WO2011126090A1 - 液晶表示装置および立体表示システム - Google Patents
液晶表示装置および立体表示システム Download PDFInfo
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- WO2011126090A1 WO2011126090A1 PCT/JP2011/058844 JP2011058844W WO2011126090A1 WO 2011126090 A1 WO2011126090 A1 WO 2011126090A1 JP 2011058844 W JP2011058844 W JP 2011058844W WO 2011126090 A1 WO2011126090 A1 WO 2011126090A1
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Definitions
- the present invention relates to a liquid crystal display device and a stereoscopic display system.
- the liquid crystal display device has advantages such as light weight, thinness, and low power consumption, and is used not only as a small display device such as a display unit of a mobile phone but also as a large television.
- a general liquid crystal display device performs planar display, but in recent years, it has been proposed to use a liquid crystal display device to perform more realistic three-dimensional display (see Patent Document 1).
- Patent Document 1 discloses a stereoscopic video display device (stereoscopic display system) including a liquid crystal display device that alternately displays a left-eye frame and a right-eye frame and shutter glasses. An observer wears shutter glasses and observes the display screen of the liquid crystal surface device.
- the liquid crystal display device continuously displays the first and second left-eye frames of the same video, and subsequently the first and second right-eye frames of the same video.
- the left eye shutter of the shutter glasses is open from the vertical blanking period after the first left eye frame is written to the liquid crystal display device to the next second left eye frame period.
- the right eye shutter is open from the vertical blanking period after the first right eye frame is written to the liquid crystal display device to the next second right eye frame period.
- the observer visually recognizes the left-eye frame and the right-eye frame at the same time, and the observer visually recognizes the left-eye frame and the right-eye frame.
- the period during which the image can be generated is lengthened, thereby increasing the luminance.
- the liquid crystal display device displays two frames for one left eye frame (left eye image), and one right eye frame (right eye image). For this reason, the liquid crystal display device displays two frames, and the liquid crystal display device displays four frames so that the viewer can view one stereoscopic image.
- the liquid crystal display device needs to be driven at a high vertical scanning frequency.
- the liquid crystal display device is driven at a high vertical scanning frequency, since the period in which each pixel is selected is shortened, the influence of signal delay is increased, and the luminance of the pixel does not change to a predetermined value. Display unevenness may occur.
- the input video signal itself input to the liquid crystal display device does not always conform to the stereoscopic display mode, and the observer does not want to see the stereoscopic display by wearing shutter glasses. is there.
- the liquid crystal display device may be required to be capable of normal display (planar display) as well as stereoscopic display.
- the power consumption of a liquid crystal display device capable of not only stereoscopic display but also flat display is increased as compared with a general liquid crystal display device.
- the present invention has been made in view of the above problems, and an object of the present invention is to provide a liquid crystal display device and a stereoscopic display system capable of performing stereoscopic display with suppressed display unevenness. Another object of the present invention is to provide a low power consumption liquid crystal display device and a stereoscopic display system that can be switched between a stereoscopic display mode and a flat display mode.
- the liquid crystal display device is a liquid crystal display device provided with a plurality of pixels that performs display in a stereoscopic display mode, and each of the plurality of pixels has a left-eye image every two consecutive vertical scanning periods. Data and right eye image data are alternately written, and each of the plurality of pixels has the same polarity over the two vertical scanning periods in which the left eye image data is written, and the two vertical images in which the right eye image data is written. It shows the same polarity over the scanning period.
- the polarity of each of the plurality of pixels is inverted every two or more even vertical scanning periods.
- the polarity of each of the plurality of pixels is inverted every two vertical scanning periods.
- the polarity of each of the plurality of pixels is inverted every four vertical scanning periods.
- the plurality of pixels are arranged in a matrix of a plurality of rows and a plurality of columns, and one of the left eye image data and the right eye image data is written to the whole of the plurality of pixels. Of the plurality of pixels are adjacent to each other in the column direction.
- the plurality of pixels are arranged in a matrix of a plurality of rows and a plurality of columns, and one of the left eye image data and the right eye image data is written to the whole of the plurality of pixels. Then, the polarities of the pixels adjacent to each other in the row direction and the column direction among the plurality of pixels are different from each other.
- the plurality of pixels are divided into one or more blocks corresponding to two or more rows of the plurality of rows, and the writing of the left eye image data or the right eye image data is performed by After being performed on one pixel of the odd and even rows in the block, it is performed on the other pixel.
- the liquid crystal display device includes a front substrate, a rear substrate, a liquid crystal panel having a liquid crystal layer provided between the front substrate and the rear substrate, and a back for irradiating the liquid crystal panel with light.
- a light unit a frame rate control circuit that generates a video signal having a frame rate higher than a frame rate of the input video signal based on the input video signal; a timing controller that generates a display signal based on the video signal;
- a scanning signal driving circuit for supplying a scanning signal for selecting a pixel to be written; a display signal driving circuit for supplying the display signal to the selected pixel; and a writing state signal indicating a writing state of the plurality of pixels
- Write state signal transmission circuit for transmitting and backlight for controlling turning on and off of the backlight unit And a dynamic circuit.
- the backlight unit is lit during at least a part of a subsequent vertical scanning period of the two vertical scanning periods in which the left eye image data and the right eye image data are respectively written.
- the liquid crystal display device performs overdrive driving in each of the plurality of pixels based on the left eye image data and the right eye image data written in one or more previous vertical scanning periods. .
- the liquid crystal display device performs display by switching between the stereoscopic display mode and the planar display mode, and the planar display mode is driven at a lower vertical scanning frequency than the stereoscopic display mode.
- each of the plurality of pixels has a first subpixel and a second subpixel.
- multi-pixel driving is performed in the planar display mode, and multi-pixel driving is not performed in the stereoscopic display mode.
- the liquid crystal display device performs display by switching between a stereoscopic display mode and a planar display mode that is driven at a vertical scanning frequency lower than that of the stereoscopic display mode.
- the driving in the flat display mode is performed at a vertical scanning frequency that is half of the driving in the stereoscopic display mode.
- the liquid crystal display device includes a liquid crystal panel provided with a plurality of pixels, and a frame rate control circuit that generates a video signal having a frame rate higher than the frame rate of the input video signal based on the input video signal.
- a timing controller that generates a display signal based on the video signal, a scanning signal drive circuit that supplies a scanning signal for selecting a pixel to be written, and a display signal that supplies the display signal to the selected pixel
- the timing controller varies a frame rate of the display signal according to the stereoscopic display mode and the flat display mode.
- the liquid crystal display device further includes a backlight unit that irradiates light to the liquid crystal panel, and a backlight drive circuit that controls turning on and off of the backlight unit.
- the light irradiation by the backlight unit is changed according to the stereoscopic display mode and the flat display mode.
- the backlight unit has a plurality of irradiation areas that can be independently controlled to be turned on and off.
- the plurality of pixels are arranged in a matrix of a plurality of rows and a plurality of columns, and each of the plurality of irradiation regions corresponds to a pixel in at least one row of the plurality of rows. Correspondingly provided.
- the plurality of irradiation areas are lit in order.
- the liquid crystal panel includes a front substrate having a counter electrode, a rear substrate having a scanning wiring, a source wiring, and a pixel electrode, and a liquid crystal layer provided between the front substrate and the rear substrate.
- the scanning signal drive circuit and the display signal drive circuit when performing display in the flat display mode, drive the liquid crystal panel at a vertical scanning frequency that is half that when performing display in the stereoscopic display mode. .
- the frame rate control circuit sets the frame rate of the video signal to twice the frame rate of the input video signal.
- left-eye image data and right-eye image data are alternately arranged in the input video signal, and the frame rate control circuit outputs the video signal to the video signal.
- One set of the left eye image data and the right eye image data in the input video signal is repeatedly arranged in two sets.
- the timing controller sequentially arranges the left eye image data and the right eye image data of the video signal two by two on the display signal.
- the timing controller when performing display in the stereoscopic display mode, sets the frame rate of the display signal to twice the frame rate of the video signal, and when performing display in the planar display mode, The timing controller sets the frame rate of the display signal equal to the frame rate of the video signal.
- the frame rate control circuit sets the frame rate of the video signal to four times the frame rate of the input video signal.
- left-eye image data and right-eye image data are alternately arranged in the input video signal, and the frame rate control circuit outputs the video signal to the video signal.
- the input video signal two sets of one set in which the left eye image data and the right eye image data are continuously arranged two by two are repeatedly arranged.
- the timing controller arranges the left eye image data and the right eye image data of the video signal in the display signal.
- the timing controller when performing display in the stereoscopic display mode, sets the frame rate of the display signal equal to the frame rate of the video signal, and when performing display in the planar display mode, the timing controller Sets the frame rate of the display signal to half the frame rate of the video signal.
- the liquid crystal display device further includes a write state signal transmission circuit that transmits a write state signal indicating a write state of the plurality of pixels.
- overdrive driving is performed on each of the plurality of pixels based on the left eye image data and the right eye image data written in one or more previous vertical scanning periods.
- a stereoscopic display system includes the liquid crystal display device described above, a left-eye shutter that opens during a period in which the liquid crystal display device displays a left-eye image, and the liquid crystal display device displays a right-eye image.
- Shutter glasses having a right-eye shutter that opens during a period of time.
- the liquid crystal display device and the stereoscopic display system according to the present invention can perform stereoscopic display in which display unevenness is suppressed. Further, according to the present invention, it is possible to provide a low power consumption liquid crystal display device and a stereoscopic display system capable of switching between the stereoscopic display mode and the flat display mode.
- FIG. 2 is a schematic diagram of the flat display mode.
- FIG. 3 is a schematic diagram showing opening / closing of a writing state signal transmission circuit and shutter glasses in the stereoscopic display system shown in FIG. 2.
- (A) is a schematic diagram of image data included in the input video signal input to the liquid crystal display device shown in FIG. 2 in the stereoscopic display mode, and (b) is a schematic diagram of image data included in the video signal.
- (C) is a schematic diagram of the image data contained in a display signal.
- A) is a schematic diagram of image data included in the input video signal input to the liquid crystal display device shown in FIG. 2 in the flat display mode
- (b) is a schematic diagram of image data included in the video signal.
- (C) is a schematic diagram of the image data contained in a display signal.
- (A) is a schematic diagram of the stereoscopic display mode of the liquid crystal display device and the stereoscopic display system of Comparative Example 1, and (b) is a schematic diagram of the flat display mode.
- (A) is a schematic diagram of image data included in the input video signal input to the liquid crystal display device shown in FIG. 7 in the stereoscopic display mode, and (b) is a schematic diagram of image data included in the video signal.
- (C) is a schematic diagram of the image data contained in a display signal.
- (A) is a schematic diagram of image data included in the input video signal input to the liquid crystal display device shown in FIG.
- FIG. 7 is a schematic diagram of image data included in the video signal.
- C is a schematic diagram of the image data contained in a display signal.
- A) is a schematic diagram which shows the time change of lighting of the backlight unit in the three-dimensional display system shown in FIG. 2,
- (b) is lighting of a backlight unit, writing to each pixel, and timing of shutter glasses.
- FIG. 3 is a diagram for explaining driving of the stereoscopic display system shown in FIG. 2
- (a) is a waveform diagram of a scanning signal voltage supplied to a plurality of scanning wirings
- (b) is a lighting / lighting of a backlight unit.
- (c) is a schematic diagram which shows opening and closing of shutter spectacles.
- (A) is a schematic diagram which shows the time change of lighting of the backlight unit in the three-dimensional display system shown in FIG. 2, (b) is lighting of a backlight unit, writing to each pixel, and timing of shutter glasses. It is a schematic diagram which shows.
- (A) is a schematic diagram which shows the time change of lighting of the backlight unit in the three-dimensional display system shown in FIG. 2, (b) is lighting of a backlight unit, writing to each pixel, and timing of shutter glasses. It is a schematic diagram which shows. It is a schematic diagram of the liquid crystal panel in the liquid crystal display device shown in FIG.
- FIG. 3A and 3B are diagrams for explaining driving of the stereoscopic display system illustrated in FIG. 2, in which FIG. 3A is a waveform diagram of the potential of the source wiring with reference to the potential of the counter electrode, and FIG. (C) is a waveform diagram of the potential of the pixel electrode with reference to the potential of the counter electrode, (d) is a schematic diagram showing lighting / non-lighting of the backlight unit, and (e) is a shutter. It is a schematic diagram which shows opening and closing of spectacles.
- FIG. 3 is a diagram for explaining driving of the stereoscopic display system shown in FIG.
- FIG. 3 is a diagram for explaining driving of the stereoscopic display system shown in FIG. 2, (a) is a schematic diagram showing the polarity of written pixels and the order of writing, and (b) is an opposing view in one frame update period.
- FIG. 3A and 3B are diagrams for explaining driving of the stereoscopic display system illustrated in FIG. 2, in which FIG. 3A is a waveform diagram of the potential of the source wiring with reference to the potential of the counter electrode, and FIG. (C) is a waveform diagram of the potential of the pixel electrode with reference to the potential of the counter electrode, (d) is a schematic diagram showing lighting / non-lighting of the backlight unit, and (e) is a shutter. It is a schematic diagram which shows opening and closing of spectacles.
- FIG. 3 is a diagram for explaining driving of the stereoscopic display system shown in FIG.
- FIG. 2 (a) is a waveform diagram of a display signal voltage, (b) is a waveform diagram of a scanning signal voltage, and (c) is a facing diagram. It is a wave form diagram which shows the change of the electric potential of the pixel electrode on the basis of the electric potential of an electrode, (d) is a schematic diagram which shows lighting / non-lighting of a backlight unit, (e) is a schematic diagram which shows opening and closing of shutter glasses.
- FIG. It is the schematic diagram which showed the change of the image data in the three-dimensional display system shown in FIG. 2 in which an overdrive process is performed.
- It is a schematic diagram which shows the pixel in the liquid crystal panel shown in FIG.
- FIG. 1 shows the pixel in the liquid crystal panel shown in FIG.
- FIG. 23 is an equivalent circuit diagram of the liquid crystal panel shown in FIG. 22.
- (A) is a schematic diagram of the stereoscopic display mode of 2nd Embodiment of the liquid crystal display device and stereoscopic display system by this invention,
- (b) is a schematic diagram of planar display mode.
- (A) is a schematic diagram of image data included in an input video signal input to the liquid crystal display device shown in FIG. 24 in the stereoscopic display mode
- (b) is a schematic diagram of image data included in the video signal.
- (C) is a schematic diagram of the image data contained in a display signal.
- (A) is a schematic diagram of image data included in an input video signal input to the liquid crystal display device shown in FIG.
- FIG. 24 is a schematic diagram of the stereoscopic display mode of the liquid crystal display device and stereoscopic display system of Comparative Example 2
- FIG. 25 is a schematic diagram illustrating changes in image data in the stereoscopic display system illustrated in FIG. 24 in which overdrive processing is performed.
- A)-(d) is a schematic diagram which shows the image displayed in 3rd Embodiment of the liquid crystal display device by this invention, and a three-dimensional display system.
- A) is a schematic diagram of the stereoscopic display system shown in FIG.
- FIG. 29 is a schematic diagram of a liquid crystal panel in the liquid crystal display device shown in (a). It is a figure for demonstrating the drive of the three-dimensional display system shown in FIG. 29, (a) is a waveform diagram of a display signal voltage, (b) is a waveform diagram of a scanning signal voltage, (c) is opposing. It is a wave form diagram which shows the change of the electric potential of the pixel electrode on the basis of the electric potential of an electrode, (d) is a schematic diagram which shows lighting / non-lighting of a backlight unit, (e) is a schematic diagram which shows opening and closing of shutter glasses.
- (A) is a schematic diagram of the liquid crystal display device of the comparative example 3, and a three-dimensional display system
- (b) is a schematic diagram of the liquid crystal panel in the liquid crystal display device shown to (a). It is a figure for demonstrating the drive of the three-dimensional display system of the comparative example 3
- (a) is a waveform figure of the potential of the source wiring on the basis of the electric potential of a counter electrode
- (b) is a wave form diagram of a scanning signal voltage
- (C) is a waveform diagram of the potential of the pixel electrode with reference to the potential of the counter electrode
- (d) is a schematic diagram showing lighting / non-lighting of the backlight unit
- (e) is shutter glasses. It is a schematic diagram which shows opening and closing of.
- FIG. 30 is a diagram for explaining driving of the stereoscopic display system shown in FIG. 29, (a) is a waveform diagram of a scanning signal voltage supplied to a plurality of scanning wirings, and (b) is a lighting / lighting of a backlight unit; It is a schematic diagram which shows non-lighting, (c) is a schematic diagram which shows opening and closing of shutter spectacles. 29A and 29B are diagrams for explaining the driving of the stereoscopic display system shown in FIG. 29, in which FIG. 29A is a waveform diagram of the potential of the source wiring with reference to the potential of the counter electrode, and FIG.
- FIG. 30 is a diagram for describing driving of the stereoscopic display system illustrated in FIG. 29, in which (a) is a schematic diagram illustrating the polarity of written pixels and the order of writing, and (b) is a diagram illustrating the opposite in one frame update period. It is a waveform diagram of the potential of a specific source wiring with reference to the potential of the electrode. 29A and 29B are diagrams for explaining the driving of the stereoscopic display system shown in FIG.
- FIG. 29A is a waveform diagram of the potential of the source wiring with reference to the potential of the counter electrode
- FIG. (C) is a waveform diagram of the potential of the pixel electrode with reference to the potential of the counter electrode
- (d) is a schematic diagram showing lighting / non-lighting of the backlight unit
- (e) is a shutter. It is a schematic diagram which shows opening and closing of spectacles. It is a figure for demonstrating the drive of the three-dimensional display system shown in FIG. 29, (a) is a waveform diagram of a display signal voltage, (b) is a waveform diagram of a scanning signal voltage, (c) is opposing.
- FIG. It is a wave form diagram which shows the change of the electric potential of the pixel electrode on the basis of the electric potential of an electrode
- (d) is a schematic diagram which shows lighting / non-lighting of a backlight unit
- (e) is a schematic diagram which shows opening and closing of shutter glasses.
- FIG. It is a schematic diagram which shows an example of the three-dimensional display system shown in FIG.
- the stereoscopic display system 300 includes a liquid crystal display device 100 and shutter glasses 280.
- the liquid crystal display device 100 is provided with a plurality of pixels.
- the liquid crystal display device 100 performs display at least in the stereoscopic display mode.
- the liquid crystal display device 100 displays the left eye image in a certain period and displays the right eye image in another period.
- the liquid crystal display device 100 that performs display in the stereoscopic display mode displays the left eye image and the right eye image in different periods.
- the liquid crystal display device 100 is used together with the shutter glasses 280.
- the shutter glasses 280 have a left eye shutter 282 and a right eye shutter 284.
- the shutter glasses 280 are designed to be worn by an observer.
- the shutter glasses 280 are controlled based on a signal output from the liquid crystal display device 100.
- the left eye shutter 282 is opened when the liquid crystal display device 100 displays a left eye image
- the right eye shutter 284 is opened when the liquid crystal display device 100 displays a right eye image. Therefore, the left eye of the observer wearing the shutter glasses 280 visually recognizes the left eye image of the liquid crystal display device 100 via the left eye shutter 282 of the shutter glasses 280, and the right eye of the observer is the right eye of the shutter glasses 280.
- the right eye image of the liquid crystal display device 100 is visually recognized via the shutter 284.
- the shutter glasses 280 are also called active glasses.
- the left eye shutter 282 of the shutter glasses 280 is open and the right eye shutter 284 is closed.
- the shutter glasses 280 are mounted on the observer's head in the same manner as so-called glasses that correct myopia, hyperopia, astigmatism, etc., and the observer visually recognizes the liquid crystal display device 100 via the shutter glasses 280.
- the shutter glasses 280 are designed to be worn simultaneously with so-called glasses for correcting myopia, hyperopia, astigmatism and the like.
- the left eye shutter 282 and the right eye shutter 284 are each made of liquid crystal.
- the left-eye shutter 282 and the right-eye shutter 284 may be manufactured using TN (Twisted Nematic) liquid crystal, or may be manufactured using OCB (Optically Compensated Bend) liquid crystal.
- the right eye shutter 284 of the shutter glasses 280 is open and the left eye shutter 282 is closed.
- the left eye image and the right eye image displayed on the liquid crystal display device 100 in the stereoscopic display mode are switched at high speed, and accordingly, the opening and closing of the left eye and right eye shutters 282 and 284 are also switched at high speed. In this way, the observer can visually recognize the image displayed on the liquid crystal display device 100 in a three-dimensional manner.
- the liquid crystal display device 100 can perform display in the flat display mode as well as the stereoscopic display mode.
- the liquid crystal display device 100 performs display by switching between the stereoscopic display mode and the flat display mode.
- the stereoscopic display mode may be referred to as 3D display
- the flat display mode may be referred to as 2D display.
- FIG. 1C is a schematic diagram of the liquid crystal display device 100 that performs display in the flat display mode.
- the observer can visually recognize a normal display without using the shutter glasses 280.
- the switching between the stereoscopic display mode and the flat display mode is performed. Based on.
- switching between the stereoscopic display mode and the flat display mode may be performed based on a command from an observer or the like.
- vertical scanning period means a period until a pixel is selected and then the pixel is selected, Typically, this means a period from when a scanning line for selecting a pixel to be written is selected until the next scanning line is selected.
- One vertical scanning period in a general liquid crystal panel that does not perform double speed driving corresponds to one frame period of the input video signal when the input video signal is a signal for non-interlace driving, and the input video signal is interlaced. In the case of the signal for use, it corresponds to one field period of the input video signal.
- one vertical scanning period of the liquid crystal display device is 16.7 ms that is the reciprocal of the field frequency (60 Hz) of the NTSC signal.
- the reciprocal of the field frequency of the NTSC signal is the vertical scanning period.
- the difference (period) between the time for selecting a certain scanning line and the time for selecting the next scanning line is referred to as one horizontal scanning period (1H).
- the “frame update period” corresponds to a period from the start of writing of a certain frame to the start of writing of the next frame.
- the “frame update period” is the first time that the scan wiring (typically the scan wiring located at the upper end of the liquid crystal display device) is selected corresponding to a certain frame, and then the first frame corresponding to the next frame.
- a scanning wiring typically, a scanning wiring located at the upper end of the liquid crystal display device
- the “vertical scanning period” described above is defined for each pixel or row of pixels of the liquid crystal display device, whereas the “frame update period” is defined for the liquid crystal display device.
- the lengths of the “vertical scanning period” and the “frame update period” are equal, but the starting points may not be the same depending on the pixel of interest.
- vertical scanning period when simply referred to as “vertical scanning period” or “frame period”, “vertical scanning period” and “frame period” are “vertical scanning period of a liquid crystal display device or a liquid crystal panel”, “ “Frame period of liquid crystal display device or liquid crystal panel” means “vertical scanning period”, “frame period” (ie, “vertical scanning period of liquid crystal display device or liquid crystal panel”, “frame of liquid crystal display device or liquid crystal panel” "Period”) is used in a different meaning from “vertical scanning period of input video signal” and "frame period of input video signal”.
- the “vertical scanning period of the input video signal” is a period of one frame or one field of the input video signal.
- the liquid crystal display device displays the left eye image and the right eye image.
- the period during which the left eye image and the right eye image are continuously displayed is long, the observer The right eye image itself is visually recognized, and a stereoscopic image cannot be visually recognized. For this reason, it is preferable that the period during which the display of the left eye image and the right eye image is continued is short.
- a plurality of scanning lines are selected within the frame update period, and writing is performed on the pixels corresponding to the selected scanning lines.
- writing is performed in order. For example, in the frame update period in which the left eye image is written, the pixels in each row from the pixels in the row corresponding to the scanning wiring at the upper end of the liquid crystal display device 100 to the pixels in the row corresponding to the scanning wiring at the lower end of the liquid crystal display device 100.
- the left eye image data is written every time. Further, in the frame update period in which the right-eye image is written, each pixel in each row from the pixel in the row corresponding to the scanning wiring at the upper end of the liquid crystal display device 100 to the pixel in the row corresponding to the scanning wiring at the lower end of the liquid crystal display device 100.
- the right eye image data is written in The plurality of pixels are each divided into one or more blocks corresponding to two or more rows, and after writing sequentially in the same polarity as one pixel of the odd and even rows in the block, Writing may be sequentially performed on the other pixel in the block with a polarity different from that of the one pixel.
- the writing of the left eye image data is completed in a part of the liquid crystal display device 100 (for example, the upper part). Regardless, there is a period in which the writing of the left eye image data is not completed in another part (for example, the lower part) of the liquid crystal display device 100 and the right eye image data is still written. Similarly, in the frame update period in which the image data to be written is changed from the left eye image data to the right eye image data, the writing of the right eye image data is completed in a part of the liquid crystal display device 100 (for example, the upper part).
- the left eye image data and the right eye image data are alternately written every two consecutive frame update periods, and the liquid crystal display device 100 displays both the left eye image and the right eye image.
- the backlight unit 250 is turned off and / or both the left eye shutter 282 and the right eye shutter 284 of the shutter glasses 280 are closed. Thereby, crosstalk can be suppressed.
- the backlight unit 250 is turned on and the left eye shutter 282 of the shutter glasses 280 is turned on in the second frame update period of the two frame update periods in which the left eye image data is continuously written.
- the observer visually recognizes the left eye image.
- the backlight unit 250 and opening the right eye shutter 284 of the shutter glasses 280 in the second frame update period of the two frame update periods in which the right eye image data is continuously written The observer visually recognizes the right eye image.
- the conventional liquid crystal display device is driven at a vertical scanning frequency of 60 Hz
- a liquid crystal display device driven at a vertical scanning frequency of 120 Hz has been produced in order to realize high-speed driving.
- This driving of the liquid crystal display device is also called double speed driving.
- such a liquid crystal display device of double speed driving is driven at a vertical scanning frequency of 120 Hz and stereoscopic display is performed without deteriorating moving image performance, it is necessary to switch the left eye image and the right eye image for each frame update period. Become. In this case, for example, the blanking time from when the right eye image data is written to all the pixels until the next writing of the left eye image data is started is only 1 msec or less.
- the right eye shutter is opened after the liquid crystal molecules below the liquid crystal display device responds. Then, since the left eye image data has already been written in the upper pixel of the liquid crystal display device, the viewer sees not only the right eye image but also the left eye image, and crosstalk occurs. .
- a liquid crystal display device that is driven at a vertical scanning frequency of 240 Hz is used, the left eye image and the right eye image are written in the liquid crystal display device that has a vertical scanning frequency of 120 Hz once during the writing of the left eye image and the right eye image once.
- each image can be written twice, for example, even if the shutter glasses are opened during the second frame update period of 4.2 msec or more, both the left eye image and the right eye image are not visually recognized, and the cross The occurrence of talk can be suppressed.
- one stereoscopic image is visually recognized by one left eye image and one right eye image, it can be said that a 60 Hz stereoscopic image is visually recognized by driving the liquid crystal display device at a vertical scanning frequency of 240 Hz. .
- the liquid crystal display device is preferably driven at a relatively high vertical scanning frequency in the stereoscopic display mode.
- the influence of the signal delay of the liquid crystal display device becomes large, and appropriate display may not be performed.
- the aperture ratio is reduced due to the expansion of the wiring width.
- the liquid crystal display device 100 of the present embodiment is driven at a lower vertical scanning frequency in the flat display mode than in the stereoscopic display mode. Thereby, power consumption in the flat display mode can be reduced without reducing the aperture ratio.
- the liquid crystal display device 100 is driven at a vertical scanning frequency of 240 Hz in the stereoscopic display mode, and is driven at a vertical scanning frequency of 120 Hz in the flat display mode.
- the liquid crystal display device 100 includes a frame rate control circuit 110, a timing controller 120, a writing state signal transmission circuit 130, a scanning signal driving circuit 140, a display signal driving circuit 150, a backlight driving circuit 160, and a liquid crystal panel. 200 and a backlight unit 250.
- the scanning signal driving circuit 140 is also called a gate driver
- the display signal driving circuit 150 is also called a source driver.
- the liquid crystal panel 200 has a plurality of pixels arranged in a matrix of a plurality of rows and a plurality of columns.
- a red pixel, a green pixel, and a blue pixel are provided as pixels
- a color display pixel composed of a red pixel, a green pixel, and a blue pixel functions as a display unit of an arbitrary color.
- the color display pixel may further include another pixel (for example, a yellow pixel) in addition to the red, green, and blue pixels.
- the liquid crystal panel 200 includes a front substrate, a rear substrate, and a liquid crystal layer sandwiched between them.
- an input video signal having a frame rate of 60 fps is input to the frame rate control circuit 110.
- the input video signal is an NTSC signal.
- the frame rate control circuit 110 generates a video signal having a frame rate higher than the frame rate of the input video signal based on the input video signal. Since the frame rate of the video signal generated by the frame rate control circuit 110 is a predetermined value, this process is also called FRC (Frame Rate Control).
- FRC Full Rate Control
- the number of fields per second included in an input video signal displayed on a general television device is 60, and the frame rate of this input video signal is expressed as 60 fps (frames per second).
- the frame rate control circuit 110 generates a video signal with a frame rate of 120 fps based on an input video signal with a frame rate of 60 fps.
- the video signal includes image data to be displayed in the stereoscopic display mode.
- the video signal includes image data to be displayed in the flat display mode.
- the video signal is expressed as 24p in the BD standard or the like, for example, 2-3 pull-down conversion is performed before being input to the frame rate control circuit 110, and the frame rate control circuit 110 has a frame rate of 60 fps. Input video signal is input.
- the timing controller 120 controls the writing state signal transmission circuit 130, the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160.
- the timing controller 120 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 150.
- the timing controller 120 sets the frame rate of the display signal to 240 fps.
- the timing controller 120 sets the frame rate of the display signal to 120 fps.
- the timing controller 120 varies the frame rate of the display signal according to the display mode.
- the scanning signal driving circuit 140 supplies a scanning signal for selecting a pixel to be written on the liquid crystal panel 200.
- the display signal driving circuit 150 supplies a display signal to the selected pixel of the liquid crystal panel 200.
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency corresponding to the frame rate of the display signal.
- the timing controller 120 varies the display signal frame rate according to the display mode, whereby the vertical scanning frequency of the liquid crystal panel 200 can be varied according to the display mode.
- the writing state signal transmission circuit 130 transmits a writing state signal indicating a writing state of a plurality of pixels in the stereoscopic display mode.
- the shutter glasses 280 open and close the left eye shutter 282 and the right eye shutter 284 based on the writing state signal.
- the backlight driving circuit 160 drives the backlight unit 250.
- FIG. 3A is a schematic diagram of the liquid crystal display device 100 that performs display in the stereoscopic display mode
- FIG. 4 is a schematic diagram illustrating opening and closing of the writing state signal transmission circuit 130 and the shutter glasses 280.
- the image data shown in FIG. 3A is enlarged and shown in FIG. 5A is a schematic diagram of image data included in the input video signal
- FIG. 5B is a schematic diagram of image data included in the video signal
- FIG. 5C is included in the display signal. It is a schematic diagram of image data.
- an input video signal having a frame rate of 60 fps is input to the frame rate control circuit 110, and this input video signal includes image data to be displayed in the stereoscopic display mode.
- left eye image data and right eye image data are shown alternately.
- the left eye image data corresponds to 30 fps
- the right eye image data corresponds to 30 fps.
- the left eye image data L1, the right eye image data R1, the left eye image data L2, the right eye image data R2,... are arranged in this order (FIG. 5A). See also).
- right eye image data R0 and left eye image data L0 are arranged in front of left eye image data L1.
- the frame rate control circuit 110 generates a video signal having a frame rate higher than the frame rate of 60 fps of the input video signal based on the input video signal.
- the frame rate of the video signal is set to 120 fps.
- the frame rate control circuit 110 duplicates one set of left-eye image data and right-eye image data of the input video signal, and repeatedly arranges this set in the video signal.
- the image data is arranged in the order of R0, L1, R1, L1, R1, L2, R2,... In the video signal (see also FIG. 5B).
- the frame rate of the video signal is set to 120 fps.
- the left eye image data corresponds to 60 fps
- the right eye image data corresponds to 60 fps.
- the frame rate (120 fps) of the video signal is set to twice the frame rate (60 fps) of the input video signal.
- the frame rate control circuit 110 is manufactured using one application specific integrated circuit (ASIC) having relatively high versatility. be able to.
- ASIC application specific integrated circuit
- the timing controller 120 controls the writing state signal transmission circuit 130, the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160.
- the timing controller 120 generates a display signal having a frame rate of 240 fps based on the video signal having a frame rate of 120 fps.
- the timing controller 120 duplicates the left-eye image data and the right-eye image data of the video signal, respectively, and sequentially arranges the left-eye image data and the right-eye image data two by two on the display signal.
- the image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,... (FIG. 5C).
- the frame rate (240 fps) of the display signal is set to twice the frame rate (120 fps) of the video signal.
- the timing controller 120 outputs a display signal to the display signal driving circuit 150.
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency of 240 Hz.
- the left eye image data corresponds to 120 fps
- the right eye image data corresponds to 120 fps.
- the writing state signal transmission circuit 130 transmits a writing state signal to the shutter glasses 280.
- the writing state signal transmission circuit 130 outputs a writing state signal to the shutter glasses 280, whereby when the liquid crystal panel 200 displays a left eye image, the left eye shutter 282 of the shutter glasses 280 is opened, and the liquid crystal panel 200 When displaying the right eye image, the right eye shutter 284 of the shutter glasses 280 is opened.
- High (high) corresponding to the right eye image and Low (low) corresponding to the left eye image are output from the timing controller 120 to the write state signal transmission circuit 130, and the write state signal transmission circuit 130 outputs high (low) and low (low) binarization signals to the shutter glasses 280 based on the binarization signals as write state signals.
- the writing state signal when the writing state signal is Low and the liquid crystal panel 200 displays a left eye image, the left eye shutter 282 is opened and the right eye shutter 284 is closed.
- the writing state signal When the writing state signal is High and the liquid crystal panel 200 displays a right eye image, the right eye shutter 284 is opened and the left eye shutter 282 is closed.
- the writing state signal may be an infrared signal, a signal conforming to the Bluetooth standard, or a radio wave signal.
- the write status signal is preferably transmitted wirelessly.
- the left eye image data and the right eye image data are continuously arranged in the display signal by two.
- the backlight unit 250 converts the left eye image data and right eye image data, which are arranged in succession two by two, into the previous image data.
- the light is turned off and turned on corresponding to the subsequent image data.
- the backlight unit 250 is controlled to be turned on / off, the liquid crystal panel 200 appears to be performing impulse display even if it is hold-driven.
- FIG. 3B is a schematic diagram of the liquid crystal display device 100 that performs display in the flat display mode.
- the image data included in the signal shown in FIG. 3B is enlarged and shown in FIG. 6A is a schematic diagram of image data included in the input video signal, FIG. 6B is a schematic diagram of image data included in the video signal, and FIG. 6C is included in the display signal. It is a schematic diagram of image data.
- An input video signal having a frame rate of 60 fps is input to the frame rate control circuit 110, and this input video signal includes image data to be displayed in the flat display mode.
- the image data is arranged in the order of N1, N2, N3, N4... In the input video signal (see also FIG. 6A).
- the image data N0 is arranged before the image data N1.
- the frame rate control circuit 110 generates a video signal having a frame rate higher than the frame rate of 60 fps of the input video signal based on the input video signal.
- the frame rate of the video signal is set to 120 fps.
- the frame rate control circuit 110 generates one piece of interpolated image data based on two continuous image data of the input video signal, arranges the two continuous image data in the video signal, and outputs the interpolated image data. They are arranged between the two consecutive image data.
- the frame rate control circuit 110 generates the interpolated image data C0 based on the image data N0 and N1, arranges the image data N0 and N1 of the input video signal in the video signal, and the image data N0 and the image Interpolated image data C0 is arranged between the data N1.
- the frame rate control circuit 110 generates interpolated image data C1 based on the image data N1 and N2, and arranges the interpolated image data C1 and the image data N2 after the image data N1 of the input video signal in the video signal.
- the moving image display performance can be improved by using the interpolated image data generated based on the two continuous image data.
- image data is arranged in the order of C0, N1, C1, N2, C2, N3, C3, N4...
- the video signal includes the image data included in the input video signal and the interpolated image data generated by the interpolation alternately, and the frame rate (120 fps) of the video signal is the frame rate (120 fps) of the input video signal. 60 fps).
- the timing controller 120 controls the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160.
- the timing controller 120 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 150.
- the frame rate of the display signal is set to 120 fps similarly to the frame rate of the video signal.
- the display signal includes image data arranged in the order of C0, N1, C1, N2, C2, N3, C3, N4... (See also FIG. 6C).
- the frame rate (120 fps) of the signal is set equal to the frame rate (120 fps) of the video signal.
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency of 120 Hz.
- the backlight drive circuit 160 controls the backlight unit 250 so that the backlight unit 250 is lit in all periods.
- the backlight driving circuit 160 is within the display screen area.
- the illumination area of the backlight unit 250 may be controlled to be turned on / off according to the gradation level of the pixel.
- the vertical scanning frequency of the liquid crystal panel 200 changes according to the display mode under the control of the timing controller 120. Specifically, the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz in the stereoscopic display mode, and is driven at a vertical scanning frequency of 120 Hz in the flat display mode. For this reason, an increase in power consumption in the flat display mode can be suppressed.
- the frame rate control circuit 110 generates the interpolated image data based on the continuous image data of the input video signal in the plane display mode.
- the frame rate is increased by duplicating the image data of the input video signal.
- the frame rate can be easily increased by duplicating the image data instead of generating the interpolated image data.
- the frame rate control circuit 110 also generates interpolated left eye image data based on continuous left eye image data included in the input video signal even in the stereoscopic display mode, and similarly, the right eye image included in the input video signal. Interpolated right eye image data may be generated based on the data, thereby further improving the moving image display performance in the stereoscopic display mode.
- the stereoscopic display system 900 includes a liquid crystal display device 700 and shutter glasses 880.
- the liquid crystal display device 700 includes a frame rate control circuit 710, a timing controller 720, a writing state signal transmission circuit 730, a scanning signal driving circuit 740, a display signal driving circuit 750, a backlight driving circuit 760, and a liquid crystal panel. 800 and a backlight unit 850.
- the frame rate of the video signal generated by the frame rate control circuit 710 is set to 240 fps, and the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz in both the stereoscopic display mode and the flat display mode. 700 and the stereoscopic display system 900 are different from the liquid crystal display device 100 and the stereoscopic display system 300.
- FIG. 7A is a schematic diagram of a liquid crystal display device 700 that performs display in the stereoscopic display mode.
- the image data shown in FIG. 7A is enlarged and shown in FIG.
- FIG. 8A is a schematic diagram of image data included in the input video signal
- FIG. 8B is a schematic diagram of image data included in the video signal
- FIG. 8C is included in the display signal. It is a schematic diagram of image data.
- An input video signal with a frame rate of 60 fps is input to the frame rate control circuit 710.
- image data is arranged in the order of L1, R1, L2, R2,... (See also FIG. 8A).
- right eye image data R0 and left eye image data L0 are arranged in front of left eye image data L1.
- the display is performed in the stereoscopic display mode.
- the frame rate control circuit 710 generates a video signal having a frame rate higher than the frame rate of 60 fps of the input video signal based on the input video signal.
- the frame rate of the video signal is set to 240 fps.
- the frame rate control circuit 710 duplicates the left-eye image data and the right-eye image data of the input video signal, and 2 sets of one set in which the left-eye image data and the right-eye image data are continuously arranged two by two. Repeat the set. Therefore, in the video signal output from the frame rate control circuit 710, the image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, R1, L2, L2,. (See also FIG. 8 (b)). As described above, the left-eye image data and the right-eye image data are alternately arranged in the video signal by two.
- a frame rate control circuit 710 that generates a video signal with a frame rate of 240 fps uses two special-purpose integrated circuits 712a and 712b that are relatively versatile. Produced.
- the special purpose integrated circuit 712a is used for driving the left half of the liquid crystal panel 800
- the special purpose integrated circuit 712b is used for driving the right half of the liquid crystal panel 800.
- the timing controller 720 controls the writing state signal transmission circuit 730, the scanning signal driving circuit 740, the display signal driving circuit 750, and the backlight driving circuit 760.
- the timing controller 720 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 750.
- the frame rate of the display signal is set to 240 fps, which is equal to the frame rate of the video signal.
- the display signal includes image data R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,. .. are arranged in the order (see also FIG. 8C). For this reason, the scanning signal driving circuit 740 and the display signal driving circuit 750 drive the liquid crystal panel 800 at a vertical scanning frequency of 240 Hz.
- the backlight driving circuit 760 controls the backlight unit 850, so that the backlight unit 850 corresponds to the previous image data of the left eye image data and the right eye image data arranged in succession. Turns off and lights up corresponding to later image data.
- the shutter glasses 880 Based on the writing state signal from the writing state signal transmission circuit 730, the shutter glasses 880 opens the left eye shutter 882 during the period in which the liquid crystal panel 800 displays the left eye image, and the liquid crystal panel 800 displays the right eye image. Open the right eye shutter 884 during the period.
- FIG. 7B is a schematic diagram of a liquid crystal display device 700 that performs display in the flat display mode. Note that image data included in the signal shown in FIG. 7B is enlarged and shown in FIG.
- FIG. 9A is a schematic diagram of image data included in the input video signal
- FIG. 9B is a schematic diagram of image data included in the video signal
- FIG. 9C is included in the display signal. It is a schematic diagram of image data.
- An input video signal with a frame rate of 60 fps is input to the frame rate control circuit 710.
- image data is arranged in the order of N1, N2, N3, N4... (See also FIG. 9A). Although not shown here, the image data N0 is arranged before the image data N1.
- the frame rate control circuit 710 generates a video signal having a frame rate of 240 fps based on the input video signal. For example, the frame rate control circuit 710 generates interpolated image data C0a, C0b, C0c based on the image data N0 and N1 of the input video signal, arranges the image data N0, N1 in the video signal, and sets the image data N0. Interpolated image data C0a, C0b, and C0c are arranged between the image data N1.
- the frame rate control circuit 710 generates interpolated image data C1a, C1b, and C1c based on the image data N1 and N2 of the input video signal, and the interpolated image data C1a, C1b is generated in the video signal after the image data N1. , C1c and image data N2 are arranged. As described above, the frame rate control circuit 710 generates three pieces of interpolated image data based on two consecutive image data included in the input video signal, and the continuous two image data together with the two continuous image data are generated in the video signal. Three interpolated image data are arranged between the two image data.
- the image data is arranged in the order of N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4. (See also FIG. 9B).
- the frame rate (240 fps) of the video signal output from the frame rate control circuit 710 is four times the frame rate (60 fps) of the input video signal.
- the timing controller 720 controls the scanning signal driving circuit 740, the display signal driving circuit 750, and the backlight driving circuit 760. Note that the timing controller 720 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 750.
- the frame rate of the display signal is set to 240 fps, which is equal to the frame rate of the video signal, and the display signal includes image data N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4... Are arranged in this order (see also FIG. 9C).
- the scanning signal driving circuit 740 and the display signal driving circuit 750 drive the liquid crystal panel 800 at a vertical scanning frequency of 240 Hz.
- the backlight drive circuit 760 controls the backlight unit 850 so that the backlight unit 850 is lit in all periods.
- the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz regardless of the stereoscopic display mode and the flat display mode. For this reason, power consumption increases.
- the liquid crystal display device 100 of this embodiment in the flat display mode, the liquid crystal panel 200 is driven at a vertical scanning frequency of 120 Hz, which is half that of the stereoscopic display mode, so that an increase in power consumption can be suppressed.
- the power consumption of the liquid crystal display device 700 is 24 W
- the power consumption of the liquid crystal display device 100 is 15 W.
- the frame rate control circuit 710 conforming to the full high-definition liquid crystal panel 800 is manufactured using a general-purpose integrated circuit with relatively high versatility
- the two special-purpose integrated circuits 712a and 712b are formed. It is necessary to use it.
- the special purpose integrated circuit 712a is driven to control the left half pixel of the display screen of the liquid crystal panel 800
- the special purpose integrated circuit 712b is driven to control the right half pixel of the display screen of the liquid crystal panel 800.
- the frame rate control circuit 110 can be manufactured using one application specific integrated circuit having relatively high versatility.
- the timing controller 120 needs to generate a display signal with a frame rate of 240 fps.
- image data may be duplicated. Therefore, cost and circuit scale can be suppressed.
- the frame rate of the input video signal input to the liquid crystal display device 100 is 60 fps, but the present invention is not limited to this.
- the frame rate of the input video signal may be another value.
- the input video signal may be a PAL signal, and the frame rate of the input video signal may be 50 fps.
- the frame rate of the video signal is set to 100 fps
- the frame rate of the display signal is set to 200 fps in the stereoscopic display mode, and is set to 100 fps in the flat display mode.
- the backlight unit 250 in the liquid crystal display device 100 of the present embodiment has eight irradiation areas 252 that can be individually controlled to be turned on and off.
- Each of the irradiation regions 252 is arranged so as to irradiate at least one row of pixels of the liquid crystal panel 200, and the pixels provided in the liquid crystal panel 200 are irradiated by one of the plurality of irradiation regions 252.
- a light source (not shown) is provided corresponding to the irradiation region 252, and this light source is provided along a plurality of rows of pixels provided in the liquid crystal panel 200.
- the light source may be an LED (Laser Emitting Diode) or a cold cathode tube (Cold Cathode Fluorescent Lamp: CCFL).
- the backlight unit 250 may have a divided light guide plate, or may have a light guide plate having a slit structure.
- the plurality of irradiation areas 252 start to turn on in order, and turn off after a predetermined period.
- FIG. 10A only one irradiation region 252 is turned on in a certain period and the other irradiation regions 252 are turned off. However, two or more irradiation regions 252 may be turned on in a certain period.
- FIG. 10B shows the timing of writing the left eye image data and right eye image data to the liquid crystal panel 200 in the stereoscopic display mode and opening / closing the shutter glasses 280.
- the vertical scanning frequency is 240 Hz.
- the writing of the left eye image data in the liquid crystal panel 200 will be described. As described above, the writing of the left eye image is performed continuously for two frame update periods. After the second left-eye image data is written to the liquid crystal panel 200, lighting of the corresponding irradiation region 252 of the backlight unit 250 is started.
- the alignment direction of the liquid crystal molecules depends on the previous right eye image data even after one vertical scanning period has elapsed since the first left eye image data was written. For example, even if the gradation levels of the left eye image data are equal, if the gradation levels of the right eye image data written before that are different, one vertical scan is performed after the first left eye image data is written. The alignment directions of the liquid crystal molecules immediately after the lapse of time are not equal. For this reason, lighting of the corresponding irradiation region 252 is started after a predetermined period has elapsed since the second writing of the left eye image data.
- the corresponding irradiation region 252 is turned off immediately before the right eye image data is written or after a predetermined time has elapsed since the right eye image data was written. If the liquid crystal molecules respond in a short time, in principle, the irradiation region 252 should be turned off before the right-eye image data is written. Since time is required, even after the right eye image data is written, the orientation direction of the liquid crystal molecules depends on the left eye image data written before the right eye image data, for a while. Therefore, even if the irradiation region 252 is lit during this period, there is substantially no problem.
- the operation of opening the left eye shutter 282 is started at the start of the frame update period in which the second writing of the left eye image is performed.
- the left-eye shutter 282 opens before the irradiation area 252 is first turned on within this frame update period.
- the period during which each irradiation region 252 is lit is within the period during which the left-eye shutter 282 is open. Since the left eye shutter 282 is open during the period in which the irradiation area 252 is lit, the period during which the irradiation area 252 is lit corresponds to the luminance of the pixel. As described above, the luminance of the left eye image can be increased by continuing lighting of the corresponding irradiation region 252 after the right eye image data is written.
- the left eye image and the right eye image are displayed in different periods in the liquid crystal display device 100, if the luminance at the edge portion of a certain object included in the image on which the stereoscopic display is performed is not properly displayed, the stereoscopic display is appropriately performed. I can't do it. Therefore, it is preferable to perform control so that the observer does not visually recognize the display corresponding to the left eye (or right eye) image data that depends on the immediately preceding right eye (or left eye) image data.
- the illumination region 252 is turned on and off in order corresponding to the lower end portion from the upper end portion of the liquid crystal panel 200.
- the left-eye shutter 282 starts an operation of closing after the irradiation region 252 is finally turned off within this frame update period.
- the right eye image is written continuously for two frame update periods. For the same reason as described above, lighting of the corresponding irradiation region 252 of the backlight unit 250 is started after a predetermined period has elapsed since the second right-eye image data was written to the liquid crystal panel 200. The irradiation region 252 is turned off immediately before the next left eye image data is written or after a predetermined period has elapsed since the next left eye image data was written.
- the period during which each of the irradiation areas 252 is lit is within the period during which the right-eye shutter 284 is open. Since the right-eye shutter 284 is open during the period in which the irradiation area 252 is lit, the period during which the irradiation area 252 is lit corresponds to the luminance of the pixel. As described above, the luminance of the right eye image can be increased by continuing lighting of the corresponding irradiation region 252 even after the left eye image data is written.
- the left-eye shutter 282 is open during at least a part of the period during which the liquid crystal display device 100 that performs display in the stereoscopic display mode displays the left-eye image, and is closed during the other periods.
- the period during which the liquid crystal display device 100 displays the left eye image does not have to coincide with the frame period during which the left eye image is written.
- the right eye shutter 284 is open during at least a part of the period during which the liquid crystal display device 100 that performs display in the stereoscopic display mode displays the right eye image, and is closed during the other periods.
- the period during which the left eye image and the right eye image are viewed with respect to the display period of the liquid crystal panel 200 is about 1/8.
- the left eye shutter of the shutter glasses 280 at the end of the frame update period in which the first writing of each of the left eye image data and the right eye image data is performed.
- both 282 and the right eye shutter 284 are closed, the present invention is not limited to this.
- the backlight unit 250 is provided with eight irradiation areas 252.
- the number of irradiation areas provided in the backlight unit 250 may be any number.
- FIG. 11A is a waveform diagram of scanning signal voltages supplied to a plurality of scanning wirings
- FIG. 11B is a schematic diagram showing lighting / non-lighting of the backlight unit 250.
- FIG. ) Is a schematic diagram showing opening and closing of the shutter glasses 280.
- the right-eye image data is written in the first frame update period (1F) and the second frame update period (2F), and left in the third frame update period (3F) and the fourth frame update period (4F).
- the eye image data is written.
- the first frame update period (1F) a plurality of scanning wirings are selected in order.
- the left eye shutter 282 of the shutter glasses 280 remains open over the first frame update period.
- all of the plurality of irradiation areas 252 provided in the backlight unit 250 are lit. Therefore, at the start time of the first frame update period, the left eye of the observer The image is visible.
- the scanning wiring is selected in the first frame update period, the corresponding irradiation regions 252 are turned off in turn, and the observer does not visually recognize the left eye image.
- the second frame update period (2F) a plurality of scan wirings are selected in order. Over the second frame update period, the left eye shutter 282 of the shutter glasses 280 remains closed and the right eye shutter 284 remains open. Further, at the start of the second frame update period, all of the plurality of irradiation areas 252 provided in the backlight unit 250 are turned off, and the observer does not visually recognize the left eye image at this time. As the scanning wiring is selected in the second frame update period, the corresponding irradiation areas 252 are sequentially turned on, and accordingly, the observer visually recognizes the right eye image.
- the third frame update period (3F) a plurality of scanning wirings are selected in order. Over the third frame update period, the right eye shutter 284 of the shutter glasses 280 remains open. Further, at the start of the third frame update period, all of the plurality of irradiation areas 252 provided in the backlight unit 250 are lit, and at this point, the observer visually recognizes the right eye image. As the scanning wiring is selected in the third frame update period, the corresponding irradiation areas 252 are sequentially turned off, and the observer does not visually recognize the right eye image.
- the fourth frame update period (4F) a plurality of scan wirings are selected in order. Over the fourth frame update period, the right eye shutter 284 of the shutter glasses 280 remains closed and the left eye shutter 282 remains open. At the start of the fourth frame update period, the plurality of irradiation areas 252 provided in the backlight unit 250 are all turned off, and at this time, the observer does not visually recognize the left eye image. As the scanning wiring is selected in the fourth frame update period, the corresponding irradiation areas 252 are sequentially turned on, and accordingly, the observer visually recognizes the left eye image.
- the liquid crystal panel 200 performs display in the stereoscopic display mode
- one of the left eye shutter 282 and the right eye shutter 284 of the shutter glasses 280 is open, and the viewer visually recognizes that the backlight unit 250 is turned on.
- -It may change according to the lights off.
- the backlight unit 250 may have one irradiation region that can be turned on and off, and the entire liquid crystal panel 200 may be irradiated with light from the irradiation region.
- the backlight unit 250 is turned on for a certain period, irradiates the entire liquid crystal panel 200 with light, and is turned off for another period.
- FIG. 12B shows the timing of writing the left eye image data and right eye image data to the liquid crystal panel 200 in the stereoscopic display mode and opening / closing the shutter glasses 280.
- the lighting of the backlight unit 250 is started immediately before the end of the frame update period for performing the second writing of the left eye image, and the backlight unit 250 is turned off after a predetermined period has elapsed since the start of the frame update period for writing the right eye image data. During this period, the orientation direction of the liquid crystal molecules at the upper end of the liquid crystal panel 200 in which the right eye image data is first written in the frame update period in which the right eye image data is written does not depend on the left eye image data written first. It is a period.
- the backlight unit 250 may have two irradiation areas.
- the backlight unit 250 has an irradiation area 252a that irradiates the upper half of the liquid crystal panel 200 and an irradiation area 252b that irradiates the lower half of the liquid crystal panel 200.
- FIG. 13B shows the timing of writing the left eye image data and right eye image data to the liquid crystal panel 200 in the stereoscopic display mode and opening / closing the shutter glasses 280.
- the irradiation area 252a starts to light immediately after the second writing of the left eye image data is completed for the row of pixels near the center of the liquid crystal panel 200, and the right eye image data Turns off immediately before start of frame update period for writing.
- writing of the right eye image data among the pixels corresponding to the irradiation region 252a is performed after the second writing of the left eye image data among the pixels corresponding to the irradiation region 252a is performed last. Is the period until the first time.
- the illumination region 252b starts to light up immediately before the end of the frame update period in which the second writing of the left eye image is performed, and the right eye image data is written to the row of pixels near the center of the liquid crystal panel 200. Turns off immediately before starting. During the lighting period of the irradiation region 252b, writing of the right eye image data among the pixels corresponding to the irradiation region 252b is performed after the second writing of the left eye image data is finally performed among the pixels corresponding to the irradiation region 252b. Is the period until the first time.
- the illumination areas 252a and 252b are turned on during the period when the left-eye shutter 282 is open. The right eye image data is written in the same manner.
- the irradiation area of the backlight unit 250 is simply separated for each of a plurality of rows. It is preferable that the plurality of columns are separated.
- the backlight unit 250 is controlled to be turned on and off in the stereoscopic display mode.
- the backlight unit 250 is always turned on, and only the shutter glasses 280 are opened and closed. The image to be viewed may be switched.
- a high contrast ratio can be realized by turning on and off the backlight unit 250.
- the backlight unit 250 has a plurality of irradiation regions 252
- the gray level of the pixel corresponding to the irradiation region 252 is also obtained in the flat display mode in order to achieve a high contrast ratio.
- the lighting area 252 may be turned on and off according to the above.
- FIG. 14 shows a schematic diagram of the liquid crystal panel 200.
- the liquid crystal panel 200 includes a front substrate 210, a rear substrate 220, and a liquid crystal layer 230 provided between the front substrate 210 and the rear substrate 220.
- the front substrate 210 has a transparent insulating substrate 212 and a counter electrode 214
- the back substrate 220 has a transparent insulating substrate 222 and a pixel electrode 224.
- a pixel is defined by the pixel electrode 224.
- the shape of the pixel may be a rectangular shape or a shape extending in two orthogonal directions.
- the front substrate 210 and the back substrate 220 are also called a counter substrate and an active matrix substrate, respectively.
- the liquid crystal layer 230 includes a nematic liquid crystal material having a negative dielectric anisotropy, and is displayed in a normally black mode in combination with a polarizing plate arranged in a crossed Nicol arrangement.
- the front substrate 210 is further provided with a color filter layer, an alignment film, and the like
- the rear substrate 220 has a scanning wiring, an insulating layer, and a source wiring.
- a thin film transistor (TFT), an alignment film, and the like are further provided.
- a polarizing plate is provided outside the front substrate 210 and the back substrate 220.
- the display signal driving circuit 150 supplies a display signal (source signal) to the source wiring.
- a display signal source signal
- the timing controller 120 described above receives the counter signal supplied to the counter electrode 214 (and further assists if necessary).
- a display signal supplied to the source wiring is generated in consideration of the auxiliary capacitance signal supplied to the capacitor wiring.
- the transmittance of the liquid crystal layer (that is, the luminance of the pixel) is changed by controlling the voltage applied to the liquid crystal layer between the counter electrode and the pixel electrode.
- the voltage applied to the liquid crystal layer becomes an AC voltage. Is set as follows. Specifically, the potential relationship between the pixel electrode and the counter electrode is reversed every fixed time, and the direction of the electric field applied to the liquid crystal layer (the direction of the lines of electric force) is reversed every fixed time. Is done.
- a positive polarity (+) indicates that the potential of the pixel electrode is higher than that of the counter electrode, and a negative polarity (if the potential of the pixel electrode is lower than the potential of the counter electrode).
- the polarity represents the direction of the electric field applied to the liquid crystal layer.
- a display signal having a higher potential than the counter electrode is supplied to the source wiring.
- negative polarity ( ⁇ ) when writing with negative polarity ( ⁇ ) is performed, a display signal having a lower potential than the counter electrode is supplied to the source wiring.
- the left-eye image data is written over the continuous two-frame update period, and each pixel corresponds to the left-eye image data over two vertical scanning periods. Exhibits brightness. Further, the writing of the right eye image data is performed over another continuous two-frame update period, and each pixel exhibits luminance corresponding to the right eye image data over two vertical scanning periods. At this time, if the polarity of the pixel is reversed during two vertical scanning periods in which the right eye image data and the left eye image data are written, the pixel may not exhibit a predetermined luminance.
- a signal delay is caused because a time for selecting a scanning wiring and supplying a voltage to the pixel electrode 224 (that is, a time for charging the liquid crystal layer 230) is short.
- the potential of the pixel electrode 224 does not reach a predetermined potential, and as a result, the pixel does not exhibit a predetermined luminance.
- the potential of the pixel electrode 224 changes greatly every vertical scanning period, the potential of the pixel electrode 224 does not reach the luminance corresponding to the gradation level, and the pixel does not exhibit a predetermined luminance.
- the right eye image data is written with negative polarity
- the left eye image data is written with positive polarity
- the left eye image data is written with negative polarity
- the gradation of the right eye image data written before that is written.
- the levels are different, the luminance of a plurality of pixels in which the left eye image data is written at the same gradation level may be different from each other. In this way, by reversing the pixel polarity for each vertical scanning period, the display of the target right-eye image or left-eye image is affected by the immediately preceding left-eye image or right-eye image. Is visually recognized as display unevenness.
- the wiring resistance is reduced by increasing the wiring width and the signal It is preferable to suppress the influence of the delay, and thereby display unevenness can be suppressed.
- the wiring width is increased as described above, the aperture ratio of the liquid crystal panel 200 may be lowered.
- the polarities of the respective pixels are made equal over two vertical scanning periods in which the writing of the right eye image data and the left eye image data is continuously performed. As a result, it is possible to suppress a decrease in aperture ratio as well as display unevenness.
- FIG. 15A shows a change in the potential VLs of the display signal based on the potential Vcom of the counter electrode 214 in the liquid crystal panel 200 in the stereoscopic display mode
- FIG. 15B shows a waveform of the scanning signal voltage VLg
- FIG. 15C shows a change in the potential Vpe of the pixel electrode 224 with reference to the potential Vcom of the counter electrode 214
- FIG. 15D shows whether the specific irradiation region 252 of the backlight unit 250 is turned on / off. Illumination is shown, and the opening and closing of the shutter glasses 280 is shown in FIG.
- one vertical scanning period (frame update period) is about 4.2 ms.
- the liquid crystal panel 200 complies with the high vision standard, and the period during which one scanning line is selected is about 3.4 ⁇ s. This period corresponds to the horizontal scanning period.
- the vertical scanning period is 8.4 ms, and the period during which one scanning wiring is selected is 6.8 ⁇ s.
- the relationship between the potential of the display signal supplied to each source line and the potential of the counter electrode does not change over the frame update period, and is adjacent in the column direction at the end of the frame update period.
- the polarities of the pixels are equal to each other. Therefore, a change in the potential of the display signal within the frame update period can be reduced, and power consumption can be reduced.
- the positive polarity display signal voltage is supplied to the source wiring in the first frame update period, but the negative polarity is applied to the source wiring adjacent to the source wiring in the first frame update period. A display signal voltage is supplied.
- the maximum value and the minimum value of the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 are +7 V and ⁇ 7 V, respectively, and the potential Vpe of the pixel electrode 224 with reference to the potential Vcom of the counter electrode 214 is It varies within this range.
- the gradation level of this pixel does not change from the first frame update period (1F) to the fourth frame update period (4F), and the gradation level of this pixel of the left eye image data is the gradation of the right eye image data. It is almost equal to the level.
- this pixel corresponds to a central portion of an object included in an image on which stereoscopic display is performed.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the scanning signal voltage for selecting a certain pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as a target potential, and the target potential corresponds to the gradation level of the potential difference between the counter electrode 214 and the pixel electrode 224. Is set to In this manner, charging of the liquid crystal layer 230 proceeds by supplying the display signal voltage to the pixel electrode 224.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz, and since the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 224 is relatively short, the potential of the pixel electrode 224 reaches the target potential.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the irradiation region 252 of the backlight unit 250 is extinguished at least during the first frame update period, and the right-eye image written in the first frame update period is not visually recognized by the observer. Further, the right eye shutter 284 opens in the second half of the first frame update period.
- the second frame update period (2F) a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the display signal voltage supplied to the source wiring uses the potential of the pixel electrode 224 as the target potential having the same polarity as the target potential in the first frame update period. Is set to For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the target potential in the second frame update period is equal to the target potential in the first frame update period.
- the target potential in the second frame update period is the first potential due to overdrive driving or the like. It may be different from the target potential in the frame update period.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- a display signal having a lower potential than the counter electrode 214 is supplied to the source wiring in the third frame update period.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as the target potential, but the target potential in the third frame update period is set to a polarity different from that in the second frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the backlight unit 250 remains lit at the start of the third frame update period, but is turned off before the left-eye image data is written in the third frame update period, and the third frame is updated.
- the left eye image written in the update period is not visually recognized by the observer.
- the left eye shutter 282 is opened in the second half of the third frame update period.
- a display signal indicating a lower potential than the counter electrode 214 is supplied to the source wiring.
- writing of the left eye image is performed continuously for two frame update periods.
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the polarity written in the fourth frame update period is equal to that in the third frame update period, and the display signal voltage supplied to the source line sets the potential of the pixel electrode 224 to the target potential having the same polarity as the target potential in the third frame update period. Is set to For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the left eye image data is written with the same polarity for two consecutive vertical scanning periods
- the right eye image data is written with the same polarity for two consecutive vertical scanning periods. Further, display unevenness can be suppressed.
- a so-called double speed drive liquid crystal panel can be used as the liquid crystal panel 200.
- the occurrence of flicker can be suppressed by reversing the polarity of the pixels every two vertical scanning periods.
- the right eye image data is written with a positive polarity and the left eye image data is written with a negative polarity.
- the luminance of the pixel to which the right-eye image data is written is the same as that of the pixel to which the left-eye image data is written. Unlike brightness, proper display may not be performed.
- the right eye image data is written with a plus polarity and a minus polarity according to the period, and similarly, the left eye image data is also written with a plus polarity and a minus polarity according to the period.
- FIG. 16A shows a change in the potential VLs of the source wiring with reference to the potential Vcom of the counter electrode 214
- FIG. 16B shows a waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 is shown.
- FIG. 16D shows lighting / non-lighting of the backlight unit 250, and FIG. Shows opening and closing.
- the relationship between the potential of the display signal supplied to each source wiring and the potential of the counter electrode does not change within the frame update period. For this reason, a change in the potential of the display signal within the frame update period can be reduced, and power consumption is reduced.
- this pixel corresponds to a central portion of an object included in an image on which stereoscopic display is performed.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the scanning signal voltage for selecting a certain pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as a target potential, and the target potential corresponds to the gradation level of the potential difference between the counter electrode 214 and the pixel electrode 224. Is set to In this manner, charging of the liquid crystal layer 230 proceeds by supplying the display signal voltage to the pixel electrode 224.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz, and the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 224 is relatively short, the potential of the pixel electrode 224 reaches the target potential. Before the scanning signal voltage is returned to the off voltage. Note that the irradiation region 252 of the backlight unit 250 is extinguished at least during the first frame update period, and the right-eye image written in the first frame update period is not visually recognized by the observer. Further, the right eye shutter 284 opens in the second half of the first frame update period.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the display signal voltage supplied to the source wiring uses the potential of the pixel electrode 224 as the target potential having the same polarity as the target potential in the first frame update period. Is set to For this reason, the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- a display signal having a higher potential than the counter electrode 214 is supplied to the source wiring in the third frame update period.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set to a target potential having the same polarity as the second frame update period. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the backlight unit 250 remains lit at the start of the third frame update period, but is turned off before the left-eye image data is written in the third frame update period, and in the third frame update period.
- the written left eye image is not visually recognized by the observer.
- the left eye shutter 282 is opened in the second half of the third frame update period.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage is set so that the polarity written in the fourth frame update period is equal to that in the third frame update period, and the potential of the pixel electrode 224 is equal to the target potential in the third frame update period.
- the potential of 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- a display signal indicating a lower potential than the counter electrode 214 is supplied to the source wiring.
- a scanning signal voltage for selecting a certain pixel becomes an on-voltage
- a display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential, but the target potential in the fifth frame update period is set to a polarity different from that in the fourth frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the irradiation region 252 of the backlight unit 250 is extinguished at least during the fifth frame update period, and the right-eye image written in the fifth frame update period is not visually recognized by the observer. Also, the right eye shutter 284 is opened in the second half of the fifth frame update period.
- the polarity of the display signal voltage and the polarity of the pixel electrode 224 are different from the second frame update period (2F) to the fourth frame. This is the same as the update period (4F), and redundant description is omitted to avoid redundancy.
- the polarity of the pixel may be reversed every four vertical scanning periods.
- the right eye image data and the left eye image data are written with the same polarity for every two vertical scanning periods, so that a decrease in aperture ratio and display unevenness can be suppressed. Further, by reversing the polarity of the pixels every four vertical scanning periods, the right eye image data is written with positive polarity and negative polarity and the left eye image data is written with positive polarity and negative polarity according to the vertical scanning period. As a result, luminance deviation due to polarity can be suppressed.
- display signal voltages having different polarities are supplied to adjacent source lines, but the present invention is not limited to this.
- the display signal voltage having the same polarity may be supplied to all the source wirings in a certain frame update period.
- the polarity of the display signal voltage supplied to each source line may be inverted every horizontal scanning period.
- the liquid crystal panel 200 may be driven by dot inversion. That is, the polarity of the pixels adjacent in the row direction and the column direction may be reversed at the end of a certain frame update period.
- the pixels arranged in a matrix are selected in order from the upper end to the lower end of the liquid crystal panel, but the present invention is not limited to this.
- the plurality of pixels are each divided into one or more blocks corresponding to two or more rows, and after writing sequentially in the same polarity as one pixel of the odd and even rows in the block, Writing may be sequentially performed on the other pixel in the block with a polarity different from that of the one pixel.
- pixels correspond to a plurality of blocks in the liquid crystal panel 200
- the other pixels are sequentially written with a polarity different from that of the one pixel. For example, after writing in order to one pixel in an odd row and even row in a block, write in order to the other pixel, and then in turn to one pixel in an odd row and even row in the next block. After writing to the pixel, writing is sequentially performed on the other pixel.
- Such driving is also called block inversion driving.
- the number of pixel rows included in each block that is, the number of scanning wirings) is equal to each other.
- the number of rows of pixels included in each block may be different.
- Such source line inversion driving and block inversion are described in International Publication No. 2008/139963, and the description of International Publication No. 2008/139963 is incorporated herein by reference.
- FIG. 17A shows the polarity of pixels written in the block and the order in which writing is performed. For example, after a pixel having a different polarity is written to a pixel adjacent in a row direction in a certain horizontal scanning period, a row of pixels in which writing is performed in the immediately preceding horizontal scanning period in the next horizontal scanning period. The pixel adjacent to is skipped and writing is performed with the same polarity as the polarity of the immediately preceding horizontal scanning period to the pixels in the row that is two rows away from the row of pixels that were written in the immediately preceding horizontal scanning period. Similarly, writing is performed in order with the same polarity every other row.
- writing is sequentially performed on the pixel rows skipped by the previous writing in the block with a polarity different from the previous writing.
- This writing is also performed with the same polarity every other row.
- the writing of the positive polarity is performed on the pixels of the even-numbered rows
- the writing of the negative polarity is performed on the pixels of the odd-numbered rows.
- FIG. 17B shows a change in the potential VLs of the source wiring with the potential Vcom of the counter electrode 214 as a reference.
- attention is paid to a change in the potential VLs within one frame update period of a specific source wiring in the liquid crystal panel 200 divided into two blocks.
- this source wiring within one frame update period, for example, a positive polarity write is performed on odd-numbered rows of pixels in the first block, then a negative polarity write is performed on even-numbered rows of pixels, and then The positive polarity writing is performed on the odd-numbered pixels in the second block, and the negative polarity writing is performed on the even-numbered pixels.
- negative polarity writing is performed on the odd-numbered pixels in the first block, and then positive polarity writing is performed on the even-numbered pixels in the source wiring adjacent to the source wiring.
- negative polarity writing is performed on the odd-numbered pixels in the second block, and then positive polarity writing is performed on the even-numbered pixels.
- FIG. 18A shows a change in the potential VLs of the display signal based on the potential Vcom of the counter electrode 214 in the liquid crystal panel 200 in the stereoscopic display mode
- FIG. 18B shows a waveform of the scanning signal voltage VLg
- FIG. 18C shows a change in the potential Vpe of the pixel electrode 224 with reference to the potential Vcom of the counter electrode 214
- FIG. 18D shows whether the specific irradiation region 252 of the backlight unit 250 is turned on / off. Illumination is shown, and the opening and closing of the shutter glasses 280 is shown in FIG. 18 is the same as FIG. 15 described above except that the change in the potential VLs of the display signal shown in FIG. 18A is different, and redundant description is omitted to avoid redundancy.
- the relationship between the potential of the display signal supplied to the source wiring and the potential of the counter electrode does not change over about 1 ⁇ 4 of the frame update period, so that power consumption can be reduced. it can.
- odd-numbered rows of pixels in the first block are written with positive polarity
- odd-numbered rows of pixels in the second block are written with positive polarity
- even rows of pixels are written with negative polarity.
- the polarities of pixels adjacent in the column direction are different from each other at the end of the frame update period.
- FIG. 18A attention is paid to the source wiring in which the polarity of the display signal voltage changes to plus, minus, plus, and minus polarity in the first frame update period.
- the polarity of the display signal voltage supplied to the source line adjacent to the gate line changes to minus, plus, minus, and plus polarity.
- FIG. 18B the period during which the scanning signal voltage VLg is on is 3.4 ⁇ s.
- FIG. 18C attention is paid to a change in the potential Vpe of the pixel electrode 224 of a specific pixel selected when a positive polarity display signal is supplied from the source wiring in the frame update period.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity is performed.
- the potential of the pixel electrode 224 may not reach the target potential.
- the polarity of the display signal supplied to this source line changes to plus, minus, plus and minus polarity.
- the right eye image is written continuously for two frame update periods.
- a display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the polarity in the first frame update period is performed.
- the target potential in the second frame update period is equal to the target potential in the first frame update period.
- the target potential in the second frame update period is the first potential due to overdrive driving or the like. It may be different from the target potential in the frame update period.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- the polarity of the display signal supplied to the source line changes to minus, plus, minus, and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as the target potential, but the target potential in the third frame update period is set to a polarity different from that in the second frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a negative polarity equal to the third frame update period is performed. For this reason, the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the left eye image data is written with the same polarity for each pixel for two vertical scanning periods, and the right eye image data for each pixel is written for two vertical scanning periods.
- the same polarity Therefore, a decrease in aperture ratio and display unevenness can be suppressed, and a so-called double speed driving liquid crystal panel can be used as the liquid crystal panel 200.
- the occurrence of flicker can be suppressed by reversing the polarity of the pixels every two vertical scanning periods.
- the right eye image data is written with positive polarity and the left eye image data is written with negative polarity in the pixel.
- the gradation levels of the right eye image data and the left eye image data of a certain pixel are equal to each other.
- the luminance of the pixel in which the right eye image data is written is different from the luminance of the pixel in which the left eye image data is written, and appropriate display may not be performed.
- the right eye image data is written with a positive polarity and a negative polarity according to the period, and similarly, the left eye image data is also written with a positive polarity and a negative polarity according to the period.
- FIG. 19A shows a change in the potential VLs of the source wiring with reference to the potential Vcom of the counter electrode 214
- FIG. 19B shows a waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 is shown.
- FIG. 19D shows lighting / non-lighting of the backlight unit 250
- FIG. 19E shows shutter glasses 280. Shows opening and closing.
- the relationship between the potential of the display signal supplied to the source wiring and the potential of the counter electrode does not change over about 1 ⁇ 4 of the frame update period, so that power consumption can be reduced. it can.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus and plus polarity.
- FIG. 19C attention is paid to a change in the potential Vpe of the pixel electrode 224 of a specific pixel selected when a positive polarity display signal is supplied to the source wiring in the frame update period.
- FIG. 19 is the same as FIG. 18 described above except that the change in the potential VLs of the display signal shown in FIG. 19A is different, and redundant description is omitted to avoid redundancy.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential.
- the scan signal voltage is set to the off voltage before the potential of the pixel electrode 224 reaches the target potential. May return.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the second frame update period is performed. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes an on-voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the third frame update period is performed, and the potential of the pixel electrode 224 becomes the target Reach potential.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential, but the target potential in the fifth frame update period is set to a polarity different from that in the fourth frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the sixth frame update period (6F) to the eighth frame update period (8F) are the second frame update period (2F) except that the polarity of the display signal voltage is reversed and the polarity of the pixel electrode 224 is different.
- the polarity of each pixel may be inverted every four vertical scanning periods.
- the pixel may be divided into three or more blocks. Further, the number of blocks may be set according to the irradiation region 252 of the backlight unit 250, for example.
- odd-numbered lines and even-numbered lines in a continuous block are written alternately.
- the present invention is not limited to this.
- Writing one of the odd and even rows across successive blocks may be performed sequentially. For example, after writing a positive polarity to the odd-numbered pixels in the first block, writing a negative polarity to the even-numbered pixels in the first block, and then writing a negative polarity to the even-numbered pixels in the second block After that, positive polarity writing may be performed on the pixels in the odd-numbered rows of the second block.
- plus polarity writing may be performed on pixels in odd rows in the third block, and minus polarity writing may be performed on pixels in even rows in the third block.
- the left-eye image data and the right-eye image data are each written in 2 vertical scanning periods, and the polarity of each pixel is inverted every 2 or 4 vertical scanning periods.
- the present invention is not limited to this.
- the polarity of each pixel may be inverted every two or more even vertical scanning periods.
- the polarity of each pixel may be inverted every six or eight or more vertical scanning periods.
- the right eye image data and the left eye image data written for the second time are equal to the right eye image data and the left eye image data written for the first time, respectively.
- writing at the same gradation level is performed twice, the present invention is not limited to this.
- the gradation level of the image data may be set based on the gradation level of certain image data and the gradation level of the image data immediately before the image data.
- the gradation level is set so that the change amount of the gradation level is larger than the original change amount.
- the gradation level corresponding to the low effective voltage changes to the gradation level corresponding to the high effective voltage in the continuous image data
- the gradation level is set to correspond to a higher effective voltage.
- the gradation level corresponding to the high effective voltage changes to the gradation level corresponding to the low effective voltage in the continuous image data
- the gradation level is set to correspond to a lower effective voltage.
- Such driving is also called overdrive driving.
- FIG. 20 shows a schematic diagram of a stereoscopic display system 300 that performs overdrive driving.
- the timing controller 120 includes a signal duplicating unit 122 and an overdrive driving unit 124.
- the frame rate control circuit 110 generates a video signal having a frame rate higher than the frame rate of 60 fps of the input video signal based on the input video signal.
- image data is arranged in the order of R0, L1, R1, L1, R1, L2, R2, L2,.
- the signal duplicating unit 122 generates a display signal with a frame rate of 240 fps based on a video signal with a frame rate of 120 fps. Specifically, the signal duplicating unit 122 duplicates the left eye image data and the right eye image data of the video signal, respectively, and the left eye image data and the right eye image data are continuously added to the display signal by two each. Arrange.
- the image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, R1, L2, L2, R2, R2, L2, L2,.
- the overdrive drive unit 124 creates new image data based on the target image data and the previous image data. Specifically, a new gradation level is set for each of the plurality of pixels based on the gradation level of the target image data and the gradation level of the previous image data.
- the image data of the display signal output from the signal duplication unit 122 When the image data of the display signal output from the signal duplication unit 122 does not change, overdrive driving is not performed.
- the function OS (X ⁇ Y) indicates the image data of the display signal output from the overdrive drive unit 124 when the image data of the display signal output from the signal duplication unit 122 changes from X to Y. Yes.
- the gradation level of a pixel in the image data R0 corresponds to a low voltage
- the gradation level of the pixel in the image data L1 corresponds to a high voltage.
- the low voltage indicates that the absolute value of the applied voltage of the liquid crystal layer 230 of the liquid crystal panel 200 is small
- the high voltage indicates that the absolute value of the applied voltage of the liquid crystal layer 230 of the liquid crystal panel 200 is large.
- the liquid crystal panel 200 is in the normally black mode, and the luminance corresponding to the low voltage is higher than the luminance corresponding to the high voltage.
- a voltage VL1 'that is higher than the voltage VL1 corresponding to the gradation level of the image data L1 is applied to the liquid crystal layer 230.
- the overdrive driving unit 124 sets a gradation level higher than the gradation level obtained by the signal duplicating unit 122. .
- Such driving is also called overshoot driving.
- a voltage VL1 'that is lower than the voltage VL1 corresponding to the gradation level of the image data L1 is applied to the liquid crystal layer 230.
- the overdrive driving unit 124 corresponds to a voltage lower than the gradation level obtained by the signal duplicating unit 122.
- Such driving is also called undershoot driving.
- the overshoot drive and the undershoot drive are collectively referred to as overdrive drive.
- the term overshoot drive may be used in the same meaning as overdrive drive in this specification. Further, in that case, the term undershoot driving may refer to driving that applies a voltage corresponding to a gradation lower than the target gradation.
- the display signal output from the overdrive drive unit 124 includes image data R0, R0, L1 ′, L1, R1 ′, R1, L1 ′, L1, R1 ′, R1, L2 ′, L2, R2 ′, R2. , L2 ′, L2... Therefore, the potential of the pixel electrode 224 can be set to the target potential even in the vertical scanning period in which the right eye image data and the left eye image data are switched.
- the backlight unit 250 lights up in correspondence with the vertical scanning period of the latter half of the right eye image data and the left eye image data written continuously for two vertical scanning periods. Specifically, the backlight unit 250 is turned off during the period in which the image data subjected to overdrive driving is written, and is turned on in the period in which the next image data is written.
- the left eye shutter 282 of the shutter glasses 280 is opened during a period in which the liquid crystal panel 200 displays a left eye image and the backlight unit 250 is lit, and is closed during other periods.
- the right eye shutter 284 of the shutter glasses 280 is opened during a period in which the liquid crystal panel 200 displays a right eye image and the backlight unit 250 is lit, and is closed during other periods.
- the potential of the pixel electrode 224 quickly reaches the target potential. Therefore, the illumination region 252 of the backlight unit 250 is turned on and the shutter glasses 280 are opened quickly to increase the luminance. May be. For example, when the shutter glasses 280 are opened, the irradiation region 252 of the backlight unit 250 may be turned on as soon as the second writing of the left eye image data and the right eye image data is completed.
- overdrive driving may be performed with reference to a lookup table, or may be performed by arithmetic processing. Alternatively, the overdrive drive may be performed by combining both.
- overdrive driving is performed based on the gradation level of the target image data and the gradation level of the previous image data, but the present invention is not limited to this.
- the overdrive drive may be performed based on the gradation level of the target image data and the gradation levels of the two image data before the image data.
- the overdrive driving may be performed based on the gradation level of the target image data and the gradation level of at least one image data before the image data.
- the signal duplicating unit 122 duplicates the image data as described above, but the image signal is to be displayed in the flat display mode. If included, the signal duplicating unit 122 does not duplicate the image data.
- the liquid crystal panel 200 may have a multi-pixel structure. By having a plurality of sub-pixels in which each pixel can have a different luminance, the viewing angle dependency of the ⁇ characteristic can be improved.
- FIG. 21 shows a schematic diagram of one pixel in the liquid crystal panel 200.
- the pixel P has a sub-pixel Spa and a sub-pixel Spb.
- the subpixel Spa is defined by the subpixel electrode 224a
- the subpixel Spb is defined by the subpixel electrode 224b.
- two source lines Lsa and Lsb are provided for the pixels P in one column.
- the subpixel electrodes 224a and 224b are connected to different source wirings Lsa and Lsb via different TFTs 226a and 226b, and are driven so that the potentials of the two subpixel electrodes 224a and 224b are different at least in a certain intermediate gradation. . Since the voltages applied to the liquid crystal layers of the sub-pixels Spa and Spb are different due to the different potentials of the sub-pixel electrodes 224a and 224b in this way, the luminance of the sub-pixels Spa and Spb is different from each other. Figured.
- FIG. 22 shows a schematic diagram of one pixel in another liquid crystal panel 200.
- the pixel P has a sub-pixel Spa and a sub-pixel Spb.
- the subpixel Spa is defined by the subpixel electrode 224a
- the subpixel Spb is defined by the subpixel electrode 224b.
- the sub-pixel Spa has a liquid crystal capacitor and an auxiliary capacitor CCa, and the liquid crystal capacitor is constituted by the counter electrode 214, the sub-pixel electrode 224a, and the liquid crystal layer 230 provided therebetween.
- the auxiliary capacitance CCa is composed of an auxiliary capacitance electrode electrically connected to the sub-pixel electrode 224a, an auxiliary capacitance counter electrode EOa electrically connected to the auxiliary capacitance line Lcsa, and an insulating layer provided therebetween. It is configured.
- the subpixel Spb has a liquid crystal capacitor and an auxiliary capacitor CCb.
- This liquid crystal capacitance is constituted by a counter electrode 214, a sub-pixel electrode 224b, and a liquid crystal layer 230 provided therebetween.
- the auxiliary capacitor CCb includes an auxiliary capacitor electrode electrically connected to the sub-pixel electrode 224b, an auxiliary capacitor counter electrode electrically connected to the auxiliary capacitor line Lcsb, and an insulating layer provided therebetween. It is constituted by.
- the subpixel electrodes 224a and 224b are connected to the same source line Ls via different TFTs 226a and 226b. At least in a certain intermediate gray scale level, the two subpixel electrodes 224a and 224b are driven so that the average potentials differ according to the auxiliary capacitance signal supplied to the auxiliary capacitance lines Lcsa and Lcsb. For example, when the average potential of one of the two subpixel electrodes 224a and 224b increases from the potential corresponding to the display signal voltage supplied to the source line Ls, the display signal voltage of the other average potential supplied to the source line Ls. Decreases from the potential corresponding to.
- the sub-pixel electrodes 224a and 224b have different average potentials, the voltages applied to the liquid crystal layers of the sub-pixels are different, so that the luminances of the sub-pixels Spa and Spb are different from each other, thereby improving whitening. .
- one source wiring is provided for one column of pixels, so that a decrease in aperture ratio and an increase in power consumption are suppressed.
- FIG. 23 shows an equivalent circuit of the liquid crystal panel 200 shown in FIG.
- the storage capacitor lines Lcsa and Lcsb are respectively supplied with storage capacitor signals from the storage capacitor trunk lines Ltcsa and Ltcsb.
- the scanning signal voltage supplied to the scanning wiring Lg changes from the off voltage to the on voltage, and thereby the TFTs 226a and 226b are turned on.
- the scanning line Lg selects a pixel
- the display signal voltage supplied to the source line Ls is applied to the sub-pixel electrodes 224a and 224b.
- the scanning signal voltage supplied to the scanning wiring Lg changes from the on voltage to the off voltage, and thereby the TFTs 226a and 226b change to the off state.
- the auxiliary capacitance signal voltage supplied to the auxiliary capacitance lines Lcsa and Lcsb changes in different directions, whereby the potential of the sub-pixel electrode 224a changes.
- the first change of the auxiliary capacitance signal supplied to the auxiliary capacitance line Lcsa after the TFTs 226a and 226b are changed to the off state with respect to the pixel P on which the positive polarity is written is an increase, and the auxiliary capacitance line Lcsb is increased.
- the initial change of the auxiliary capacitance signal supplied to is a decrease, the luminance of the sub-pixel Spa is higher than that of the sub-pixel Spb.
- the first change of the auxiliary capacitance signal supplied to the auxiliary capacitance line Lcsa after the TFTs 226a and 226b change to the off state with respect to the pixel P on which the negative polarity is written is an increase, and the auxiliary capacitance line Lcsb is increased. If the initial change in the auxiliary capacitance signal supplied to is reduced, the luminance of the subpixel Spa is lower than that of the subpixel Spb.
- the sub-pixel electrodes 224a and 224b have substantially the same potential when the TFTs 226a and 226b are in the on state, but the auxiliary capacitance signal voltage supplied to the auxiliary capacitance lines Lcsa and Lcsb after the TFTs 226a and 226b are changed to the off state. Therefore, the effective potentials of the subpixel electrodes 224a and 224b can be made different, whereby the luminance of the subpixels Spa and Spb can be made different to improve the viewing angle dependency of the ⁇ characteristic.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 120 Hz in the flat display mode and is driven at a vertical scanning frequency of 240 Hz in the stereoscopic display mode.
- the effective voltage may not be appropriately changed due to a signal delay of the auxiliary capacitance signal supplied to the auxiliary capacitance wiring.
- the same auxiliary capacitance signal may be supplied to different auxiliary capacitance lines.
- multi-pixel driving is realized by supplying different auxiliary capacitance signals to the auxiliary capacitance lines Lcsa and Lcsb in the flat display mode, and the stereoscopic display mode.
- multi-pixel driving may not be realized by supplying the same auxiliary capacitance signal to the auxiliary capacitance lines Lcsa and Lcsb.
- the liquid crystal panel 200 having the multi-pixel structure as shown in FIGS. 21 to 23 when the liquid crystal panel 200 performs display in the flat display mode, multi-pixel driving is performed, and the liquid crystal panel 200 is in the stereoscopic display mode. When performing display, multi-pixel driving may not be performed. When the liquid crystal panel 200 performs display in the stereoscopic display mode, it is assumed that the observer observes the liquid crystal panel 200 from a limited range. For this reason, in the flat display mode, by performing multi-pixel driving, the luminance of the sub-pixel Spa is made different from the luminance of the sub-pixel Spb at least in a certain intermediate gradation, while the viewing angle characteristics are improved.
- the luminance of the sub-pixel Spa may be made equal to the luminance of the sub-pixel Spb at an arbitrary gradation without performing multi-pixel driving.
- the luminance of the sub-pixel Spa may be made equal to the luminance of the sub-pixel Spb at an arbitrary gradation without performing multi-pixel driving.
- the frame rate control circuit generates a video signal with a frame rate of 120 fps, but the present invention is not limited to this.
- the frame rate control circuit may generate a video signal having a frame rate of 240 fps.
- 24A and 24B are schematic diagrams of the liquid crystal display device 100A and the stereoscopic display system 300A according to the present embodiment.
- the stereoscopic display system 300A includes a liquid crystal display device 100A and shutter glasses 280.
- the liquid crystal display device 100A includes a frame rate control circuit 110, a timing controller 120, a writing state signal transmission circuit 130, a scanning signal driving circuit 140, a display signal driving circuit 150, a backlight driving circuit 160, and a liquid crystal panel. 200 and a backlight unit 250.
- the liquid crystal display device 100A and the stereoscopic display system 300A have the same configuration as the liquid crystal display device 100 and the stereoscopic display system 300 described above except that the frame rate control circuit 110 generates a video signal having a frame rate of 240 fps. In order to avoid redundancy, redundant description is omitted.
- FIG. 25A is a schematic diagram of image data included in the input video signal
- FIG. 25B is a schematic diagram of image data included in the video signal
- FIG. 25C is included in the display signal. It is a schematic diagram of image data.
- an input video signal having a frame rate of 60 fps is input to the frame rate control circuit 110.
- the input video signal is an NTSC signal.
- This input video signal includes image data to be displayed in the stereoscopic display mode. Left-eye image data and right-eye image data are alternately shown in the input video signal.
- the video signal is arranged in the order of image data L1, R1, L2, R2,. (See also FIG. 25 (a)).
- right eye image data R0 and left eye image data L0 are arranged in front of left eye image data L1.
- the frame rate control circuit 110 generates a video signal higher than the frame rate of the input video signal based on the input video signal having a frame rate of 60 fps.
- the frame rate of the video signal is set to 240 fps.
- the frame rate control circuit 110 duplicates the left eye image data and the right eye image data of the input video signal, respectively, and one set in which the left eye image data and the right eye image data are successively arranged in the video signal. Repeat two sets. Thereby, two left eye image data and two right eye image data are alternately arranged in the video signal.
- image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,... (FIG. 25B).
- the frame rate (240 fps) of the video signal is set to four times the frame rate (60 fps) of the input video signal.
- the frame rate of the video signal is set to 240 fps, among which the left eye image data corresponds to 120 fps and the right eye image data corresponds to 120 fps.
- the frame rate control circuit 110 that generates a video signal with a frame rate of 240 fps uses two special-purpose integrated circuits 112a and 112b having relatively high versatility. Produced.
- the special purpose integrated circuit 112 a is used for driving the left half of the liquid crystal panel 200
- the special purpose integrated circuit 112 b is used for driving the right half of the liquid crystal panel 200.
- the timing controller 120 controls the writing state signal transmission circuit 130, the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160. Note that the timing controller 120 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 150.
- the frame rate of the display signal is set to 240 fps, which is equal to the frame rate of the video signal.
- the display signal includes image data R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,.
- the display signal frame rate (240 fps) is set equal to the video signal frame rate (240 fps).
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency of 240 Hz.
- the left eye image data corresponds to 120 fps
- the right eye image data corresponds to 120 fps.
- the writing state signal transmission circuit 130 transmits a writing state signal indicating a writing state of a plurality of pixels in the stereoscopic display mode.
- the shutter glasses 280 open and close the left eye shutter 282 and the right eye shutter 284 based on the writing state signal.
- FIG. 24B is a schematic diagram of a liquid crystal display device 100A that performs display in the flat display mode. Note that the image data included in the signal shown in FIG. 24B is enlarged and shown in FIG. 26A is a schematic diagram of image data included in the input video signal, FIG. 26B is a schematic diagram of image data included in the video signal, and FIG. It is a schematic diagram of the image data contained in the video signal to be performed.
- An input video signal with a frame rate of 60 fps is input to the frame rate control circuit 110.
- image data is arranged in the order of N1, N2, N3, and N4 (see also FIG. 26A). Although not shown here, the image data N0 is arranged before the image data N1.
- the frame rate control circuit 110 generates a video signal having a frame rate of 240 fps, which is higher than the frame rate of 60 fps of the input video signal, based on the input video signal. For example, the frame rate control circuit 110 generates three interpolated image data based on two consecutive image data included in the input video signal, and the two image data together with the two image data in the video signal. Three pieces of interpolated image data are arranged in between.
- the frame rate control circuit 110 generates interpolation image data C0a, C0b, C0c based on the image data N0 and N1 of the input video signal, arranges the image data N0, N1 in the video signal, Interpolated image data C0a, C0b, and C0c are arranged between the image data N0 and the image data N1.
- the image data is N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4. They are arranged (see also FIG. 26 (b)).
- the video signal includes the image data included in the input video signal and the interpolated image data generated by the interpolation, and the frame rate (240 fps) of the video signal is the frame rate (60 fps) of the input video signal. Is set to 4 times.
- the timing controller 120 controls the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160.
- the timing controller 120 generates a display signal having a frame rate of 120 fps, which is lower than the frame rate of 240 fps of the video signal.
- the timing controller 120 generates a display signal by thinning out part of the image data of the video signal.
- the video signal includes image data of N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4.
- the timing controller 120 thins out the image data C0a, C0c, C1a, C1c, C2a, C2c, C3a, C3c. As described above, the timing controller 120 thins out every other image data included in the video signal, so that the frame rate of the display signal becomes half that of the video signal.
- the display signal includes image data arranged in the order of N0, C0b, N1, C1b, N2, C2b, N3, C3b, N4... (See also FIG. 26C).
- the frame rate (120 fps) is set to half the frame rate (240 fps) of the video signal.
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency of 120 Hz.
- the backlight drive circuit 160 controls the backlight unit 250 so that the backlight unit 250 is lit in all periods.
- the vertical scanning frequency of the liquid crystal panel 200 driven by the display signal driving circuit 150 and the backlight driving circuit 160 changes according to the display mode under the control of the timing controller 120. Specifically, the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz in the stereoscopic display mode, and is driven at a vertical scanning frequency of 120 Hz in the flat display mode. For this reason, an increase in power consumption in the flat display mode can be suppressed.
- the frame rate control circuit 110 increases the frame rate by generating interpolated image data based on continuous image data of the input video signal in the flat display mode.
- the frame rate is increased by duplicating the image data of the input video signal in the stereoscopic display mode.
- the frame rate can be easily increased by duplicating the image data instead of generating the interpolated image data.
- the frame rate control circuit 110 generates interpolated left eye image data based on continuous left eye image data included in the input video signal even in the stereoscopic display mode, and similarly, the right eye image included in the input video signal. Interpolated right eye image data may be generated based on the data.
- the stereoscopic display system 900A includes a liquid crystal display device 700A and shutter glasses 880.
- the liquid crystal display device 700A includes a frame rate control circuit 710, a timing controller 720, a writing state signal transmission circuit 730, a scanning signal driving circuit 740, a display signal driving circuit 750, a backlight driving circuit 760, and a liquid crystal panel.
- the frame rate control circuit 710 generates a video signal having a frame rate of 240 fps based on the input video signal having a frame rate of 60 fps, and the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz in both the stereoscopic display mode and the flat display mode.
- the liquid crystal display device 700A and the stereoscopic display system 900A are different from the liquid crystal display device 100A and the stereoscopic display system 300A.
- An input video signal having a frame rate of 60 fps is input to the frame rate control circuit 710.
- image data is arranged in the order of L1, R1, L2, R2,.
- right eye image data R0 and left eye image data L0 are arranged in front of left eye image data L1.
- the frame rate control circuit 710 generates a display signal with a frame rate of 240 fps based on an input video signal with a frame rate of 60 fps.
- the frame rate control circuit 710 duplicates the left-eye image data and the right-eye image data of the input video signal, respectively, and the left-eye image data and the right-eye image data are successively arranged in the video signal two by two. 1 set is repeated 2 sets. Thereby, two left eye image data and two right eye image data are alternately arranged in the video signal.
- the image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,.
- the frame rate control circuit 710 includes application specific integrated circuits 712a and 712b.
- the timing controller 720 controls the writing state signal transmission circuit 730, the scanning signal driving circuit 740, the display signal driving circuit 750, and the backlight driving circuit 760.
- the timing controller 720 generates a display signal based on the video signal and outputs the display signal to the display signal driving circuit 750.
- the frame rate of the display signal is set to 240 fps, which is equal to the frame rate of the video signal.
- the display signal includes image data R0, R0, L1, L1, R1, R1, L1, L1, R1, L2, L2,. ⁇ ⁇ ⁇ Arranged in the order.
- the scanning signal driving circuit 740 and the display signal driving circuit 750 drive the liquid crystal panel 800 at a vertical scanning frequency of 240 Hz.
- the backlight driving circuit 760 controls the backlight unit 850 so that the backlight unit 850 is turned on corresponding to the subsequent image data of the left eye image data and the right eye image data in which the backlight units 850 are continuously arranged. .
- the shutter glasses 880 opens the left eye shutter 882 during the period in which the liquid crystal panel 800 displays the left eye image, and the liquid crystal panel 800 displays the right eye image. Open the right eye shutter 884 during the period.
- An input video signal having a frame rate of 60 fps is input to the frame rate control circuit 710.
- image data are arranged in the order of N1, N2, N3, N4.
- the image data N0 is arranged before the image data N1.
- the frame rate control circuit 710 generates a video signal having a frame rate of 240 fps based on an input video signal having a frame rate of 60 fps.
- the frame rate control circuit 710 generates three interpolated image data based on two consecutive image data included in the input video signal, arranges the two image data in the video signal, and also outputs the two image data. Three pieces of interpolated image data are arranged in between.
- the image data is arranged in the order of N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4. Has been.
- the timing controller 720 controls the scanning signal driving circuit 740, the display signal driving circuit 750, and the backlight driving circuit 760.
- the timing controller 720 generates a display signal having a frame rate of 240 fps that is equal to the frame rate of 240 fps of the video signal.
- the image data is arranged in the order of N0, C0a, C0b, C0c, N1, C1a, C1b, C1c, N2, C2a, C2b, C2c, N3, C3a, C3b, C3c, N4. Yes.
- the scanning signal driving circuit 740 and the display signal driving circuit 750 drive the liquid crystal panel 800 at a vertical scanning frequency of 240 Hz. Note that in the flat display mode, the backlight drive circuit 760 controls the backlight unit 850 so that the backlight unit 850 is lit in all periods.
- the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz regardless of the stereoscopic display mode and the flat display mode. For this reason, power consumption increases.
- the liquid crystal panel 200 in the flat display mode, is driven at a vertical scanning frequency of 120 Hz, which is half that of the stereoscopic display mode, so that an increase in power consumption can be suppressed.
- the frame rate of the input video signal input to the liquid crystal display device 100A is 60 fps, but the present invention is not limited to this.
- the frame rate of the input video signal may be another value.
- the input video signal may be a PAL signal, and the frame rate of the input video signal may be 50 fps.
- the frame rate of the video signal is set to 200 fps
- the frame rate of the display signal is set to 200 fps in the stereoscopic display mode, and is set to 100 fps in the flat display mode.
- display signal voltages having different polarities may be supplied to adjacent source lines, or display signal voltages having the same polarity may be supplied to all source lines in a certain frame update period. May be. In this case, the polarities of adjacent pixels in the column direction are equal at the end of a certain frame update period.
- the polarity of pixels adjacent in the row direction and the column direction may be reversed at the end of a certain frame update period.
- the polarity of the display signal voltage supplied to each source line may be inverted every horizontal scanning period.
- the liquid crystal panel 200 may be driven by dot inversion.
- the pixels may be selected in order from the upper end to the lower end of the liquid crystal panel, or the pixels arranged in a matrix form are the pixels in the odd and even rows in the block. May be written. For example, writing to each pixel may be performed as described above with reference to FIGS.
- the left eye image data is written on the liquid crystal panel 200 for two consecutive vertical scanning periods, and the right eye image data is written for two consecutive vertical scanning periods.
- the left-eye image data or the right-eye image data is written with a polarity equal to two consecutive vertical scanning periods.
- the left eye image is output even if the display signal voltage is not sufficiently supplied to the pixel electrode 224 by the first writing of the left eye image data or the right eye image data.
- the display signal voltage can be sufficiently supplied to the pixel electrode 224 by the second writing of data or right-eye image data.
- overdrive driving may also be performed in the liquid crystal display device 100A and the stereoscopic display system 300A.
- FIG. 28 shows a schematic diagram of a stereoscopic display system 300A that performs overdrive driving.
- the stereoscopic display system 300A has the same configuration as that of the stereoscopic display system 300 described above with reference to FIG. 20 except that the timing controller 120 does not have the signal duplicating unit 122, so that redundancy is avoided. A duplicate description is omitted.
- the frame rate control circuit 110 generates a video signal having a frame rate of 240 fps, which is higher than the frame rate of 60 fps of the input video signal, based on the input video signal.
- image data is arranged in the order of R0, R0, L1, L1, R1, R1, L1, L1, R1, R1, L2, L2, R2, R2, L2, L2,.
- the overdrive drive unit 124 creates new image data based on the target image data and the previous image data. Specifically, a new gradation level is set for each of the plurality of pixels based on the gradation level of the target image data and the gradation level of the previous image data.
- the image data of the video signal changes from R0 to L1 different from R0
- overdrive driving is performed.
- a voltage VL1 'that is higher than the voltage VL1 corresponding to the gradation level of the image data L1 is applied to the liquid crystal layer 230.
- the overdrive drive unit 124 sets a gradation level that is higher than the gradation level of the image data of the video signal.
- a voltage VL1 'that is lower than the voltage VL1 corresponding to the gradation level of the image data L1 is applied to the liquid crystal layer 230.
- the overdrive driving unit 124 changes the gradation level corresponding to a voltage lower than the gradation level of the image data of the video signal.
- the display signal output from the overdrive drive unit 124 includes image data R0, R0, L1 ′, L1, R1 ′, R1, L1 ′, L1, R1 ′, R1, L2 ′, L2, R2 ′, R2. , L2 ′, L2... Therefore, the potential of the pixel electrode 224 can be set to the target potential even in the vertical scanning period in which the right eye image data and the left eye image data are switched.
- the backlight unit 250 lights up corresponding to the latter half vertical scanning period of the right eye image data and the left eye image data written continuously for two vertical scanning periods. Specifically, the backlight unit 250 is turned off during the period in which the image data subjected to overdrive driving is written, and is turned on in the period in which the next image data is written.
- the left eye shutter 282 of the shutter glasses 280 is opened during a period in which the liquid crystal panel 200 displays a left eye image and the backlight unit 250 is lit, and is closed during other periods.
- the right eye shutter 284 of the shutter glasses 280 is opened during a period in which the liquid crystal panel 200 displays a right eye image and the backlight unit 250 is lit, and is closed during other periods.
- overdrive driving may be performed with reference to a lookup table, or may be performed by arithmetic processing. Alternatively, the overdrive drive may be performed by combining both.
- overdrive driving is performed based on the gradation level of the target image data and the gradation level of the previous image data, but the present invention is not limited to this.
- Overdrive drive may be performed based on the gradation level of the target image data and the gradation levels of two or more previous image data.
- the overdrive driving may be performed based on the gradation level of the target image data and the gradation level of at least one image data before the image data.
- the liquid crystal display device described above can switch between the stereoscopic display mode and the flat display mode, but the present invention is not limited to this.
- the liquid crystal display device may display only in the stereoscopic display mode and may not switch the display mode.
- FIG. 29 shows a liquid crystal display device 100B and a stereoscopic display system 300B of this embodiment.
- the liquid crystal display device 100B of the present embodiment performs display only in the stereoscopic display mode without performing display in the flat display mode.
- the stereoscopic display system 300B of this embodiment includes a liquid crystal display device 100B and shutter glasses 280.
- the liquid crystal display device 100B is driven at a vertical scanning frequency of 240 Hz, for example.
- FIGS. 29 (a) to 29 (d) are schematic diagrams of the stereoscopic display system 300B in successive frame update periods.
- FIGS. 29A to 29D show, for example, the stereoscopic display system 300B at the end of each frame update period.
- the liquid crystal display device 100B displays a right eye image. Both the left eye shutter 282 and the right eye shutter 284 of the shutter glasses 280 are closed.
- the polarities of the pixels of the liquid crystal display device 100B are, for example, the polarities of the pixels adjacent in the column direction are equal, and the polarities of the pixels adjacent in the row direction are inverted.
- the polarity of all the pixels may be positive polarity or negative polarity.
- the polarities of the pixels adjacent in the row direction and the column direction may be reversed from each other.
- the liquid crystal display device 100B displays the right eye image even in the next frame update period. Also in the liquid crystal display device 100B, the right eye image is written over a continuous two-frame update period. At this time, the right eye shutter 284 of the shutter glasses 280 is open, and the observer can visually recognize the right eye image. In the liquid crystal display device 100B, the right-eye image data is written with the same polarity over two consecutive vertical scanning periods, so that the polarity of each pixel is the same as the polarity of the previous frame update period.
- the liquid crystal display device 100B displays the left eye image.
- both the left eye shutter 282 and the right eye shutter 284 of the shutter glasses 280 are closed. Note that the polarity of each pixel is reversed from the polarity of the previous frame update period.
- the liquid crystal display device 100B displays the left eye image even in the next frame update period. Also in the liquid crystal display device 100B, the writing of the left eye image is performed over two consecutive frame update periods. At this time, the left eye shutter 282 of the shutter glasses 280 is open, and the observer can visually recognize the left eye image. In the liquid crystal display device 100B, since the writing of the left eye image data is performed with the same polarity over two consecutive vertical scanning periods, the polarity of each pixel is equal to the polarity of the previous frame update period.
- writing of the left eye image data is performed with the same polarity over two consecutive vertical scanning periods
- writing of the right eye image data is performed with the same polarity over two consecutive vertical scanning periods.
- the luminance of each pixel in the visually recognized period can be changed to a predetermined luminance, and display unevenness can be suppressed. it can.
- liquid crystal display device 100B and the stereoscopic display system 300B will be described with reference to FIG. 30 and FIG.
- FIG. 30A shows a schematic diagram of a stereoscopic display system 300B.
- the liquid crystal display device 100B includes a liquid crystal panel 200 and a backlight unit 250 that irradiates the liquid crystal panel 200 with light.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz.
- the backlight unit 250 has a plurality of irradiation areas that can be individually turned on / off.
- FIG. 30B shows a schematic diagram of the liquid crystal panel 200.
- the liquid crystal panel 200 includes a front substrate 210, a rear substrate 220, and a liquid crystal layer 230 provided between the front substrate 210 and the rear substrate 220.
- the front substrate 210 has a transparent insulating substrate 212 and a counter electrode 214
- the back substrate 220 has a transparent insulating substrate 222 and a pixel electrode 224.
- the liquid crystal panel 200 has the same configuration as the liquid crystal panel described above with reference to FIG. 14, and redundant description is omitted to avoid redundancy.
- FIG. 31A shows a change in the potential VLs of the source wiring with reference to the potential Vcom of the counter electrode 214
- FIG. 31B shows a waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 is shown.
- FIG. 31D shows lighting / non-lighting of a specific irradiation region of the backlight unit 250.
- FIG. Fig. 6 shows opening and closing of the shutter glasses 280.
- one vertical scanning period (frame update period) is about 4.2 ms. Further, here, the liquid crystal panel 200 complies with the high vision standard, and the period during which one scanning line is selected is about 3.4 ⁇ s.
- the relationship between the potential of the display signal supplied to each source line and the potential of the counter electrode does not change over the frame update period, and is adjacent in the column direction at the end of the frame update period.
- the polarities of the pixels are equal to each other. Therefore, a change in the potential of the display signal within the frame update period can be reduced, and power consumption can be reduced.
- a positive polarity display signal voltage is supplied to the source wiring in the first frame update period. However, in the first frame update period, a negative polarity is applied to the source wiring adjacent to the source wiring. A display signal voltage is supplied.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the scanning signal voltage for selecting a certain pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as a target potential, and the target potential corresponds to the gradation level of the potential difference between the counter electrode 214 and the pixel electrode 224. Is set to In this manner, charging of the liquid crystal layer 230 proceeds by supplying the display signal voltage to the pixel electrode 224.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz, and the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 224 is relatively short, the potential of the pixel electrode 224 reaches the target potential. Before the scanning signal voltage is returned to the off voltage. Note that the irradiation area of the backlight unit 250 is extinguished at least during the first frame update period, and the right eye image written in the first frame update period is not visually recognized by the observer. Further, the right eye shutter 284 opens in the second half of the first frame update period.
- the second frame update period (2F) a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the display signal voltage supplied to the source line is equal to the target potential in the first frame update period. It is set to be a target potential of polarity. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the target potential itself in the second frame update period is equal to the target potential in the first frame update period, but the target potential in the second frame update period is the same as that in the first frame update period due to the above-described overdrive driving or the like. It may be different from the target potential.
- the scanning signal voltage returns to the off voltage.
- the irradiation area of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the potential of the pixel electrode 224 has reached the target potential, and this pixel has luminance corresponding to the gradation level.
- the left eye image data is written in the third frame update period (3F).
- a display signal having a lower potential than the counter electrode 214 is supplied to the source wiring in the third frame update period.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source line is set so that the potential of the pixel electrode 224 is the target potential.
- the target potential in the third frame update period is set to a polarity different from that in the second frame update period, and the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the irradiation area of the backlight unit 250 remains turned on at the start of the third frame update period, but is turned off before the left-eye image data is written in the third frame update period.
- the left eye image written in the third frame update period is not visually recognized by the observer.
- the left eye shutter 282 opens.
- a display signal indicating a lower potential than the counter electrode 214 is supplied to the source wiring.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the polarity written in the fourth frame update period is equal to that in the third frame update period, and the display signal voltage supplied to the source line has the potential of the pixel electrode 224 equal to the target potential in the third frame update period. It is set to be a target potential of polarity. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the scanning signal voltage returns to the off voltage.
- the irradiation area of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the potential of the pixel electrode 224 has reached the target potential, and this pixel has luminance corresponding to the gradation level.
- the left eye image data is written in the liquid crystal panel 200 with the same polarity for two vertical scanning periods, and the right eye image data is written with the same polarity for two vertical scanning periods. For this reason, a decrease in aperture ratio and display unevenness can be suppressed.
- FIG. 32A shows a schematic diagram of a stereoscopic display system 900B.
- the stereoscopic display system 900B includes a liquid crystal display device 700B and shutter glasses 880.
- the liquid crystal display device 700B includes a liquid crystal panel 800 and a backlight unit 850.
- the backlight unit 850 has a plurality of irradiation areas that can be individually turned on / off.
- the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz. Note that the display mode is not switched in the liquid crystal display device 700B of Comparative Example 3, and the liquid crystal display device 700B performs display only in the stereoscopic display mode.
- FIG. 32B shows a schematic diagram of the liquid crystal panel 800.
- the liquid crystal panel 800 includes a front substrate 810, a rear substrate 820, and a liquid crystal layer 830 provided between the front substrate 810 and the rear substrate 820.
- the front substrate 810 has a transparent insulating substrate 812 and a counter electrode 814
- the back substrate 820 has a transparent insulating substrate 822 and a pixel electrode 824.
- FIG. 33A shows the change in the potential VLs of the source wiring with reference to the potential of the counter electrode 814
- FIG. 33B shows the waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 824 with respect to the potential of the electrode 814 is shown.
- FIG. 33D shows lighting / non-lighting of a specific irradiation region of the backlight unit 850
- FIG. The opening and closing of the shutter glasses 880 is shown.
- a display signal indicating a higher potential than the counter electrode 814 is supplied to the source wiring.
- a scanning signal voltage for selecting a certain pixel becomes an on-voltage
- a display signal voltage is supplied to the pixel electrode 824 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 824 is set as a target potential, and the target potential corresponds to the gray level of the potential difference between the counter electrode 814 and the pixel electrode 824. It is set to be. In this manner, charging of the liquid crystal layer 830 proceeds by supplying the display signal voltage to the pixel electrode 824.
- the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz, and since the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 824 is relatively short, the potential of the pixel electrode 824 reaches the target potential. Before the scanning signal voltage is returned to the off voltage. Note that the irradiation area of the backlight unit 850 is extinguished at least during the first frame update period, and the right-eye image written in the first frame update period is not visually recognized by the observer. Further, the right eye shutter 884 is opened in the second half of the first frame update period.
- the second frame update period (2F) a display signal indicating a lower potential than the counter electrode 814 is supplied to the source wiring.
- the right eye image is written continuously for two frame update periods.
- a display signal voltage is supplied to the pixel electrode 824 of the pixel and writing with a negative polarity is performed.
- the polarity written in the second frame update period is different from that in the first frame update period.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 824 is set as a target potential, and the target potential corresponds to the gray level of the potential difference between the counter electrode 814 and the pixel electrode 824.
- the liquid crystal panel 800 is driven at a vertical scanning frequency of 240 Hz, and since the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 824 is relatively short, the potential of the pixel electrode 824 reaches the target potential. Before the scanning signal voltage is returned to the off voltage. The irradiation region of the backlight unit 850 is lit for one vertical scanning period after the pixel is written in the second frame update period. The right eye shutter 884 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer. However, as described above, the potential of the pixel electrode 824 does not reach the target potential, and the pixel does not exhibit luminance corresponding to the gradation level.
- the left eye image data is written in the third frame update period (3F).
- a display signal having a higher potential than the counter electrode 814 is supplied to the source wiring in the third frame update period.
- the scanning signal voltage for selecting the pixel is turned on, the display signal voltage is supplied to the pixel electrode 824 of the pixel, and the potential of the pixel electrode 824 becomes higher than the potential of the counter electrode 814.
- positive polarity writing is performed in the third frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 824 reaches the target potential.
- the irradiation area of the backlight unit 850 remains turned on at the start of the third frame update period, but is turned off before the left-eye image data is written in the third frame update period.
- the left eye image written in the third frame update period is not visually recognized by the observer.
- the right eye shutter 884 is opened in the second half of the third frame update period.
- a display signal indicating a lower potential than the counter electrode 814 is supplied to the source wiring.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes an on voltage
- a display signal voltage is supplied to the pixel electrode 824 of the pixel and writing with a negative polarity is performed.
- the polarity written in the fourth frame update period is different from that in the third frame update period. For this reason, the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 824 reaches the target potential.
- the irradiation region of the backlight unit 850 is turned on for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 882 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the potential of the pixel electrode 824 does not reach the target potential, and the pixel does not exhibit luminance corresponding to the gradation level.
- the potential of the pixel electrode 824 may not reach the target potential in any period because the polarities of the pixels in the two vertical scanning periods in which the right eye image data and the left eye image data are respectively written are different.
- the potential of the pixel electrode 824 may not reach the target potential.
- the potential of the pixel electrode 824 of the other pixel is significantly different from the potential of the counter electrode 814 in the second frame update period (the gray level of this pixel is high), this pixel electrode in the third frame update period.
- the potential of 824 does not reach the target potential, and the potential of the pixel electrode 824 may reach the target potential of the counter electrode 814 in the fourth frame update period.
- the right eye image or the left eye image is written in the two vertical scanning periods in which the right eye image data and the left eye image data are written, so that the right eye image or the left eye image to be displayed is displayed immediately before the left eye image. Or it may be influenced by a right-eye image, and this is visually recognized as display unevenness.
- the wiring width in the liquid crystal panel 800 is increased in order to suppress signal delay or the like, it is not impossible to suppress display unevenness itself, but in this case, the aperture ratio of the liquid crystal panel 800 is reduced. End up.
- the left eye image data and the right eye image data are written with the same polarity over two consecutive vertical scanning periods, so that display unevenness is suppressed without reducing the aperture ratio. can do.
- a so-called double speed driving liquid crystal panel can be suitably used as the liquid crystal panel 200 driven at a vertical scanning frequency of 240 Hz.
- the occurrence of flicker can be suppressed by reversing the polarity of the pixels every two vertical scanning periods.
- FIG. 34A is a waveform diagram of scanning signal voltages supplied to a plurality of scanning wirings
- FIG. 34B is a schematic diagram showing lighting / non-lighting of the backlight unit
- FIG. FIG. 4 is a schematic diagram showing opening and closing of shutter glasses.
- the first frame update period (1F) a plurality of scanning wirings are selected in order.
- the left eye shutter 282 of the shutter glasses 280 remains open over the first frame update period.
- all of the plurality of irradiation areas 252 provided in the backlight unit 250 are lit. Therefore, at the start time of the first frame update period, the left eye of the observer The image is visible.
- the scanning wiring is selected in the first frame update period, the corresponding irradiation regions 252 are turned off in turn, and the observer does not visually recognize the left eye image.
- the second frame update period (2F) a plurality of scan wirings are selected in order. Over the second frame update period, the left eye shutter 282 of the shutter glasses 280 remains closed and the right eye shutter 284 remains open. Further, at the start of the second frame update period, all of the plurality of irradiation regions 252 provided in the backlight unit 250 are turned off, and thus the observer does not visually recognize the left eye image during this period. As the scanning wiring is selected in the second frame update period, the corresponding irradiation areas 252 are sequentially turned on, and accordingly, the observer visually recognizes the right eye image.
- the third frame update period (3F) a plurality of scanning wirings are selected in order. Over the third frame update period, the right eye shutter 284 of the shutter glasses 280 remains open. Further, at the start of the third frame update period, all of the plurality of irradiation areas 252 provided in the backlight unit 250 are lit. For this reason, the observer visually recognizes the right eye image during this period. As the scanning wiring is selected in the third frame update period, the corresponding irradiation areas 252 are sequentially turned off, and the observer does not visually recognize the right eye image.
- the fourth frame update period (4F) a plurality of scan wirings are selected in order. Over the fourth frame update period, the right eye shutter 284 of the shutter glasses 280 remains closed and the left eye shutter 282 remains open. At the start of the fourth frame update period, all of the plurality of irradiation areas 252 provided in the backlight unit 250 are turned off. For this reason, the observer does not visually recognize the left eye image during this period. As the scanning wiring is selected in the fourth frame update period, the corresponding irradiation areas 252 are sequentially turned on, and accordingly, the observer visually recognizes the left eye image. In this way, either the left eye shutter 282 or the right eye shutter 284 of the shutter glasses 280 is open, and the image visually recognized by the observer may change according to whether the backlight unit 250 is turned on or off.
- the right eye image data is written with a positive polarity and the left eye image data is written with a negative polarity in this pixel. become.
- the luminance of the pixel to which the right eye image data is written is that of the pixel to which the left eye image data is written. Unlike brightness, proper display may not be performed.
- the right eye image data is written with a plus polarity and a minus polarity according to the period, and similarly, the left eye image data is also written with a plus polarity and a minus polarity according to the period.
- FIG. 35A shows a change in the potential VLs of the source wiring with reference to the potential Vcom of the counter electrode 214
- FIG. 35B shows a waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 is shown.
- FIG. 35D shows lighting / non-lighting of the backlight unit 250
- FIG. 35E shows shutter glasses 280. Shows opening and closing.
- the relationship between the potential of the display signal supplied to each source wiring and the potential of the counter electrode does not change within the frame update period. For this reason, a change in the potential of the display signal within the frame update period can be reduced, and power consumption is reduced.
- the gradation level of this pixel does not change from the first frame update period (1F) to the eighth frame update period (8F), and the gradation level of this pixel of the left eye image data is the gradation of the right eye image data. It is almost equal to the level.
- this pixel corresponds to a central portion of an object included in an image on which stereoscopic display is performed.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the scanning signal voltage for selecting a certain pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as a target potential, and the target potential corresponds to the gradation level of the potential difference between the counter electrode 214 and the pixel electrode 224. Is set to In this manner, charging of the liquid crystal layer 230 proceeds by supplying the display signal voltage to the pixel electrode 224.
- the liquid crystal panel 200 is driven at a vertical scanning frequency of 240 Hz, and the period during which the scanning wiring is selected and the display signal voltage is supplied to the pixel electrode 224 is relatively short, the potential of the pixel electrode 224 reaches the target potential. Before the scanning signal voltage is returned to the off voltage. Note that the irradiation region 252 of the backlight unit 250 is extinguished at least during the first frame update period, and the right-eye image written in the first frame update period is not visually recognized by the observer. Further, the right eye shutter 284 opens in the second half of the first frame update period.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the display signal voltage supplied to the source wiring uses the potential of the pixel electrode 224 as the target potential having the same polarity as the target potential in the first frame update period. Is set to For this reason, the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- a display signal having a higher potential than the counter electrode 214 is supplied to the source wiring in the third frame update period.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set to a target potential having the same polarity as the second frame update period. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the backlight unit 250 remains lit at the start of the third frame update period, but is turned off before the left-eye image data is written in the third frame update period, and in the third frame update period.
- the written left eye image is not visually recognized by the observer.
- the left eye shutter 282 is opened in the second half of the third frame update period.
- a display signal indicating a higher potential than the counter electrode 214 is supplied to the source wiring.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the display signal voltage is set so that the polarity written in the fourth frame update period is equal to that in the third frame update period, and the potential of the pixel electrode 224 is equal to the target potential in the third frame update period.
- the potential of 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- a display signal indicating a lower potential than the counter electrode 214 is supplied to the source wiring.
- a scanning signal voltage for selecting a certain pixel becomes an on-voltage
- a display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential, but the target potential in the fifth frame update period is set to a polarity different from that in the fourth frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the irradiation region 252 of the backlight unit 250 is extinguished at least during the fifth frame update period, and the right-eye image written in the fifth frame update period is not visually recognized by the observer. Also, the right eye shutter 284 is opened in the second half of the fifth frame update period.
- the polarity of the display signal voltage and the polarity of the pixel electrode 224 are different from the second frame update period (2F) to the fourth frame. This is the same as the update period (4F), and redundant description is omitted to avoid redundancy.
- the polarity of the pixel may be reversed every four vertical scanning periods.
- the right eye image data and the left eye image data are written with the same polarity for every two vertical scanning periods, so that a decrease in aperture ratio and display unevenness can be suppressed. Further, by reversing the polarity of the pixels every four vertical scanning periods, the right eye image data is written with positive polarity and negative polarity and the left eye image data is written with positive polarity and negative polarity according to the vertical scanning period. As a result, luminance deviation due to polarity can be suppressed.
- display signal voltages having different polarities are supplied to adjacent source lines, but the present invention is not limited to this.
- the display signal voltage having the same polarity may be supplied to all the source wirings in a certain frame update period. In this case, the polarities of the pixels adjacent in the column direction are equal at the end of the frame update period.
- the polarities of adjacent pixels in the row direction and the column direction may be reversed at the end of the frame update period.
- the polarity of the display signal voltage supplied to each source line may be inverted every horizontal scanning period, and the liquid crystal panel 200 may be driven by dot inversion.
- the pixels arranged in a matrix may be divided into one or more blocks in which writing is performed on one pixel in an odd row and an even row and then writing is performed on the other pixel.
- FIG. 36 (a) shows the polarities of the pixels written in the block and the order of writing. For example, after a pixel having a different polarity is written to a pixel adjacent in a row direction in a certain horizontal scanning period, a row of pixels in which writing is performed in the immediately preceding horizontal scanning period in the next horizontal scanning period. The pixel adjacent to is skipped and writing is performed with the same polarity as the polarity of the immediately preceding horizontal scanning period to the pixels in the row that is two rows away from the row of pixels that were written in the immediately preceding horizontal scanning period. Similarly, writing is performed in order with the same polarity every other row.
- writing is sequentially performed on the pixel rows skipped by the previous writing in the block with a polarity different from the previous writing.
- This writing is also performed with the same polarity every other row.
- the writing of the positive polarity is performed on the pixels of the even-numbered rows
- the writing of the negative polarity is performed on the pixels of the odd-numbered rows.
- FIG. 36B shows a change in the potential VLs of the source wiring with the potential Vcom of the counter electrode 214 as a reference.
- attention is paid to a change in the potential VLs within one frame update period of a specific source wiring in the liquid crystal panel 200 divided into two blocks.
- this source wiring within one frame update period, for example, a positive polarity write is performed on odd-numbered rows of pixels in the first block, then a negative polarity write is performed on even-numbered rows of pixels, and then The positive polarity writing is performed on the odd-numbered pixels in the second block, and the negative polarity writing is performed on the even-numbered pixels.
- negative polarity writing is performed on the odd-numbered pixels in the first block, and then positive polarity writing is performed on the even-numbered pixels in the source wiring adjacent to the source wiring.
- negative polarity writing is performed on the odd-numbered pixels in the second block, and then positive polarity writing is performed on the even-numbered pixels.
- FIG. 37A shows a change in the potential VLs of the display signal based on the potential Vcom of the counter electrode 214 in the liquid crystal panel 200
- FIG. 37B shows a waveform of the scanning signal voltage VLg
- FIG. FIG. 37C shows a change in the potential Vpe of the pixel electrode 224 with reference to the potential Vcom of the counter electrode 214
- FIG. 37D shows lighting / non-lighting of a specific irradiation region 252 of the backlight unit 250.
- FIG. 37 (e) shows the opening and closing of the shutter glasses 280.
- FIG. 37 is the same as FIG. 33 described above except that the change in the potential VLs of the display signal shown in FIG. 37A is different, and redundant description is omitted to avoid redundancy.
- the relationship between the potential of the display signal supplied to the source wiring and the potential of the counter electrode does not change over about 1 ⁇ 4 of the frame update period, so that power consumption can be reduced. it can.
- odd-numbered rows of pixels in the first block are written with positive polarity
- odd-numbered rows of pixels in the second block are written with positive polarity
- even rows of pixels are written with negative polarity.
- the polarities of pixels adjacent in the column direction are different from each other at the end of the frame update period.
- FIG. 37A attention is paid to the source wiring in which the polarity of the display signal voltage changes to plus, minus, plus, and minus polarity in the first frame update period.
- the polarity of the display signal voltage supplied to the source line adjacent to the gate line changes to minus, plus, minus, and plus polarity.
- FIG. 37B the period during which the scanning signal voltage VLg is on is 3.4 ⁇ s.
- FIG. 37C attention is paid to a change in the potential Vpe of the pixel electrode 224 of a specific pixel selected when a positive polarity display signal is supplied from the source wiring in the frame update period.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity is performed.
- the potential of the pixel electrode 224 may not reach the target potential.
- the polarity of the display signal supplied to this source line changes to plus, minus, plus and minus polarity.
- the right eye image is written continuously for two frame update periods.
- a display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the polarity in the first frame update period is performed.
- the target potential in the second frame update period is equal to the target potential in the first frame update period.
- the target potential in the second frame update period is the first potential due to overdrive driving or the like. It may be different from the target potential in the frame update period.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- the polarity of the display signal supplied to the source line changes to minus, plus, minus, and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is set as the target potential, but the target potential in the third frame update period is set to a polarity different from that in the second frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a negative polarity equal to the third frame update period is performed. For this reason, the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the left eye image data is written with the same polarity for each pixel for two vertical scanning periods, and the right eye image data for each pixel is written for two vertical scanning periods.
- the same polarity Therefore, a decrease in aperture ratio and display unevenness can be suppressed, and a so-called double speed driving liquid crystal panel can be used as the liquid crystal panel 200.
- the occurrence of flicker can be suppressed by reversing the polarity of the pixels every two vertical scanning periods.
- the right eye image data is written with positive polarity and the left eye image data is written with negative polarity in the pixel.
- the gradation levels of the right eye image data and the left eye image data of a certain pixel are equal to each other.
- the luminance of the pixel in which the right eye image data is written is different from the luminance of the pixel in which the left eye image data is written, and appropriate display may not be performed.
- the right eye image data is written with a positive polarity and a negative polarity according to the period, and similarly, the left eye image data is also written with a positive polarity and a negative polarity according to the period.
- FIG. 38A shows the change in the potential VLs of the source wiring with reference to the potential Vcom of the counter electrode 214
- FIG. 38B shows the waveform of the scanning signal voltage VLg
- FIG. A change in the potential Vpe of the pixel electrode 224 with respect to the potential Vcom of the counter electrode 214 is shown.
- FIG. 38D shows lighting / non-lighting of the backlight unit 250
- FIG. 38E shows shutter glasses 280. Shows opening and closing.
- the relationship between the potential of the display signal supplied to the source wiring and the potential of the counter electrode does not change over about 1 ⁇ 4 of the frame update period, so that power consumption can be reduced. it can.
- attention is paid to the source wiring in which the polarity of the display signal changes to plus, minus, plus, and minus polarity in the first frame update period.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus, and plus polarity.
- FIG. 38C attention is paid to a change in the potential Vpe of the pixel electrode 224 of a specific pixel selected when a positive polarity display signal is supplied to the source wiring in the frame update period.
- FIG. 38 is the same as FIG. 37 described above except that the change in the potential VLs of the display signal shown in FIG. 38A is different, and redundant description is omitted to avoid redundancy.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential.
- the scan signal voltage is set to the off voltage before the potential of the pixel electrode 224 reaches the target potential. May return.
- the polarity of the display signal supplied to this source line changes to plus, minus, plus and minus polarity.
- the right eye image is written continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes the on voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel and writing with a positive polarity is performed.
- the polarity written in the second frame update period is equal to that in the first frame update period, and the potential of the pixel electrode 224 reaches the target potential. Thereafter, the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the second frame update period.
- the right eye shutter 284 remains open for the second frame update period. For this reason, the right eye image written in the second frame update period is visually recognized by the observer.
- the left eye image data is written in the third frame update period (3F).
- the polarity of the display signal supplied to the source line changes to plus, minus, plus and minus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the second frame update period is performed. For this reason, the potential of the pixel electrode 224 reaches the target potential.
- the polarity of the display signal supplied to the source wiring changes to plus, minus, plus and minus polarity.
- writing of the left eye image is performed continuously for two frame update periods.
- the scanning signal voltage for selecting the pixel becomes an on-voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with a positive polarity equal to the third frame update period is performed, and the potential of the pixel electrode 224 becomes the target Reach potential.
- the scanning signal voltage returns to the off voltage.
- the irradiation region 252 of the backlight unit 250 is lit for one vertical scanning period after the pixel is written in the fourth frame update period.
- the left eye shutter 282 remains open for the fourth frame update period. For this reason, the left eye image written in the fourth frame update period is visually recognized by the observer.
- the polarity of the display signal supplied to the source wiring changes to minus, plus, minus and plus polarity.
- the scanning signal voltage for selecting the pixel becomes the ON voltage
- the display signal voltage is supplied to the pixel electrode 224 of the pixel, and writing with negative polarity is performed.
- the display signal voltage supplied to the source wiring is set so that the potential of the pixel electrode 224 is the target potential, but the target potential in the fifth frame update period is set to a polarity different from that in the fourth frame update period.
- the scanning signal voltage returns to the off voltage before the potential of the pixel electrode 224 reaches the target potential.
- the sixth frame update period (6F) to the eighth frame update period (8F) are the second frame update period (2F) except that the polarity of the display signal voltage is reversed and the polarity of the pixel electrode 224 is different.
- the polarity of each pixel may be inverted every four vertical scanning periods.
- the pixel may be divided into three or more blocks. Further, the number of blocks may be set according to the irradiation region 252 of the backlight unit 250, for example.
- odd-numbered lines and even-numbered lines in a continuous block are alternately written, but the present invention is not limited to this.
- Writing one of the odd and even rows across successive blocks may be performed sequentially. For example, after writing a positive polarity to the odd-numbered pixels in the first block, writing a negative polarity to the even-numbered pixels in the first block, and then writing a negative polarity to the even-numbered pixels in the second block After that, positive polarity writing may be performed on the pixels in the odd-numbered rows of the second block.
- plus polarity writing may be performed on pixels in odd rows in the third block, and minus polarity writing may be performed on pixels in even rows in the third block.
- the left-eye image data and the right-eye image data are written in every 2 vertical scanning periods, and the polarity of each pixel is inverted every 2 or 4 vertical scanning periods. It is not limited. The polarity of each pixel may be inverted every two or more even vertical scanning periods. For example, the polarity of each pixel may be inverted every six or eight or more vertical scanning periods.
- FIG. 39 shows a schematic diagram of the liquid crystal display device 100B and the stereoscopic display system 300B.
- the stereoscopic display system 300B includes a liquid crystal display device 100B and shutter glasses 280.
- the liquid crystal display device 100B includes a frame rate control circuit 110, a timing controller 120, a writing state signal transmission circuit 130, a scanning signal driving circuit 140, a display signal driving circuit 150, a backlight driving circuit 160, and a liquid crystal panel. 200 and a backlight unit 250.
- an input video signal having a frame rate of 60 fps is input to the frame rate control circuit 110.
- the input video signal is an NTSC signal.
- the frame rate control circuit 110 generates a video signal having a frame rate of 120 fps, which is higher than the frame rate of 60 fps of the input video signal, based on the input video signal.
- the timing controller 120 controls the writing state signal transmission circuit 130, the scanning signal driving circuit 140, the display signal driving circuit 150, and the backlight driving circuit 160.
- the timing controller 120 generates a display signal having a frame rate of 240 fps based on the video signal having a frame rate of 120 fps, and outputs the display signal to the display signal driving circuit 150.
- the scanning signal driving circuit 140 and the display signal driving circuit 150 drive the liquid crystal panel 200 at a vertical scanning frequency of 240 Hz. At this time, the left eye image data corresponds to 120 fps, and the right eye image data corresponds to 120 fps.
- the writing state signal transmission circuit 130 transmits a writing state signal indicating a writing state of a plurality of pixels.
- the shutter glasses 280 open and close the left eye shutter 282 and the right eye shutter 284 based on the writing state signal.
- the frame rate control circuit 110 generates a video signal having a frame rate of 120 fps higher than the frame rate of 60 fps of the input video signal based on the input video signal, and the timing controller 120 generates a frame based on the video signal.
- a display signal having a rate of 240 fps is generated, the present invention is not limited to this.
- the frame rate control circuit 110 generates a video signal having a frame rate of 240 fps higher than the frame rate of 60 fps of the input video signal based on the input video signal, and the timing controller 120 displays a display signal having a frame rate of 240 fps based on the video signal. May be generated.
- the input video signal may be a PAL signal, and the frame rate thereof may be 50 fps.
- the frame rate of the video signal is set to 100 fps or 200 fps
- the frame rate of the display signal is set to 200 fps.
- the right eye image data and the left eye image data written for the second time are equal to the right eye image data and the left eye image data written for the first time, respectively.
- Overdrive driving may be performed on the right eye image data and the left eye image data written for the second time.
- the overdrive drive is performed in the same manner as described above with reference to FIGS. 20 and 28, for example.
- each pixel may have a plurality of sub-pixels in the liquid crystal panel 200 in the liquid crystal display device 300B of the present embodiment.
- each pixel of the liquid crystal panel 200 may have a configuration similar to that described above with reference to FIGS.
- the alignment film is processed so that the pretilt angle of the liquid crystal molecules is 85 ° or more and less than 90 ° with respect to the surface of the vertical alignment film.
- the pretilt angle is an angle formed between the main surface of the alignment film and the major axis of the liquid crystal molecules defined in the pretilt direction.
- a rubbing process, a photo-alignment process, a fine structure is formed in advance on the base of the alignment film, and the fine structure is reflected on the surface of the alignment film.
- a method or a method of forming an alignment film having a fine structure on the surface by obliquely depositing an inorganic substance such as SiO is known.
- rubbing treatment or photo-alignment treatment is preferable.
- the photo-alignment process is performed without contact, there is no generation of static electricity due to friction unlike the rubbing process, and the yield can be improved.
- the variation in the pretilt angle can be controlled to 1 ° or less by using a photo-alignment film containing a photosensitive group.
- the photosensitive group preferably includes at least one photosensitive group selected from the group consisting of a 4-chalcone group, a 4'-chalcone group, a coumarin group, and a cinnamoyl group.
- the liquid crystal panel 200 may be in a so-called MVA (Multi-domain Vertical Alignment) mode.
- the MVA mode liquid crystal panel 200 has linear slits formed on the electrodes and linear dielectric protrusions (ribs) formed on the liquid crystal layer side of the electrodes on a pair of substrates opposed via the liquid crystal layer.
- the directors of the liquid crystal domain formed at the time of voltage application are regulated by arranging them in parallel and alternately.
- the direction of the liquid crystal domain is a direction orthogonal to the direction in which the linear slits or dielectric protrusions (collectively referred to as “linear structures”) extend.
- the scanning wirings Lga and Lgb may be arranged so as to overlap with the boundary between different liquid crystal domains.
- the liquid crystal panel 200 may be in the PSA mode.
- PSA technology Polymer Sustained Alignment Technology (hereinafter referred to as “PSA technology”) is disclosed in, for example, JP 2002-357830 A, JP 2003-177418 A, JP 2006-78968 A, K.A. Hanaoka et al. "A New MVA-LCD by Polymer Sustained Alignment Technology", SID 04 DIGEST 1200-1203 (2004). The entire disclosure of these four documents is hereby incorporated by reference.
- a small amount of a polymerizable compound for example, a photopolymerizable monomer or oligomer
- a liquid crystal panel is assembled, and a predetermined voltage is applied to the liquid crystal layer.
- This is a technique for controlling the pretilt direction of liquid crystal molecules by irradiating active energy rays (for example, ultraviolet rays) to form a polymer.
- active energy rays for example, ultraviolet rays
- the alignment state of the liquid crystal molecules when the polymer is generated is maintained (stored) even after the voltage is removed (a state where no voltage is applied).
- a layer formed of a polymer is referred to as an orientation maintaining layer.
- the alignment maintaining layer is formed on the surface of the alignment film (on the liquid crystal layer side), but does not necessarily have a shape covering the surface of the alignment film, and may be discrete polymer particles.
- each of the pixel electrodes 224 includes a cross-shaped trunk portion that is arranged so as to overlap the polarization axes of the pair of polarizing plates, and a plurality of branch portions that extend in a direction of approximately 45 ° from the cross-shaped trunk portion.
- the branch portion extends from the trunk portion in 45 °, 135 °, 225 °, and 315 ° orientations, and the liquid crystal molecules (negative dielectric anisotropy) of the vertically aligned liquid crystal layer are separated from the trunk portion and the branch portion. Is inclined in the direction in which each branch extends.
- the oblique electric field from the branches extending in parallel to each other acts to incline the liquid crystal molecules in the direction perpendicular to the direction in which the branches extend, and the oblique electric field from the trunk portion causes the liquid crystal molecules in the direction in which each branch extends. This is because it acts so as to be inclined.
- the scanning wiring may be arranged so as to overlap with a boundary between different liquid crystal domains.
- the liquid crystal panel 200 may be in the CPA mode.
- the pixel electrode 224 may have a highly symmetric shape, and the liquid crystal molecules in each liquid crystal domain may be tilted in an axially symmetric manner by applying a voltage to the liquid crystal layer 230.
- liquid crystal panel 200 a voltage is applied to the liquid crystal layer by the electrodes provided on the front substrate and the rear substrate, but the present invention is not limited to this.
- the liquid crystal panel may apply a voltage in a horizontal direction parallel to the surface of the liquid crystal layer.
- the liquid crystal panel may be in an IPS (In Plane Switching) mode.
- display unevenness of a liquid crystal display device and a stereoscopic display system capable of stereoscopic display can be suppressed. Further, according to the present invention, it is possible to provide a low power consumption liquid crystal display device and a stereoscopic display system capable of switching between the stereoscopic display mode and the flat display mode.
- Liquid Crystal Display Device 100 Liquid Crystal Display Device 200 Liquid Crystal Panel 250 Backlight Unit 280 Shutter Glasses
Abstract
Description
以下、本発明による液晶表示装置および立体表示システムの第1実施形態を説明する。まず、図1を参照して、本実施形態の液晶表示装置100および立体表示システム300を説明する。立体表示システム300は、液晶表示装置100およびシャッター眼鏡280を備えている。液晶表示装置100には複数の画素が設けられている。
上述した説明では、フレームレート制御回路はフレームレート120fpsの映像信号を生成したが、本発明はこれに限定されない。フレームレート制御回路はフレームレート240fpsの映像信号を生成してもよい。
なお、上述した液晶表示装置は、立体表示モードおよび平面表示モードを切り換え可能であったが、本発明はこれに限定されない。液晶表示装置は、立体表示モードでのみ表示を行い、表示モードの切り換えを行わないものであってもよい。
200 液晶パネル
250 バックライトユニット
280 シャッター眼鏡
Claims (34)
- 立体表示モードで表示を行う、複数の画素が設けられた液晶表示装置であって、
前記複数の画素のそれぞれには、連続する2垂直走査期間ごとに左眼画像データおよび右眼画像データが交互に書き込まれ、
前記複数の画素のそれぞれは、前記左眼画像データの書き込まれる前記2垂直走査期間にわたって等しい極性を示し、前記右眼画像データの書き込まれる前記2垂直走査期間にわたって等しい極性を示す、液晶表示装置。 - 前記複数の画素のそれぞれの極性は2以上の偶数の垂直走査期間ごとに反転する、請求項1に記載の液晶表示装置。
- 前記複数の画素のそれぞれの極性は2垂直走査期間ごとに反転する、請求項1または2に記載の液晶表示装置。
- 前記複数の画素のそれぞれの極性は4垂直走査期間ごとに反転する、請求項1または2に記載の液晶表示装置。
- 前記複数の画素は、複数の行および複数の列のマトリクス状に配列されており、
前記複数の画素の全体に前記左眼画像データおよび前記右眼画像データの一方が書き込まれたときに前記複数の画素のうちの列方向に隣接する画素の極性は互いに等しい、請求項1から4のいずれかに記載の液晶表示装置。 - 前記複数の画素は、複数の行および複数の列のマトリクス状に配列されており、
前記複数の画素の全体に前記左眼画像データおよび前記右眼画像データの一方が書き込まれたときに前記複数の画素のうちの行方向および列方向に隣接する画素の極性は互いに異なる、請求項1から4のいずれかに記載の液晶表示装置。 - 前記複数の画素は、前記複数の行のうちの2以上の行に対応する1以上のブロックに分かれており、
前記左眼画像データまたは前記右眼画像データの書き込みは、前記ブロック内の奇数行および偶数行のうちの一方の画素に対して行われた後に、他方の画素に対して行われる、請求項6に記載の液晶表示装置。 - 前面基板、背面基板、および、前記前面基板と前記背面基板との間に設けられた液晶層を有する液晶パネルと、
前記液晶パネルに光を照射するバックライトユニットと、
入力映像信号に基づいて前記入力映像信号のフレームレートよりも高いフレームレートの映像信号を生成するフレームレート制御回路と、
前記映像信号に基づいて表示信号を生成するタイミングコントローラーと、
前記書き込みの行われる画素を選択する走査信号を供給する走査信号駆動回路と、
前記選択された画素に前記表示信号を供給する表示信号駆動回路と、
前記複数の画素の書き込み状態を示す書込状態信号を送信する書込状態信号送信回路と、
前記バックライトユニットの点灯および消灯を制御するバックライト駆動回路と
を備える、請求項1から7のいずれかに記載の液晶表示装置。 - 前記バックライトユニットは、前記左眼画像データおよび前記右眼画像データのそれぞれ書き込まれる前記2垂直走査期間のうちの後の垂直走査期間の少なくとも一部の期間、点灯する、請求項8に記載の液晶表示装置。
- 前記複数の画素のそれぞれにおいて、1以上の前の垂直走査期間に書き込まれた前記左眼画像データおよび前記右眼画像データに基づいてオーバードライブ駆動を行う、請求項1から9のいずれかに記載の液晶表示装置。
- 前記立体表示モードおよび平面表示モードを切り換えて表示を行う液晶表示装置であって、前記平面表示モードでは、前記立体表示モードよりも低い垂直走査周波数で駆動を行う、請求項1から10のいずれかに記載の液晶表示装置。
- 前記複数の画素のそれぞれは、第1副画素および第2副画素を有している、請求項1から11のいずれかに記載の液晶表示装置。
- 前記平面表示モードにおいてマルチ画素駆動が行われ、
前記立体表示モードにおいてマルチ画素駆動が行われない、請求項12に記載の液晶表示装置。 - 立体表示モード、および、前記立体表示モードよりも低い垂直走査周波数で駆動の行われる平面表示モードを切り換えて表示を行う液晶表示装置。
- 前記平面表示モードの駆動は、前記立体表示モードの駆動の半分の垂直走査周波数で行われる、請求項14に記載の液晶表示装置。
- 複数の画素が設けられた液晶パネルと、
入力映像信号に基づいて前記入力映像信号のフレームレートよりも高いフレームレートの映像信号を生成するフレームレート制御回路と、
前記映像信号に基づいて表示信号を生成するタイミングコントローラーと、
書き込みの行われる画素を選択する走査信号を供給する走査信号駆動回路と、
前記選択された画素に前記表示信号を供給する表示信号駆動回路と
を備え、
前記タイミングコントローラーは、前記立体表示モードおよび前記平面表示モードに応じて前記表示信号のフレームレートを異ならせる、請求項14または15に記載の液晶表示装置。 - 前記液晶パネルに光を照射するバックライトユニットと、
前記バックライトユニットの点灯および消灯を制御するバックライト駆動回路と
をさらに備える、請求項16に記載の液晶表示装置。 - 前記バックライトユニットによる光の照射は、前記立体表示モードおよび前記平面表示モードに応じて変更される、請求項17に記載の液晶表示装置。
- 前記バックライトユニットは、それぞれが点灯および消灯を独立に制御可能な複数の照射領域を有している、請求項17または18に記載の液晶表示装置。
- 前記複数の画素は、複数の行および複数の列のマトリクス状に配列されており、
前記複数の照射領域のそれぞれは、前記複数の行のうちの少なくとも1つの行の画素に対応して設けられている、請求項19に記載の液晶表示装置。 - 前記立体表示モードで表示を行う場合、前記複数の照射領域が順番に点灯する、請求項20に記載の液晶表示装置。
- 前記液晶パネルは、
対向電極を有する前面基板と、
走査配線、ソース配線および画素電極を有する背面基板と、
前記前面基板と前記背面基板との間に設けられた液晶層と
を有している、請求項16から21のいずれかに記載の液晶表示装置。 - 前記平面表示モードで表示を行う場合、前記走査信号駆動回路および前記表示信号駆動回路は、前記立体表示モードで表示を行う場合の半分の垂直走査周波数で前記液晶パネルを駆動する、請求項16から22のいずれかに記載の液晶表示装置。
- 前記フレームレート制御回路は、前記映像信号のフレームレートを前記入力映像信号のフレームレートの2倍に設定する、請求項16から23のいずれかに記載の液晶表示装置。
- 前記立体表示モードで表示を行う場合、前記入力映像信号には、左眼画像データおよび右眼画像データが交互に配列されており、
前記フレームレート制御回路は、前記映像信号に、前記入力映像信号のうちの前記左眼画像データおよび前記右眼画像データの1セットを2セット繰り返して配列する、請求項24に記載の液晶表示装置。 - 前記タイミングコントローラーは、前記表示信号に、前記映像信号の前記左眼画像データおよび前記右眼画像データをそれぞれ2つずつ連続して配列する、請求項25に記載の液晶表示装置。
- 前記立体表示モードで表示を行う場合、前記タイミングコントローラーは前記表示信号のフレームレートを前記映像信号のフレームレートの2倍に設定し、
前記平面表示モードで表示を行う場合、前記タイミングコントローラーは前記表示信号のフレームレートを前記映像信号のフレームレートと等しく設定する、請求項24から26のいずれかに記載の液晶表示装置。 - 前記フレームレート制御回路は、前記映像信号のフレームレートを前記入力映像信号のフレームレートの4倍に設定する、請求項16から23のいずれかに記載の液晶表示装置。
- 前記立体表示モードで表示を行う場合、前記入力映像信号には、左眼画像データおよび右眼画像データが交互に配列されており、
前記フレームレート制御回路は、前記映像信号に、前記入力映像信号のうちの前記左眼画像データおよび前記右眼画像データを2つずつ連続して配列した1セットを2セット繰り返して配列する、請求項28に記載の液晶表示装置。 - 前記タイミングコントローラーは、前記表示信号に、前記映像信号の前記左眼画像データおよび前記右眼画像データを配列する、請求項29に記載の液晶表示装置。
- 前記立体表示モードで表示を行う場合、前記タイミングコントローラーは前記表示信号のフレームレートを前記映像信号のフレームレートと等しく設定し、
前記平面表示モードで表示を行う場合、前記タイミングコントローラーは前記表示信号のフレームレートを前記映像信号のフレームレートの半分に設定する、請求項28から30のいずれかに記載の液晶表示装置。 - 前記複数の画素の書き込み状態を示す書込状態信号を送信する書込状態信号送信回路をさらに備える、請求項16から31のいずれかに記載の液晶表示装置。
- 前記複数の画素のそれぞれにおいて、1以上の前の垂直走査期間に書き込まれた前記左眼画像データおよび前記右眼画像データに基づいてオーバードライブ駆動を行う、請求項14から32のいずれかに記載の液晶表示装置。
- 請求項1から33のいずれかに記載の液晶表示装置と、
前記液晶表示装置が左眼画像を表示している期間に開く左眼シャッター、および、前記液晶表示装置が右眼画像を表示している期間に開く右眼シャッターを有するシャッター眼鏡と
を備える、立体表示システム。
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Also Published As
Publication number | Publication date |
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MX2012011461A (es) | 2012-11-29 |
US20130027525A1 (en) | 2013-01-31 |
AU2011236792A1 (en) | 2012-11-01 |
SG184465A1 (en) | 2012-11-29 |
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