JP6354406B2 - Electro-optical device and electronic apparatus - Google Patents

Description

  The present invention relates to an electro-optical device and an electronic apparatus.

  In an electronic apparatus having a display function, a transmissive electro-optical device or a reflective electro-optical device is used. Light is irradiated to these electro-optical devices, and transmitted light or reflected light modulated by the electro-optical device becomes a display image, or is projected on a screen to become a projection image. A liquid crystal device is known as an electro-optical device used in such an electronic apparatus, which forms an image using the dielectric anisotropy of liquid crystal and the optical rotation of light in the liquid crystal layer. It is. An example of a liquid crystal device is described in Patent Document 1. In the liquid crystal device described in Patent Document 1, an element substrate and a counter substrate are used, and scanning lines and signal lines are arranged on the element substrate corresponding to the image display area, and pixels are arranged in a matrix at intersections thereof. Has been. A pixel transistor is provided in the pixel, and an image signal is supplied as a pixel potential to the pixel electrode of each pixel via the pixel transistor. On the other hand, a common electrode is provided on the counter substrate, and an image is formed according to a potential difference between the common electrode and the pixel electrode.

JP 2010-102151 A

  However, the conventional liquid crystal device as described in Patent Document 1 has a problem that it is difficult to increase the resolution of a display image and a problem that signal processing is difficult. For example, recently, display of a 4K image (3840 × 2160) in which the number of pixels is four times that of a full HD image (1920 × 1080) is required. To realize this with a liquid crystal device having the same area, The area had to be reduced to a quarter of the conventional size, and its realization was extremely difficult. Also, in order to view the video recorded as a full HD image as a 4K image due to lack of content corresponding to the 4K image, the image data of the full HD image is up-converted into a pseudo 4K image, which is converted into a 4K image. It was required to display with an adapted liquid crystal device. In this case, the up-conversion technique is not easy and a complicated processing circuit is required. In other words, the conventional liquid crystal device has a problem that it is difficult to up-convert image data, and a problem that it is difficult to realize an electro-optical device that displays the up-converted image data. It was.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

Application Example 1 An electro-optical device according to this application example includes a first substrate on which a plurality of first pixel electrodes are arranged, a second substrate on which a plurality of second pixel electrodes are arranged, a first pixel electrode, One of the first pixel electrodes is adjacent to the first second pixel electrode and the first second pixel electrode in the first direction. The second pixel electrode overlaps the second second pixel electrode in plan view, and one of the second pixel electrodes is adjacent to the first first pixel electrode and the first first pixel electrode in the first direction. It is characterized by overlapping with the matching second first pixel electrode in plan view.
According to this configuration, the resolution related to the first direction of the electro-optical device is determined based on the resolution of the first pixel electrode related to the first direction on the first substrate and the resolution of the second pixel electrode related to the first direction on the second substrate. Can also be increased. Specifically, the resolution related to the first direction of the electro-optical device is determined based on the resolution of the first pixel electrode related to the first direction on the first substrate and the resolution of the second pixel electrode related to the first direction on the second substrate. Can be doubled. Accordingly, it is possible to easily realize an electro-optical device that displays a high-definition image using the first substrate and the second substrate with low resolution.

Application Example 2 In the electro-optical device according to Application Example 1, the area of the overlapping portion between one of the first pixel electrodes and the first second pixel electrode is equal to that of one of the first pixel electrodes and the second pixel electrode. Is substantially equal to the area of the overlapping portion with the second pixel electrode, and the area of the overlapping portion between one of the second pixel electrodes and the first first pixel electrode is equal to one of the second pixel electrodes and the second first pixel. It is preferable to be approximately equal to the area of the overlapping portion with the electrode.
According to this configuration, the pixel length in the first direction of the electro-optical device can be made substantially uniform. Therefore, it is possible to display an image to be displayed faithfully and with high definition.

Application Example 3 In the electro-optical device according to Application Example 1 or 2, one of the first pixel electrodes is a third second pixel electrode with respect to a second direction intersecting the first direction. It overlaps with the fourth second pixel electrode adjacent to the third second pixel electrode in plan view, and one of the second pixel electrodes is connected to the third first pixel electrode in the second direction. It is preferable that it overlaps with the fourth first pixel electrode adjacent to the third first pixel electrode in plan view.
According to this configuration, the resolution of the electro-optical device in the second direction is determined by the resolution of the first pixel electrode in the second direction on the first substrate or the resolution of the second pixel electrode in the second direction on the second substrate. Can also be increased. Specifically, the resolution of the electro-optical device in the second direction is determined by the resolution of the first pixel electrode in the second direction on the first substrate and the resolution of the second pixel electrode in the second direction on the second substrate. Can be doubled. Accordingly, it is possible to easily realize an electro-optical device that displays a high-definition image using the first substrate and the second substrate with low resolution.

Application Example 4 In the electro-optical device according to Application Example 3, the area of the overlapping portion between one of the first pixel electrodes and the third second pixel electrode is equal to that of one of the first pixel electrodes and the fourth pixel electrode. Is approximately equal to the area of the overlapping portion with the second pixel electrode, and the area of the overlapping portion between one of the second pixel electrodes and the third first pixel electrode is one of the second pixel electrodes and the fourth first pixel. It is preferable to be approximately equal to the area of the overlapping portion with the electrode.
According to this configuration, the pixel length in the second direction of the electro-optical device can be made substantially uniform. Therefore, it is possible to display an image to be displayed faithfully and with high definition.

Application Example 5 In the electro-optical device according to any one of Application Examples 1 to 4, the electro-optical device includes a drive unit, the drive unit supplies a first image signal to the first pixel electrode, and a second image signal is supplied. It is preferable to supply the second image signal to the pixel electrode.
According to this configuration, since the electro-optical material is driven by the first image signal and the second image signal, it is possible to realize an excellent electro-optical device that displays an image to be displayed faithfully and with high definition.

この構成によると、元の画像データを簡単に高解像度の画像データにアップコンバートでき、アップコンバートされた画像データを正しく表示する電気光学装置を実現する事ができる。更に、第一期間と第二期間とで電気光学材料への極性を反転させる事ができる。 Application Example 6 In the electro-optical device according to Application Example 5, the voltage applied to the electro-optical material is the original image signal V _0, and the maximum amplitude of the original image signal V ₀ is the maximum amplitude voltage V _A. When an arbitrary voltage is α, the first image signal V ₁₁ supplied to the first pixel electrode and the second image signal V ₁₂ supplied to the second pixel electrode in the first period are expressed by Equation 1 The first image signal V ₂₁ supplied to the first pixel electrode and the second image signal V ₂₂ supplied to the second pixel electrode in the second period following the first period satisfying the relational expression with Expression 2 are: It is preferable to satisfy the relational expression between Expression 3 and Expression 4.

According to this configuration, it is possible to realize an electro-optical device that can easily up-convert original image data into high-resolution image data and correctly display the up-converted image data. Furthermore, the polarity to the electro-optic material can be reversed between the first period and the second period.

Application Example 7 In the electro-optical device according to Application Example 6, it is preferable that the first period and the second period are alternately repeated.
According to this configuration, it is possible to easily realize polarity inversion driving of a high-definition image.

Application Example 8 An electronic apparatus including the electro-optical device according to any one of Application Examples 1 to 7.
According to this configuration, it is possible to realize an electronic apparatus including an electro-optical device that displays a high-definition image and an electro-optical device that displays a high-resolution image by simply performing a simple process on a low-resolution image signal. it can.

The schematic diagram of the projection type display apparatus which is an example of an electronic device. 2A and 2B illustrate a liquid crystal device which is an example of an electro-optical device. 1 is a circuit block diagram of an electro-optical device. FIG. 6 illustrates a pixel of an electro-optical device. The circuit diagram of a pixel. FIG. 3 is a schematic cross-sectional view of a liquid crystal device. The figure which shows an example of the electro-optic characteristic of an electro-optic material. The figure which shows an example of an original image signal. The figure which shows an example of a 1st image signal. The figure which shows an example of a 2nd image signal. 6A and 6B illustrate an example of display of an electro-optical device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following drawings, the scale of each layer and each member is made different from the actual scale so that each layer and each member can be recognized.

(Embodiment 1)
"Outline of electronic equipment"
FIG. 1 is a schematic diagram of a projection display device (a three-plate projector) that is an example of an electronic apparatus. Hereinafter, the configuration of the electronic apparatus will be described with reference to FIG.

  The electronic apparatus (projection type display device 1000) includes three electro-optical devices 200 (refer to FIG. 2; hereinafter, abbreviated as first panel 201, second panel 202, and third panel 203), and these electro-optical devices 200. And at least a control device 30 for supplying a control signal. The first panel 201, the second panel 202, and the third panel 203 are three electro-optical devices 200 corresponding to different display colors (red, green, and blue). Hereinafter, unless it is particularly necessary to distinguish the first panel 201, the second panel 202, and the third panel 203, these are collectively referred to as an electro-optical device 200.

  The illumination optical system 1100 supplies the red component r of the emitted light from the illumination device (light source) 1200 to the first panel 201, supplies the green component g to the second panel 202, and supplies the blue component b to the third panel 203. To supply. Each electro-optical device 200 functions as a light modulator (light valve) that modulates each color light supplied from the illumination optical system 1100 according to a display image. The projection optical system 1300 synthesizes the emitted light from each electro-optical device 200 and projects it onto the projection surface 1400.

"Outline of electro-optical device"
FIG. 2 is a diagram illustrating a liquid crystal device which is an example of an electro-optical device. Next, an outline of the electro-optical device 200 will be described with reference to FIG.

As shown in FIG. 2, the electro-optical device 200 includes a first substrate 611 and a second substrate 612, and an electro-optical material (not shown) is disposed between the first substrate 611 and the second substrate 612. In this embodiment, the electro-optic material is a liquid crystal 46 (see FIG. 6). In the electro-optical device 200, a plurality of pixels 41 (see FIG. 3) are arranged in a matrix, and each pixel 41 includes a first pixel electrode 451, a second pixel electrode 452, and an electro-optical material. A plurality of first pixel electrodes 451 are arranged on the first substrate 611 in m ₁ rows and n ₁ columns (m ₁ is an integer of 2 or more and n ₁ is an integer of 2 or more), and the second pixel electrode 452 is a second pixel electrode 452. A plurality of m ₂ rows and n ₂ columns (m ₂ is an integer of 2 or more and n ₂ is an integer of 2 or more) are arranged on the substrate 612. In this manner, the electro-optic material is sandwiched between the first pixel electrode 451 and the second pixel electrode 452 in each pixel 41.

  The electro-optical device 200 further includes a driving unit 50 (see FIG. 3). The driving unit 50 supplies a first image signal to the first pixel electrode 451 and supplies a second image signal to the second pixel electrode 452. The first pixel electrode 451 and the second pixel electrode 452 are viewed from the normal direction of the first substrate 611 and the second substrate 612 (hereinafter referred to as a plan view), and their size and arrangement. The pitch is almost equal. That is, the sizes of the first pixel electrode 451 and the second pixel electrode 452 are substantially equal, and the arrangement pitch of the first pixel electrode 451 on the first substrate 611 and the arrangement pitch of the second pixel electrode 452 on the second substrate 612. And are almost equal. As a result, the electro-optic material is driven by the potential difference between the first image signal and the second image signal for each pixel 41, and the optical state is modulated in each pixel 41. In short, the electro-optical device 200 displays an image according to the first image signal supplied to the first pixel electrode 451 and the second image signal supplied to the second pixel electrode 452.

  Although the size and arrangement pitch of the first pixel electrode 451 and the second pixel electrode 452 are substantially equal, the first pixel electrode 451 and the second pixel electrode 452 are also related to the first direction (X-axis direction). Also in the second direction (the Y-axis direction) intersecting the first direction, the arrangement is shifted by half the arrangement pitch. That is, one of the first pixel electrodes 451 includes a first second pixel electrode 452 and a second second pixel electrode 452 adjacent to the first second pixel electrode 452 in the first direction with respect to the first direction. And one of the second pixel electrodes 452 is adjacent to the first first pixel electrode 451 and the first first pixel electrode 451 in the first direction with respect to the first direction. It overlaps with the matching second first pixel electrode 451 in plan view. As a result, the resolution in the first direction of the electro-optical device 200 is set to the resolution of the first pixel electrode 451 in the first direction on the first substrate 611 or the second pixel in the first direction on the second substrate 612. The resolution of the electrode 452 is increased. Specifically, the resolution in the first direction of the electro-optical device 200 is set to the resolution of the first pixel electrode 451 in the first direction on the first substrate 611 or the second pixel electrode in the first direction on the second substrate 612. The resolution of 452 can be doubled. Therefore, it is possible to easily realize the electro-optical device 200 that displays a high-definition image by using the first substrate 611 and the second substrate 612 with low resolution.

  Similarly, one of the first pixel electrodes 451 is planar to the third second pixel electrode 452 and the fourth second pixel electrode 452 adjacent to the third second pixel electrode 452 in the second direction. One of the second pixel electrodes 452 overlaps the second direction with respect to the third first pixel electrode 451 and the fourth pixel adjacent to the third first pixel electrode 451 in the second direction. It overlaps with the first pixel electrode 451 in plan view. In this way, the resolution in the second direction of the electro-optical device 200 is set to the resolution of the first pixel electrode 451 in the second direction on the first substrate 611 and the second pixel in the second direction on the second substrate 612. The resolution of the electrode 452 is increased. Specifically, the resolution in the second direction of the electro-optical device 200 is set to the resolution of the first pixel electrode 451 in the second direction on the first substrate 611 or the second pixel electrode in the second direction on the second substrate 612. The resolution of 452 can be doubled. Therefore, it is possible to easily realize the electro-optical device 200 that displays a high-definition image by using the first substrate 611 and the second substrate 612 with low resolution.

"Configuration of electro-optical device"
FIG. 3 is a circuit block diagram of the electro-optical device. FIG. 4 is a diagram illustrating a pixel of the electro-optical device. Next, the configuration of the electro-optical device 200 will be described with reference to FIGS. 3 and 4.

  As shown in FIG. 3, the electro-optical device 200 includes at least a display area 40 and a drive unit 50. In the display area 40 of the electro-optical device 200, a plurality of first scanning lines 421 and a plurality of first signal lines 431 that intersect with each other are formed, and each intersection of the first scanning line 421 and the first signal line 431 is formed. Correspondingly, the first pixel electrodes 451 are arranged in a matrix. The first scanning line 421 extends in the row direction (first direction, a direction parallel to the X axis), and the first signal line 431 extends in the column direction (second direction, a direction parallel to the Y axis). doing. The display area 40 of the electro-optical device 200 includes a plurality of second scanning lines 422 and a plurality of second signal lines 432 that intersect each other. The second pixel electrodes 452 are arranged in a matrix corresponding to the intersections. The second scanning line 422 extends in the row direction (first direction), and the second signal line 432 extends in the column direction (second direction).

As described above, the pixel 41 is formed in an overlapping portion of the first pixel electrode 451 and the second pixel electrode 452 in plan view. Therefore, the first scanning line 421, the first signal line 431, the second scanning line 422, and the second signal line 432 are wired to each of the pixels 41 arranged in a matrix. The number m of the pixels 41 in the row direction is a number in which the first pixel electrode 451 and the second pixel electrode 452 overlap in the row direction. The number n of pixels 41 in the column direction is a number in which the first pixel electrode 451 and the second pixel electrode 452 overlap in the column direction. The number m ₁ of the row direction of the first pixel electrode 451 and the number m ₂ of the row direction of the second pixel electrode 452, either the same (m ₁ = m _2), or is one difference (m ₁ = m ₂ +1, or m ₁ + 1 = m ₂ ). In these cases, the number the number m of the row direction of the pixels 41, obtained by subtracting 1 from the sum of the number m ₂ in the row direction and the number m ₁ of the row direction of the first pixel electrode 451 second pixel electrode 452 (m = M ₁ + m ₂ -1). Similarly, the number n _{1 in} the column direction of the first pixel electrode 451 and the number n _{2 in} the column direction of the second pixel electrode 452 are the same (n ₁ = n ₂ ) or are they different by one ( n ₁ = n ₂ +1 or n ₁ + 1 = n ₂ ). In these cases, the number n in the column direction of the pixels 41, the number obtained by subtracting the number n ₁ of the column direction of the first pixel electrode 451 a 1 from the sum of the number n ₂ of the column of the second pixel electrode 452 (n = N ₁ + n ₂ -1).

In the present embodiment, the electro-optical device 200 will be described by taking m ₁ = m ₂ = 1080 and n ₁ = n ₂ = 1920 as an example. In this case, the pixel 41 with m = 2159 and n = 3839 is included in the display area 40, and a so-called 4K image is displayed in the display area 40. When specifying the i-th first scanning line 421 within the first scanning line 421, the first scanning line 421 is represented as the first scanning line 1 Gi and the first signal of the j-th column within the first signal line 431. When the line 431 is specified, it is expressed as the first signal line 1Sj. Similarly, when specifying the i-th second scanning line 422 in the second scanning line 422, the second scanning line 422 is expressed as the second scanning line 2Gi, and the j-th column in the second signal line 432. When the signal line 432 is specified, it is expressed as the second signal line 2Sj.

  One of the first pixel electrodes 451 (for example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) is the first second pixel electrode 452 (in the present example, 2G1) with respect to the first direction. And the second pixel electrode 452 formed at the intersection of 2S1 and the second pixel electrode 452 formed at the intersection of 2G2 and 2S1, and the first second pixel electrode 452 in the first direction. Adjacent second second pixel electrode 452 (in this example, second pixel electrode 452 formed at the intersection of 2G1 and 2S2 and second pixel electrode 452 formed at the intersection of 2G2 and 2S2 ) And in a plan view. On the other hand, one of the second pixel electrodes 452 (for example, the second pixel electrode 452 formed at the intersection of 2G1 and 2S1) is the first first pixel electrode 451 (in this example, in the present example). The first pixel electrode 451 formed at the intersection of 1G1 and 1S1 and the first pixel electrode 451 formed at the intersection of 1G2 and 1S1, and the first first pixel electrode 451 Second first pixel electrodes 451 adjacent in the direction (in this example, the first pixel electrode 451 formed at the intersection of 1G1 and 1S2 and the first pixel formed at the intersection of 1G2 and 1S2 It overlaps with the electrode 451) in plan view.

  Similarly, one of the first pixel electrodes 451 (for example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) has a third second pixel electrode 452 (current example) in the second direction. Then, the second pixel electrode 452 formed at the intersection of 2G1 and 2S1, the second pixel electrode 452 formed at the intersection of 2G1 and 2S2, and the third second pixel electrode 452 Fourth second pixel electrodes 452 adjacent in two directions (in this example, the second pixel electrode 452 formed at the intersection of 2G2 and 2S1, or the second pixel electrode 452 formed at the intersection of 2G2 and 2S2). It overlaps with the pixel electrode 452) in plan view. On the other hand, one of the second pixel electrodes 452 (for example, the second pixel electrode 452 formed at the intersection of 2G1 and 2S1) is the third first pixel electrode 451 (in this example, in the present example). The first pixel electrode 451 formed at the intersection of 1G1 and 1S1, the first pixel electrode 451 formed at the intersection of 1G1 and 1S2, and the third first pixel electrode 451 Fourth first pixel electrodes 451 adjacent in the direction (in this example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S1 and the first pixel formed at the intersection of 1G2 and 1S2 It overlaps with the electrode 451) in plan view.

  The first pixel electrode 451 and the second pixel electrode 452 are arranged on the respective substrates at the same arrangement pitch, and their positions are shifted by about half of the arrangement pitch in both the first direction and the second direction. As a result, one of the first pixel electrodes 451 (for example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) and the first second pixel electrode 452 (in this example, 2G1 and 2S1) The area of the overlapping portion (the pixel 41 with m = 2 and n = 2 in the present example) with the second pixel electrode 452 formed at the intersection of the first pixel electrode 451 (the present example) Then, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) and the second second pixel electrode 452 (in this example, the second pixel electrode 452 formed at the intersection of 2G1 and 2S2). ) And the area of the overlapping portion (in this example, the pixel 41 with m = 2 and n = 3). Also, one of the second pixel electrodes 452 (for example, the second pixel electrode 452 formed at the intersection of 2G1 and 2S1) and the first first pixel electrode 451 (in this example, between 1G1 and 1S1) The area of the overlapping portion (the pixel 41 with m = 1 and n = 1 in this example) with the first pixel electrode 451 formed at the intersection is one of the second pixel electrodes 452 (in this example, 2G1 and the second pixel electrode 452 formed at the intersection of 2S1) and the second first pixel electrode 451 (in this example, the first pixel electrode 451 formed at the intersection of 1G1 and 1S2). Is substantially equal to the area of the overlapping portion (in this example, the pixel 41 with m = 1 and n = 2). Thus, the pixel length in the first direction of the electro-optical device 200 is substantially uniform, and an image to be displayed is displayed faithfully and with high definition.

  Similarly, one of the first pixel electrodes 451 (for example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) and the third second pixel electrode 452 (in this example, 2G1 and 2S1) The area of the overlapping portion (the pixel 41 with m = 2 and n = 2 in the present example) with the second pixel electrode 452 formed at the intersection of the first pixel electrode 451 (the present example) Then, the first pixel electrode 451 formed at the intersection of 1G2 and 1S2) and the fourth second pixel electrode 452 (in this example, the second pixel electrode 452 formed at the intersection of 2G2 and 2S1). ) And the area of the overlapping portion (in this example, the pixel 41 with m = 3 and n = 2). Also, one of the second pixel electrodes 452 (for example, the second pixel electrode 452 formed at the intersection of 2G1 and 2S1) and the third first pixel electrode 451 (in this example, between 1G1 and 1S1) The area of the overlapping portion (the pixel 41 with m = 1 and n = 1 in this example) with the first pixel electrode 451 formed at the intersection is one of the second pixel electrodes 452 (in this example, The second pixel electrode 452 formed at the intersection of 2G1 and 2S1) and the fourth first pixel electrode 451 (in this example, the first pixel electrode 451 formed at the intersection of 1G2 and 1S1), Is substantially equal to the area of the overlapping portion (in this example, the pixel 41 with m = 2 and n = 1). Thus, the pixel length in the second direction of the electro-optical device 200 is substantially uniform, and an image to be displayed is displayed faithfully and with high definition.

  In short, as shown in FIG. 4, the first pixel electrode 451 (i, j) of i row and j column, the first pixel electrode 451 (i, j + 1) of i row j + 1 column, and the first pixel electrode of i + 1 row j column. The second pixel electrode 452 (i, j) in i row and j column overlaps the first pixel electrode 451 (i + 1, j + 1) in 451 (i + 1, j) and i + 1 row and j + 1 column in plan view, and the respective overlaps. 2i-1 row 2j-1 column pixel 41 (2i-1, 2j-1), 2i-1 row 2j column pixel 41 (2i-1, 2j) and 2i row 2j-1 column pixel 41 ( 2i, 2j-1) and 2i rows and 2j columns of pixels 41 (2i, 2j) are formed. In this way, the resolution of the electro-optical device 200 (the density of the pixels 41) is the resolution of the first substrate 611 (the density of the first pixel electrode 451) or the resolution of the second substrate 612 (the density of the second pixel electrode 452). Twice as much.

  In the present specification, “substantially equal” means that the design concept does not intentionally differ, and there may be differences in various errors such as manufacturing errors and measurement errors. More specifically, it can be said that “substantially equal” up to a difference of about 5%.

  Returning to FIG. Various signals are supplied from the drive unit 50 to the display area 40, and an image is displayed in the display area 40. That is, the drive unit 50 supplies drive signals to the plurality of first scanning lines 421, the plurality of first signal lines 431, the plurality of second scanning lines 422, and the plurality of second signal lines 432. Specifically, the drive unit 50 includes a drive circuit 51 that drives each pixel 41, a display signal supply circuit 32 that supplies a display signal to the drive circuit 51, and a storage circuit 33. The storage circuit 33 includes a temporary storage circuit that temporarily stores a frame image and a non-volatile storage circuit that stores a maximum amplitude of a voltage applied to the electro-optical material and the like over a long period of time. The display signal supply circuit 32 generates a display signal from the frame image stored in the storage circuit 33 and supplies the display signal to the drive circuit 51. The display signal is a potential (first image signal or second image signal) corresponding to display luminance at each pixel 41, a clock signal, or the like.

  The driving circuit 51 includes a first scanning line driving circuit 521, a first signal line driving circuit 531, a second scanning line driving circuit 522, and a second signal line driving circuit 532. The first scanning line driving circuit 521 outputs a scanning signal for selecting or deselecting the first pixel electrode 451 in the row direction to each first scanning line 421, and the second scanning line driving circuit 522 sets the second pixel electrode 452 to the row. A scanning signal that is selected or not selected in the direction is output to each second scanning line 422. The first scanning line 421 and the second scanning line 422 transmit these scanning signals to the first pixel electrode 451 and the second pixel electrode 452. In other words, the scanning signal has a selected state and a non-selected state, and the first scanning line 421 can be appropriately selected in response to the scanning signal from the first scanning line driving circuit 521. Further, the second scanning line 422 can be appropriately selected in response to the scanning signal from the second scanning line driving circuit 522. The first scanning line driving circuit 521 and the second scanning line driving circuit 522 include a shift register circuit (not shown), and a signal for shifting the shift register circuit is output as a shift output signal for each stage. A scanning signal is formed using this shift output signal.

  The first scanning line driving circuit 521 and the second scanning line driving circuit 522 are synchronized, and it is preferable to always select the first scanning line 421 and the second scanning line 422 in the same row at the same time. For example, when the first scanning line driving circuit 521 selects the i-th first scanning line 1Gi, the second scanning line driving circuit 522 also preferably selects the i-th second scanning line 2Gi. The first signal line driving circuit 531 supplies the first image signal to each of the n first signal lines 431 in synchronization with the selection of the first scanning line 421. The second signal line driving circuit 532 supplies the second image signal to each of the n second signal lines 432 in synchronization with the selection of the second scanning line 422. The first signal line driver circuit 531 and the second signal line driver circuit 532 are also synchronized, and it is preferable to always supply the first image signal and the second image signal to the pixels 41 in the same row. For example, when the first signal line driving circuit 531 supplies the first image signal to the first pixel electrode 451 of the pixel 41 in the i-th row, the second signal line driving circuit 532 is also in the pixel 41 in the i-th row. The second image signal is supplied to the second pixel electrode 452.

  The electro-optical device 200 is formed using a first substrate 611 (see FIG. 6) and a second substrate 612 (see FIG. 6). A first scanning line 421, a first signal line 431, a first transistor 441 (see FIG. 5), and a first pixel electrode 451 are formed on the first substrate 611, and a second scanning line 422 is formed on the second substrate 612. The second signal line 432, the second transistor 442 (see FIG. 5), and the second pixel electrode 452 are formed. Accordingly, the first scanning line driving circuit 521 and the first signal line driving circuit 531 of the driving circuit 51 are formed on the first substrate 611 using thin film elements such as thin film transistors. On the other hand, the second scanning line driving circuit 522 and the second signal line driving circuit 532 of the driving circuit 51 are formed on the second substrate 612 using thin film elements such as thin film transistors.

  A display signal supply circuit 32 and a memory circuit 33 are included in the control device 30, and the control device 30 is formed of a semiconductor integrated circuit formed over a single crystal semiconductor substrate. The first substrate 611 is provided with a first mounting area 541 (see FIG. 6), and a control device is provided via a mounting terminal arranged in the first mounting area 541 and a flexible printed circuit (SPC). The display signal is supplied from 30 to the first scanning line driving circuit 521 and the first signal line driving circuit 531 of the driving circuit 51. Similarly, the second substrate 612 is provided with a second mounting area 542 (see FIG. 6), and the display device can display from the control device 30 via the mounting terminals and the flexible printed circuit board arranged in the second mounting area 542. The signal is supplied to the second scanning line driving circuit 522 and the second signal line driving circuit 532 of the driving circuit 51. Note that the drive circuit 51 may be formed of a semiconductor integrated circuit formed over a single crystal semiconductor substrate.

`` Pixel configuration ''
FIG. 5 is a circuit diagram of each pixel. Next, the configuration of the pixel 41 will be described with reference to FIG.

  The electro-optical device 200 according to the present embodiment is a liquid crystal device, and the electro-optical material is a liquid crystal 46. As shown in FIG. 5, the pixel 41 includes a first transistor 441, a second transistor 442, an electro-optic material (liquid crystal 46), a first pixel electrode 451, and a second pixel electrode 452. The pixel 41 has a first pixel electrode 451 and a second pixel electrode 452 that face each other, and a liquid crystal 46 of an electro-optic material is disposed between these electrodes. As a result, the transmittance of light passing through the liquid crystal 46 changes according to the electric field applied between the first pixel electrode 451 and the second pixel electrode 452. As the electro-optical material, an electrophoretic material may be used instead of the liquid crystal 46. In that case, the electro-optical device 200 becomes an electrophoretic device and is used for an electronic book or the like.

  The gate of the first transistor 441 is electrically connected to the first scanning line 421, one of the source and drain of the first transistor 441 is electrically connected to the first signal line 431, and the other of the source and drain of the first transistor 441 is connected. Are electrically connected to the first pixel electrode 451. That is, the first transistor 441 is interposed between the first pixel electrode 451 and the first signal line 431 and controls the electrical connection (conduction / non-conduction) between them. In this manner, the first pixel signal 451 is supplied with the potential (first image signal) supplied to the first signal line 431 when the first transistor 441 is turned on. In this embodiment, the first transistor 441 is composed of an N-type thin film transistor, and the scanning signal supplied to the first scanning line 421 becomes a selection signal when the potential is high and is not selected when the potential is low. Signal.

  The gate of the second transistor 442 is electrically connected to the second scanning line 422, one of the source and drain of the second transistor 442 is electrically connected to the second signal line 432, and the other of the source and drain of the second transistor 442 Are electrically connected to the second pixel electrode 452. That is, the second transistor 442 is interposed between the second pixel electrode 452 and the second signal line 432 and controls the electrical connection (conduction / non-conduction) between them. As described above, the second pixel electrode 452 is supplied with the potential (second image signal) supplied to the second signal line 432 when the second transistor 442 is turned on. In this embodiment, the second transistor 442 is composed of an N-type thin film transistor, and the scanning signal supplied to the second scanning line 422 becomes a selection signal when the potential is high and is not selected when the potential is low. Signal.

  Corresponding to the first pixel electrode 451, a first capacitor 471 is further formed on the first substrate 611, and the first image signal supplied during the selection period of the first pixel electrode 451 is also transmitted during the non-selection period. maintain. The first capacitor element 471 includes a first capacitor first electrode 711, a first capacitor second electrode 712, and a dielectric film disposed between these electrodes. The first capacitor first electrode 711 is electrically connected to the first pixel electrode 451, and the first capacitor second electrode 712 is electrically connected to the first fixed potential line 481. A first fixed potential is supplied to the first fixed potential line 481, and in this embodiment, a negative power supply potential VSS is supplied.

  A second capacitance element 472 is further formed on the second substrate 612 corresponding to the second pixel electrode 452, and the second image signal supplied during the selection period of the second pixel electrode 452 is also supplied to the non-selection period. maintain. The second capacitor element 472 includes a second capacitor first electrode 721, a second capacitor second electrode 722, and a dielectric film disposed between these electrodes. The second capacitor first electrode 721 is electrically connected to the second pixel electrode 452, and the second capacitor second electrode 722 is electrically connected to the second fixed potential line 482. A second fixed potential is supplied to the second fixed potential line 482, and in this embodiment, a negative power supply potential VSS (0 V) is supplied. The first fixed potential and the second fixed potential may be any potential as long as they are fixed potentials.

  In this way, each pixel 41 performs display according to the first image signal and the second image signal. Accordingly, the electro-optical device 200 can display an image to be displayed faithfully and with high definition.

  In this specification, the term “terminal 1 and terminal 2 are electrically connected” means that terminal 1 and terminal 2 can be in the same logic state (potential on design concept). Yes. Specifically, in addition to the case where the terminal 1 and the terminal 2 are directly connected by wiring, the case where they are connected via a resistance element, a switching element, or the like is included. That is, even if the potential at the terminal 1 and the potential at the terminal 2 are slightly different, if the same logic is given on the circuit, the terminal 1 and the terminal 2 are electrically connected. Therefore, for example, as shown in FIG. 5, even when the first transistor 441 is disposed between the first signal line 431 and the first pixel electrode 451, the first signal line is in an on state. Since the first image signal supplied to 431 is supplied to the first pixel electrode 451, the first signal line 431 and the first pixel electrode 451 are electrically connected.

"Structure of liquid crystal device"
FIG. 6 is a schematic cross-sectional view of the liquid crystal device. Hereinafter, a cross-sectional structure of the liquid crystal device will be described with reference to FIG. In addition, in the following forms, when “on XX” is described, when placed on XX, or placed on XX via other components Or, when a part is arranged on OO and a part is arranged through another component, it represents.

  In the electro-optical device 200 (liquid crystal device), a first substrate 611 and a second substrate 612 constituting a pair of substrates are bonded together by a sealing material 64 arranged in a substantially rectangular frame shape in plan view. The liquid crystal device has a configuration in which a liquid crystal 46 is sealed in a region surrounded by a sealing material 64. As the liquid crystal 46, for example, a liquid crystal material having positive dielectric anisotropy is used.

  As shown in FIG. 6, a plurality of first pixel electrodes 451 are formed on the liquid crystal 46 side of the first substrate 611, and a first alignment film 621 is formed so as to cover these first pixel electrodes 451. Yes. The first pixel electrode 451 is a conductive film made of a transparent conductive material such as indium tin oxide (ITO). On the other hand, a plurality of second pixel electrodes 452 are formed on the liquid crystal 46 side of the second substrate 612, and a second alignment film 622 is formed so as to cover the second pixel electrodes 452. The second pixel electrode 452 is a conductive film made of a transparent conductive material such as ITO.

  The liquid crystal device is a transmissive type, and polarizing plates (not shown) and the like are arranged on the light incident side and the light emitting side of the first substrate 611 and the second substrate 612, respectively. The configuration of the liquid crystal device is not limited to this, and may be a reflective type or a transflective type.

  The electro-optical device 200 includes a first substrate 611 and a second substrate 612. A part of the drive circuit 51 (the first signal line drive circuit 531 is shown in FIG. 6) and a first mounting area 541 are formed on the first substrate 611, and the drive circuit 51 is formed on the second substrate 612. A part (the second signal line driver circuit 532 is shown in FIG. 6) and a second mounting region 542 are formed. Through the first mounting area 541 and the second mounting area 542, the display signal from the control device 30 is sent to the first scanning line driving circuit 521, the first signal line driving circuit 531, the second scanning line driving circuit 522, and the second. The signal is supplied to the signal line driver circuit 532 and the like.

  The first pixel electrode 451 and the second pixel electrode 452 are aligned so as to be shifted from each other by a half pitch in both the first direction and the second direction. This is the position of the opening of the first pixel electrode 451. This means that the position and the size of the opening of the second pixel electrode 452 are shifted from each other by a half pitch in both the first direction and the second direction. The first light shielding film may be formed so as to surround the first pixel electrode 451, and the common part in the plan view of the area other than the first light shielding film and the first pixel electrode 451 is the first pixel. This is an opening of the electrode 451. Similarly, a second light shielding film may be formed so as to surround the periphery of the second pixel electrode 452, and a common part in a plan view of the area other than the second light shielding film and the second pixel electrode 452 is the second. This is an opening of the pixel electrode 452.

"Driving method"
FIG. 7 is a diagram illustrating an example of electro-optical characteristics of the electro-optical material. FIG. 8 is a diagram illustrating an example of the original image signal. FIG. 9 is a diagram illustrating an example of the first image signal. FIG. 10 is a diagram illustrating an example of the second image signal. FIG. 11 is a diagram illustrating an example of display of the electro-optical device. Next, a driving method of the electro-optical device 200 will be described with reference to FIGS.

  In the electro-optical device 200, one display image is formed in one frame period. Each first scanning line 421 and each second scanning line 422 are selected at least once in one frame period. Normally, each first scanning line 421 and each second scanning line 422 are selected once. Further, in the electro-optical device 200, the first period and the second period are alternately repeated, and polarity inversion driving is performed. As a result, the durability of the electro-optic material is improved. The first period and the second period may be repeated every frame period, or may be repeated every several frame periods. Thereafter, the entire frame may have the same polarity (frame inversion driving), or the polarity may be inverted for each row of the pixels 41 (1H inversion driving). Furthermore, 1H inversion driving may be used as dot inversion driving in which the polarity is inverted in the pixels 41 adjacent in the row direction. In the present embodiment, the first period and the second period are repeated for each frame period, and frame inversion driving will be described as an example.

  The driving unit 50 supplies the first image signal to the first pixel electrode 451 and supplies the second image signal to the second pixel electrode 452 both in the first period and in the second period following the first period. The first image signal in the first period is lower than the second image signal, and the first image signal in the second period is higher than the second image signal. By doing so, it is possible to invert the polarity to the electro-optic material in the first period and the second period while the driving potential of the first image signal or the second image signal is relatively low, and the low voltage The polarity inversion drive can be realized. In the present embodiment, the case where the first image signal is lower than the second image signal is negative (the electric field applied to the electro-optic material is directed from the second pixel electrode 452 toward the first pixel electrode 451). The case where the first image signal is higher than the second image signal is positive (the electric field applied to the electro-optic material is directed from the first pixel electrode 451 to the second pixel electrode 452).

  The potential at each pixel is the difference between the first image signal and the second image signal, and this absolute value is referred to as an image voltage. The image voltage is a voltage determined according to the electrical characteristics of the electro-optic material. For example, in the electro-optical material having the electro-optical characteristics (liquid crystal 46) depicted in FIG. 7, the image voltage (value on the horizontal axis of the electro-optical characteristics in FIG. 7) corresponding to the display gradation is determined. For example, in the example of FIG. 7, the image voltage for black display (transmittance 0%) is about 0V, and similarly, the image voltage for blackish gray display (transmittance 25%) is about 2.5V. The image voltage for bright gray display (transmittance 75%) is about 3.5V, and the image voltage for white display (transmittance 100%) is about 6V. Hereinafter, the driving method will be described by taking the electro-optical characteristics of FIG. 7 as an example. Hereinafter, as an example of a driving method, an example in which an original image is displayed as a high-definition image having a fourfold resolution will be described. Specifically, a method of up-converting and displaying a full HD image (an example of an original image) to a pseudo 4K image (an example of a high-definition image) will be described.

First, the original image has m ₁ (= m ₂ ) rows n ₁ (= n ₂ ) columns, and has a unique image voltage for each pixel. When this original image is displayed, the voltage applied to the electro-optic material at the pixel in i row and j column is referred to as an original image signal V ₀ . Further, the maximum amplitude of the original image signal V ₀ is set as the maximum amplitude voltage V _A. Here, since the electro-optical characteristic shown in FIG. 7 is assumed, the maximum amplitude voltage V _A is 6V. An arbitrary voltage is α. The arbitrary voltage α is about 0V to 5V in order to avoid a situation in which a negative voltage occurs when the potential fluctuates due to capacitive coupling. In the present embodiment, α = 0V is set for easy understanding. In such a case, the first image signal V ₁₁ supplied to the first pixel electrode 451 of i row j column and the second image signal V supplied to the second pixel electrode 452 of i row j column in the first period. ₁₂ satisfies the relational expression of Formula 5 and Formula 6, and the first image signal V ₂₁ and i row j column supplied to the first pixel electrode 451 of i row j column in the second period following the first period. The second image signal V ₂₂ supplied to the second pixel electrode 452 satisfies the relational expression of Expressions 7 and 8.

  In this way, the electro-optical device 200 can easily up-convert the original image into a high-definition image having a resolution of 4 times, and the up-converted high-definition image is correctly displayed. Furthermore, the polarity to the electro-optic material is reversed between the first period and the second period. Next, this point will be described.

As shown in FIG. 8, it is assumed that the pixel (1, 1) in the first row and the first column of the original image is black and the image voltage is zero V (V ₀ = 0 V). Also, the pixel (1,2) in the first row and the second column, the pixel (2,1) in the second row and the first column and the pixel (2,2) in the second row and the second column of the original image are displayed in blackish gray. Is set to 2V (V ₀ = 2V). Further, it is assumed that the outer pixels are grayish white and their image voltage is 4V (V ₀ = 4V). Further, the pixels outside them are displayed in white and their image voltage is 6V (V ₀ = 6V).

Here, the first period will be specifically described. The first image signal V ₁₁ supplied to the first pixel electrode 451 of i row and j column in the first period and the second image signal V ₁₂ supplied to the second pixel electrode 452 of i row and j column are expressed by Equation 5: And V _A = 6V, the first pixel electrode 451 (1,1) in the first row and the first column to the first pixel electrode 451 (4,4) in the fourth row and the fourth column are satisfied. The first image signal V ₁₁ supplied to each is as shown in FIG. On the other hand, the second image signal V ₁₂ supplied from the second pixel electrode 452 (1, 1) in the first row and the first column to the second pixel electrode 452 (4, 4) in the fourth row and the fourth column is shown in FIG. As shown. Since the first pixel electrode 451 and the second pixel electrode 452 are arranged with a half-pitch shift with respect to the first direction and the second direction, the image voltage of the original image is converted by Equation 5 and Equation 6 as follows: The image voltages (V ₁₁ -V ₁₂ ) supplied from the pixel 41 (1, 1) in the row 1 column to the pixel 41 (7, 7) in the 7 row 7 column are as shown in FIG. . In the first period, negative polarity driving is taken as an example. As can be seen from FIG. 11, the image displayed by the electro-optical device 200 with respect to the original image is represented with approximately twice the resolution in one direction (the pixel size in one direction is approximately half). It can be seen that the gradation is almost doubled.

The same applies to the first image signal V ₂₁ and the second image signal V ₂₂ supplied in the second period. Further, conventionally, in order to perform polarity inversion driving, the amplitude of the image signal is double the maximum amplitude voltage. This is because the maximum potential of the image signal during positive polarity driving is the sum of the common potential and the maximum amplitude voltage, and the minimum potential of the image signal during negative polarity driving is a value obtained by subtracting the maximum amplitude voltage from the common potential. Because of it. Therefore, the electro-optical device 200 according to this embodiment has an image signal whose amplitude is half that of the conventional one, and can be reduced in voltage.

When the original image is 2m ₁ × 2n ₁ high-definition images, the inverse transformations of Equation 5 to Equation 8 are performed, and m ₁ × n ₁ first image signals V ₁₁ supplied in the first period. And the second image signal V ₁₂ and m ₁ × n ₁ first image signals V ₂₁ and second image signals V ₂₂ supplied in the second period to obtain the first pixel electrode 451 and the second pixel electrode 452. Supply.

"Other electronic devices"
The electro-optical device 200 has the above-described configuration. As an electronic apparatus incorporating the electro-optical device 200, in addition to the projector described with reference to FIG. 1, a rear projection type TV, a direct-view type TV, a mobile phone , Portable audio equipment, personal computers, video camera monitors, car navigation devices, pagers, electronic notebooks, calculators, word processors, workstations, videophones, POS terminals, digital still cameras, and the like. Such an electronic apparatus includes an electro-optical device 200 that displays a high-definition image and an electro-optical device 200 that displays a high-resolution image by simply performing a simple process on a low-resolution image signal. Become.

  The present invention is not limited to the above-described embodiment, and various modifications and improvements can be added to the above-described embodiment.

  1 Gi ... i row first scanning line, 2 Gi ... i row second scanning line, 1Sj ... j column first signal line, 2Sj ... j column second signal line, 30 ... control device, 32 Signal display circuit for display, 33 Memory circuit, 40 Display area, 41 Pixel, 46 Liquid crystal, 50 Drive unit, 51 Drive circuit, 64 Sealing material, 200 Electro-optical device, 201 First Panel, 202 ... Second panel, 203 ... Third panel, 421 ... First scanning line, 422 ... Second scanning line, 431 ... First signal line, 432 ... Second signal line, 441 ... First transistor, 442 ... Second transistor, 451 ... first pixel electrode, 452 ... second pixel electrode, 471 ... first capacitor element, 472 ... second capacitor element, 481 ... first fixed potential line, 482 ... second fixed potential line, 521 ... A first scanning line driving circuit, 522, a second scanning line driving circuit, DESCRIPTION OF SYMBOLS 31 ... 1st signal line drive circuit, 532 ... 2nd signal line drive circuit, 541 ... 1st mounting area | region, 542 ... 2nd mounting area | region, 611 ... 1st board | substrate, 612 ... 2nd board | substrate, 621 ... 1st alignment film , 622 ... second alignment film, 711 ... first capacitor first electrode, 712 ... first capacitor second electrode, 721 ... second capacitor first electrode, 722 ... second capacitor second electrode, 1000 ... projection display device DESCRIPTION OF SYMBOLS 1100 ... Illumination optical system, 1300 ... Projection optical system, 1400 ... Projection surface.

Claims (6)

A first substrate on which a plurality of first pixel electrodes are arranged;
A second substrate on which a plurality of second pixel electrodes are arranged;
An electro-optic material sandwiched between the first pixel electrode and the second pixel electrode,
One of the first pixel electrodes overlaps the first second pixel electrode and the second second pixel electrode adjacent to the first second pixel electrode in plan view in the first direction. And
One of the second pixel electrodes includes a first first pixel electrode and a second first pixel electrode adjacent to the first first pixel electrode in a plan view with respect to the first direction. Overlap,
With a drive,
The driving unit supplies a first image signal to the first pixel electrode, supplies a second image signal to the second pixel electrode,
When the electrical voltage applied to the optical material to an original image signal V _0, the maximum amplitude of the original image signal V ₀ to the maximum amplitude voltage V _A, was an arbitrary voltage alpha,
The first image signal V ₁₁ supplied to the first pixel electrode and the second image signal V ₁₂ supplied to the second pixel electrode in the first period satisfy the relational expression of Equations 1 and 2.
The first image signal V ₂₁ supplied to the first pixel electrode in the second period following the first period and the second image signal V ₂₂ supplied to the second pixel electrode are represented by the relationship between Expression 3 and Expression 4. An electro-optical device characterized by satisfying the formula .

The area of the overlapping portion between one of the first pixel electrodes and the first second pixel electrode is substantially equal to the area of the overlapping portion between one of the first pixel electrodes and the second second pixel electrode,
The area of the overlapping portion between one of the second pixel electrodes and the first first pixel electrode is substantially equal to the area of the overlapping portion between one of the second pixel electrodes and the second first pixel electrode. The electro-optical device according to claim 1. One of the first pixel electrodes includes a third second pixel electrode, a fourth second pixel electrode adjacent to the third second pixel electrode, and a second direction intersecting the first direction. , In plan view,
One of the second pixel electrodes includes a third first pixel electrode and a fourth first pixel electrode adjacent to the third first pixel electrode in a plan view in the second direction. The electro-optical device according to claim 1, wherein the electro-optical device is overlapped. The area of the overlap between one of the first pixel electrodes and the third second pixel electrode is substantially equal to the area of the overlap between one of the first pixel electrodes and the fourth second pixel electrode,
The area of the overlap between one of the second pixel electrodes and the third first pixel electrode is substantially equal to the area of the overlap between one of the second pixel electrodes and the fourth first pixel electrode. The electro-optical device according to claim 3. The electro-optical device according to any one of claims 1 to 4, characterized in that repeated alternately with the said first period the second period. An electronic apparatus comprising the electro-optical device according to any one of claims 1 to 5.

Images