Source: https://patents.google.com/patent/JP4159045B2/en
Timestamp: 2020-05-25 08:50:12
Document Index: 556905225

Matched Legal Cases: ['art 2', 'art 2', 'art 3', 'art 3', 'Application No. 0625861', 'Application No. 2252175', 'Application No. 0860728', 'Application No. 2321815', 'art 3', 'arts 64', 'art 65', 'art 65']

JP4159045B2 - Autostereoscopic display - Google Patents
JP4159045B2
JP4159045B2 JP2003322296A JP2003322296A JP4159045B2 JP 4159045 B2 JP4159045 B2 JP 4159045B2 JP 2003322296 A JP2003322296 A JP 2003322296A JP 2003322296 A JP2003322296 A JP 2003322296A JP 4159045 B2 JP4159045 B2 JP 4159045B2
JP2003322296A
JP2004110032A (en
アール． ジョーンズ グラハム
2002-09-17 Priority to GB0221583A priority Critical patent/GB2393344A/en
2003-09-12 Application filed by シャープ株式会社 filed Critical シャープ株式会社
2004-04-08 Publication of JP2004110032A publication Critical patent/JP2004110032A/en
2008-10-01 Publication of JP4159045B2 publication Critical patent/JP4159045B2/en
The present invention relates to an autostereoscopic display. Such displays may include autostereoscopic three-dimensional (3D) displays, such as in 3D television, medical imaging, computer games, telephony, scientific visualization, virtual reality and office automation equipment. Can be used.
A known type of autostereoscopic 3D display is shown in FIG. 1 of the accompanying drawings. The display comprises a diffuse backlight 1 arranged on the back of a spatial light modulator (SLM) 2, for example in the form of a liquid crystal display (LCD). The SLM 2 includes, for example, an array of pixels (pixels) as disclosed in Patent Document 1. In this disclosure, pixels are composed of columns, and adjacent columns are substantially connected to each other in the horizontal or horizontal direction.
For example, a parallax optical device 3 in the form of a lenticular screen as illustrated in FIG. 1 is disposed in front of the SLM 2. Each parallax element 6 of the parallax optical device 3 is aligned with a respective pair of pixel columns of the SLM 2. The pixel column is controlled to display every other vertical strip of two-dimensional (2D) images on the left and right eyes of the viewer, respectively. For example, a pixel indicated by 4 displays a left-eye image element, whereas a pixel indicated by 5 displays a right-eye image element.
The light from the column containing the pixels 4 and 5 is imaged by the associated parallax element 6 in the first lobe 7. Light from adjacent pixel columns indicated by 8 and 9 is imaged by the parallax element 6 into adjacent lobes 10 and 11, respectively. Furthermore, the light from the next column, indicated by 12 and 13, is imaged in the further lobes 14 and 15 by the parallax element 6.
In order to provide a view point corrected display in which each eye of the observer sees the same image throughout the display, the pitch of the parallax elements of the parallax optical device 3 is 2 of the pitch of the pixel column of the SLM 2 Slightly smaller than twice. Alternatively, the parallax optical device may be disposed between the diffuse backlight 1 and the SLM 2, in which case the pitch of the parallax elements of the parallax optical device is slightly larger than twice the pitch of the pixel columns.
This creates a viewing zone that is repeated for several lobes. If the left and right eyes of the observer are placed in one left and right viewing area of the lobe, the left eye sees only the 2D image intended to be seen by the left eye and the right eye is the right eye in the entire display. Only view 2D images that are intended to be viewed. The widest part of the viewing zone is called the viewing window and lies in a common plane indicated at 16. The viewing window 16 is formed at a predetermined viewing distance from the display.
If the left and right eyes of the viewer stay in the viewing area of the left and right eyes, the viewer sees the display orthoscopically and sees the correct 3D video. Such a viewing zone may be referred to as an orthoscopic viewing zone and the position of the viewing window for orthoscopic viewing is indicated at 17-21. However, if the viewer's left eye is located in the right viewing zone and the right eye is located in the left viewing zone, the viewer sees a pseudoscopic image. The pseudoscopic viewing window positions are indicated at 22-25 in FIG. Pseudoscopic images cause problems. This is because these images often appear to have a certain depth despite depth information being false or incorrect. Therefore, it is not always clear that the observer is in the wrong position. In addition, pseudoscopic viewing is known to cause headaches and other eye fatigue symptoms.
Further, as the viewer moves laterally, the eyes may move, for example, to a location where the content seen by the right eye includes a significant portion of the left eye lobe. This again leads to a non-ideal view position known to cause headaches and other eye fatigue symptoms.
Non-Patent Document 1 discloses a 3D index to assist an observer in finding an appropriate viewing area for an autostereoscopic 3D display of the type shown in FIG. 1 of the accompanying drawings. This indicator is shown in FIG. 2 of the accompanying drawings and includes a light blocking box 26 provided with a front slit 27 and containing light emitting diodes (LEDs) 28-32. LEDs 28, 30 and 32 emit green light, whereas LEDs 29 and 31 emit red light. The size of the slit 27 and the shape dimensions of the LEDs 28 to 32 with respect to the slit 27 are such that when the observer's eyes are placed at the orthoscopic positions 17 to 21, the light from the LEDs 32 to 28 passes through the slit 27, respectively. Can be seen. Therefore, when the observer's eyes are in one of the orthoscopic positions 17 to 21, only the green LED or only the red LED is visible. If the observer moves away from the orthoscopic position, light from both the green and red LEDs can be seen. Therefore, the observer must be in a position where only monochromatic light can be seen through the slit 27 of the indicator.
The indicator is manufactured as a separate device from the autostereoscopic display, thus ensuring that the area where only a single color is visible is accurately aligned with the orthoscopic position in the viewing window During manufacturing, precise alignment is required. Such alignment is time consuming and cumbersome, thus substantially increasing the cost and complexity of manufacturing. Furthermore, the optical system of the indicator is different from the optical system of the display itself. Thus, the indicator accurately identifies only the plane containing the viewing window and the orthoscopic viewing position very close to this plane. If the observer moves far outside this plane, the indicator no longer provides a correct indication of whether the observer is in an orthoscopic or non-orthoscopic position. Furthermore, because of the differences between the indicator optics and the display optics, the indicators provide an indication that is independent of the performance of the display optics. Thus, even if the indicator is correctly aligned with the display, in practice, if the display optics are incomplete, such as the observer is in an inappropriate viewing position, the You may receive a false indication that you are in a scoping position.
Patent Document 2 discloses a parallax barrier type autostereoscopic display. When the viewer moves out of the orthoscopic viewing area, the video seen by the viewer changes. Lateral movement darkens the perceived video, whereas vertical movement results in vertical stripes superimposed on the video. These video changes are caused by the parallax barrier structure of the display.
Patent Document 3 further discloses an autostereoscopic display in which the perceived image changes when the viewer moves outside the orthoscopic viewing area. In this case, the perceived video becomes monoscopic as soon as the viewer leaves the orthoscopic viewing zone to avoid pseudoscopic viewing.
U.S. Pat. Nos. 6,057,028 and 5,037,597 disclose an autostereoscopic 3D display as shown in FIGS. 3 and 4 of the accompanying drawings. This display differs from that shown in FIG. 1 in that it includes the viewer position indicator (VPI) configuration shown in FIG. This configuration includes a part of the backlight 1, a part of the SLM 2, and a part of the parallax optical device 3. As shown in FIG. 3, the SLM 2 includes two 2D stereos as interlaced vertical strips on every other column of pixels with each parallax element 6 optically aligned with a pair of adjacent pixel columns. It has a video part 2a for displaying a stereoscopic video. The left and right viewing zones are formed in the lobes 7, 10, 11, 14, and 15, but only the orthoscopic viewing positions 17, 19 and 21 are intended to be used by the viewer. Accordingly, the orthoscopic positions 18 and 20 shown in FIG. 1 are not intended to be used.
The viewer position indicator configuration is formed by the upper strip of the backlight 1, the signal transfer part 2 b including one or more upper rows of pixels of the SLM 2, and the upper part 3 a of the parallax optical device 3. The pixels shown in FIG. 4 are operated in horizontal pairs to function as pixels such as 30 and 31 having twice the spread and twice the pitch shown in FIG. Used for display. The upper part 3a of the parallax optical device 3 includes a part where the parallax element 32 has a horizontal pitch twice that of the parallax element 6 shown in FIG. Pixels such as 30 (shown without shadows) are controlled to provide a bright image and alternate with pixels such as 31 (shown with shading) controlled to provide a dark image. Become. In particular, pixel 30 is substantially transparent, whereas pixel 31 is substantially opaque.
Each parallax element 32 is aligned with the respective parallax element 6. Pixels 30 and 31 and parallax element 32 work together to provide a bright image for lobes 10 and 11 and a dark image for lobes 7, 14 and 15. Thus, when the viewer is located at orthoscopic positions 17, 19 and 21 in the viewing window 16, the viewer position indicator configuration appears dark. When an observer moves from an orthoscopic position such as 19 to a pseudoscopic position such as 23, light from the viewer position indicator configuration is visible, for example, to the viewer's right eye, so that the observer is orthoscopic. The observer is shown to have moved from the position to the pseudoscopic position. When only one eye sees light from the viewer position indicator configuration, the brain records this as video data. Thus, in order for the display to function, it is not necessary for the observer's eyes to see the light from the configuration. Thus, when moving to a position where the light from the viewer position indicator configuration is not visible, the observer remains in an orthoscopic position such as that shown in 17, 19 and 21.
European Patent Application No. 0625861 British Patent Application No. 2252175 WO94 / 24601 pamphlet European Patent Application No. 0860728 British Patent Application No. 2321815 E. Nakayama et al., "Proceedings of Third International Display Workshop", November 27-29, 1996, International Conference Center, Kobe, Japan (International Conference Center, 96). , Volume 2
The autostereoscopic display according to the present invention is capable of displaying images in 2D mode and 3D mode, and has an image display having the same color filter pattern for every two pixels in the horizontal direction and two in the horizontal direction. An autostereoscopic display comprising a signal display in which the color filter pattern for every other pixel is the same color and a parallax optical device, wherein the video displays are vertically connected to each other in the horizontal direction in 3D mode. Each column of a pair of pixels in the direction displays a left eye image element and a right eye image element, respectively, and the parallax optic device is associated with the image display in 3D mode to The first horizontal pitch corresponding to the horizontal pitch of each row A first portion that forms a plurality of right viewing areas and a left viewing area in a viewing area by an array of parallax elements, and a first portion that is visible in an orthoscopic viewing area of the viewing area in association with the signal display. And a second portion that forms a second signal image that can be seen in a pseudoscopic viewing area adjacent to the orthoscopic viewing area, wherein the second position is the signal display. A parallax having a second pitch equal to the pitch of every other color filter pattern pixel of the same color in the horizontal direction and substantially equal to 1.5 times the first pitch in the horizontal direction A first signal image that includes an array of elements and is visible in the orthoscopic viewing area and a second signal image that is visible in the pseudoscopic viewing area have different color brightness. To.
The video display and the signal display may each include a first portion and a second portion of a common display.
The common display may include a light source and one of a light transmission type and a light reflection type spatial light modulator.
The spatial light modulator may include a liquid crystal device.
The image display and the first part may be linked to form the viewing zone with a plurality of lobes having two of the viewing zones for each lobe.
The transflective spatial light modulator may include a liquid crystal device.
The video display and the first portion and is in conjunction may form the viewing area in the right eye area and a plurality of lobes having a left eye area for each lobe.
The parallax optical device may include an array of hologram optical elements.
The parallax optical device may include a parallax barrier.
The first part of the parallax barrier includes a plurality of slits having a first width, and the second part of the parallax barrier includes a plurality of slits having a second width smaller than the first width. You may prepare.
The parallax barrier includes a plurality of parallax elements, and every other element of the parallax elements in the second part is aligned with each element of the parallax elements in the first part in a vertical direction. May be.
The parallax optical device may be removable in the non-autostereoscopic display mode.
The parallax barrier includes a first layer and a removable second layer, the first layer including a barrier region for supplying light having a first polarization, and at least the first layer An aperture region for providing light having a second polarization substantially orthogonal to the polarization, the second layer comprising a polarizer for passing the light of the second polarization Also good.
The video display and the signal display are configured to supply the first polarized light, the barrier region is configured to pass the first polarized light, and the opening region is The first polarized light may be configured to at least partially convert to the second polarized light.
The first layer is a half-wave plate, the barrier region has an optical axis parallel to the first polarization, and the aperture region is aligned at 45 ° with respect to the first polarization. You may have the optical axis made.
The signal display may be configured to be active over the entire lateral extent corresponding to the lateral extent of each 3D video displayed by the video display.
According to the present invention, an autostereoscopic display including a video display, a signal display, and a parallax optical device is provided. The parallax optical device is associated with the video display, in a first region forming a plurality of left and right eye viewing areas in the viewing area, and in association with the signal display in at least one first portion of the viewing area. And a second portion that forms a first signal image that is visible and a second signal image that is visible in at least one second portion of the viewing area. The first portion includes an array of parallax elements having a first pitch in a first direction, and the second portion is substantially equal to 1.5 times the first pitch in the first direction. It includes an array of parallax elements having a second pitch.
Therefore, it is possible to provide a configuration that allows the observer to determine the position of the observer with respect to the autostereoscopic display regardless of whether an actual image is displayed. In particular, by viewing the first and second signal images, the observer can determine whether they are in the first part or the second part of the viewing area. Since the index has a higher spatial frequency than that provided by the index in Patent Document 4, the index pattern is less visible. If the display is switchable mechanically or electrically between 3D mode and 2D mode, any residual visibility of the 2D mode indicator pattern is also reduced. For a pixellated display, a brighter indicator can be provided because more pixels are used to provide the indicator.
The at least one first portion may include an orthoscopic viewing zone. The at least one second portion may include a pseudoscopic viewing area adjacent to the orthoscopic viewing area. Therefore, it is possible to determine whether or not the observer is located in the orthoscopic viewing area.
The first signal video and the second signal video may be different in various ways. For example, one of the first signal video and the second signal video may be a bright video, and the other of the first video and the second video may be a dark video. In another example, the first signal image can be a first color and the second signal image can be a second color different from the first color.
By using a parallax optical device having a first portion and a second portion, alignment is automatically provided during manufacture of the parallax optical device. Further, the video display and the signal display may each include a first portion and a second portion of the common display. Thus, alignment of the first and second portions can be achieved during manufacture, and therefore no adjustments are required during assembly of the autostereoscopic display to achieve alignment.
The common display can be implemented in various ways. For example, the common display may include a light transmission type or transmission reflection type spatial light modulator such as a liquid crystal device, and a light source. The present invention can be used in transmissive or transflective liquid crystal display devices.
The video display and the first site can work together to form a viewing zone in multiple lobes with two viewing zones per lobe. By minimizing the number of viewing zones per lobe, improved 3D video resolution and, in some cases, improved brightness can be achieved.
The parallax optical device can be implemented in various ways. For example, the parallax optical device may include a lens array such as a lenticular screen. As an alternative, the parallax optical device may comprise an array of holographic optical elements. As a further alternative, the parallax optical device may comprise a parallax barrier. The first part of the parallax barrier may include a plurality of slits having a first width, and the second part of the parallax barrier may include a plurality of slits having a first width. As an alternative, the first part of the parallax barrier may comprise a plurality of slits of a first width and the second part of the parallax barrier comprises a plurality of slits of a second width less than the first width. Can be prepared.
Every other parallax element of the second part may be aligned with each parallax element of the first part in a second direction substantially perpendicular to the first direction.
The parallax optical device may be removable (eg, mechanically) for a non-autostereoscopic display mode. Such a configuration can be used to provide a full resolution 2D viewing mode. Alternatively, the parallax optical device may be electrically switchable to 2D mode, for example as disclosed in EP0 833 183. Such an electrically switchable parallax barrier may be configured to switch the viewer position indicator on or off, and thus more displays to display 3D video when the viewer position indicator is not required. Can be used.
When the parallax optical device is implemented as a parallax barrier, the parallax barrier may include a first layer and a removable second layer, the first layer allowing light having a first polarization to pass through. And an aperture region for supplying light having a second polarization that is at least substantially perpendicular to the first polarization, the second layer comprising light of the second polarization Is provided with a polarizer. The second layer functions as an output polarizer that absorbs the first polarized light and transmits the second polarized light when the display is in 3D mode. The first layer can be accurately positioned and secured relative to the rest of the autostereoscopic display. Switching between autostereoscopic and non-autostereoscopic modes can be achieved by removing and replacing the second layer, this switching being angular with respect to the rest of the display. The difficulty of aligning the movable element can be reduced or avoided since it only requires positioning and thus reduces the acceptance requirements.
The video display and the signal display can be configured to provide a first polarization of light, the barrier region can be configured to pass the first polarization of light, and the aperture region can be configured to pass the first polarization of light. Can be configured to at least partially convert the second light into second polarized light. The first layer can be a half-wave plate, the barrier region can have an optical axis parallel to the first polarization, and the aperture region aligned at 45 ° with respect to the first polarization. It may have an optical axis. By avoiding the use of devices such as polarization rotators in the barrier region, the suppression of light from the barrier region can be maximized over the visible spectrum. This makes it possible to minimize crosstalk between views.
The signal display may be configured to be active across the lateral extent of the 3D video displayed by the video display, or the lateral extent corresponding to each 3D video. Such a configuration allows the vertical viewing freedom of the display to be optimally shown.
The autostereoscopic display according to the present invention comprises an SLM that is controlled to provide a video display and a signal display. The parallax optical device has a first portion that forms a plurality of viewing windows in association with the video display. The second part of the parallax optical device forms a first image and a second image that can be seen by the observer, and the viewer has a desired orthoscopic viewing area and an undesired viewing position such as a pseudoscopic position. Makes it possible to distinguish between The pitch of the parallax elements in the second part is 1.5 times the pitch of the parallax elements in the first part. Thereby, it is possible to determine the position of the observer with respect to the autostereoscopic display regardless of whether an actual image is displayed.
FIG. 5 shows a VPI portion of an autostereoscopic display different from that shown in FIGS. Here, the pitch of the parallax elements 32 in the upper part 3a of the parallax optical device 3 is equal to 1.5 times the pitch of the parallax elements 6 that are part of the parallax optical device 3 that forms the viewing zone shown in FIG. This is in contrast to the pitch of element 32 in FIG. 4, which is twice the pitch of element 6 in FIG.
This is schematically illustrated in FIG. 6 for a parallax optical device in the form of a parallax barrier. The lateral positions of the barrier slit 32 and SLM2 pixels are illustrated (a) for the video display and generator of the display, (b) for the VPI shown in FIG. 4 and (c) for the VPI shown in FIG. The In (b) and (c), the red pixels that are linked to the slits in the VPI portion of the barrier and provide a normal indicator to the viewer are shaded. Thus, in FIG. 6 (c), every other pixel across the display is illuminated to provide a location indicator, and the color filter pattern is such that all of these pixels are red. Thus, when the viewer leaves the central orthoscopic viewing area 19, the display provides a red indicator that is visible to the viewer.
The display is intended to be viewed from the central orthoscopic viewing area 19 and the viewer typically views the display relative to the central area of the display. Adjacent to the central orthoscopic viewing region are two pseudoscopic regions 23 and 24. If the observer moves into these pseudoscopic areas, he sees the indicator from the VPI and knows he is in the wrong position to see the display.
When the user is in the correct orthoscopic viewing area, as in the display shown in FIGS. 3 and 4, the use of the orthoscopic areas 18 and 20 is abandoned to provide a clear indication to the user. Is done. In regions 18 and 20, the observer sees an indication from the VPI that informs the observer that he is in the wrong viewing area.
In the configuration shown in FIG. 5, if the observer is in the pseudoscopic regions 22 and 25, no indication is provided to this observer. Further, when the observer is in the orthoscopic viewing regions 17 and 21, an indicator visible to the observer is provided. However, for typical displays that are typically intended to be viewed from the central region of the display, the pseudoscopic viewing regions 22 and 25 are usually offset by approximately 30 ° from the normal to the center of the display. Therefore, it is clear to the observer that such a position is not the correct viewing position of the display. The VPI provides a reliable indication of correct orthoscopic viewing in the central orthoscopic region 19 and thus allows the viewer to avoid adjacent pseudoscopic viewing regions 23 and 24.
Compared to the known VPI configuration shown in FIGS. 4 and 6 (b), the configuration illustrated in FIGS. 5 and 6 (c) provides an index with a higher spatial frequency, and thus VPI The pattern of the element to be formed is not very visible. For displays that are switchable to 2D mode operation, the VPI pattern may have a certain residual visibility in 2D mode . In addition, more pixels are illuminated for a given size of VPI. This produces more light, so the VPI indicators in the pseudoscopic areas 23 and 24 are brighter and are therefore more effective in alerting viewers at incorrect positions.
FIG. 7 illustrates a particular configuration of a display where the SLM includes the LCD 2 and the parallax optic device includes the lenticular screen 3. The configuration of FIG. 8 is different from that of FIG. 7 in that the lenticular screen 3 is replaced with a parallax barrier constituting the parallax optical device. Although the parallax barrier 3 is illustrated on the output side of the LCD 2, it can alternatively be disposed between the LCD 2 and the backlight 1. In this case, the pitch of the parallax barrier 3 is slightly larger than twice the pitch of the pixel column in order to provide viewpoint correction.
Other forms of parallax optical device 3 are possible, such as hologram optical elements.
FIG. 9 illustrates the allowable range of observer movement. As described above, the display including the elements 1, 2, and 3 is of a type in which the viewpoint in which the left and right viewing zones 35 and 36 are formed is modified. The display is configured to form a viewing zone such that the widest lateral extent that forms the viewing window has a pitch that is substantially equal to the observer's average interocular separation. Is done. If the viewer's left and right eyes stay within the respective viewing zones 35 and 36, the viewer sees the desired 3D image. If the observer moves in the horizontal direction or the vertical direction so that at least one eye moves outward from the viewing area, the observer will see an undesired image. For example, as described above, when the observer moves in the horizontal direction on the plane including the viewing window, pseudoscopic viewing in which left and right images are seen by the left and right eyes of the observer is brought about.
The lower part of FIG. 9 illustrates the formation of a zone 37 in which the viewpoint of the viewer position index configuration is modified. The observer's eyes must be in zone 37 in order to see the orthoscopic image. The configuration of the pixels of the SLM 2 and the elements 6 and 32 of the parallax optic device 3 is such that the zone 37 is aligned laterally and longitudinally with adjacent pairs of orthoscopic viewing zones 35 and 36. . If the observer stays in the dark zone 37 and the light from the viewer position indicator configuration is not visible to either eye, the observer is located in the central orthoscopic viewing zone intended for use. If the observer moves outside the dark zone 37 as a result of moving laterally or vertically relative to the displays 1, 2 and 3, or both laterally and longitudinally, the light is visible to the observer.
For example, the near point 38 and the far point 39 are shown in FIG. 9 and represent the observer's closest and farthest orthoscopic viewing position. By moving toward or away from the display, the viewer moves outside of the zone 37 and the viewer sees light from the viewer position indicator configuration. As shown at the top of FIG. 9, such a movement causes the viewer to go outside the intended orthoscopic viewing zone. Thus, the viewer position indicator configuration provides a clear indication for any moved observer outside the intended central orthoscopic viewing zone. As the observer moves further away from the intended orthoscopic viewing area, more light is seen across the area of the viewer position indicator configuration. This therefore helps the viewer to be in the correct position for orthoscopic viewing of 3D video.
By using different parts of the SLM 2 and the parallax optical device 3 to provide a viewer position indicator configuration, such a configuration does not increase the bulk of the autostereoscopic display and involves a small additional cost. Or may be provided at no additional cost. Because the viewer position indicator configuration is aligned with the rest of the display, an alignment process during manufacturing is not required. This is because the alignment is guaranteed to be within an allowable error in each of the SLM 2 and the parallax optical device 3. Similarly, misalignment cannot occur while using an autostereoscopic display. Furthermore, substantially the same viewing performance is provided for the display portion and the viewer position indicator component. Accordingly, aberrations, defocusing, scattering, and other effects that degrade viewing window quality also affect the performance of the viewer position indicator configuration. Position indicators are provided in the area of the display and are therefore easily visible to the viewer.
The viewer location indicator configuration requires no additional power or connection. Furthermore, this configuration can be easily incorporated into a small handheld device or laptop type display.
FIG. 10 illustrates different possible positions for the strip-shaped viewer position indicator configuration 42. This configuration may include a horizontal strip located at the top of the display as described above and as illustrated in the upper left of FIG. The upper right portion of FIG. 10 illustrates an alternative location at the bottom of the display. The lower left part of FIG. 10 illustrates vertical strips on opposite sides of the display. The lower right portion of FIG. 10 illustrates a combination of upper and lower horizontal strips and vertical strips on opposite sides. A preferred configuration for maximizing recognition that there is an indication that the observer is in an incorrect viewing position is a horizontal strip as illustrated in the upper left and upper right portions of FIG. As will be described later, when the viewer is not in the plane of the viewing window, the strip 42 illuminates different points along its width.
FIG. 11 illustrates a laptop computer 60 having a display in the form of an autostereoscopic display as described above. The display includes a parallax optical device 3 in the form of a parallax barrier of the type shown in FIG. The upper part of FIG. 11 illustrates the use of the display in autostereoscopic 3D mode. The parallax barrier is placed on the attachment 61 and properly positioned with the SLM pixels in the display. For example, the barrier can be fabricated on a glass or acrylic substrate whose coefficient of thermal expansion is sufficiently close to that of the LCD glass forming the SLM. The barrier opening can be made from an exposed or developed photographic emulsion. Such exposure can be produced with a tolerance of 0.1 μm using a flatbed laser scanning device.
The lower part of FIG. 11 illustrates a 2D mode in which the parallax barrier 3 is removed from the attachment 61 and stored, for example, in a suitable receptacle or pouch on the back of the display. This allows the full spatial resolution of the SLM to be used in 2D mode.
Other configurations are possible to allow the parallax barrier to be removed or disabled in the full resolution 2D mode. For example, the barrier can be hinged to the top of the display, or can be located on a roll-up blind that can be pulled down to the front of the SLM 2 as needed. Alternatively, an array of half-wave plate 90 degree polarization rotators (which may be half-wave plates) is attached to, for example, a layer that can be attached to the output polarizer of the SLM2, or near the output polarizer, and It can be provided by patterning into aligned separator sheets. In 2D mode this cannot be seen. However, by placing additional polarizers in front of the display, areas with a 90 degree rotator will transmit light, whereas areas without such a rotator will extinguish light and parallax. Form a barrier. Since the further polarizer does not need to be patterned, alignment with the display is less important. Such a polarizing layer can be made more robust than a removable parallax barrier and is not affected by thermal expansion differences. The alignment tolerance is significantly reduced compared to the alignment of the barrier itself.
This type of configuration is shown in FIG. 12a. The parallax optical device 3 includes a substrate having a portion 64 that does not affect polarization and a strip-shaped portion 65 that functions as a half-wave plate. In the 3D mode, the linearly polarizing sheet 66 is disposed so as to cover the substrate. The polarized light from the SLM 2 passes through the region 64 unchanged, while the light passing through the half-wave plate 65 has a polarization vector that is rotated 90 degrees. The polarization direction of the polarizing sheet 66 is orthogonal to the direction of polarization of incoming light so that light passing through the region 64 is extinguished and light passing through the half-wave plate 65 is transmitted. If the display is required to operate in full resolution 2D mode, the polarizing sheet 66 is removed and all light from the SLM 2 is transmitted.
A 90 degree rotator such as a half wave plate tends to be optimized for a specific wavelength. Thus, in 3D mode, light transmitted through the slit can be slightly colored. Single layer retarder elements may be suitable for this application, but the use of a multilayer retarder structure can improve the color performance. Any light transmitted through the area between the slits causes unwanted video crosstalk. However, since no polarization modulation is used in the area between the slits, most of the light is absorbed by the polarizing sheet 66 which may have good broadband absorption characteristics. Accordingly, display crosstalk can be minimized.
FIG. 12b illustrates a similar type of configuration as shown in FIG. 12a. However, parts 64 and 65 all comprise half-wave plates, but their optical axes are aligned differently. The input polarizer 63 is indicated by an axis that is polarized by 45 ° with respect to the reference direction (horizontal). The input polarizer 63 is typically constituted by the output polarizer of the SLM 2 when implemented as an LCD. The optical axis of portion 64 is aligned at 45 ° and is therefore parallel to the polarization vector of the light from the input polarizer. Accordingly, the portion 64 has substantially no influence on the polarization, so that light passing through the portion 64 is absorbed by the output polarizer 66. The polarization axis of this output polarizer 66 is aligned at 135 °.
The optical axis of part 65 is aligned at 90 °, so the polarization vector of light passing through part 65 is changed to 135 ° and transmitted by the output polarizer. Thus, a parallax barrier is used to provide 3D viewing with an appropriately positioned output polarizer. By removing the output polarizer from the output path, a full resolution 2D mode is provided.
Every other portion 65 extends downward, as indicated by 65 ', to form a 3D mode barrier 3a to provide a viewer position indicator. However, if the output polarizer is removed, the entire SLM can be used to display 2D video.
FIG. 13 illustrates another configuration of switching between 3D mode and 2D mode. SLM 2 includes an LCD comprising an input polarizer 67 having a polarization direction illustrated by a double-headed arrow 68, a liquid crystal pixel layer 69, and an output polarizer 70 having a polarization direction illustrated by a double-headed arrow 71. The wave plate substrate 72 includes a transparent substrate that is disposed adjacent to the output polarizer 70 and supports the strip-shaped half-wave plate 73. The substrate 72 forms part of the parallax optical device 3, and the parallax optical device 3 includes a wide-area switchable polarization modulator 74 and an output polarizer 75 having a polarization direction indicated by a double-headed arrow 76.
In the 3D mode illustrated in FIG. 13, the output light from the SLM 2 is polarized in the direction indicated by the double-headed arrow 77. The light passing through the wave plate 73 has a polarization direction rotated by 90 ° so as to be directed in the direction indicated by the double-headed arrow 78. Light passing through the substrate 72 between the wave plates 73 is not affected. The polarization modulator 74, which may comprise, for example, a twisted nematic cell or a pi-cell, is controlled so that the polarization is not affected, so that the output polarizer 75 passes light having polarization 78, but extinguishes light having polarization 77. Is done. Therefore, the parallax optical device 3 functions as a parallax barrier.
FIG. 14 illustrates the operation in full resolution 2D mode. In this mode, the active layer 79 of the polarization modulator 74 is controlled to rotate the polarization of incoming light by 45 °. The active layer 79 can accomplish this by rotating the polarization by 45 ° or by imparting a quarter-wave phase shift. Therefore, light from all parts of the substrate 72 including the wave plate 73 is incident on the output polarizer 75 in the polarization direction of 45 ° on the polarization axis 76 of the polarizer 75 or circularly polarized light. Accordingly, the output polarizer 75 transmits light from all regions of the substrate 72 with substantially the same and relatively low attenuation, and the parallax optic is substantially extinguished.
In the configuration described above, some of the SLM2 pixel rows are used to provide location indicators. This results in some loss of resolution and 3D video size. However, this can be recovered in particular by providing additional pixels for the position indicator, for example, only switching between a certain color and black may be possible. Alternatively, time multiplexing between the 3D image and the position indicator may be possible. There are few processing electronics requirements associated with such pixels, and therefore the cost of the driver need not be substantially affected. Since the data regarding such pixels is fixed for each operation mode, a device such as a thin film transistor is not required to control these pixels.
FIG. 15 illustrates the effect of using SLM2, where the pixels are organized in columns, which are separated laterally by successive vertical strips of the SLM's black mask. The top of FIG. 15 illustrates that the viewing window 16 is no longer laterally continuous but is separated by a vertical strip such as 83 on which the vertical black mask strip is projected. Therefore, the allowable viewing zones 35a and 36a are more spatially limited than the viewing zones 35 and 36 shown in FIG. However, as shown at the bottom of FIG. 15, the same effect exists in the viewer position indicator configuration, and therefore there is a reduced viewpoint correction zone 37a with near point 38a and far point 39a closer to the plane of the viewing window. Generated. Since the reduced zone 37a corresponds to the reduced zones 35a and 36a, the correct viewer position indication is given to this embodiment.
All of the pixels in the viewer position indicator configuration can be used to generate an illumination window for providing a viewer position indicator. Thus, a relatively bright indicator can be provided.
As described above, FIG. 9 illustrates the viewing freedom in the vertical direction when the displays 1, 2, and 3 display full-width 3D video. However, the vertical extension of the viewing zone is enlarged when the horizontal size of the 3D video is smaller than the width of the displays 1, 2, and 3. This is illustrated in FIG. In FIG. 16, the 3D image is laterally limited as indicated at 115, and viewing zones 35 'and 36' are substantially longer. In this case, the new near point 38 'is closer to the displays 1, 2, 3 than the near point 38 shown in FIG. Similarly, the new far point 39 'is farther from the displays 1, 2, 3 than the far point 39 shown in FIG.
In order to provide a correct indication to a viewer with increased vertical movement freedom, the portion of the display that provides the viewer position indication is all laterally outward of the lateral extent 115 of the 3D image. It can be blackened in the area. Thus, as shown in FIG. 16, for example, only the pixel portion 116 that provides the viewer position indicator is used. Thereby, as shown in FIG. 16, the viewpoint correction zone 37 'coincides with the viewing zones 35' and 36 '. Accordingly, the zone 37 'has the same viewing freedom in the vertical direction as the displayed video.
The 3D video when one or more are displayed, or all lateral extents 115 of the 3D video, can be determined by the controller for controlling the video display and can be supplied to the visual position index width calculation routine Accordingly, the lateral portion 116 of the activity index coincides with the entire lateral extent of the displayed 3D image. As shown in FIG. 17, the displays 1, 2, 3 may have several regions 117 where 3D video is displayed. To provide a correct indication of viewing freedom, the entire width of the active portion of the display that provides the viewer position indication is as indicated at 118. The active portion continuously extends from the lateral position of the leftmost boundary of the 3D image to the rightmost boundary. Thus, the optimal viewing freedom of the display can be achieved for all images.
The present invention has been described above with respect to a display incorporating a transmissive spatial light modulator. The invention can also be applied to displays that incorporate transflective spatial light modulators.
FIG. 1 is a schematic cross-sectional view relating to a horizontal cross section of a known autostereoscopic 3D display. FIG. 2 is a schematic cross-sectional view relating to a horizontal cross-section of a known observer position indicator. FIG. 3 is a schematic cross-sectional view of horizontal sections at different heights of another known autostereoscopic 3D display. FIG. 4 is a schematic cross-sectional view of a horizontal section at different heights of another known autostereoscopic 3D display. FIG. 5 is a cross-sectional view relating to a horizontal cross section of a part of an autostereoscopic 3D display constituting the embodiment of the present invention. FIG. 6 is a diagram illustrating the relationship between the parallax elements / pixels of FIGS. 3, 4, and 5. FIG. 7 is a schematic cross-sectional view illustrating a lenticular screen display. FIG. 8 is a schematic cross-sectional view illustrating a front parallax barrier display. FIG. 9 is a plan view illustrating the formation of the viewing zone. FIG. 10 illustrates possible sensor positions for an autostereoscopic 3D display of the type shown in FIGS. 3 and 4. FIG. 11 illustrates a laptop computer with a display of the type shown in FIGS. 3 and 5 having a removable parallax barrier. FIG. 12a illustrates a first configuration for switching between 3D mode and 2D mode. FIG. 12b illustrates a second configuration for switching between 3D mode and 2D mode. FIG. 13 is a schematic cross-sectional view of a third configuration operating in 3D mode and 2D mode. FIG. 14 is a cross-sectional view of a third configuration that operates in 3D mode and 2D mode. FIG. 15 is a view similar to FIG. 9 illustrating the effect of pixel columns separated laterally by a continuous strip of black mask. FIG. 16 is similar to FIG. 9, but illustrates that the degree of freedom of viewing in the vertical direction is increased due to the reduced horizontal spread of the displayed 3D image. FIG. 17 illustrates the appearance of the display when operating as illustrated in FIG.
An image display capable of displaying images in 2D mode and 3D mode and having the same color filter pattern for every second pixel in the horizontal direction and the same color filter pattern for every two pixels in the horizontal direction An autostereoscopic display comprising a signal display and a parallax optical device,
In the 3D mode, each column of a pair of vertically connected pixels adjacent to each other in the 3D mode displays a left eye image element and a right eye image element, respectively.
In the 3D mode, the parallax optical device is coupled with the video display by viewing an array of parallax elements having a first horizontal pitch corresponding to a horizontal pitch of each column of the vertical pixels. A first portion that forms a plurality of right viewing areas and left viewing areas in the area; a first signal image that is viewed in an orthoscopic viewing area of the viewing area in association with the signal display; A second portion forming a second signal image visible in a pseudoscopic viewing area adjacent to the copic viewing area;
The second portion is equal to the pitch of the pixels of the color filter pattern of the same color in every other horizontal direction of the signal display, and substantially equal to 1.5 times the first pitch in the horizontal direction. An array of parallax elements having a second pitch equal to each other,
An autostereoscopic display characterized in that brightness of a predetermined color is different between the first signal image seen in the orthoscopic viewing area and the second signal image seen in the pseudoscopic viewing area .
The autostereoscopic display according to claim 1, wherein the video display and the signal display include a first portion and a second portion of a common display, respectively.
The autostereoscopic display according to claim 2, wherein the common display includes a light source and one of a light transmission type and a transmission reflection type spatial light modulator.
The autostereoscopic display according to claim 3, wherein the transflective spatial light modulator includes a liquid crystal device.
2. The autostereoscopic according to claim 1, wherein the video display and the first part are linked to form the viewing area by a plurality of lobes having the right viewing area and the left viewing area for each lobe. display.
The autostereoscopic display according to claim 1, wherein the parallax optical device includes a lens array.
The autostereoscopic display according to claim 6, wherein the lens array includes a lenticular screen.
The autostereoscopic display according to claim 1, wherein the parallax optical device includes an array of hologram optical elements.
The autostereoscopic display according to claim 1, wherein the parallax optical device includes a parallax barrier.
The first part of the parallax barrier includes a plurality of slits having a first width, and the second part of the parallax barrier includes a plurality of slits having a second width smaller than the first width. The autostereoscopic display according to claim 9.
The parallax barrier includes a plurality of parallax elements, and every other element of the parallax elements in the second part is aligned with each element of the parallax elements in the first part in a vertical direction. The autostereoscopic display according to claim 9.
The autostereoscopic display according to claim 1, wherein the parallax optical device is removable in a non-autostereoscopic display mode.
The parallax barrier includes a first layer and a removable second layer, the first layer including a barrier region for supplying light having a first polarization, and at least the first layer An aperture region for providing light having a second polarization substantially orthogonal to the polarization, the second layer comprising a polarizer for passing light of the second polarization; The autostereoscopic display according to claim 9.
The video display and the signal display are configured to supply the first polarized light, the barrier region is configured to pass the first polarized light, and the opening region is 14. The autostereoscopic display of claim 13, configured to convert the first polarized light at least in part to the second polarized light.
The first layer is a half-wave plate, the barrier region has an optical axis parallel to the first polarization, and the aperture region is aligned at 45 ° with respect to the first polarization. The autostereoscopic display according to claim 14, having an optical axis.
The autostereoscopic of claim 1, wherein the signal display is configured to be active across a lateral extent corresponding to the lateral extent of each 3D video displayed by the video display. display.
JP2003322296A 2002-09-17 2003-09-12 Autostereoscopic display Active JP4159045B2 (en)
GB0221583A GB2393344A (en) 2002-09-17 2002-09-17 Autostereoscopic display
JP2004110032A JP2004110032A (en) 2004-04-08
JP4159045B2 true JP4159045B2 (en) 2008-10-01
ID=9944254
JP2003322296A Active JP4159045B2 (en) 2002-09-17 2003-09-12 Autostereoscopic display
US (1) US6929369B2 (en)
EP (1) EP1401216B1 (en)
JP (1) JP4159045B2 (en)
CN (1) CN1323314C (en)
GB (1) GB2393344A (en)
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2002-09-17 GB GB0221583A patent/GB2393344A/en not_active Withdrawn
2003-09-12 EP EP03103379A patent/EP1401216B1/en not_active Expired - Fee Related
2003-09-12 JP JP2003322296A patent/JP4159045B2/en active Active
2003-09-15 US US10/662,262 patent/US6929369B2/en active Active
2003-09-17 CN CNB031589987A patent/CN1323314C/en active IP Right Grant
EP1401216A3 (en) 2006-02-08
US20040057016A1 (en) 2004-03-25
EP1401216A2 (en) 2004-03-24
US6929369B2 (en) 2005-08-16
EP1401216B1 (en) 2012-12-05
GB2393344A (en) 2004-03-24
CN1487332A (en) 2004-04-07
JP2004110032A (en) 2004-04-08
CN1323314C (en) 2007-06-27
GB0221583D0 (en) 2002-10-23
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