JP3863445B2 - Image display apparatus and information processing apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image display apparatus having a displacement means for displacing in each subframe a light beam from a display device for displaying an image of the sub-frame.
[0002]
[Prior art]
Conventionally, an image display device using a CRT has been widely used as an image display device, but in recent years, an image display device using a liquid crystal display element or the like has come into general use. In an image display device using a liquid crystal display element, the fineness of an image to be displayed is basically determined by the number of pixels constituting the liquid crystal display element, but the number of pixels is increased to obtain a high-definition image. As a result, the cost of the liquid crystal display element is increased, and a higher-speed signal processing circuit is required.
[0003]
Therefore, a technique for displaying a higher-definition image using a liquid crystal display element having a limited number of pixels has been developed. As such a technique, for example, Japanese Patent Application Laid-Open No. 4-63332 and Japanese Patent Application Laid-Open No. 7-36054 use a birefringent plate to shift the optical axis of light from the display element. More specifically, this technique increases the number of observed pixels by, for example, shifting the optical axis of light emitted from the liquid crystal display element in time series and sequentially shifting the apparent pixel position. It has become.
[0004]
Furthermore, these publications divide one frame into four subfields, and perform a four-point pixel shift technique for moving the apparent pixel position for each of these subfields, and a multipoint pixel shift. Is described. A similar one is also described in Japanese Patent Laid-Open No. 2001-66625.
As described above, as a display element used in the image display apparatus as described above, an LCD (liquid crystal display element) of a type that emits light polarized in a horizontal direction or a vertical direction is generally used.
[0005]
[Problems to be solved by the invention]
Some image display devices divide one frame into a plurality of subfields as described above, and perform pixel shift for moving the apparent pixel position for each subfield. However, in this image display device, when trying to display a high-definition image, it is necessary to transfer very large image data. Since this image data transfer amount is very large, there are cases where image data transfer cannot be performed to that extent.
An object of the present invention is to provide an image display apparatus that enables high-definition image display with a small amount of image data transfer.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 divides one frame into a predetermined number of subframes, stores a display element that displays an image of the subframe, and stores image data of each subframe as a subfield. An image display device comprising storage means, video signal processing means for sequentially displaying each subframe, and displacement means for displacing a light beam from a display element for displaying an image of the subframe for each subframe, The subfield of the image data of the subframe rewritten to the storage means within the time for displaying one frame is a subframe thinned out from a predetermined number .
[0007]
The invention according to claim 2 divides one frame into a predetermined number of subframes, a display element for displaying an image of the subframe, storage means for storing image data of each subframe as a subfield, and each subframe Video signal processing means for sequentially displaying, a displacement means for displacing a light beam from a display element for displaying an image of a sub-frame for each sub-frame, and a receiving means for receiving the image data from the information processing apparatus side an image display device comprising in, in time for displaying one frame, the subfields of the image data of the sub-frame is rewritten to the storage means are those which are sub frames thinned out from the predetermined number.
[0008]
The invention according to claim 3 is the image display device according to claim 2 , wherein the display of the subframe in the image display device and the reception of the image data from the information processing device are performed asynchronously .
[0009]
Memory invention is the storage means, and the memory field is divided into each sub-field, when acquiring the subfield image data of the sub-frame to be rewritten, corresponding to the subfield according to claim 4 The image display device according to claim 1, wherein the image display device is rewritten to a field.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows Embodiment 1 of the present invention. A graphic controller 2 of a host (host computer) 1 as an information processing apparatus is provided with data processing means 3 for dividing and rearranging image data. The host computer 1 is connected to an image display device 5 by an interface (I / F) unit 4, and the image display system according to the first embodiment includes the host computer 1 and the image display device 5. The image display device 5 includes a video signal processing circuit 6 and a display unit 8 that displays an image using an image shifting element. The video signal processing circuit 6 includes a memory 7 as storage means for storing image data.
[0015]
The display unit 8 is known from Japanese Patent Application Laid-Open No. 2001-66625 and the like. For example, a backlight that emits illumination light, and an LCD (LCD) as a display element that emits illumination light by emitting illumination light from the backlight. A liquid crystal display element), an image shifting element that sequentially shifts the apparent position of the image by shifting the optical axis of the pixel luminous flux emitted from the LCD in time series, and an image of the pixel that has passed through the image shifting element And an eyepiece optical system that enables observation with magnification.
[0016]
The electric circuit of the image display device 5 includes, for example, a video signal processing circuit 6 that performs signal processing including double speed processing on image data for each subframe obtained by dividing one frame into a plurality of subframes, and the video signal processing circuit 6. A driving circuit that drives the LCD based on the processed image data; and a control circuit that receives the synchronization signal and the field determination signal output from the driving circuit and drives the image shifting element in synchronization with the LCD. The position of the image is shifted for each subframe, and the image is displayed by filling the screen with pixels so that the pixel density is increased in both the horizontal and vertical directions depending on the shifted apparent pixel position.
[0017]
FIG. 2 is a diagram for explaining a method of displaying an image of one frame in the first embodiment. The host computer 1 divides one frame of image data 9 to be displayed on the image display device 5 into four subfields 1 to 4 of image data 10 to 13 by the data processing means 3 in the graphic board 2. The image data is transferred to the image display device 5 via the I / F unit 4.
[0018]
The image display device 5 stores the image data 10-13 of the subfield transferred from the host computer 1 via the I / F unit 4 after the signal processing is performed by the video signal processing circuit 6 or before the signal processing. 7, and the image data 10 to 13 of the four subfields stored in the memory 7 are used to shift the images 14 to 17 of each subfield in order for each subframe using a pixel shift element in the display unit 8. The image is displayed by displaying at a cycle. Even if the human eye divides and displays one image at a cycle shorter than a predetermined cycle, the image does not appear to be divided and displayed due to a phenomenon such as an afterimage. Looks tied.
[0019]
According to the image display device 5 of the first embodiment, image data divided and rearranged for each subfield is acquired from the host computer 1 side as an information processing device, and a plurality of subframes are obtained based on the image data. Since the images are sequentially displayed, the load of image data division rearrangement can be eliminated.
[0020]
In addition, according to the host computer 1 as the information processing apparatus of the first embodiment, data processing for dividing and rearranging image data to be used in the image display apparatus 5 for each subfield is performed. Since the image data is transferred to the image display device 5, the load of image data division rearrangement on the image display device side can be eliminated.
[0021]
Next, Embodiment 2 of the present invention will be described. In the second embodiment, in the first embodiment, the memory 7 has a capacity for storing image data of one frame or more, and the image display device 5 is transferred from the host computer 1 via the I / F unit 4. The image data 10-13 of the subfield is stored in each memory field of the memory 7 determined after the signal processing by the video signal processing circuit 6 or before the signal processing, and the four subfields stored in the memory 7 are stored. The image display is performed by displaying the images 14 to 17 of each subfield in order at a constant cycle for each subframe using the pixel shift element in the display unit 8 by the image data 10 to 13 of the field.
[0022]
At this time, the host computer 1 displays the image data of the subfields divided and rearranged by the data processing means 3 while the image display device 5 performs image display using the image data of the three subfields. Only the image data of the subfield is transferred. In other words, as shown in FIG. 3, the host computer 1 displays only one subfield image data, for example, subfield image data 10 → subfield image data, while performing image display using three subfield image data. 13 → subfield image data 12 → subfield image data 11 → subfield image data 10 are repeatedly transferred to the image display device 5 via the I / F unit 4 and transferred to other images in one frame. The image data of the three subfields is not transferred to the image display device 5.
[0023]
Then, the image display device 5 stores the memory 7 in the subfield after the signal processing by the video signal processing circuit 6 or before the signal processing with the subfield image data transferred from the host computer 1 via the I / F unit 4. The image data of the four subfields stored in the memory 7 is updated by the amount of pixels, and the image shifters 14 are used to display the images 14 to 17 of each subfield in order at a constant cycle for each subframe using a pixel shift element in the display unit 8. The image is displayed by displaying. FIG. 3 shows a display image of one cycle until all image data for one screen in the memory 7 is rewritten to new image data.
[0024]
The display unit 8 displays the images 19 to 30 in the order of the image data of each subfield. Assuming that the image 18 is displayed on the screen of the display unit 8 based on the image data in the memory 7, first, one subfield of the memory 7 is updated with the image data 10 of the subfield 1, and the image 19 is updated. The image data 10 is displayed on the display unit 8. While the images 19 to 21 are displayed, the image data 13 of the subfield 4 is transferred from the host computer 1 to the image display device 5, and the memory 7 in the image display device 5 stores the image data of the subfield 4. The rewritten portion is rewritten with the transferred image data 13.
[0025]
The images 20 and 21 are displayed by the image data of each subfield in the same frame as the image 18 stored in the memory 7. When the image 22 is displayed, the image data of the subfield 4 that has been rewritten and renewed in the memory 7 is updated, and the image 22 is displayed on the display unit 8 by this image data. Next, while the images 22 to 24 are displayed, the image data 12 of the subfield 3 is transferred from the host computer 1 to the image display device 5, and the image data of the subfield 3 of the memory 7 in the image display device 5 is transferred. The stored portion is rewritten with the transferred image data 12. In this manner, only one subfield of the memory 7 is updated with the image data of one new subfield while the image display is performed using the image data of the three subfields.
[0026]
In the second embodiment, the amount of data required for image data transfer is one-third that of the case where all the image data of one frame is transferred. The image data processed by the data processing means 3 in one cycle in the host computer 1 and sent to the image display device 5 is the image data 10 to 13 of the subframes 1 to 4 for displaying the images 19, 22, 25 and 28. 4 are necessary for image display, and other image data is not transferred to the image display device 5, so that the data processing means 3 divides and processes only the image data of the subfield to be transferred and processes the graphics. The data is transferred to the controller 2 and transferred to the image display device 5 for image display.
[0027]
According to the image display device 5 of the second embodiment, the memory 7 is provided as a storage unit having a capacity for storing image data of one frame or more, and one frame of image data from the host computer 1 as the information processing device. Since the image data obtained by thinning out the image data of a predetermined number of subframes is acquired and expanded in the memory 7, and the image data of the plurality of subframes are sequentially displayed by the image data of the plurality of subfields expanded in the memory 7. It is not necessary to acquire image data of a predetermined number of subfields thinned out of one frame of image data, and it is possible to reduce the load due to the transfer of the corresponding image data. In addition, the image data of all subfields can be stored in the storage means, so that even if image data obtained by thinning out a predetermined number of subframe image data from one frame of image data is acquired, the image data can be obtained using all the image data of one frame. Can be displayed, and a high-quality image can be displayed.
[0028]
Further, the host computer 1 as the information processing apparatus according to the second embodiment has the data processing means 3 that thins out a predetermined number of subframes from the image data of a plurality of subframes. Therefore, it is not necessary to transfer image data of a predetermined number of subfields thinned out of one frame of image data to the image display device. Can reduce the load.
[0029]
Next, a third embodiment of the present invention will be described. When the image data transfer and the image display of the image display device are synchronized, when the entire image of one frame is displayed at 60 Hz, the image display device using the pixel shift element displays the image of one frame. In order to do this, images of four subfields must be displayed, so an image of one subfield is displayed at 240 Hz, and image data transfer is also based on this cycle.
[0030]
Therefore, in the third embodiment, in the first or second embodiment, the host computer 1 is asynchronous with the image display of the image display device 5 and does not depend on the cycle of displaying the image of the image display device 5. Is transferred to the image display device 5 via the I / F unit 4. The image display device 5 performs signal processing on the image data of each subfield transferred from the host computer 1 via the I / F unit 4 by the video signal processing circuit 6 or in the memory 7 before signal processing. The subfield image data 10-13 stored in the memory 7 is used to display the images 14-17 of each subfield in order at a constant cycle every subframe using a pixel shifting element on the display unit 8. The image is displayed.
[0031]
According to the image display device 5 of the third embodiment, image display of a plurality of subframes is performed asynchronously with image data transfer from the host computer 1 side as an information processing device, and therefore image data transfer from the host computer 1 side. The image display can be performed with the image data stored in the storage means without being restricted by the period.
[0032]
Further, according to the host computer 1 as the information processing apparatus of the third embodiment, the image data transfer to the image display apparatus 5 is performed asynchronously with the image display of the plurality of subframes by the image display apparatus 5. The image data can be transferred without being restricted by the image display period.
[0033]
Next, a fourth embodiment of the present invention will be described. In the fourth embodiment, in the first, second or third embodiment, the host computer 1 divides and rearranges one frame of image data into subfield image data by the data processing means 3. The data for identifying which subfield is added to the image data of the subfield rearranged here, and the image data with the data for identifying the subfield is added via the I / F unit 4. Transfer to the image display device 5.
[0034]
The image display device 5 analyzes the data for identifying the subfield by the video signal processing circuit 6 from the data transferred from the host computer 1 through the I / F unit 4 and transfers the transferred image data. Of the subfields 1 to 4 is identified, and the contents of the memory field designated by the identified subfield of the memory 7 in the transferred subfield image data are identified. Update. Here, the video signal processing circuit 6 is a very simple selector having two inputs and four outputs by adding data for identifying the subfield to the image data, and is designated by the identified subfield of the memory 7. The transferred image data can be distributed to the memory field.
[0035]
According to the image display device 5 of the fourth embodiment, a plurality of image data added with data for identifying a subfield is acquired from the host computer 1 as an information processing device, and the subfield is identified. Since the predetermined memory field of the memory 7 as the storage unit is updated with the acquired image data of the plurality of subfields using the data of the image data, it is not necessary to process the image data with a signal at the time of image data transfer, A circuit for performing processing on the image display apparatus side can be simplified, thereby reducing costs.
[0036]
Further, according to the host computer 1 as the information processing apparatus of the fourth embodiment, data for identifying subfields is added to the image data of a plurality of subfields and transferred to the image display apparatus 5, so that image data transfer is performed. It is not necessary to process the image data on the image display device side or the like according to the time signal, and the circuit for processing on the image display device side can be simplified, thereby reducing the cost.
[0037]
【The invention's effect】
As described above, according to the present invention, the image display device can eliminate the load of image data division rearrangement on the image display device side. In addition, it is not necessary to acquire a predetermined number of subfield image data thinned out of one frame of image data, and the load due to the transfer of the image data can be reduced. In addition, the image data of all subfields can be stored in the storage means, so that even if image data obtained by thinning out a predetermined number of subframe image data from one frame of image data is acquired, an image can be obtained with one frame of image data. It can be displayed, and a high-quality image can be displayed. Further, it is possible to display an image using image data stored in the storage means without being restricted by the cycle of image data transfer. Further, it is not necessary to process the image data with a signal at the time of transferring the image data, and the circuit for performing the processing on the image display device side can be simplified, thereby reducing the cost.
[Brief description of the drawings]
FIG. 1 is a block diagram showing Embodiment 1 of the present invention.
FIG. 2 is a diagram for explaining a method of displaying an image of one frame in the first embodiment.
FIG. 3 is a diagram showing an image of one cycle until all image data for one screen in the memory is rewritten to new image data in the second embodiment of the present invention.
[Explanation of symbols]
1 Host computer 2 Graphic board 3 Data processing means 4 I / F unit 5 Image display device 6 Video signal processing circuit 7 Memory 8 Display unit

Claims (4)

A display element that divides one frame into a predetermined number of subframes and displays an image of the subframe;
Storage means for storing the image data of each subframe as a subfield ;
Video signal processing means for sequentially displaying each subframe;
An image display device having displacement means for displacing a light beam from a display element that displays an image of a subframe for each subframe,
An image display device characterized in that subfields of image data of subframes rewritten to the storage means within a time for displaying one frame are subframes thinned out from a predetermined number . A display element that divides one frame into a predetermined number of subframes and displays an image of the subframe;
Storage means for storing the image data of each subframe as a subfield ;
Video signal processing means for sequentially displaying each subframe;
A displacement means for displacing the light beam from the display element that displays the image of the subframe for each subframe;
An image display device having receiving means for receiving the image data from the information processing device side;
An image display device characterized in that subfields of image data of subframes rewritten to the storage means within a time for displaying one frame are subframes thinned out from a predetermined number .   The image display apparatus according to claim 2, wherein the display of the subframe and the reception of the image data from the information processing apparatus are performed asynchronously in the image display apparatus. The said storage means, the memory field is divided for each sub-field,
When acquiring the subfield image data of the sub-frame to be rewritten, image Display apparatus according to any one of claims 1 to 3, characterized in that rewriting in the memory field corresponding to the sub-field.

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