TW201227705A - Liquid crystal display device, 3d display system, control program, and recording medium - Google Patents

Abstract

This liquid crystal display device (100) comprises a liquid crystal panel (200) having a plurality of pixels, and a polarity control circuit (121) for controlling the polarity of the pixels. The polarity control circuit (121) has a plurality of polarity inversion schemes having mutually different periods by which the polarity is inverted.

Description

201227705 VI. Description of the Invention: [Technical Field] The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal display device having a stereoscopic display function. [Prior Art] The liquid crystal display device has the advantages of light weight, thinness, and low power consumption, and is used not only as a small display device such as a display portion of a mobile phone but also as a large-sized television. In general, liquid crystal display devices are used for flat display. However, in recent years, it has been proposed to use a liquid crystal display device to perform a more realistic display (see Patent Document 1). Patent Document 1 discloses a stereoscopic image 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. It is worn by the viewer to view the display of the liquid crystal display device. Fig. 4 is a timing chart showing the frame material disclosed in Patent Document 1 and the control method of the liquid crystal shutter. In the liquid crystal display device of Patent Document 1, the first left-eye frame L i and the second left-eye for the same image as the first left-eye frame L1 are sequentially displayed during the display period of the left-eye image. Frame L2; In the display period of the right-eye image, the first right-eye frame R1, the first right-eye frame, and the second right-eye frame R2 of the same image as R1 are sequentially displayed. At this time, the left-eye shutter of the shutter glasses is controlled by the liquid crystal shutter L signal 108, and the vertical blanking period 2〇5 after being written into the liquid crystal display device from the first left-eye frame L1 to the second thereafter The left eye is opened during the period of frame L2. Further, the right eye shutter of the shutter glasses is subjected to the liquid crystal shutter R control signal 109, and is written in the vertical blanking period 205 after the 160473.doc 201227705 liquid crystal display device is written from the first right eye frame R1 to the subsequent 2 The right eye is opened during the period of frame R2. Therefore, in the stereoscopic image display device of Patent Document 1, in order to prevent the viewer from simultaneously viewing the crosstalk caused by the left-eye frame and the right-eye frame, the viewer can extend the left-eye frame and the right eye. During the use of the frame, it is sought to increase the brightness. [PRIOR ART DOCUMENT] [Patent Document 1] [Patent Document 1] Japanese Laid-Open Patent Publication No. 2009-232249 (published on Oct. 8, 2009). According to the stereoscopic display system of Patent Document 1, in order to display one left-eye frame (left-eye image), the liquid crystal display device displays two frames, and displays one right-eye frame ( In the right eye image), the liquid crystal display device displays two frames, and the liquid crystal display device displays four frames in order to allow the viewer to visually recognize one stereoscopic image. In this case, in order for the viewer to recognize the stereoscopic image dynamically displayed, it is necessary to drive the liquid crystal display device at a high vertical scanning frequency. In the case where the liquid crystal display device is driven at a frequency as it is, the period during which each pixel is selected is shortened, so that the influence of the signal delay is large, and the luminance of the pixel may not reach a specific value. Therefore, in the case of a general liquid crystal display device, the polarity of the pixel is inverted every frame, and in order to make the brightness of the pixel reach a specific brightness, it is necessary to display the image for the right eye in the frame of the left eye image. Like the 2 frame period 160473.doc 201227705 'maintains the same pixel polarity. In this case, when the pixel polarity is the same during the two frame periods and the pixel polarity is reversed in two frame periods, the pixel polarity when the left eye image is displayed and the pixel polarity when the right eye image is displayed are displayed. Each of them is fixed without change, and a pixel afterimage may be generated due to the left and right image data. In the case where the pixel polarity is reversed by the 4-frame period, only one of the right eye images is switched to the left eye image or the left eye image is switched to the right eye image. The polarity is always reversed, resulting in different images seen from the left and right. Further, in the case where the pixel polarity is reversed at a period of six or more frames, since the period in which the pixels maintain the same polarity is long, flicker occurs. This will be specifically described with reference to FIG. 5. Fig. 5 U) shows a graph of the polarity of each pixel of the liquid crystal panel in the case where the pixel polarity is reversed every two frames. Further, Fig. 5(b) is a view showing the polarity of each pixel of the liquid crystal panel in the case where the pixel polarity is reversed every four frames. In FIGS. 5(a) and 5(b), "+" and "_" described in the squares indicate that the pixel polarity is positive polarity and negative polarity, and the pixel polarities adjacent to each other in the row direction and the column direction are different from each other. The way it is configured. In Fig. 5(a), if attention is paid to the pixel at the top left corner, when the left eye image of the fifth frame, the sixth frame, and the ninth frame of the third frame is displayed, The pixel polarity is always displayed as the positive polarity, while in the third frame, the fourth frame, the seventh frame, and the eighth frame, the pixel polarity is always displayed as the negative polarity. That is, each pixel in the left eye image display always shows the same polarity, and each pixel in the right eye image display always shows the same polarity. At this time, for example, the liquid crystal panel is a panel of the black matrix display mode, and if the pixel 1·50473. is displayed in the image of the right eye, the display pixel is always in the minimum state, since the pixel is always only in the positive polarity. If there is a change in the range, pixel residual images will be generated. In this case, when the pixel polarity is continuously inverted in the frame period of 2, the residual image of the pixel may be generated due to the pixel data to be displayed. (b) If you look at the pixel in the top left corner, the left eye image and the right eye image of the jade frame to the fourth frame all show positive polarity, and the left frame of the $ frame to the eighth frame Both the eye image and the right eye image show a negative polarity, and the ninth frame returns to the positive polarity again. The polarity of the pixel changes from positive to negative when it is converted to the fifth frame in the fourth frame, and is shown in Fig. 8. When the frame is changed to the ninth frame, the negative inversion is positive, but it can be seen that in either case, the polarity of the pixel is reversed when switching from the right eye image to the left eye image. Therefore, the pixel polarity is continuously 4 In the case where the frame period is reversed, the inversion timing of the pixel polarity becomes solid. When switching from the right eye image to the left eye image, or from the left eye image to the right eye image, the result is that the left eye image and the right eye image look different. The input image signal of the device is 6 〇 fps or less, and it is expanded into two frames for the left eye image and two frames for the right eye image. When the total number of frames is 4, the cycle is 6 frames or more. In the case of inverting the polarity of the pixel, the inversion frequency of the pixel polarity is 4 Hz or less, and there is a possibility that the jump phenomenon of the so-called flicker display due to the polarity inversion of the pixel occurs. Thus, if the polarity of the pixel is always reversed with a certain period In the case of each pixel, 'the polarity of the image displayed by the left eye and the polarity of the image of the right eye are always fixed at each time', so that the pixel afterimage is generated, or only the image from the right eye is switched to The left eye image and the left eye image are switched to the right eye image. 160473.doc 201227705 The polarity is reversed when switching either side, so the left eye image and the right eye image look different. The invention is completed to solve the above problems. The object of the present invention is to provide a liquid crystal display device and a stereoscopic display system capable of suppressing the image of the residual image and the display unevenness of the pixel. [Technical Solution to Problem] In order to solve the above problem, the liquid crystal display device of the present invention includes a liquid crystal panel. And comprising a plurality of pixels; and a polarity control mechanism that controls polarity of the plurality of pixels; wherein the polarity control mechanism has a plurality of polarity inversion patterns in which periods of polarity inversion are different from each other. The polarity control mechanism for controlling the polarity of a plurality of pixels has a plurality of polarity inversion patterns in which the periods of polarity inversion are different from each other. Thereby, the period of polarity inversion in each pixel is always changed rather than fixed. When the inversion period is always fixed, the ratio of the polarity of the left eye image to the polarity of the right eye image is displayed, and when switching from the left eye image to the right eye image, and from the right eye image The deviation of the inversion frequency of the image polarity at the time of the left eye image is lowered. Therefore, it is possible to realize a liquid crystal display device which can suppress display of residual images and display unevenness of pixels. [Effects of the Invention] As described above, the liquid crystal display device of the present invention includes: a liquid crystal panel including a plurality of pixels; and a polarity control mechanism that controls the plurality of pixels; and the polarity control mechanism has a polarity inversion Since the plurality of polarity inversion patterns having different periods are different from each other, the effect of the liquid crystal display device capable of suppressing the residual image and display unevenness of the pixel can be realized. 160473.doc Έ; 201227705 [Embodiment] One embodiment will be described based on Fig. 1 to Fig. 3 as follows. Fig. 1 is a block diagram showing a stereoscopic display system 300 of the present embodiment. The stereoscopic display system 300 includes a liquid crystal display device 1 and shutter glasses 28A. (Configuration of Liquid Crystal Display Device) The liquid crystal display device 100 includes a frame rate control circuit 11A, a timing controller 120, a write state signal transfer circuit 13A, a scan signal drive circuit 140, a display signal drive circuit 150, and a backlight drive circuit. 16" LCD panel 200, and backlight unit 25". The scan signal drive circuit 14 is also referred to as a gate driver, and the display signal drive circuit 15 is also referred to as a source driver. The liquid crystal panel 200 has a plurality of pixels arranged in a matrix in a plurality of columns and a plurality of rows. Typically, a red pixel, a green pixel, and a blue pixel are provided as a pixel system, and 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. In addition, the color display pixels may have other pixels (e.g., yellow pixels) in addition to the red, green, and blue pixels. Although not illustrated here, the liquid crystal panel 200 includes a front substrate, a rear substrate, and a liquid crystal layer interposed therebetween. =, for the figure of the rate control circuit, the frame rate is 6 as the input shadow said. For example, the input image signal is an NTSC signal. Frame rate control ::2 0 based on the input image signal, the frame rate of the input image signal is more than two frame rate / gold image pseudo-唬. Frame rate control circuit U〇

The frame rate of the image signal is a specific value, so the process is also called FRC 160473.doc 201227705 (Frame Rate Control • Frame Rate Control). Generally, the number of fields corresponding to one second contained in the round image signal displayed by the television device is 6 〇, and the frame rate of the input image signal is 60 fps (frames per sec nd: ). For example, the frame rate control circuit 110 generates an image signal having a frame rate of 120 fps based on the input image signal at a frame rate of 6 〇 fps. The liquid crystal display device 1 has a stereoscopic display mode for stereoscopic display and a flat display mode for performing flat display; and in the case of a stereoscopic display mode, the image signal includes image data to be displayed in a stereoscopic display mode. Further, in the case of the flat display mode, the image signal includes image data to be displayed in the flat display mode. Further, in the case where the video signal is written as 24p in the BD standard or the like, before being input to the frame rate control circuit 110, for example, 2_3 pull-down conversion is performed, and the frame rate control circuit 110 is input with a frame rate of 6 frames. 3 input image k number. However, in addition to inputting 6〇 fpS, image signals such as 5〇 fpS, 48 fps, etc. are also input. The timing controller 120 controls the write state signal transmission circuit 13A, the scan signal drive circuit 140' display signal drive circuit 15A, and the backlight drive circuit 160 » the timing controller 12 to generate a display signal based on the image signal, and will display The signal is output to the display signal driving circuit 丨50. When the image signal includes image data to be displayed in the stereoscopic display mode, the timing controller 120 expands the image data for the left eye into two frames, and expands the image data for the right eye into two frames, and Set the frame rate of the display signal to 24〇fps. At this time, the left eye image of the first frame and the left eye image of the second frame, the right eye image of the first frame, and the right eye image of the second frame may be respectively 160473.doc 201227705 The same image, can also be I PJ circle 1 for different images for overdrive. Further, if the image L number L 3 should be displayed in the flat display mode, the timing controller 120 sets the frame rate of the display signal to 12 prints $. . In this manner, the timing controller 12 changes the frame rate of the display signal to change the scanning signal driving circuit Μ (4) to supply the selected image. The scanning signal selects the pixel writing of the liquid crystal panel 2 . (4) The signal driving circuit 15G supplies the display signal to the liquid crystal panel. The selected pixel number driving circuit 14G and the display signal driving circuit drive the liquid crystal panel 2? γ in accordance with the vertical scanning frequency of the display signal frame rate. By changing the frame rate of the display signal in accordance with the display mode by the timing controller 120, the vertical scanning frequency of the liquid crystal panel 200 can be changed corresponding to the display mode. In the φ state, the liquid crystal display device 1 has a stereoscopic display function, and when the display signal driving circuit 150 performs stereoscopic display, the left eye image data and the right eye image data are alternately written every two consecutive vertical scanning periods. Enter each of a number of pixels. Further, the timing controller 120 is provided with a polarity control circuit 丨21. The polarity control circuit 121 outputs a polarity control signal for performing polarity control of a plurality of pixels in the liquid crystal panel 2, and corresponds to a polarity control mechanism in the patent application. The details of the polarity control will be described later. The write status signal transmission circuit 130 transmits a write status signal indicating a write state of a plurality of pixels in the stereoscopic display mode to the shutter glasses 280. [Configuration of Shutter Glasses] 160473.doc -10- 201227705 Shutter glasses 280, also referred to as active glasses, have a left eye shutter and a right eye shutter. When the liquid crystal display device 100 displays the image of the left eye, the write status signal indicates the display of the left eye image, and the left eye shutter of the shutter glasses 28 opens. The right eye shutter is closed. The liquid crystal display device 1 〇 情形 When the right eye image is displayed, the write status signal indicates the display of the right eye image, and the right eye shutter of the shutter glasses 280 is opened. The left eye shutter is closed. Therefore, the viewer wearing the shutter eyeglass 280 can view the left-eye image displayed by the liquid crystal display device 100 with only the left eye, and view the right-eye image displayed by the liquid crystal display device 1〇〇 only with the right eye. Further, the backlight driving circuit 160 drives the backlight unit 250. Thereby, the backlight unit 250 irradiates light from the back surface of the liquid crystal panel 2A. [Pixel Polarity Control] Next, the polarity control of the pixels in the liquid crystal panel 200 will be described with reference to Figs. 2 and 3'. The polarity of the plurality of pixels in the liquid crystal panel 200 is determined based on the polarity control signal '' output from the polarity control circuit 121 of the timing controller 120 and driven by the display signal drive circuit 150 to drive each of the plurality of pixels. In the present embodiment, the polarity of the pixel means the potential polarity of the pixel electrode based on the potential of the common electrode which is commonly provided for each pixel of the liquid crystal panel 200. The polarity control circuit 121 controls the polarity of a plurality of pixels so that the pixel polarities are the same in the two vertical scanning periods in which the left eye image data is written and the two vertical scanning periods in which the right eye image data is written. Further, the polarity control circuit 121 has a plurality of polarity inversion patterns in which the periods of polarity inversion are different from each other. The polarity inversion form includes: every 2 vertical scanning periods J60473.doc 201227705 Reverse polarity polarity inversion form (polarity inversion of every 2 frames, first polarity determination form); and each 4 vertical scanning period Polarity polarity inversion form (polarity inversion of every 4 frames, other polarity determination forms). First, referring to Fig. 2, a technique in which the polarity inversion of every two frames is reversed as a basic operation, and the polarity inversion of every four frames is inserted therebetween will be described. The item of the frame number in Fig. 2 indicates that the current frame is the first frame. In the item of the parallax image, the symbols "L" and "R" indicate the image for the left eye and the image for the right eye, respectively. In the item of the pixel polarity, the symbols "+" and "_" indicate whether the pixels are positive polarity or negative polarity when focusing on the pixels on the liquid crystal panel 200. First, from the first frame to the n-1th frame, the pixel polarity is reversed by the 2-frame period, and the positive polarity is displayed in the left-eye image, and the negative polarity is displayed in the right-eye image. Next, the same polarity is maintained from the nth frame to the 4th frame of the η+3 frame, and after the n+4th frame, the polarity is inverted every 2 frames. By this, 'n=4th frame and later' displays negative polarity in the left eye image, positive polarity in the right eye image, and the first frame to the η_1 frame relative to the left eye image, right The polarity of the eye image is reversed. That is, if the first frame (the previous start frame) and the n+4 frame (the subsequent start frame) are compared, the pixel polarities are the same, but the parallax images are different. In addition, in FIG. 2, from the η-2 frame to the η+1 frame, the four frame periods are kept at the same polarity (+polarity), and after the η+2 frame, they become again every two. The case where the frame inverts the polarity 'is also shown that after the n + 2 frame, the negative polarity is displayed in the left eye image and the positive polarity is displayed in the right eye image. That is, if the first frame (the previous start frame) and the n+2 frame (the subsequent start picture 160473.doc -12-201227705 frame) are compared, the parallax images are the same, but the pixel polarities are different. Thus, since the previous start frame and the subsequent start frame are different from each other in the parallax image and the pixel polarity, the polarity inversion operation of each of the two frames is used as the basic action. Inserting the polarity inversion form of polarity inversion in four frames therebetween can reduce the deviation of the pixel polarity in the left eye image and the right eye image. In the 'Fig. 2', when the polarity inversion form of the four frame periods is inserted, only one polarity inversion is performed including the polarity inversion in the case of switching the polarity inversion form, but even the switching polarity inversion form is included. When the polarity is reversed, the inversion of the odd-numbered four-frame period is performed three times or more, and the polarity deviation can be eliminated as well. In other words, in the polarity inversion form of the insertion, the polarity inversion is performed including the polarity inversion in the case of switching the polarity inversion, and then the polarity inversion is switched. By the fact that the 'before the start frame and the start frame after the 'because the difference between the parallax image and the pixel polarity can be different, the pixel polarity in the left eye image and the right eye image can be reduced. deviation. Next, a technique in which the polarity inversion of every four frames is reversed as a basic operation and the polarity inversion of each of the two frames is inserted will be described with reference to Fig. 3'. First, from the first frame to the n-1th frame, the pixel polarity is inverted by four frame periods and the pixel polarity is reversed when the right eye image is switched to the left eye image. Next, the frame period from the η frame to the n+1 frame is kept at the same polarity, and after the η+2 frame, the polarity is inverted every four frames. Therefore, after the n+2th frame, the pixel polarity is reversed when switching from the left eye image to the right eye image, which is opposite to the third frame to the nqth frame. 160473.doc •13-201227705 Relationship" and 'in Figure 3', the same polarity (positive polarity) is maintained during the frame from the nth through the 4th to the nth frame, and the polarity is reversed every 4 frames after the η_2 frame. The case 'is also reversed the pixel polarity when switching from the left eye image to the right eye image after the η-2 frame. By using the polarity inversion operation of each of the four frames as the basic motion, the polarity of the right-eye image and the left-eye image in the pixel polarity inversion timing can be reduced by the polarity inversion of the two frames inserted therebetween. . In FIG. 3, when the polarity inversion form of the two-frame period is inserted, only one polarity inversion is performed including the polarity inversion in the case of switching the polarity inversion form, but even if the switching polarity inversion form is included In the polarity inversion, the odd-numbered inversion is performed three times or more in a period of two frames, and the polarity deviation can be similarly reduced. In Fig. 2 and Fig. 3, the timing of inserting other polarity inversion forms other than the basic polarity inversion period can be periodically inserted into each predetermined frame ‘or randomly inserted. That is, the period from the basic polarity inversion form to the other polarity inversion form may be fixed or irregular. As a technique of randomly inserting other polarity inversion forms, there is a method of generating a random pattern by generating a random number in a R〇M or a register of the timing controller 120, or generating a random pattern based on it, or in timing control The device 12 is further provided with a random number generating circuit represented by a LFSR (Linear Feedback Shift Register), and a random pattern is generated based on a random number sequence generated by the random number generating circuit. [Modification of polarity control] 160473.doc • 14-201227705 Further, the basic pixel polarity inversion period is not particularly specified, and the polarity deviation can be eliminated even if a plurality of inversion periods are switched. That is, the switching order of the plurality of polarity inversion forms may also be irregular. For example, using any of the above random number column generation methods to generate a random number of ibit units, and assigning that if the random value is 0, the pixel polarity is inverted by 4 frames, and if the random value is 1, the pixel polarity is inverted by 2 frames. As long as the random value is updated every time the pixel polarity is reversed, the deviation of the pixel polarity can be eliminated. In this case, it is preferable to switch the polarity inversion form after performing the polarity inversion one or more times including the polarity inversion in the case of switching the polarity inversion form in each polarity control mode. The order in which the plurality of polarity inversion forms are switched may also be regular. Further, in the present embodiment, the polarity control circuit 121 has a polarity inversion form in which the polarity is inverted every two vertical scanning periods, and a polarity inversion form in which the polarity is reversed every four vertical scanning periods, but the polarity is not limited thereto. It is also possible to have a polarity inversion form in which the polarity is reversed every one vertical scanning period, or a polarity inversion form in which the polarity is reversed every six vertical scanning periods. In the case where the polarity inversion period other than the basic polarity inversion period is inserted by any method, it is preferable to eliminate the following deviation: (1) the ratio of the positive polarity to the negative polarity when the left eye image is displayed, (2) The ratio of the positive polarity to the negative polarity when the right eye image is displayed, (3) the ratio of the positive polarity to the negative polarity of the entire image display period, and (4) the switching from the left eye image to the right eye image, The frequency of inversion of the pixel polarity when switching from the right eye image to the left eye image. In the present embodiment, the display signal drive circuit 150 is configured to alternately write the left eye image data 160473.doc • 15-201227705 and the right eye image data into each of the two consecutive vertical scanning periods during stereoscopic display. Each of the pixels may be configured to alternately write left eye image data and right eye image data for each vertical scanning period. In the present embodiment, the polarity control circuit 121 is configured to store pixels adjacent to the column direction and the row direction among a plurality of pixels when one of the plurality of pixels is written in one of the left eye image data and the right eye image data. The manner in which the polarities are different from each other 'controls the polarity of a plurality of pixels, but is not limited thereto. For example, when the polarity control circuit 121 is written in the entirety of a plurality of pixels in one of the left eye image data and the right eye image data, the polarities of the pixels adjacent to the row direction among the plurality of pixels are identical to each other. Controlling the Polarity of a Plural of Pixels" [The present invention by software] Further, each block of the above liquid crystal display device 100, particularly the polarity control circuit 121, may be constituted by hardware logic, or may be used as follows. And by software. In other words, the liquid crystal display device 100 includes a CPU (central processing unit) that executes a command to implement a control program for each function, and a ROM (read only memory) that stores the above program, RAM. (random access memory) is used to expand the above program; and a memory device (recording medium) such as a memory, which stores the above program and various materials. Moreover, the object of the present invention can also be achieved by recording a program code (executable program, intermediate code program) of a control program of a liquid crystal display device that is readable by a computer for realizing the above functions. The recording medium of the 'source program' is supplied to the above-mentioned 160473.doc 201227705 liquid crystal display device H)0, and the computer (or cpu' Mpu) reads out the program of the recorded recording medium and executes it. As the recording medium, for example, a magnetic tape system such as a magnetic tape or a cassette tape, a disk containing a floppy disk (registered trademark)/hard disk, or a disk such as cd_R〇M/M〇/MD/DVD/CD_R can be used. a disk system; a card system such as a (including a hidden card)/optical card; or a semiconductor memory system such as a mask ROM/EPR (10)/EEPROM/flash Rqm. Further, the liquid crystal display device 1A may be connected to the communication network, and the code may be supplied via the communication network. The communication network is not particularly limited. For example, the Internet, the internal network, the commercial network, the LAN, the ISDN, the VAN, the CATV communication network, and the virtual private network (vmual pnvate netw〇rk) can be utilized. , telephone line network mobile communication network, and satellite communication network. Further, 'the transmission medium constituting the communication network is not particularly limited. For example, a dirty line such as dirty 1394, (4), power line transmission, loop circuit, telephone line, and ADSL circuit can be used, and infrared rays or the like such as IrDA or remote control can be used. (4) (Bluetooth, registered trademark), 8〇2.U wireless, HDR (high data rate), mobile phone network, satellite circuit, and ground wave digital network and other wireless lines. Alternatively, the present invention can be realized by electronically transmitting the above-described code, i.e., by inserting a computer data signal into a carrier wave. [Additional Items] The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims. #,About the implementation of the technical solution that incorporates the appropriate changes within the scope of the request, is also covered by Shu Ming's technical model 160473.doc -17· 201227705. In the liquid crystal display device of the present invention, the polarity inversion form may include a first polarity inversion form in which the polarity is reversed in each of the first vertical scanning periods, and the polarity control means alternately switches the first polarity inversion form and The polarity inversion form other than the first polarity inversion form, and the period of switching from the first polarity inversion form to the other polarity inversion form other than the first polarity inversion form is fixed. The liquid crystal display device of the present invention may also be used. The polarity inversion form includes a first polarity inversion form in which the polarity is reversed in each of the first vertical scanning periods, and the polarity control means alternately switches the first polarity inversion form and the first polarity inversion form. In the other polarity inversion form, the period from the first polarity inversion form to the other polarity inversion form other than the first polarity inversion form is irregular. In the liquid crystal display device of the present invention, the polarity control means may perform switching of the polarity inversion form after performing polarity inversion once or more in each polarity control mode. The switching order of the polarity inversion form is regular. The liquid crystal display device of the present invention may be such that the switching order of the polarity inversion form is irregular. Preferably, the liquid crystal display device of the present invention has a stereoscopic display function, and has a signal driving circuit for writing image data for displaying an image into the plurality of pixels, and the display signal driving circuit performs stereoscopic display every 2 The left eye image data and the right eye image data 160473.doc 201227705 are alternately written into each of the plurality of pixels during a continuous vertical scanning period, and the polarity control mechanism is configured such that the polarity of each pixel is written in the left eye. The polarities of the plurality of pixels are controlled in such a manner that the two vertical scanning periods of the image data are the same as the two vertical scanning periods in which the right-eye image data is written. According to the above configuration, when stereoscopic display is performed, left eye image data and right eye image data are alternately written into each of the plurality of pixels every two consecutive vertical scanning periods, and the polarity of each pixel is written in the above The two vertical scanning periods of the left eye image data are the same as those of the two vertical scanning periods in which the right eye image data is written. Thereby, the viewer can be prevented from simultaneously visually recognizing the crosstalk caused by the left eye frame and the right eye frame. Further, since the viewer can recognize that the period for the left eye frame and the right eye frame is extended, the brightness can be increased. In the liquid crystal display device of the present invention, the second polarity inversion form may be a polarity inversion form in which the polarity is reversed every two vertical scanning periods, and the other polarity inversion form reverses the polarity of the polarity every four vertical scanning periods. In the inverted form, or the first polarity inversion form is a polarity inversion form in which the polarity is reversed every four vertical scanning periods, and the other polarity inversion forms are reversed in polarity of the polarity inversion every two vertical scanning periods. Transfer form. According to the above configuration, it is possible to suppress the flicker which occurs when the luminance of the pixel is reversed in the case where the pixel polarity is reversed, or when the pixel polarity is reversed by the sixth frame. Preferably, in the liquid crystal display device of the present invention, when the polarity control means controls the polarity by the other polarity inversion form, the polarity inversion is included when the polarity of the switching pole 160473.doc -19-201227705 is reversed. After the odd polarity inversion is performed, the first polarity inversion form is switched. According to the above configuration, the first frame in the polarity control by the first polarity inversion form before switching to the other polarity inversion form is used as the previous start frame, and will be switched to the other polarity. The first frame in the polarity control performed by the first polarity inversion form after the conversion form is used as the subsequent start frame', and the first polarity inversion form and the other polarity inversion patterns are respectively in every two vertical scanning periods. And in the case where the polarity inversion form of the polarity is reversed every four vertical scanning periods, either the parallax image and the pixel polarity are different in the previous start frame and the subsequent start frame. Therefore, the ratio of the polarity of the left eye image display to the polarity of the right eye image display can be reduced. Further, in the case where the first polarity inversion form and the other polarity inversion patterns are reversed in polarity inversion for each of the four vertical scanning periods and every two vertical scanning periods, the pixel polarity is reversed before switching. When the polarity control is performed by the first polarity inversion form before switching to another polarity inversion form, and the polarity is controlled by the first polarity inversion form after switching to another polarity inversion form different. Therefore, when the left-eye image is switched to the right-eye image, the deviation from the inversion frequency of the pixel polarity when switching from the right-eye image to the left-eye image is lowered. Preferably, in the liquid crystal display device of the present invention, the plurality of pixels are arranged in a matrix of a plurality of columns and a plurality of rows, and the polarity control mechanism is written in one of the left eye image data and the right eye image data. When the total number of the plurality of pixels is entered, the polarities of the plurality of pixels 160473.doc • 20-201227705 are controlled such that the polarities of the pixels adjacent to the column direction and the row direction are different from each other. According to the above configuration, flicker and bright spots can be suppressed. In the liquid crystal display device of the present invention, the plurality of pixel systems may be arranged in a matrix of a plurality of columns and a plurality of rows, and the polarity control means is written in one of the left eye image data and the right eye image data. In the case of the entirety of the plurality of pixels, the polarities of the plurality of pixels are controlled such that the polarities of the pixels adjacent to the row direction of the plurality of pixels are identical to each other. The stereoscopic display system of the present invention is characterized by comprising: any one of the above liquid crystal display devices; and shutter glasses having a left eye shutter and a right eye shutter; and the left eye shutter is written in the left eye image data During the period of opening, the right eye shutter is opened during the writing of the right eye image data. According to the above configuration, the viewer of the liquid crystal display device can view the stereoscopic image. Further, as the polarity control means of the liquid crystal display device, a control program for operating a computer and a recording medium for recording the control program and being readable by a computer are also included in the technical scope of the present invention. Further, the present invention can also be expressed in the following form. In other words, in the liquid crystal display device of the present invention, in the liquid crystal display device in which a plurality of pixels are provided, each of the plurality of pixels displays the same polarity in one or more vertical scanning periods, and has two or more polarity inversions. Cycle. Further, it is preferable that each of the plurality of pixels has a polarity inversion operation for each vertical scanning period as a basic operation, and periodically generates a polarity inversion period with the base 160473.doc -21 - 201227705 The polarity of the different periods is reversed, and the polarity inversion is performed one or more times in a cycle different from the above-described basic operation. Further, it is preferable that each of the plurality of pixels has a polarity inversion operation in each vertical scanning period as a basic operation, and randomly generates a polarity inversion in a period different from a polarity inversion period in the basic operation. The polarity inversion is performed one or more times in a cycle different from the above-described basic operation. Further, it is preferable that each of the plurality of pixels is alternately switched between a plurality of periods of polarity inversion each time the polarity is inverted one or more times. Further, it is preferable that, in the plurality of polarity inversion periods, when switching from a certain polarity inversion period to another polarity inversion period, the polarity inversion period of the switching is selected by a predetermined mode. Further, it is preferable that the polarity inversion period of the switching is randomly selected when switching from a certain polarity inversion period to another polarity inversion period in the plurality of polarity inversion periods. Further, it is preferable that the liquid crystal display device has a stereoscopic display function, and when performing stereoscopic display, the left eye image data and the right eye image data are alternately written into each of the plurality of pixels every two consecutive vertical scanning periods. And each of the plurality of pixels displays the same polarity in the two vertical scanning periods in which the left-eye image data is written, and displays the same polarity in the two vertical scanning periods in which the right-eye image data is written. Further, it is preferable that the plurality of pixel systems are arranged in a matrix of a plurality of columns and a plurality of rows and are adjacent to one of the plurality of pixels of the left eye image data and the right eye image data. The polarities of the pixels in the row direction in the plurality of pixels are the same as each other. 160473.doc -22· 201227705 Further, 'preferably, the plurality of pixels are arranged in a matrix of a plurality of columns and a plurality of rows' and are written in the plural number of the left eye image data and the right eye image data. In the case of the entire pixel, the polarities of the pixels adjacent to the column direction and the row direction of the plurality of pixels are different from each other. [Industrial Applicability] The present invention is particularly suitable for a liquid crystal display device capable of displaying a stereoscopic image. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing a stereoscopic display system according to an embodiment of the present invention. Fig. 2 is a view showing an example of pixel polarity control. Fig. 3 is a view showing another example of pixel polarity control. Fig. 4 is a timing chart showing the manner in which the frame material and the liquid crystal shutter in the prior art are controlled. Figure 5 (a) shows the polarity of each pixel of the liquid crystal panel in the case where the polarity of the pixel is inverted every 2 frames; (b) shows the polarity of each pixel of the liquid crystal panel in the case where the polarity of the pixel is inverted every 4 frames Picture. [Main component symbol description] 100 liquid crystal display device 108 liquid crystal shutter L control signal 109 liquid crystal shutter R control signal 110 frame rate control circuit 120 timing controller 121 polarity control circuit (polarity control mechanism) 130 write state signal transmission circuit] 60473 .doc .23· 201227705 140 Scanning signal driving circuit 150 Display signal driving circuit 160 Backlight driving circuit 200 Liquid crystal panel 205 Vertical blanking period 250 Backlight unit 280 Shutter glasses 300 Stereoscopic display system 160473.doc -24-

Claims (1)

201227705 VII. Patent application scope: 1. A liquid crystal display device comprising: a liquid crystal panel comprising a plurality of pixels; and a polarity control mechanism for controlling polarity of the plurality of pixels; wherein: • the polarity control mechanism There are a plurality of polarity inversion forms in which the periods in which the polarities are reversed are different from each other. 2. The liquid crystal display device of claim 1, wherein the polarity inversion form includes a first polarity inversion form in which a polarity is reversed in each of the first vertical scanning periods; and the polarity control mechanism alternately switches the first polarity inversion The form is different from the polarity inversion form other than the first polarity inversion form; the period from the first polarity inversion form to the other polarity inversion form other than the first polarity inversion form is fixed. The liquid crystal display device of claim 1, wherein the polarity inversion form includes a first polarity inversion form in which the polarity is reversed in each of the first vertical scanning periods; and the polarity control mechanism alternately switches the first polarity inversion Form and other polarity inversion forms other than the 1*th polarity inversion form; . The period from the first polarity inversion form to the other polarity inversion form other than the first polarity inversion form is irregular. 4. The liquid crystal display of claim 1 is installed! The polarity control means switches the polarity inversion form after performing polarity inversion once or more in each polarity control mode. The liquid crystal display device of claim 4, wherein the switching order of the polarity inversion form is a regularity β. 6. The liquid crystal display device of the item 4 is switched in the polarity inversion form The order is irregular. 7. The liquid crystal display device of claim 2 or 3, wherein the display signal driving circuit is provided with a stereoscopic display function and having image data for writing an image for displaying the plurality of pixels; In the stereoscopic display, the left eye image data and the right eye image data are alternately written into each of the plurality of pixels every two consecutive vertical scanning periods; the polarity control mechanism is such that the polarity of each pixel is written in the above The polarity of the plurality of pixels is controlled in such a manner that the two vertical scanning periods of the left-eye image data and the two vertical scanning periods of the right-eye image data are the same. 8. The liquid crystal display device of claim 7, wherein the first polarity inversion form is a polarity inversion form in which the polarity is inverted every two vertical scanning periods; and the other polarity inversion patterns are inverted every four vertical scanning periods. Polarity polarity inversion form. 9. The liquid crystal display device of claim 7, wherein the first polarity inversion form is a polarity inversion form that reverses polarity every four vertical scanning periods; and the other polarity inversion patterns are inverted every two vertical scanning periods. Polarity polarity inversion form. 10. The liquid crystal display device of claim 8, wherein the polarity control mechanism controls the polarity by the other polarity inversion form, and the polarity inversion is performed when the pole 160473.doc 201227705 is reversed. After the odd polarity inversion, the mode switches to the first polarity inversion form. 11. The liquid crystal display device of claim 7, wherein the plurality of pixels are arranged in a matrix of a plurality of columns and a plurality of rows; wherein the polarity control mechanism is one of the left eye image data and the right eye image data When writing the entirety of the plurality of pixels, the polarities of the plurality of pixels are controlled such that the polarities of the pixels adjacent to the column direction and the row direction of the plurality of pixels are different from each other. 12. The liquid crystal display device of claim 7, wherein the plurality of pixels are arranged in a matrix of a plurality of columns and a plurality of rows; wherein the polarity control mechanism is one of the left eye image data and the right eye image data When writing the entirety of the plurality of pixels, the polarity of the plurality of pixels is controlled to control the polarities of the pixels adjacent to the row direction among the plurality of pixels. 13. A stereoscopic display system comprising: a liquid crystal display device according to claim 7; and shutter glasses having a left eye shutter and a right eye shutter; and wherein said left eye shutter is attached to said left eye image data Opening during writing The above right eye shutter is opened during the writing of the above right eye image data. A control program for causing a computer actor to act as the polarity control mechanism of the liquid crystal display device of any one of the claims id. 15. A computer-readable recording medium that records a control program such as a request item. I60473.doc