JP3877943B2 - Liquid crystal display device and window display enlargement control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a display device, and more particularly to a digital interface display device connected to a PC, WS, or the like.
[0002]
[Prior art]
Conventionally, a display image is processed by a graphic controller of a host device such as a personal computer (PC) and transferred to the display device. In recent years, this display device has progressed beyond the processing capability of the host device. For example, in the LCD, from the conventional XGA (1024 × 768 dots), SXGA (1280 × 1024 dots), and UXGA (1600 × 1200), QXGA (2048 × 1536 dots) and QSXGA (2560 × 2048) which are higher definition. Dot), QUXGA (3200 × 2400), etc. are being put into practical use. On the other hand, the performance of a general graphic controller is limited to about QXGA, and about VGA is limited to moving images.
[0003]
In recent years, a “multi-panel” in which a plurality of panels are combined into a single panel has been put into practical use, and further high definition can be achieved.
[0004]
Furthermore, when transferring display data compatible with ultra-high definition, it is necessary to increase the transfer rate as the definition increases, so recently, LVDS (Low Voltage Differential Signaling), TMDS (Transition Minimized Differential Signaling), GVIF ( Low-voltage differential digital interfaces such as Gigabit Video Interface) are becoming widespread. By increasing the number of these signal lines, it is possible to cope with the above high definition.
[0005]
Further, as in Japanese Patent Laid-Open No. 7-168557, image data in an arbitrary range of each image displayed on the display 1 such as a personal computer is transferred to a high-definition secondary display unit, where these images A and B are transferred. , C ... are combined and displayed, and there is a method for deriving the display position of the image C from the size data of the new image C and the display positions of the images A and B displayed so far. It is being considered.
[0006]
[Problems to be solved by the invention]
However, in the prior art such as the LVDS, a new interface development such as an increase in the number of signal lines or an LSI development is required because a large transfer rate is required every time the definition is increased or depending on the size of the window area. Is required.
[0007]
In the invention described in Japanese Patent Laid-Open No. 7-168557, the display position of a new window is managed in accordance with the already displayed window, but the position and size of the new window are directly defined from the PC side. That is not taken into account.
[0008]
An object of the present invention is to provide a liquid crystal display device and a window display enlargement control method for displaying a window area such as a moving image of about VGA on a large-screen display device such as an ultra-high definition or multi-panel without increasing the transfer rate. To do.
[0009]
[Means for Solving the Problems]
The liquid crystal display device of the present invention includes a liquid crystal display panel, display data corresponding to a rectangular area (window) which is a part of the liquid crystal display panel from an external device, and position information on which the display data is to be displayed on the liquid crystal display panel. A display control circuit for receiving a display for receiving a control parameter including an enlargement ratio of display data, and a capacity for storing image data for at least one screen displayed on the liquid crystal display panel. Storage means for storing the image data in correspondence with the position and the storage position. The display control circuit converts the display data into image data to be output to the liquid crystal display panel according to the control parameter, and outputs the image data in correspondence with the display position on the liquid crystal display panel corresponding to the storage position of the storage means. Data for one screen of the liquid crystal display panel including the image data stored in the means is read out and displayed on the liquid crystal display panel.
[0010]
A liquid crystal display device according to another aspect of the present invention includes a plurality of liquid crystal display panels, a display control circuit provided corresponding to each of the plurality of liquid crystal display panels, and a storage unit. One is display data corresponding to a rectangular area (window) which is a part of one display screen composed of a plurality of liquid crystal display panels from an external device, and a display screen where the display data is composed of a plurality of liquid crystal display panels. Receiving the control parameter including the position information to be displayed above and the control parameter including the enlargement ratio of the display data, determining whether the received display data should be processed based on the position information of the control parameter; As a result of the determination, display data to be processed by itself is converted into image data according to the control parameter, and display data to be processed by another display control circuit is transferred to the other display control circuit. One of the storage means has a capacity for storing display data for at least one screen displayed on one liquid crystal display panel of a plurality of liquid crystal display panels, and is provided by a corresponding display control circuit. The converted image data is stored in correspondence with the display position and the storage position in the display panel according to the control parameter, and each display control circuit includes a liquid crystal display panel including the image data stored in the corresponding storage means. The data for one screen is read out and displayed on the corresponding liquid crystal display panel.
[0011]
Further, the window display enlargement control method of the present invention includes display data corresponding to a rectangular area (window) which is a part of the liquid crystal display panel from an external device, position information on which the display data should be displayed on the liquid crystal display panel, Control parameters including the magnification of display data are received, display data is converted into image data to be output to a liquid crystal display panel according to the control parameters, and image data for at least one screen displayed on the liquid crystal display panel can be stored The storage means having the capacity stores the image data by associating the display position of the liquid crystal display panel with the storage position, and outputs the image data by associating the storage position of the storage means with the display position on the liquid crystal display panel. The data for one screen of the liquid crystal display panel including the image data stored in the means is read and displayed on the liquid crystal display panel. Configuration was.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
Hereinafter, a first mode of an embodiment of the present invention will be described in detail with reference to the drawings.
[0013]
FIG. 1 shows an example of a liquid crystal display device according to an embodiment of the present invention.
[0014]
In FIG. 1, reference numeral 200 denotes an external information processing apparatus such as a personal computer, 202 denotes a graphic controller provided in the external information processing apparatus 200, 203 denotes a system bus such as a PCI bus, and the graphic controller 202 is The external information processing apparatus 200 is connected to a processor (not shown) and a main memory (not shown) via a bus adapter (not shown). A digital interface 204 is connected to the digital interface 205 of the liquid crystal display device 201 via the external bus 206.
[0015]
1 is a vertical synchronizing signal, 2 is a horizontal synchronizing signal, 3 is a data valid signal, 4 is display data, 5 is a synchronizing clock, vertical synchronizing signal 1 is a signal of one display cycle, and horizontal synchronizing signal 2 is one horizontal cycle The data valid signal 3 is a signal indicating a period during which the display data 4 is valid, and is all input in synchronization with the synchronous clock 5. In this embodiment, these display data are conventionally divided into two types: when one screen is transferred in a raster scan format (conventional mode) and when only the display update portion is transferred in packets (packet mode). This will be described below.
[0016]
Reference numeral 6 denotes communication data, and reference numeral 7 denotes a communication clock, which is bidirectional communication data and a synchronous clock for transferring information such as a display data mode from the host side or transferring display resolution and data transfer error information from the display side. . In the present embodiment, the communication data 6 and the communication clock 7 will be described below as being in the DDC (Display Data Channel) format.
[0017]
8 is a display control unit, 9 is a data line driving signal, 10 is a scanning line driving signal, 11 is a storage / read command signal, 12 is a storage / read address, 13 is stored data, 14 is screen storage means, 15 is The display control unit 8 determines whether the display data 4 is the conventional mode or the packet mode. In the conventional mode, the display control unit 8 converts the display data 4 according to the resolution of the liquid crystal panel (described later), A storage / read command signal 11, a storage / read address 12, and storage data 13 for temporarily storing at least one screen of the liquid crystal panel in the screen storage means 14 are generated. Further, the storage / read command signal 11 and the storage / read address 12 are generated so as to read the display data for one screen in accordance with the display timing of the liquid crystal panel. The screen storage means 14 stores the stored data 13 or reads the screen read data 15 according to the store / read command 11 and the store / read address. In the present embodiment, the screen storage means 14 will be described below as storing display data for one screen of the liquid crystal panel 20.
[0018]
The display control unit 8 generates a data line driving signal 9 and a scanning line driving signal 10 from the screen read data 15. This operation is the same as the conventional operation.
[0019]
In the case of the packet mode, a storage / read command signal 11 for storing in the screen storage means 14 so as to write on one screen of the liquid crystal panel according to parameters such as a display position and an enlargement ratio included in the display data 4, storage A read address 12 and stored data 13 are generated. Similarly to the conventional mode, the storage / read command signal 11 and the storage / read address 12 are generated so as to read the display data for one screen in accordance with the display timing of the liquid crystal panel. The screen storage means 14 stores the stored data 13 or reads the screen read data 15 in accordance with the store / read command 11 and the store / read address as in the conventional mode. The display control unit 8 generates a data line driving signal 9 and a scanning line driving signal 10 from the screen read data 15. This operation is also the same as in the conventional mode. Details will be described later. Reference numeral 16 denotes a data line driving means, 17 denotes a data line driving signal, 18 denotes a scanning line driving means, 19 denotes a scanning line driving signal, and 20 denotes a liquid crystal panel. The display operation on the liquid crystal panel 20 is the same as the conventional one. In the present embodiment, the liquid crystal panel 20 will be described below as having a resolution of 1280 × 1024 dots.
[0020]
FIG. 2 shows an embodiment of the internal configuration of the display control unit 8 shown in FIG.
[0021]
In FIG. 2, 21 is a parameter control unit, 22 is parameter data, 23 is a parameter address, 24 is a parameter write strobe, 25 is an enlargement control unit, 26 is a data transfer error signal, 27 is enlarged display data, and 28 is enlarged display data. Address, 29 is an enlargement control unit, 30 is a storage timing signal, 31 is liquid crystal panel display data, 32 is a liquid crystal display signal generation unit, parameter control unit 21 is an enlargement control unit 25, storage control unit 29, liquid crystal display signal Control parameters required by the generation unit 32 are output as parameter data 22 at a timing of the parameter write strobe 24 with a predetermined parameter address 23 added. The enlargement control unit 25, the storage control unit 29, and the liquid crystal display signal generation unit 32 determine from the parameter address 23 whether or not the parameter is necessary for the parameter control unit 23, and take in the parameter data 22. In this embodiment, the display data transfer mode necessary for the enlargement control unit related to the present invention will be described below as being included in this parameter. Further, the parameter control unit 21 receives the data transfer error signal 26 output when the enlargement processing unit 25 receives an error when receiving the display data 4, and transfers the data transfer error signal 26 to the host side via the communication data. The enlargement control unit 25 determines from the parameter address 23 whether it is a parameter address representing a predetermined display data transfer mode, and takes in the parameter data 22. Here, description will be made below assuming that the display data transfer mode is the packet mode when the parameter data is “1”. Next, in the conventional mode, the enlargement control unit 25 uses the vertical synchronization signal 1, the horizontal synchronization signal 2, the data valid signal 3, the display data 4, the synchronization clock 5, and the storage timing signal 30 to enlarge the display data 27, The display data address 28 is generated. In the packet mode, the enlarged display data 27 and the enlarged display data address 28 are generated from the data valid signal 3, the display data 4, the synchronous clock 5, and the storage timing signal 30. The storage control unit 29 generates the storage / read command 11 and the storage / read address 12 so as to output the liquid crystal display data 31 in accordance with the display timing of the liquid crystal panel 20, and the screen read data 15 from the screen storage unit 14. , And the storage / read command 11, the storage / read address 12, and the storage data 13 are generated to store the enlarged display data 27 at an address according to the enlarged display data address 28. In the present embodiment, the following description will be made assuming that the parameter from the parameter control unit 21 is not required. The liquid crystal display signal generation unit 32 generates data for driving the data line driving unit 16 from the liquid crystal display data 31, a data line driving signal 9 including a timing signal, and a timing signal for operating the scanning line driving unit 18. The scanning line driving signal 10 including is generated. This operation is the same as the conventional operation. Here, the following description will be given assuming that the parameter from the parameter control unit 21 is not required.
[0022]
FIG. 3 shows an embodiment of the packet mode of the data valid signal 3 and the display data 4 shown in FIG.
[0023]
In FIG. 3, 33 is a first packet, 34 is a second packet, 35 is a third packet, and the data valid signal 3 becomes valid data during the “1” period. The names are just for convenience. 36 is the head signal, 37 is the main signal, 38 is the end signal, 39 is the window ID, 40 is the main signal type, 41 is the main signal address, 42 is the window horizontal start position, 43 is the window vertical start position, and 44 is The window enlargement ratio 45 is window display data, and the signal 37 may indicate window parameters or display data. For example, the window parameter is transferred in the first packet 33, and the display data is transferred in the second packet 34 and thereafter. The head signal 36 is a signal indicating the start of a packet. In this embodiment, the window ID 39 indicating the ID of the window to which the display data belongs, and this signal indicating whether the signal 37 is the above-described parameter or display data. In the following description, it is assumed that the type 40 includes the main signal address 41 indicating the display position when the main signal is display data.
[0024]
When the signal 37 is a parameter, a window horizontal start position 42 indicating the horizontal start position of the window indicated by the window ID 39, and a window vertical start position 43 indicating the vertical start position of the window indicated by the window ID 39. In the following description, it is assumed that the window ID 39 includes a window enlargement ratio 44 indicating an enlargement ratio when the window indicated by the window ID 39 is enlarged, and that the display data includes only display data in the window indicated by the window ID 39. Here, as the window display data 45, it is conceivable to transfer all display data in the window, but if the packet length changes depending on the size of the window, the processing may become complicated. The following description assumes that display data is transferred for each 16 × 16 dot area. Further, the main signal of the first packet 33 is described as a parameter, and the main signals of the second packet 34 and the third packet 35 are described as display data.
[0025]
FIG. 4 is a diagram showing the concept of windows and packets in the present invention.
[0026]
In FIG. 4, 46 is an entire screen, 47 is a window area, 48 is a window area start position, 49 is a packet area, 50 is a packet area start position, and the entire screen 46 has a resolution of 1280 × 1024 dots in this embodiment. And the display data of the window area 47 is transferred into it. At this time, starting from the packet area 49, the display data in the window area 47 is transferred by transferring a packet of the same size 20 times. The coordinates of the window area start position 48 correspond to the window horizontal direction start position 42 and the window vertical direction start position 43 in FIG. 3, and the coordinates of the packet area start position 50 correspond to the main signal address 41 in FIG.
[0027]
FIG. 5 is a diagram illustrating an example of an internal configuration of the enlargement control unit 25 illustrated in FIG. 2.
[0028]
In FIG. 5, 51 is a parameter storage unit, 52 is a data transfer mode signal, 53 is a data enlargement ratio, 54 is a data display position, 55 is a signal separation unit, 56 is a packet mode display valid signal, and 57 is packet mode display data. , 58 are packet mode synchronization clocks, 59 is a packet mode parameter, and the parameter storage unit 51 captures the parameter data 22 according to the parameter write strobe 24 when the parameter address 23 is an address indicating the transfer mode of the display data. The transfer mode signal 52 is output.
[0029]
When the data transfer mode signal 52 is “1” indicating the packet mode, the signal separation unit 55 separates the head signal, the end signal, and the signal, and outputs a packet mode display valid signal 56, packet mode display data 57, A packet mode synchronization clock 58 is generated, and control parameters such as a head signal, a window enlargement ratio and a window display start position included in this signal are output as packet mode parameters 59.
[0030]
When a reception error occurs, a transfer error signal 26 is output. The parameter storage unit 51 stores the packet mode parameter 59 and outputs it as a data expansion rate 53 and a data display position 54. Reference numeral 60 denotes a data expansion processing unit. When the data transfer mode signal 52 is “0” indicating the conventional mode, the vertical synchronization signal 1, horizontal synchronization signal 2, data valid signal 3, display data 4, and synchronization clock 5 are used. When the enlarged display data 27 is generated and the data transfer mode signal 52 is “1” indicating the packet mode, the enlarged display data 27 is obtained from the packet mode display valid signal 56, the packet mode display data 57, and the packet mode synchronization clock 58. Generate. Reference numeral 61 denotes an address processing unit. When the data transfer mode signal 52 is “0” indicating the conventional mode, the enlarged display data address 28 is generated from the vertical synchronizing signal 1, the horizontal synchronizing signal 2, and the data valid signal 3, When the data transfer mode signal 52 is “1” indicating the packet mode, the enlarged display data address 28 is generated from the data enlargement ratio 53 and the data display position 54.
[0031]
FIG. 6 is a diagram showing an example of details of the packet data separation operation of the signal separation unit 55.
[0032]
In FIG. 6, since this signal is a parameter for the first packet 33, the packet mode display data 57 and the packet mode display valid signal 56 are not valid. Since this signal is the window display data 45 in the second packet 34 and the third packet 35, the packet mode display data 57 and the packet mode display valid signal 56 are validated only in that portion. At this time, the head signal 36 and the end signal 38 are not valid.
[0033]
FIG. 7 is a diagram illustrating an example of the relationship between the read data 15 and the display data 4 to the stored display data 13.
[0034]
In FIG. 7, 62 is the first line read data, 63 is the first line blanking period, 64 is the second line read data, and 65 is the second line blanking period, and according to the display timing of the conventional liquid crystal panel. This is the read data and blanking period corresponding to the raster scan line by line. Reference numeral 66 denotes fourth packet data, and reference numeral 67 denotes fifth packet data, which is packet data subsequent to the first packet data 33, the second packet data 34, and the third packet data shown in FIG. In the present embodiment, the fourth packet data 66 and the fifth packet data 67 will be described below assuming that this signal is display data, similarly to the second packet data 34 and the third packet data 35.
[0035]
68 is the second packet display data, 69 is the third packet display data, 70 is the fourth packet display data, and 71 is the fifth packet display data. The second packet data 34, the third packet data 35, and the fourth packet, respectively. This corresponds to the main signal portion of the data 66 and the fifth packet data 67. 72 is the second packet enlarged display data, 73 is the third packet enlarged display data, 74 is the fourth packet enlarged display data, and 75 is the fifth packet enlarged display data. The second packet display data 68 and the third packet display, respectively. Data 69, fourth packet display data 70, and fifth packet display data 71 are expanded data. 76 is the second packet storage data, 77 is the third packet storage data, 78 is the fourth packet storage data, and 79 is the fifth packet storage data, and the second packet expansion display data 72 and the third packet expansion display data 73, respectively. The fourth packet enlarged display data 74 and the fifth packet enlarged display data 75 are assigned to the first line return period 63 and the second line return period 65 corresponding to the idle time of the read operation. In the present embodiment, the following description will be given on the assumption that the write operation is performed in the idle time, that is, in the blanking period with priority on the read operation.
[0036]
FIG. 8 is a diagram showing a series of enlargement operations as a screen image.
[0037]
In FIG. 8, 80 is the original full screen, 81 is the original window screen, and 82 is the window display size. The host side displays the original window screen 81 on the original screen 80, and the position and size of the window display size 82. Trying to display with. Reference numeral 83 denotes a window transfer screen, 84 denotes an enlarged window screen, the window transfer screen 83 is a reception screen of the enlargement control unit 25, and the enlargement window screen 84 is an output screen of the enlargement control unit 25. Reference numeral 85 denotes a storage full screen, and 86 denotes a storage window screen. The storage full screen 85 is the same as the original full screen on the screen storage means 14, and the storage window screen 86 is a screen storage means. 14 is written on. Reference numeral 87 denotes a liquid crystal display full screen. The full screen 85 stored on the screen storage means 14 is sequentially read and displayed together with the storage window screen 86.
[0038]
Hereinafter, packet data expansion processing according to the present embodiment will be described with reference to FIGS.
[0039]
First, the flow of data processing will be described with reference to FIGS.
[0040]
In FIG. 1, the display control unit 8 determines whether the display data 4 is a conventional raster scan method or a certain area on the screen from the display data mode included in the communication data 7 sent in synchronization with the communication clock 7. The display data processing is performed according to the mode, and the storage display data 13 is stored in the screen storage unit 14. Also, in accordance with the display timing of the liquid crystal panel 20, display data for one screen is read from the screen storage means, and a data line driving signal 9 and a scanning line driving signal 10 are output. Details will be described later. The screen storage means 14 has a capacity of at least one screen of the liquid crystal panel 20 and generally uses a memory means called SDRM (Synchronous Dynamic Random Access Memory). Since the data line driving unit 16, the scanning line driving unit 18, and the liquid crystal panel 20 may be those that have already been widely used, the details are omitted.
[0041]
An outline of the operation of the display control unit 8 shown in FIG. 1 will be described with reference to FIG.
[0042]
In FIG. 2, the parameter control unit 21 transfers display data necessary for the enlargement control unit 25 as conventional raster scan data from the control data transferred via the communication data 6 and the communication clock 7 from the host side. Or a data transfer parameter indicating whether or not only the data of the portion whose display is to be updated is transferred as packet data, and the enlargement ratio parameter required by the enlargement control unit 25 is determined in advance from the control parameters stored in advance. The parameter address 22 is added and output as parameter data 23 in synchronization with the parameter write strobe 24. When the parameter address 22 is a data transfer mode or an address indicating an enlargement ratio, the enlargement control unit 25 takes in the parameter data 23, that is, the parameters of the data transfer mode and the enlargement ratio, according to the timing of the parameter write strobe 24. Details will be described later.
[0043]
Next, the enlargement control unit 25 selects the enlarged display data address 27, the enlargement from the vertical synchronization signal 1, the horizontal synchronization signal 2, the data valid signal 3, the display data 4, and the synchronization clock 5 in accordance with the fetched data transfer parameter and enlargement ratio. Display data 28 is generated. The output timing follows the storage timing signal 30. Details will be described later. The storage control unit 29 outputs a storage / read command 11 for reading the data in the screen storage means 14 as a read command according to the display timing of the liquid crystal panel 20, and also outputs a storage / read address 12. The read storage read data 15 is output as liquid crystal display data 31. Further, the storage timing signal 30 is output so that the enlarged display data is written to the screen storage unit 14 at a timing other than the readout timing, and the storage / read command 11 is stored from the enlarged display data address 27 and the enlarged display address 28 output accordingly. It is generated as a command, and a storage read address 12 and storage data 13 are also generated. The liquid crystal display signal generation unit 32 generates the data line driving signal 9 and the scanning line driving signal 10 from the liquid crystal display data 31 as in the conventional case.
[0044]
Details of the display data 4 when the display data transfer mode is the packet mode will be described with reference to FIGS.
[0045]
In FIG. 3, the data valid signal 3 indicates that the display data 4 is in a valid period “1”. In the conventional mode, only the display data is input when the data valid signal 3 is “1”, whereas in the packet mode, the display data is transferred and the display data is enlarged or displayed. Display control parameters such as position may be transferred. In the first packet data 33, the display control parameter is transferred before the window display data is transferred, and the subsequent second packet data 34, the third packet data 35, and the data in the window area are displayed on the actual liquid crystal panel. Transfer is performed in 16 × 16 dot areas. In the period when the window display data valid signal 3 is “1”, a head signal 36 and an end signal 38 are added in addition to the main signal 37 which is display data or a display control parameter. The head signal 36 includes the ID of the window to which the display data belongs, the main signal type 40 indicating whether the main signal 37 transferred next to the head signal 36 is display data or a display control parameter, and the main signal 37. Is a main signal address 41 indicating the display position of the display data. The main signal address 41 may be position information that can be specified at any position on the whole screen 46 or may be position information that can specify the position specified by the window ID. Of course, the latter is more advantageous for shortening the length. The end signal 38 is a parity bit for error detection.
[0046]
In the case of display data, this signal 37 is RGB 8-bit window display data 45 in an area corresponding to 16 × 16 dots on an actual liquid crystal panel. In the case of display control parameters, this signal 37 is the horizontal direction of the window area. The window horizontal start position 42, which is the start position address, the window vertical start position 43, which is the vertical start position address, and the window enlargement ratio 44 which is the enlargement ratio at which the host wants to enlarge the window area.
[0047]
In FIG. 4, when the area on the entire screen 46 where the host wants to update the display data is the window area 47, the display control parameter is that the upper left corner of the area is the horizontal window start position 42 in FIG. 3 and the vertical window start. At the position 43, together with the window enlargement ratio 44, the packet before the display data is transferred is transferred separately from the display data. The display data in the window area 47 is transferred for each packet area 49 in units of 16 × 16 dots.
[0048]
In this embodiment, the window area 47 is described as one. However, even when this area increases, it is possible to cope by increasing the types of window IDs 39 included in the head signal 36 for identification. is there. In addition, parameters other than the window display data 45 may be the same for every 8 bits of RGB, and error detection may be performed such that an error occurs if they are different. It is also possible to shorten the length. Furthermore, although the packet area is a rectangular area of 16 × 16 dots, line transfer may be performed such that the window area is raster scanned.
[0049]
Details of the packet data and the enlargement processing operation of the enlargement processing unit 25 will be described with reference to FIGS.
[0050]
In FIG. 5, the main signal separation unit 55 extracts the main signal 37 portion shown in FIG. 3 from the start position of the data valid signal 3, and becomes “1” only during the period of the main signal 37 as shown in FIG. A packet mode display valid signal 56 is generated, and only the portion of this signal 37 is set as packet mode display data 57 and output in synchronization with the packet mode display data synchronization clock 58. Therefore, as shown in FIG. 6, the packet mode display data valid signal 56 is a signal that becomes “1” only in the window display data 45 of the second packet data 34 and the third packet data 35. Further, the signal separation unit 55 uses the parity bit of the end signal 38 and outputs the transfer error signal 26 so as to be “1” in the case of an error. Further, the display control parameter included in the main signal 37 of the first packet data 33 and the head signal 36 included in each packet are extracted and output as packet mode parameter data 59. The parameter storage unit 51 receives the packet mode parameter data 59 and outputs it as a data expansion rate 53 and a data display position 54. Since the type of the packet mode parameter data is determined by the position from the start position of the data valid signal 3, it can be discriminated by timing. Further, it is determined from the parameter address 22 whether or not the parameter data 23 is an address indicating a data transfer mode necessary for enlargement control, and is taken in at the timing of the parameter write strobe 24 and output as a data transfer mode signal 52. Here, the parameters necessary for the control from the host side are only the data transfer mode, but even when there are other necessary parameters, it can be dealt with by increasing the types of parameter addresses. When the data transfer mode signal 52 is “0” indicating the conventional mode, the data enlargement unit 60 performs the same enlargement process as before, and performs the vertical synchronization signal 1, horizontal synchronization signal 2, data valid signal 3. The enlarged display data 27 is generated from the display data 4 and the synchronous clock 5, and when the packet mode is “1”, the enlargement process according to the data enlargement rate 53 is performed, the packet mode display data valid signal 56, the packet mode display is performed. The enlarged display data 27 is generated from the data 57 and the packet mode display data synchronization clock 58. When the data transfer mode signal 52 is “0” indicating the conventional mode, the address processing unit 61 stores all data for one screen in the screen storage unit 14 from the top. An enlarged display data address 28 is generated from the signal 2 and the data valid signal 3, and when the packet mode is “1”, the data display position is stored so that only the display data of the area transferred to the screen storage unit 14 is stored. In 54, the address increase corresponding to the data expansion rate 53 is calculated, and an enlarged display data address 28 is generated and output to the storage control unit 28.
[0051]
The timing of the above enlargement process will be described with reference to FIG.
[0052]
In FIG. 7, the read data 15 is the first line read data 62, the first line blanking period 63, the second line read data 64, the second line for each line in accordance with the raster scan timing of the liquid crystal panel 20. The read data 65 and reading according to a certain cycle are shown. The display data 4 indicates that the fourth packet data 66 and the fifth packet data 66 are input following the first packet data 33, the second packet data 34, and the third packet data 35 shown in FIG. Yes. With respect to the first to fifth packet data, the packet mode display data 57 is valid only for the window display data 45 shown in FIG. 3, so nothing from the first packet data 33 to which display control parameters are transferred. The second packet display data 68, the third packet display data 69, the fourth packet display data 70, and the fifth packet display data 71, which are window display data portions in the second to fifth packet data, are transferred without being transferred. . The enlarged display data 28 enlarges the second to fifth packet display data in accordance with the window enlargement ratio transferred in the first packet data, so that the second packet enlarged display data 72, the third packet enlarged display data 73, and the fourth As shown in the packet enlarged display data 74 and the fifth packet enlarged display data 75, the data period is long. Since the display on the liquid crystal panel 20 is a raster scan method, the stored display data 13 is preferentially read out data 15, and the first line blanking period 63 and the second line blanking period are the blanking periods. In 65, the second packet storage data 76, the third packet storage data 77, the fourth packet storage data 78, and the fifth packet storage data 79 are transferred. Therefore, it is desirable that the storage control unit 29 shown in FIG. 2 has storage means for several lines. However, by informing the host of the read blanking period, data transfer is performed in accordance with the read blanking period. Alternatively, if the data transfer from the host side hits the read period, a retransfer may be requested by returning an error signal.
[0053]
The enlargement process will be described using a screen image with reference to FIG.
[0054]
In FIG. 8, the conventional mode is a raster scan method in which the display data of the original full screen 80 is transferred at a constant cycle for each line, and the packet method uses the original window screen 81 as an area where the host side wants to update the display data. Only the display data in this area is further subdivided into 16 × 16 dot areas and transferred in a format with display control parameters added. At this time, the host side adds an enlargement ratio for enlarging the original window screen 81 to the window display size 82. Therefore, the window transfer screen 83 has an original size and becomes an enlarged window screen 84 by the enlargement process. The entire storage screen 85 needs to be written at the initial start-up, but after that, only the updated portion is written, and therefore, here, only the enlarged window screen 85 is written as the storage window screen 86. . The liquid crystal panel display indicates that the storage full screen 85 including the storage window screen 86 is read out and the liquid crystal display full screen 87 in a form in which the enlarged window screen is pasted is displayed.
[0055]
This completes the transfer, enlargement, and display of the window area.
[0056]
(Embodiment 2)
A second embodiment of the present invention will be described in detail with reference to the drawings. The same reference numerals as those in the first embodiment indicate that the configuration and operation are the same.
[0057]
FIG. 9 shows an example of a liquid crystal display device according to an embodiment of the present invention.
[0058]
In FIG. 9, 3 is a data valid signal, 4 is display data, 5 is a synchronous clock, 6 is communication data, and 7 is a communication clock, which are the same as those in the first embodiment. Only the packet mode will be described without dealing with the conventional mode. Reference numeral 88 denotes a first liquid crystal display module, 89 denotes a second liquid crystal display module, 90 denotes a third liquid crystal display module, and 91 denotes a fourth liquid crystal display module. The four liquid crystal display modules constitute one screen. In the present embodiment, the first to fourth liquid crystal display modules 88 to 91 all have a resolution of 1280 × 1024 dots, that is, four modules constitute a 2560 × 2048 dot screen. Is called “multi-panel configuration” and will be described below.
[0059]
92 is the first second inter-module communication data, 93 is the first second inter-module communication clock, 94 is the second third inter-module communication data, 95 is the second third inter-module communication clock, 96 is the third fourth The inter-module communication data 97 is a third and fourth inter-module communication clock, and is a signal in the same format as the communication data 6 and the communication clock 7. The first module 88 to the second liquid crystal module 89, the second module 89 to the third liquid crystal module 90, and the third module 90, respectively, by the first second inter-module communication data 92, the first second inter-module communication clock 93, and the like. To the fourth liquid crystal module 91 is assigned a module ID for identifying the module. The modules 88 and 89 include communication means for transferring the first and second inter-module communication data 92 and the first and second inter-module communication clock 92. Each module is provided with a communication means for transferring communication data and a communication clock.
[0060]
Reference numeral 98 denotes a second third and fourth module data valid signal, 99 denotes second and third and fourth module display data, 100 denotes a second and third and fourth module synchronous clock, and the first liquid crystal display module 88 displays the display data 4 2nd, 3rd, 4th module data valid signal so that the display data is transferred to the next liquid crystal display module without processing. 98, the second third fourth module display data 99, and the second third fourth module synchronous clock 100. 101 is the third fourth module data valid signal, 102 is the third fourth module display data, 103 is the third fourth module synchronous clock, and the second crystal display module 89 is the second third fourth module display. The third and fourth module data valid signals are used to determine and process whether the data 99 is to be displayed on its own panel, and to transfer the display data to the next liquid crystal display module without processing. 101, third and fourth module display data 102, and third and fourth module synchronous clock 103 are output. 104 is a fourth module data valid signal, 105 is fourth module display data, 106 is a fourth module synchronization clock, and the third liquid crystal display module 90 displays the third fourth module display data 102 on its own panel. The fourth module data valid signal 104, the fourth module display data 105, the fourth module data valid signal 104, the fourth module display data 105, the fourth module data valid signal 104, the fourth module display data 105, and the fourth module display data 105 are transferred to the next liquid crystal display module without processing. Output as module synchronous clock 106.
[0061]
FIG. 10 shows an example of the internal configuration of the first liquid crystal display module 88 shown in FIG. The second to third liquid crystal display modules 89 to 91 have the same configuration.
[0062]
In FIG. 10, reference numeral 106 denotes a multi-panel display control unit, which is a module ID assigned via the communication data 6 and the first and second inter-module communication data 92 and where each ID is 2560 × 2048 dots. In accordance with information indicating the following (hereinafter referred to as sub-panel information) and the display position parameter added to the display data 4, it is determined whether or not the display data 4 is data to be displayed on its own panel. An enlargement process similar to that of the first embodiment is performed. If it is not the data of its own panel, the second and third and fourth module data valid signal 98, the second and third and fourth module display data 99, and the second and third and fourth module synchronous clock 100 are output without performing the enlargement process. To do. In addition, the screen storage unit 14, the data line driving unit 16, the scanning line driving unit 18, and the liquid crystal panel 20 operate in the same manner as in the first embodiment.
[0063]
FIG. 11 shows an example of the internal configuration of the multi-panel display controller 106 shown in FIG.
[0064]
In FIG. 11, 107 is a multi-panel parameter control unit, 108 is a multi-panel enlargement control unit, and the multi-panel parameter control unit 107 requires the multi-panel enlargement control unit 108, the storage control unit 29, and the liquid crystal display signal generation unit 32. The control parameter is output as parameter data 22 at the timing of the parameter write strobe 24 with a predetermined parameter address 23 added. The multi-panel enlargement control unit 108 determines from the parameter address 23 whether or not the parameter is necessary, and takes in the parameter data 22. In the present embodiment, description will be made below assuming that the parameter address 23 includes sub-panel information indicating the position in the multi-panel necessary for the enlargement control unit related to the present invention.
[0065]
The multi-panel enlargement control unit 108 determines from the parameter address 23 whether it is a parameter address representing predetermined sub-panel information, and takes in the parameter data 22. Next, when the display data 4 is data to be displayed on its own panel from the sub-panel information, it is enlarged from the data valid signal 3, the display data 4, the synchronous clock 5, and the storage timing signal 30 as in the first embodiment. Display data 27 and enlarged display data address 28 are generated. If the data is not to be displayed on its own panel, the second third and fourth module data valid signal 98, the second and third and fourth module data valid signal 99, and the second and third and fourth module data valid signal 100 are output. . In addition, the storage control unit 29 and the liquid crystal display signal generation unit 32 operate in the same manner as in the first embodiment.
[0066]
FIG. 12 is a diagram illustrating an example of an internal configuration of the multi-panel enlargement control unit 108 illustrated in FIG. 11.
[0067]
In FIG. 12, 109 is a multi-panel parameter storage unit, 110 is a sub-panel information signal, 111 is a multi-panel main signal separation unit, and the multi-panel parameter storage unit 109 has a parameter when the parameter address 23 is an address indicating sub-panel information. Data 22 is captured according to parameter write strobe 24 and output as sub-panel information signal 110. In this embodiment, the sub-panel information signal 110 will be described below as the coordinates of the start position of the display position with respect to the module ID. The multi-panel main signal separation unit 111 determines whether or not the display data 4 is data to be displayed on its own panel from the sub-panel information signal 110 and the display control parameter included in the display data 4, and the data to be displayed. In this case, as in the operation of the first embodiment, the head signal, the end signal, and this signal are separated, and the packet mode display valid signal 56, the packet mode display data 57, and the packet mode synchronization clock 58 are generated. If the data is not to be displayed, the second third and fourth module data valid signal 98, the second and third and fourth module data valid signal 99, and the second and third and fourth module data valid signal 100 are output. In addition, the data enlargement processing unit 60 and the address processing unit 61 are the same as those in the first embodiment.
[0068]
FIG. 13 is a diagram showing the concept of enlarging and displaying the window area on the multi-panel.
[0069]
In FIG. 13, 112 is the first screen, 113 is the second screen, 114 is the third screen, 115 is the fourth screen, 116 is the window area, 117 is the enlarged display area, and the first to fourth screens 112 to 115 are shown. Are images of 1280 × 1024 dots, which are images viewed from the host side, in which the data of the window region 116 is enlarged to an area of 2560 × 2048 dots in total, and displayed in the enlarged display area 117. 118 is the first screen area data, 119 is the second screen area data, 120 is the third screen area data, 121 is the fourth screen area data, and from the screen to which the enlarged area 117 when the window area 116 is enlarged, The window area before enlargement is divided. 122 is a first liquid crystal panel display, 123 is a second liquid crystal panel display, 124 is a third liquid crystal panel display, 125 is a fourth liquid crystal panel display, 126 is a first panel window enlarged display, and 127 is a second panel window enlarged display, 128 is a third panel window enlarged display, and 129 is a fourth panel window enlarged display. The first to fourth screens are displayed on the multi-panel which combines the first to fourth liquid crystal panel displays 122 to 125 into one screen. The area data 118 to 121 are respectively enlarged to form first to fourth panel window displays 126 to 129.
[0070]
The operation for enlarging and displaying the window area on the multi-panel in the present embodiment will be described below with reference to FIGS.
[0071]
In FIG. 9, first, the first liquid crystal display module 88 notifies the second liquid crystal display module 89 that the module ID is “1” via the first second inter-module communication data 92. Thereafter, the second liquid crystal display module 89 informs the third liquid crystal display module 90 that the module ID is “2” via the second third inter-module communication data 94, and the third liquid crystal display module 90 The module ID “3” is notified to the fourth liquid crystal display module 91 via the third and fourth inter-module communication data 96. All module IDs are transferred to the host side via each communication data, and the host side has 1280 × 1024 dots to be displayed in the entire 2560 × 2048 dot screen for each module ID. The area is transferred through the communication data 6 as sub-panel information. As described above, each of the first to fourth liquid crystal display modules 88 to 91 can determine display data to be displayed in the display data 4.
[0072]
Next, the first liquid crystal display module 88 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be displayed, the display operation is performed by itself in accordance with the data valid signal 3, the display data 4, and the synchronous clock 5. If the data is not to be displayed, the second, third and fourth data valid signals 98, 2 3rd 4th display data 99 and 2nd 3rd 4th synchronous clock 100 are output. Similarly, the second liquid crystal display module 89 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be displayed, the display operation is performed by itself according to the second, third, fourth data valid signal 98, the second, third, fourth display data 99, and the second, third, fourth synchronous clock 100. If it is not power data, the third fourth data valid signal 101, the third fourth display data 102, and the third fourth synchronous clock 103 are output. The third liquid crystal display module 90 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4 and displays it. If the data is to be displayed, the display operation is performed by itself according to the third fourth data valid signal 101, the third fourth display data 102, and the third fourth synchronization clock 103. If the data is not to be displayed, the fourth data The valid signal 104, the fourth display data 105, and the fourth synchronous clock 106 are output. The fourth liquid crystal display module 91 performs a display operation according to the third fourth data valid signal 101, the third fourth display data 102, and the third fourth synchronous clock 103.
[0073]
Details of the operation of the first liquid crystal display module 88 will be described with reference to FIGS. The operations of the second to fourth liquid crystal display modules 89 to 91 are the same.
[0074]
In FIG. 10, the multi-panel display control unit 106 indicates that its own module ID is “1” to the host side via the communication data 6, and displays the second liquid crystal display via the first second inter-module communication data 92. Output each to the module. Accordingly, the module IDs are sequentially determined as “2”, “3”, and “4” after the second liquid crystal module 89. After all the module IDs are assigned, the sub-panel information is transferred from the host side via the communication data 6 so that the module ID “1” displays the upper left quarter screen of the entire 2560 × 2048 dots. The multi-panel display control unit 106 determines whether the display data 4 is its own display data from the sub-panel information and the window display position information added to the display data 4, and if it is its own display data, The enlargement process similar to that of the first embodiment is performed, and the screen storage unit 14, the data line driving unit 16, the scanning line driving unit 18, and the liquid crystal panel 20 are also operated in the same manner as in the first embodiment to perform display. If it is not its own display data, it is output as the second third fourth data valid signal 98, the second third fourth display data 99, and the second third fourth synchronous clock 100.
[0075]
In FIG. 11, as described above, the multi-panel parameter control unit 107 indicates that its own module ID is “1” to the host side via the communication data 6, and the first second inter-module communication data 92. To the second liquid crystal display module. Next, sub-panel information transferred via the communication data 6 from the host side and the communication clock 7 is added with a predetermined parameter address 22 and output in synchronization with the parameter write strobe 24. When the parameter address 22 is an address indicating sub-panel information, the multi-panel enlargement control unit 108 captures the parameter data 23, that is, the parameters of the sub-panel information according to the timing of the parameter write strobe 24. Details will be described later. Next, if the display data 4 is data to be displayed by itself based on the captured sub-panel information and the window display position information added to the display data 4, the data valid signal 3, the display data 4, and the synchronous clock 5 are expanded. When the display data address 27 and the enlarged display data 28 are generated and are not the data to be displayed, the second, third, fourth, data valid signal 98, second, third, third data valid signal 3, display data 4, and synchronous clock 5 are used. The fourth display data 99 and the second, third, and fourth synchronous clocks 100 are generated. Details will be described later. In addition, the storage control unit 29 and the liquid crystal display signal generation unit 32 operate in the same manner as in the first embodiment.
[0076]
In FIG. 12, the multi-parameter storage unit 109 determines whether the parameter data 23 is an address indicating sub-panel information for determining whether the display data 4 is data to be displayed by itself from the parameter data address 22. The data is captured at the timing of the write strobe 24 and output as the sub-panel information signal 110. As in the first embodiment, the multi-panel main signal separation unit 111 extracts the display control parameter portion from the display data 4, and the display data 4 itself is extracted from the window display position information included therein and the sub-panel information signal 110. In the same manner as in the first embodiment, the packet mode display valid signal 56 and the packet mode display data 57 are output in synchronization with the packet mode display data synchronization clock 58. To do. If it is not its own display data, the second third fourth data valid signal 98, the second third fourth display data 99, and the second third fourth synchronous clock 100 are generated. At this time, the display data displayed on the first liquid crystal display module 88 and the data valid signal portion may be output as they are, or may be masked and not output. In any case, each liquid crystal display module processes only display data related to itself from sub-panel information and window display position information. In addition, the data enlargement processing unit 60 and the address processing unit 61 are the same as those in the first embodiment.
[0077]
Details of the sub-panel information and the window display position information will be described with reference to FIG.
[0078]
In FIG. 13, since the window area 116 is on the first screen 112, display data is processed only by the first liquid crystal display module when displayed in this size.
[0079]
However, when the display as shown in the enlarged display area 117 is performed, since the data after enlargement spans each screen, it is determined which screen the display data in the window area 116 belongs to from the enlargement ratio. For each screen to which the screen belongs, a determination is made so that the area divided into the first to fourth screen area data 118 to 121 is processed by each liquid crystal display module. The calculation of which screen will belong after the enlargement is made by calculating the window horizontal start position 42 and window vertical start position, the window enlargement ratio 44 and the liquid crystal display panel of each liquid crystal display module sent from the external information processing apparatus. Based on the display area.
[0080]
Accordingly, the first screen area data 118 is processed by the first liquid crystal display module 88 and the first panel window enlarged display 126, and the second screen area data 119 is processed by the second liquid crystal display module 89 and the second panel window enlarged display 127, The third screen area data 120 is processed by the third liquid crystal display module 90 to be the third panel window enlarged display 128, and the fourth screen area data 121 is processed by the fourth wave crystal display module 91 to be the fourth panel window enlarged display 129. On the 2560 × 2048 dot multi-panel composed of the first to fourth liquid crystal panel displays 122 to 125, it is possible to perform an enlarged window display across the liquid crystal panel.
[0081]
(Embodiment 3)
A third mode of the embodiment of the present invention will be described in detail with reference to the drawings. The same reference numerals in the drawings as those in the first and second embodiments indicate that the configuration and operation are the same.
[0082]
FIG. 14 shows an example of a liquid crystal display device according to an embodiment of the present invention.
[0083]
In FIG. 14, 3 is a data valid signal, 4 is display data, 5 is a synchronous clock, 6 is communication data, and 7 is a communication clock. Similar to the second embodiment, the conventional mode is not handled, and only the packet mode will be described. . 130 is a first panel display control unit, 131 is a first panel data line driving signal, 132 is a first panel scanning line driving signal, 133 is a first panel storing / reading command signal, and 134 is a first panel storing / reading signal. Address, 135 is the first panel storage data, 136 is the second third fourth panel data valid signal, 137 is the second third fourth panel display data, 138 is the second third fourth panel synchronization clock, 139 is the first 1 is the first inter-panel communication data, 140 is the first second inter-panel communication clock, 141 is the first panel screen storage means, 142 is the first panel screen read data, and the first panel display control unit 130 is the embodiment. 2, the panel ID assigned via the communication data 6 and the first second inter-panel communication data 139 and the information indicating where each ID is in the entire screen. (Hereinafter referred to as sub-panel information), it is determined whether or not the display data 4 is data to be displayed on its own panel (first panel) according to the display position parameter added to the display data 4. Generates the first panel storage / read command 133, the first panel storage / read address, and the first panel storage data 135 by the enlargement process similar to the first embodiment. If it is not the data of its own panel, the enlargement process is not performed, and the second, third, fourth panel data valid signal 136, the second, third, fourth panel display data 137, and the second, third, fourth panel synchronization clock 138 are output. To do. Similarly to the conventional case, the first panel data line driving signal 131 and the first panel data line driving signal 132 are generated. The first panel screen storage means 141 is the same as in the first and second embodiments. Reference numeral 143 denotes a first data line driving means, 144 denotes a first data line driving signal, 145 denotes a first scanning line driving means, and 146 denotes a first scanning line driving signal, which are applied to a liquid crystal panel, which will be described later, as in the prior art. A voltage is generated to display the first panel portion. 147 is a second panel display control unit, 148 is a second panel data line driving signal, 149 is a second panel scanning line driving signal, 150 is a second panel storing / reading command signal, and 151 is a second panel storing / reading signal. Address, 152 is data stored in the second panel, 153 is the third fourth panel data valid signal, 154 is the third fourth panel display data, 155 is the third fourth panel synchronization clock, and 156 is the second third panel communication Data, 157 is the second third panel communication clock, 158 is the second panel screen storage means, 159 is the second panel screen read data, and the second panel display control unit 147 is connected to the first panel display control unit 130. By the same operation, the second panel data line drive signal 148, the second panel data line drive signal 149, the second panel store / read command 150, the second Nell storage and read address 151, the second panel storage data 152, third fourth panel data valid signal 153, third fourth panel display data 154, and outputs a third fourth panel synchronous clock 155. The second panel screen storage means 158 is the same as in the first and second embodiments. Reference numeral 160 denotes second data line driving means, 161 denotes a second data line driving signal, 162 denotes second scanning line driving means, and 163 denotes a second scanning line driving signal, which are applied to a liquid crystal panel, which will be described later, as in the prior art. A voltage is generated to display the second panel portion. 164 is a third panel display control unit, 165 is a third panel data line driving signal, 166 is a third panel scanning line driving signal, 167 is a third panel storing / reading command signal, and 168 is a third panel storing / reading signal. Address, 169 is the third panel storage data, 170 is the fourth panel data valid signal, 171 is the fourth panel display data, 172 is the fourth panel synchronization clock, 173 is the third fourth inter-panel communication data, and 174 is the third The fourth inter-panel communication clock, 175 is the third panel screen storage means, 176 is the third panel screen read data, the third panel display control unit 164 is the first panel display control unit 130, the second panel display control unit 147, the third panel data line drive signal 165, the third panel data line drive signal 166, the third panel storage / read frame De 167, third panel storage and read address 168, the third panel storage data 169, the fourth panel data valid signal 170, a fourth panel display data 171, and outputs a fourth panel synchronous clock 172. The third panel screen storage means 175 is the same as in the first and second embodiments. Reference numeral 177 denotes third data line driving means, 178 denotes a third data line driving signal, 179 denotes third scanning line driving means, and 180 denotes a third scanning line driving signal, which are applied to a liquid crystal panel, which will be described later, as in the prior art. A voltage is generated to display the third panel portion. 181 is a fourth panel display control unit, 182 is a fourth panel data line driving signal, 183 is a fourth panel scanning line driving signal, 184 is a fourth panel storing / reading command signal, and 185 is a fourth panel storing / reading signal. Address 186 is the fourth panel storage data, 187 is the fourth panel screen storage means, 188 is the fourth panel screen read data, the fourth panel display control unit 181 is the first panel display control unit 130, the second panel The fourth panel data line drive signal 182, the fourth panel data line drive signal 183, the fourth panel store / read command 184, and the fourth panel are operated in the same manner as the display control unit 147 and the third panel display control unit 164. The storage / reading address 185 and the fourth panel storage data 186 are output. The fourth panel screen storage means 187 is the same as in the first and second embodiments. 189 is a fourth data line driving means, 190 is a fourth data line driving signal, 191 is a fourth scanning line driving means, and 192 is a fourth scanning line driving signal, which is applied to a liquid crystal panel, which will be described later, as in the prior art. A voltage is generated and the fourth panel portion is displayed. 193 is a bonded liquid crystal panel, 194 is a first panel region, 195 is a second panel region, 196 is a third panel region, and 196 is a fourth panel region. The bonded liquid crystal panel 193 is apparently a single sheet. Although it is a liquid crystal panel, it divides | segments into 4 surfaces of the 1st-4th panel area | regions 194-196, and drives each. In this embodiment, the first to fourth panel regions 194 to 196 are 1280 × 1024 dots, and therefore, the resolution of the bonded liquid crystal panel will be described below as 2560 × 2048 dots.
[0084]
The operation will be described.
[0085]
In FIG. 14, as in the second embodiment, first, the first panel display control unit 130 notifies the second panel display control unit 147 that the first panel display control unit 130 has the panel ID “1”. Inform via data 139. Thereafter, the second panel display control unit 147 notifies the third panel display control unit 164 that the module ID is “2” via the second third inter-panel communication data 156, and the third panel display control unit. 164 notifies the fourth panel display control unit 181 that the module ID is “3” via the third and fourth inter-panel communication data 173. All panel IDs are transferred to the host side via each communication data, and the host side has 1280 × 1024 dots to be displayed in the entire 2560 × 2048 dot screen for each panel ID. The area is transferred through the communication data 6 as sub-panel information. As described above, each of the first to fourth display control units 130, 147, 164, and 181 can determine the display data to be displayed in the display data 4. Next, the first panel display control unit 130 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be displayed, an enlargement process similar to that of the first embodiment is performed so that the display operation is performed by itself according to the data valid signal 3, the display data 4, and the synchronous clock 5, and the first panel data line driving A signal 131, a first panel scanning line driving signal 132, a first panel storage / read command 133, a first panel storage / read address 134, and first panel storage data 135 are generated. In addition, the first panel screen storage unit 141, the first data line driving unit 143, the scanning line driving unit 145, and the first panel region 194 also perform display by operating in the same manner as in the first embodiment. If the data is not to be displayed, the second third fourth panel data valid signal 136, the second third fourth panel display data 137, and the second third fourth panel synchronization clock 137 are output. The second panel display control unit 147 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be transmitted, the display operation is performed by itself according to the second third fourth panel data valid signal 136, the second third fourth panel display data 137, and the second third fourth panel synchronization clock 138. The same enlargement process as in the first embodiment is performed to generate the second panel data line driving signal 148, the second panel storage / read command 150, the second panel storage / read address 151, and the second panel storage data 152. The second scanning line driving signal 149 is different from the first embodiment in the connection direction of the second scanning line driving means 162 to the liquid crystal panel, so that the scanning direction of the liquid crystal panel is the same as in the first embodiment, that is, The second scanning line driving unit 162 is generated so as to scan in the direction opposite to the first scanning line driving unit 145. The second panel screen storage unit 158, the second data line driving unit 160, and the second panel area 195 perform display in the same manner as in the first embodiment. If the data is not to be displayed, the third fourth panel data valid signal 153, the third fourth panel display data 154, and the third fourth panel synchronization clock 155 are output. The third panel display control unit 164 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be processed, the display operation is performed in accordance with the third fourth panel data valid signal 153, the third fourth panel display data 154, and the third fourth panel synchronization clock 155. Enlargement processing is performed to generate a third panel storage / read command 167, a third panel storage / read address 168, and third panel storage data 169. Since the third panel data line driving signal 165 is different from the first embodiment in the connection direction of the third data line driving means 177 to the liquid crystal panel, the display data is arranged in order from the left as in the first embodiment. That is, the third data line driving unit 177 generates the data so as to arrange the data in the direction opposite to that of the first data line driving unit 143. The third scanning line driving signal 166 is different from the first embodiment in the connection direction of the third scanning line driving means 179 to the liquid crystal panel, so that the scanning direction of the liquid crystal panel is the same as in the first embodiment, that is, The third scanning line driving unit 179 is generated so as to scan in the direction opposite to the first scanning line driving unit 145. The third panel screen storage means I75 and the third panel area 196 perform display by operating in the same manner as in the first embodiment. If the data is not to be displayed, the fourth panel data valid signal 170, the fourth panel display data 171 and the fourth panel synchronization clock 172 are output. The fourth panel display control unit 181 determines whether or not the display data 4 is data to be displayed by itself from the sub-panel information described above and the window display position information added to the display data 4. In the case of data to be processed, an enlargement process similar to that in the first embodiment is performed so that the display operation is performed in accordance with the fourth panel data valid signal 170, the fourth panel display data 171, and the fourth panel synchronization clock 172. A 4-panel scanning line driving signal 153, a fourth panel storage / read command 184, a fourth panel storage / read address 185, and fourth panel storage data 186 are generated. Since the fourth panel data line driving signal 182 is different from the first embodiment in the connection direction of the fourth data line driving means 189 to the liquid crystal panel, the display data is arranged in order from the left as in the first embodiment. In other words, the fourth data line driving unit 189 generates the data so as to arrange the data in the direction opposite to that of the first data line driving unit 143. The fourth panel screen storage unit 187, the fourth scanning line driving unit 191, and the fourth panel region 197 perform display by operating in the same manner as in the first embodiment.
[0086]
Therefore, in the third embodiment, the enlargement process and the screen storage process are the same as those in the second embodiment, and only the data line driving and the scanning line driving are different.
[0087]
【The invention's effect】
The effects obtained by the invention disclosed in the present application will be briefly described as follows.
[0088]
By providing the liquid crystal display device with enlargement processing means for performing enlargement processing according to the enlargement ratio added to the display data of the area to be updated and a screen storage means for one screen, a display screen with a small resolution is displayed on the high-definition liquid crystal. In this case, high-definition and large-screen display can be performed without increasing the display data transfer rate.
[0089]
In addition, by writing the display data after enlargement processing to the screen storage means, the screen image on the screen storage means becomes the same as the display image on the liquid crystal panel, so that simple readout corresponding to the raster scan of the liquid crystal panel is possible It becomes.
[Brief description of the drawings]
FIG. 1 is a block diagram of a display device according to a first embodiment of the present invention.
2 is a block diagram illustrating an example of an internal configuration of a display control unit illustrated in FIG. 1; FIG.
FIG. 3 is a diagram illustrating an example of packet data according to the present invention.
FIG. 4 is a diagram showing an image transfer image by packet data according to the present invention.
5 is a block diagram illustrating an example of an internal configuration of an enlargement control unit illustrated in FIG. 2. FIG.
6 is a diagram illustrating an operation of the signal separation unit illustrated in FIG. 5;
7 is a diagram illustrating an operation of the data enlargement processing unit illustrated in FIG. 5;
FIG. 8 is a diagram showing a flow of image images from packet transfer to enlarged display according to the present invention.
FIG. 9 is a block diagram of a display device according to a second embodiment of the present invention.
10 is a block diagram showing an example of the internal configuration of the liquid crystal display module shown in FIG. 9. FIG.
11 is a block diagram showing an example of the internal configuration of the multi-panel display control unit shown in FIG.
12 is a block diagram showing an example of the internal configuration of the multi-panel enlargement control unit shown in FIG.
FIG. 13 is a diagram showing a concept of window enlarged display on a multi-panel in the present invention.
FIG. 14 is a block diagram of a display device according to a third embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Vertical synchronizing signal, 2 ... Horizontal synchronizing signal, 3 ... Data valid signal, 4 ... Display data, 5 ... Synchronization clock, 6 ... Communication data, 7 ... Communication clock, 8 ... Display control part, 9 ... For data line drive Signals: 10 ... Scanning line driving signals, 11 ... Storage / reading command signals, 12 ... Storage / reading addresses, 13 ... Storage data, 14 ... Screen storage means, 15 ... Screen reading data, 16 ... Data line driving means, 17 Data line drive signal 18 Scan line drive means 19 Scan line drive signal 20 Liquid crystal panel 21 Parameter control unit 22 Parameter data 23 Parameter address 24 Parameter write strobe 25 Enlarge Control unit 26 ... Data transfer error signal, 27 ... Enlarged display data, 28 ... Enlarged display data address, 29 ... Enlarged control unit, 30 ... Storage timing signal 31 ... Liquid crystal panel display data, 32 ... Liquid crystal display signal generator, 33 ... First packet, 34 ... Second packet, 35 ... Third packet, 36 ... Lead signal, 37 ... Main signal, 38 ... End signal, 39 ... Window ID, 40 ... Main signal type, 41 ... Main signal address, 42 ... Window horizontal start position, 43 ... Window vertical start position, 44 ... Window enlargement ratio, 45 ... Window display data, 46 ... Whole screen, 47 ... Window area, 48 ... Window area start position, 49 ... Packet area, 50 ... Packet area start position, 51 ... Parameter storage section, 52 ... Data transfer mode signal, 53 ... Data enlargement ratio, 54 ... Data display position, 55 ... This signal separation unit, 56 ... packet mode display valid signal, 57 ... packet mode display data, 58 ... Flat-screen mode-locked clock, 59 ... packet mode parameters.

Claims (12)

A liquid crystal display panel;
Display data corresponding to a window area which is a part of the liquid crystal display panel from an external device, position information on which the display data should be displayed on the liquid crystal display panel, and control parameters including an enlargement ratio of the display data A display control circuit for receiving;
A storage unit for storing the image data in association with a display position and a storage position of the liquid crystal display panel; and a capacity for storing at least one screen of image data displayed on the liquid crystal display panel. ,
The display data input from the external device is sent as a plurality of packet data for each data obtained by subdividing the liquid crystal display panel into predetermined areas including a plurality of vertical and horizontal dots,
The display control circuit includes:
The packet data is enlarged according to the enlargement ratio, an address corresponding to the enlargement ratio for the position information is calculated, and the enlarged packet data is stored in the storage position of the storage means corresponding to the display position on the liquid crystal display panel. Generating an address for storage, storing the enlarged packet data in a storage position of the storage means corresponding to a display position in the liquid crystal display panel;
A liquid crystal display device, wherein data for one screen of the liquid crystal display panel including the packet data stored in the storage means is read and displayed on the liquid crystal display panel. The liquid crystal display device according to claim 1.
The liquid crystal display device according to claim 1, wherein the predetermined area is obtained by subdividing the window area of the liquid crystal display panel into a plurality of vertical and horizontal dots . The liquid crystal display device according to claim 1.
The position information of the control parameter input from the external device includes a signal address that specifies a position of a predetermined area with respect to the entire screen of the liquid crystal display panel or a position of the predetermined area with respect to the window area, and the display data includes the display data A liquid crystal display device comprising: address information representing a display position to be displayed on a liquid crystal display panel in a horizontal direction and a vertical direction. The liquid crystal display device according to claim 1.
The display control circuit includes:
Wherein when storing the display data in the storage means, performs overwriting of the display data storage position only of said storage means for the display data corresponding to the display position of definitive on the liquid crystal display panel,
Wherein when reading the display data from the storage means, a liquid crystal display device in which the read display data corresponding to the entire area of the liquid crystal display panel, and outputs to the liquid crystal display panel. The liquid crystal display device according to claim 1.
The display data is serial data,
The liquid crystal display device, wherein the display control circuit expands the serial data to R, G, B parallel display data. The liquid crystal display device according to claim 1.
The display data is LVDS (low voltage differential signaling) serial data or GVIF (gigabit video interface),
The liquid crystal display device, wherein the display control circuit expands the serial data to R, G, B parallel display data.   Display data from an external device corresponding to a window area which is a part of the liquid crystal display panel, and is sent as a plurality of packet data for each data obtained by subdividing the liquid crystal display panel into predetermined areas including a plurality of vertical and horizontal dots. Receiving display data, position information on which the display data is to be displayed on the liquid crystal display panel, and a control parameter including an enlargement ratio of the display data;
  The packet data is enlarged according to the enlargement ratio, an address corresponding to the enlargement ratio for the position information is calculated, and the enlarged packet data is stored in the storage position of the storage means corresponding to the display position on the liquid crystal display panel. Generate an address to store,
  Storing the enlarged packet data in a storage position corresponding to the display position of the liquid crystal display panel of storage means having a capacity capable of storing display data for at least one screen displayed on the liquid crystal display panel;
  A window display enlargement control method in a liquid crystal display device, wherein data for one screen of the liquid crystal display panel including the packet data stored in the storage means is read and displayed on the liquid crystal display panel.   In the window display expansion control method according to claim 7,
  The window display enlargement control method, wherein the predetermined area is obtained by subdividing the window area of the liquid crystal display panel into a plurality of vertical and horizontal dots.   In the window display expansion control method according to claim 7,
  The position information of the control parameter input from the external device includes a signal address that specifies a position of a predetermined area with respect to the entire screen of the liquid crystal display panel or a position of the predetermined area with respect to the window area, and the display data includes the display data A window display enlargement control method comprising: address information representing a display position to be displayed on a liquid crystal display panel in a horizontal direction and a vertical direction.   In the window display expansion control method according to claim 7,
  When the display data is stored in the storage means, the display data is overwritten only in the storage position of the storage means corresponding to the display position of the liquid crystal display panel, and the display data is read out from the storage means. In this case, the window display enlargement control method is characterized in that display data corresponding to the entire area of the liquid crystal display panel is read and output to the liquid crystal display panel.   In the window display expansion control method according to claim 7,
  The display data is serial data,
  The window display enlargement control method, wherein the display control circuit enlarges the serial data to R, G, B parallel display data.   In the window display expansion control method according to claim 7,
  The display data is LVDS (low voltage differential signaling) serial data or GVIF (gigabit video interface),
  The window display enlargement control method, wherein the display control circuit enlarges the serial data to R, G, B parallel display data.

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