, by using the LVDS signal level, handling can be facilitated by using a thinner cable. Further, the conventional distribution processing apparatus 1 shown in FIG. 3 is expensive because it employs a long-distance data transfer interface using a coaxial cable. With this interface, the connection length of the cable can be extended to about 200 m, but in reality, such a long-distance connection is rarely required. In an actual scene, the above specifications are scarcely required, and a distance of several meters is sufficient to connect the units of the distribution processing device assembly 17. Therefore, the present embodiment employs an intermediate data transfer interface and is designed so that the cable length can be connected up to about 1 m to 10 m. In particular, in the embodiment of the present invention, since the distribution processing device 1 has a high degree of freedom in configuration that can be constructed according to the connection form of the display unit, this specification can sufficiently cope with the specification in many cases. Even if the required distance is insufficient, the connection length can be further extended by interposing a repeater. The repeater is a device that transmits received data as it is. As described above, according to the embodiment of the present invention, it is possible to eliminate the over-specification and obtain an apparatus with no excess or shortage, thereby appropriately controlling the cost.
[0048]
Further, conventionally, information of image data to be displayed is stored in a memory provided in the distribution processing device 1 in order to transmit the information to the drive circuit 6 for each LED unit 5. For this reason, the distribution processing device 1 needs a memory corresponding to the number of LED units 5 to be connected. For example, when connecting 3 × 4 12 LED units 5 as a display unit, a memory having a capacity capable of storing data to be displayed by the 12 LED units 5 at one time is required. Large-capacity memories are expensive, and this has led to an increase in cost. On the other hand, in the embodiment of the present invention, since the capacity of the memory provided on the distribution processing device 1 side is sufficient for one unit, an excellent feature that a large-capacity memory is not required is realized. This is because each distribution processing device 1 processes the image data for the LED unit 5 in charge of each in parallel.
[0049]
In the embodiment of the present invention, a dynamic drive system is used for lighting the LED. In the dynamic driving method, as described with reference to FIG. 1, the common source line connected to the lit LED is sequentially switched. It is necessary to read data for controlling the lighting of the LED according to the switching speed. As the frame switching period becomes faster, the data reading speed must be increased. For example, in the case of performing quadruple-speed display in order to suppress display flicker, it is necessary to switch the common source line at a speed four times the video cycle of 60 Hz, and the readout speed must be increased accordingly. Conventionally, a method has been adopted in which data is transferred collectively in a time-division manner and then stored data is read. That is, image data for one frame to be displayed is temporarily stored in a memory such as a RAM that can be read at high speed, and data read into the memory is read from a parallel bus to perform processing such as quadruple speed display. Was. In this method, the distribution processing device 1 needs a high-speed temporary memory for temporarily storing image data for one frame. Such a large-capacity memory is expensive, and the drive circuit 6 is complicated, the circuit itself becomes large, and there is a drawback that the housing for housing the circuit becomes large.
[0050]
On the other hand, in the embodiment of the present invention, the memory capacity required for the distribution processing device 1 is sufficient to be (the number of ports of the display unit interface 21 included in the distribution processing device 1) × (1 display). . Each distribution processing device 1 receives only the assigned image data from the interface by high-speed serial transfer. Then, only the data of the connected LED units 5 is stored in the RAM and read out, and the data is sequentially transferred to the LED units 5 connected in the row direction such as the first and second stages. Do. For this reason, for example, in the distribution processing device aggregate 17 to which the M × N LED units 5 are connected, it is sufficient that the entire distribution processing device aggregate 17 has only the memory of the data corresponding to M rows. If each distribution processing apparatus 1 has a three-port display unit interface 21, only a memory for image data corresponding to three LED units 5 is sufficient. Further, each LED unit 5 can also have a memory corresponding to the data displayed by the LED unit 5. If the distribution processing device 1 has a large-capacity memory, the memory capacity is wasted when the number of connected LED units 5 is small, but if the LED unit 5 has a memory, only the necessary amount is required. Thus, efficient use can be realized in proportion to the cost. As described above, the processing proceeds in parallel by processing only the image data of the LED unit 5 in charge of each of the distribution processing devices 1 connected to the display unit. As a result, since a small memory is required, advantages such as a reduction in manufacturing cost, a simplification of a circuit configuration, a reduction in the size of an apparatus, and a reduction in the size of a housing can be obtained, which can contribute to a reduction in overall cost.
[0051]
FIG. 7 shows an example of a logic circuit constituting one distribution processing device. The distribution processing device shown in this figure incorporates two RAMs as memories for holding image data. As a result, image data of two screens can be held as image data, and while image display data is written in one RAM, it is possible to read image display data already configured from the other RAM. By performing the reading and the reading in parallel, a high-speed operation is realized. Each RAM is a dual port RAM (DPRAM # 1, DPRAM # 2), and has a writing terminal and a reading terminal individually. In the figure, the terminal connected to the selector (SEL) on the left is for writing, and the terminal connected to SEL on the right is for reading. Addresses for writing and reading to and from each DPRAM are specified by a write address generator (WR_ADR) and a read address generator (RD_ADR), respectively. These operations are executed in increments according to the timing of the write clock (WRCLK) and the read clock (RDCLK). WRCLK is obtained from the DS-LINK receiving unit. RDCLK is generated by a unit data strobe link timing generator (Unit DS-LINK TG). The Unit DS-LINK TG is connected to a DS-LINK receiving unit.
[0052]
Further, in the distribution processing device of FIG. 7, the DS-LINK receiving unit and the DS-LINK transmitting unit on the left side constitute an aggregate interface. The right terminal constitutes a display unit interface 21 for communicating with the LED unit 5, and realizes bidirectional communication. The information from the LED unit 5 can be returned to the display control device 10 via the display unit interface 21 by the two-way communication, and for example, LED failure information can be detected and notified to the display control device 10. .
[0053]
Further, the lower terminal constitutes a distribution processing device interface 20 for communicating with another distribution processing device constituting the distribution processing device aggregate. This distribution processing device interface 20 is connected in parallel by reducing the data transfer speed. Since another distribution processing device can be connected to the distribution processing device interface 20, the number of output ports for connecting the LED units 5 is not limited to the number mounted on one distribution processing device. The desired number of output ports can be adjusted by adding or deleting the number of distribution processing devices. This makes it possible to configure a large-screen display composed of many LED units, even if a distribution processing device with a small number of ports is used.
[0054]
Furthermore, the unit ID controller (U_ID_CTL) is for assigning an ID number as unique identification information to each LED unit connected to the distribution processing device, and performs communication between the units when the device is started. And autonomously set according to the configuration of the unit. Therefore, a unique ID number can be assigned to each LED unit 5 according to the connection mode between the LED units, and packet data in which an ID number is set to image data to be displayed by each LED unit 5 is communicated. As a result, necessary image data is distributed to each LED unit, and a desired image can be displayed on the entire display unit. With this configuration, in addition to being able to adjust the number of LED units connected by the distribution processing device interface 20, the number and layout of the LED units 5 constituting the display unit can be arbitrarily set, and user freedom can be increased. .
[0055]
The RAM may be built-in as shown in the example of FIG. 7 or may be provided externally. Further, when the capacity of the built-in RAM is insufficient, the memory capacity can be supplemented by an external RAM. FIG. 8 shows an example in which SRAM # 0 is added as an external RAM to the distribution processing device of FIG.
[0056]
【The invention's effect】
As described above, according to the distribution processing device of the image display device of the present invention, the configuration of the distribution processing device can be freely changed according to the unit size, arrangement, configuration, and the like. The present invention is not limited to the case where a rectangular LED display is used as the display unit. Can be handled by arranging. Further, the display and the panel can be arranged apart from each other.
[0057]
In addition, there is an advantage that not only the arrangement of the display unit but also the size limit is relaxed. That is, the number of connected LED units constituting the display unit is not limited to the number of ports of the substrate of each distribution processing device, and can be expanded by adding a distribution processing device. Such a feature that a display with a high degree of freedom and high usability can be configured is also realized.
[Brief description of the drawings]
FIG. 1 is a circuit diagram schematically showing a driving method of an image display device.
FIG. 2 is a schematic diagram showing an example of a conventional distribution processing device.
FIG. 3 is a schematic diagram showing another example of a conventional distribution processing device.
FIG. 4 is a schematic diagram illustrating an example of a distribution processing apparatus aggregate according to an embodiment of the present invention.
FIG. 5 is a schematic diagram showing an example of a distribution processing device according to another embodiment of the present invention.
FIG. 6 is a schematic diagram illustrating an example of a distribution processing device according to another embodiment of the present invention.
FIG. 7 is a schematic diagram illustrating an example of a circuit configuration of a distribution processing device according to an embodiment of the present invention.
FIG. 8 is a schematic diagram illustrating an example of a circuit configuration of a distribution processing device according to another embodiment of the present invention.
[Explanation of symbols]
1 ... Distribution processing device
1A Long distance receiver
1B ... distribution unit
2 ... Input side interface
3 ... Output side interface
4: Coaxial cable
5 ... LED unit
6 ... Drive circuit
7 ... Input interface
8 Interface for output
9 ... Driver circuit
10 Display control device
11a LED
12 ... Common source line
13 ... Current line
14a: constant current source
15 Flat cable
16 ・ ・ ・ Output port
17 ・ ・ ・ Distribution processing device aggregate
18 Display unit
19 ・ ・ ・ Assembly interface
20 ・ ・ ・ Interface for distribution processing device
21 ・ ・ ・ Display unit interface
22 ... distribution processing unit connection cable

Claims (3)

An image display that receives data related to an image to be displayed on a display unit configured by connecting a plurality of display units from an image data source, and transfers necessary data to the display unit of the image display device based on the received data. A distribution processing device for the device,
An interface for a distribution processing device for performing data communication by connecting a plurality of distribution processing devices;
A display unit interface for transferring data to a display unit constituting a display unit of the image display device,
The distribution processing device for an image display device, wherein the interface for the distribution processing device is capable of transferring data at a higher speed than the interface for the display unit. One or more distribution processing devices are connected to form one distribution processing device aggregate, and each distribution processing device aggregate has an aggregate interface for performing data transfer to another distribution processing device aggregate. 2. The distribution processing device for an image display device according to claim 1, wherein data transmission is performed in a packet format by adding unique identification information to each unit. 3. The distribution processing device according to claim 1, wherein the distribution processing devices are connected in parallel with each other, and the distribution processing devices forming one distribution processing device group can be arbitrarily added or deleted. .

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