The present disclosure relates to a display device.
The present disclosure relates to a display device, and, in particular, to a display device which displays an image. Display devices can display images, and thus are utilized in televisions or monitors, for example.
A display user and a display supplier sometimes desire to shift a location of a display image in a display portion. For example, a display device is proposed in which two display panels are stacked, one on top of another, to allow display of an image having a contrast ratio. In this case, these two panels are stacked such that one pixel in one panel can be strictly positioned to overlap one corresponding pixel in another panel in a plan view. However, it is very difficult to match two display panels without off-setting any pixels.
The present disclosure is made to solve such problems and has an object to provide a display device which can easily shift a display position within a display portion.
The present disclosure has been made in view of the above circumstances, and an object thereof is to be able to easily shift a display position within a display portion.
In one general aspect, the instant application describes a display device including a primary display area which comprises a first display area and a second display area which is unique from the first display area, a control unit configured to display an image in the primary display area, an image signal generating unit configured to generate display data based on externally input image data for a single image. The image signal generating unit comprises a memory which stores display-position information indicating a display location of a first image displayed in the primary display area. The display data comprises first and second display data to be displayed in the first display area and the second display area, respectively. The first display data is generated based on the externally input single image data and the display-position information. The control unit is configured to cause a first image to be displayed in the first display area based on the first display data.
The above general aspect may include one or more of the following features. The image signal generating unit may be configured to generate the second display data, the second display data configured to cause a second image to be displayed in the second area, irrespective of external input image signal.
The second image may be a predetermined image of a gray scale image.
The gray scale image may be substantially black.
The image signal generating unit may be configured to generate the second image data based on a part of the first image signal, which corresponds to outermost pixels of the first area.
The second image data may be generated by copying a part of first image signal corresponding to the outermost pixels of the first area.
The second area may extend from the first area and extends in at least one of the first and second directions.
The display-position information may include off-set information from a normal area, wherein the normal area is a central area in the display area.
The display-position information may include at least a position of one corner of the first display area.
The display device may further include at least a first display panel and a second display panel stacked on each other. The display area may be formed in one of the first display panel and the second display panel.
The first display panel may displays in monotone, the second display panel may display in color, and the display area may be formed in the first display panel.
The second display panel may include a display portion. The display portion may be configured to display the image based on the external input image data. The display area may overlap the display portion in plan view. The display area may be larger than the display portion.
The first display area may have a same area as the display portion.
The image signal generating unit may be configured to generate the second image data based on at least a part of the first image signal corresponding to the outermost pixels of the first area.
The first display panel may displays in monotone, the second display panel may display in color, and the display area may be formed in the second display panel.
The first display panel may include a display portion, the display portion configured to display the image based on the external input image data. The display area may overlap the display portion in a plan view. The display area may be larger than the display portion.
The first display area may be a same area as the display portion.
The image signal generating unit may be configured to generate the second image data to display a substantially black image in the second area.
The first display panel may display in monotone, the second display panel may display in color. The display area may be formed in each of the first and second display panels.
The first display area in the first display panel may be a same area as the first display area in the second display panel.
The image signal generating unit may be configured to: generate the second image data for the first display panel so as to display a substantially black image in the second area, and to generate the second image data for the second display panel based on at least a part of the first image signal corresponding to the outermost pixels of the first area.
The display device may further include a positional change unit, wherein the positional change unit is configured to rewrite the display-position information stored in the memory unit.
An embodiment of the present disclosure is described below with reference to the accompanying drawings. In the embodiment of the present disclosure, a liquid crystal display device is taken as an example, but a display device according to the present disclosure is not limited to the liquid crystal display device, and may be, for example, an organic EL display device.
The image signal generating unit includes a first image signal generating unit, a second image signal generating unit, and a positional memory. The first image signal generating unit generates a first image signal based on the external input image data Data. The first image signal is used so as to display a main image in a part of the display area, which is a main display area. The external input image data Data includes luminescence data and color data for pixels located in the main display area. The display area is larger size than the main display area. An area other than the main display area in the display area is a marginal display area. The second image signal generating unit generates a second image signal for displaying a marginal image in the marginal display area. A way to generate the second image signal will be described later in details. The image signal generating unit has the positional memory which stores display-position information. The display-position information indicates a location where the main image is displayed within the display area. The image signal generating unit generates the image signal by combining the first display signal and the second display signal with the display-position information.
The image signal generating unit outputs the image signal to the timing controller. The timing controller controls driving circuits so as to display the main image in a main display area and the marginal image in a marginal display area according to the display-position information stored in the positional memory.
A data signal (data voltage) is supplied from a source driver to each data line DL, and a gate signal (gate voltage) is supplied from a gate driver to each gate line GL. Common voltage Vcom is supplied to the common electrode. When an on voltage of the gate signal (gate-on voltage) is supplied to gate line GL, a TFT connected to gate line GL is turned on to supply the data voltage to pixel electrode PX through the data line DL connected to the TFT. An electric field is generated by a difference between the data voltage supplied to pixel electrode and the common voltage Vcom supplied to common electrode. The liquid crystal is driven by the electric field which controls the transmittance of the light transmitted from the backlight, thereby displaying an image. The desired data voltages are supplied to data lines connected to pixel electrodes PX of the pixels PIX, thereby displaying an image.
The timing controller performs known image processing. For example, based on the image signal generated by the first image signal generating unit and control signal (a clock signal CS, a vertical synchronizing signal, and a horizontal synchronizing signal, for example), the timing controller can generate various timing signals (data start pulse DSP, data clock DCK, gate start pulse GSP, and gate clock GCK, for example) controlling the driving voltage of the source driver and the gate driver and image data configured to be input into the source driver.
The marginal display area corresponds to pixels connected to 10 data lines in the left side of the main display area and the right side of the main display area, and pixels connected to 10 gate lines in both the top side of the main display area and the bottom side of the main display area. The second image single generating unit generates a second image signal and a marginal image is displayed in the marginal display area according to the second image signal. A way to generate the second image signal will be described later.
According to the display-position information and pixel information included in the first image signal, a position of the main display is fixed. Image voltage according to the first display signal is written to pixels in the main display area, whereby the main image is displayed in the main display area. The same image voltage written to a pixel in an edge of the main display area is written to pixels in the marginal display area. For example, pixels located within a region from pixel (1, 1) to pixel (9, 1) in the row direction and pixels from pixel (1, 1) to pixel (1, 9) in the column direction display the same luminescence, because the second image signal generating unit generates the second display signal so as to copy the first display signal corresponding to pixel (9,9) in the main display area to the other pixels in the marginal display area. Pixels in the marginal display area, which are on the left side of the main display area, display the same luminescence as the pixel on the left edge of the main display area. For example, the main display signal corresponding to pixel (9,10) in the main display area is copied to the second display signal corresponding to each of pixels (1,10)≈(8,10). In the same manner, pixels in the marginal display area, which are located above the main display area, display the same luminescence as the pixel in the top edge of the main display area. For example, the first display signal corresponding to pixel (10,9) in the main display area is copied to the marginal display signal corresponding to each of pixels (10,1) ≈(10,8). This way generating a second image signal is done by copying of a part of the first image signal. This technique is not limited to this embodiment. The second image signal generating unit may perform a smoothing process on the second image signal so as to make a boundary between the main and marginal display areas inconspicuous. For example, the second image signal generating unit may generate the second image signal based on the first image signal corresponding to pixels on the edge of the main display area as well as pixels inside the main display area. The second display signal corresponding to each of pixels (1,10)≈(8,10) is generated based on the first display signal corresponding to not only pixel (9,10) but also to pixel (10,10) in the main display area. When the second image signal generating unit generates the second image signal based on at least the first image signal corresponding to pixels on the edge of the main display area, it is within a scope of this embodiment.
In examples described with
The display-position information may be rewritable. The main display area can be changed within the display area. In the above example, the top-left corner of the main display area can change from pixel (1, 1) to pixel (20, 1) in the row direction and from pixel (1, 1) to pixel (1, 20) in the column direction. For example, a user can change the position of the main display area with a switch, which can be realized by rewriting the display-position information stored in the positional memory.
According to the first embodiment, a display position of the main image can be changed within the display area. And the display area surrounding the main display area displays the second image, which can be made based on the external input image data, or can be made irrespective of the external input image data.
A second exemplary embodiment of the present disclosure will be described below with reference to the drawings. For convenience, the components having the same functions as those of the first exemplary embodiment are designated by the same reference marks, and their description is omitted.
A liquid crystal display device 5 according to the second embodiment includes a plurality of display panels for displaying images, a plurality of drive circuits (a plurality of source drive, a plurality of gate drivers, for example) for driving the respective display panels, and a plurality of timing controllers controlling each of the drive circuits, an image signal generating unit which performs image processing on an external input image data and outputs image data to each timing controller, and a backlight (not shown in
The image signal generating unit generates an image data by combining the first image signal and the second image signal with display-position information stored in the positional memory. The third image signal generating unit generates the first image signal based on the external input image data Data so as to display a color image in a display portion. The external input image data Data includes image data to display color and luminescence in each pixel in the display portion of the front display panel. For example, 4096 pixels in the row direction and 2160 pixels in the column direction are arranged in a matrix in the display portion of the front display panel. All the pixels are driven by each independent image data corresponding to each pixel according to the external input image data Data. On the other hand, 4116 pixels in the row direction and 2180 pixels in the column direction are arranged in a matrix in the display area of the back display panel, which is more than the number of pixels corresponding to the external input image data Data. Thus, the display area in the back display panel is larger than the display portion in the front display panel. A main display area in the back display panel overlaps the display portion in the front display panel in a plan view. A marginal area surrounds the main display area. A main image is displayed in the main display area according to the main image display signal. A marginal image is displayed in the marginal display area according to the marginal image display signal. In this embodiment, the marginal display signal is generated based on the main display signal corresponding to pixels on the edge of the main display area, as previously described in the first embodiment.
The front display panel and the back display panel are stacked adjacent to each other such that a central display area in the back display panel matches with the display portion in the front display panel. In this case, there are 20 more pixels in the display area of the back display panel that are arranged in the column direction, than the display portion of the front display panel. And there are 20 more pixels in the display area of the back display panel that are arranged in the row direction, than the display portion of the main display panel. Thus, the central display area in the back display panel corresponds to an area from pixel (11, 11) to pixel (4106, 11) in the row direction and pixel (11, 11) to pixel (11, 2170) in the column direction.
However, it is almost impossible to match the central display area of the back display panel with the display portion of the front display panel without any off-set, in a liquid crystal display device. Or it may require a high investment for a manufacturing machine to prevent the off-set.
According to this embodiment, after the front and back display panels are stacked adjacent to each other, an off-set is measured between the central display area in the back display panel and the display portion in the front display panel. The off-set that has occurred, that is display-position information, is stored in the positional memory. Then the main display image is displayed in the main display area of the back display panel which overlaps the display portion of the front display panel.
The configuration of the front display panel will be described with reference to
As shown in
Next, the configuration of the back display panel will be described with reference to
As shown in
The configuration of the back display panel is similar to the display panel in the first embodiment, except for a pixel size. External input image data Data for one pixel includes luminescence and colors of red, green, and blue. Based on the information for one pixel, one pixel consisting of three sub-pixels, a red sub-pixel, a green sub-pixel and a blue sub-pixel is driven. In the back display panel, no color filter is formed, and one pixel defined by two adjacent data lines and two adjacent gate lines is driven based on the external input image data Data for one pixel. Thus, one pixel consisting of three sub-pixels formed in the front display panel corresponds to and overlaps in a plan view with one pixel formed in the back display panel. A size of one pixel of the back display panel is nearly the same size as one pixel of the three sub-pixels of the front display panel.
Therefore, when this off-set value is stored in the positional memory as display-position information, the image signal generating unit generates image data so as to display a main image in the main area of the display area of the back display panel. The other area is designated as the marginal area where a marginal image is displayed. The marginal image is generated by the second image signal generating unit so as to prevent an edge area of the liquid crystal display device from being dark even when a viewer looks at the display portion in an oblique angle. The marginal image is generated based on the main image data corresponding to outermost pixels of the first area.
The front and the back display panels are ideally stacked to each other such that a red sub-pixel, which connects with a data line connecting an output terminal SD1-1 of the first source driver, a green sub-pixel, which connects a data line connecting with an output terminal SD1-2 of the first source driver, and a blue sub-pixel, which connects a data line connecting with an output terminal SD1-3 of the first source driver, overlap one pixel which connects a data line connecting an output terminal SD2-11 of the second source driver and connects a gate line connecting an output terminal GD2-11 of the second gate driver. This sometimes fails and an off-set is occurs, such that these three sub-pixels of the front display panel overlap one pixel connecting the data line connecting an output terminal SD2-10 of the second source driver and connects with a gate line connecting an output terminal GD2-9 of the second gate driver. Therefore, the off-set value is stored in the positional memory as display-position information. The first image signal generating unit generates a first display signal so as to display a first image in the main display area based on the display-position information.
The second image signal generating unit generates a second image signal based on the first image signal corresponding to pixels in the outermost area of the main display area, as shown in
The same image voltage written to a pixel in an edge of the main display area is written to pixels in the second display. For example, pixels from pixel (1, 1) to (10, 1) in the row direction and from pixel (1, 1) to pixel (1, 9) in the column direction display the same image, because the second image signal generating unit generates the second display signal so as to copy the first display signal corresponding to pixel (10, 9) in the main display area to the other pixels in the marginal display area. Pixels in the marginal display area, which is left side of the main display area, display the same luminescence as the pixel on the left edge of the main display area. For example, the first display signal corresponding to pixel (9, 10) in the main display area is copied to the second display signal corresponding to each of pixels (1, 10)≈(8, 10). In the same manner, Pixels in the marginal display area, which is located above the main display area, display the same luminescence as the pixel in the top edge of the main display area. For example, the first display signal corresponding to pixel (11, 9) in the main display area is copied to the second display signal corresponding to each of pixels (11, 1)≈(11, 8). This way of generating a second image signal is a copy of a part of the first image signal. This technique is not limited to this embodiment. The second image signal generating unit may perform a smoothing process on the second image signal so as to make a boundary between the marginal display areas and the main display areas inconspicuous. For example, the second image signal generating unit may generate the second image signal based on the first image signal corresponding to pixels on the edge of the main display area, as well as pixels inside the main display area. The second display signal corresponding to each of pixels (1, 10)≈(9,10) is generated based on the first display signal corresponding to not only pixel (10,10) but also to pixel (11,10) in the main display area. When the second image signal generating unit generates the second image signal based on at least the first image signal corresponding to pixels in the edge of the main display area, it is within a scope of this embodiment.
A third exemplary embodiment of the present disclosure will be described below with reference to the drawings. For convenience, the components having the same functions as those of the first and second exemplary embodiment are designated by the same reference marks, and their description is omitted.
The liquid crystal display device according to the second embodiment can be applied to a front display panel.
A fourth exemplary embodiment of the present disclosure will be described below with reference to the drawings. For convenience, the components having the same functions as those of the first, second and third exemplary embodiment are designated by the same reference marks, and their description is omitted.
The liquid crystal display device according to the second embodiment can be applied to a front display panel and a back display panel. Both of the front and back display panels have a greater number of pixels than a number of pixels included in an external input image data Data. A main display area in the front display panel includes the same number of pixels as a main display area in the back display panel. A marginal display area in the front display panel includes the same number of pixels as a marginal display area in the back display panel. But the embodiment is not limited to this. The marginal display area in the front display panel may include a different number of pixels compared to the marginal display area in the back display panel. In this configuration, the main display area of the front display panel overlaps the main display area of the back display panel by setting the main display area off the central display area. For example, in
Although exemplary embodiments of the present disclosure are described above, the present disclosure is not limited to these exemplary embodiments. It is noted that other embodiments properly changed from the exemplary embodiments described above by those skilled in the art without departing from the scope of the present disclosure are fully supported by the present disclosure.