JP2004104371A - Stereoscopic image display apparatus, and polarizing glasses apparatus for stereoscopic image display apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stereoscopic image display apparatus adopting polarizing eyeglasses wherein a stereoscopic image with high quality can always be viewed by making the positional relation of the polarizing eyeglasses with respect to an image display screen nearly constant in the case of viewing the stereoscopic image on the stereoscopic image display apparatus. <P>SOLUTION: A polarizing eyeglasses apparatus for the stereoscopic image display apparatus serves for fitting the polarized eyeglasses to the stereoscopic image display apparatus 5 provided with an image display section 6 including an image display means for displaying image information corresponding to parallax and a polarization control means for dividing the image information to control a polarization direction. The polarizing eyeglasses apparatus is provided with a fitting means 3 removably fitted to the image display section at one end of a support arm, the polarizing eyeglasses 4 being supported at the other end of the support arm. The position of the polarizing eyeglasses is kept nearly at a position apart from the image display section by the length of the support arm. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a novel stereoscopic image display device and a polarizing glasses device for the stereoscopic image display device. More specifically, the present invention relates to a technique for making the positional relationship of polarized glasses with respect to an image display surface substantially constant when viewing a stereoscopic image with a polarized glasses-type stereoscopic image display device.
[0002]
[Prior art]
There is a technology for displaying a stereoscopic image by inputting an image with binocular parallax to the left and right eyes of an observer, and is used in many fields such as photographs, television, and movies. Are divided into two types: glasses using polarized glasses and glassesless without glasses.
[0003]
[Problems to be solved by the invention]
In the glasses-type stereoscopic image display technology, when the distance between the image display surface and the observer's eye is relatively short, for example, an image display for personal use such as a portable personal computer or a portable DVD player In the device, when the distance between the image display surface and the observer's eye is out of a certain range, image deterioration such as loss of stereoscopic effect, blurring of color, blurring of image, etc. occurs. There's a problem.
[0004]
FIG. 24 shows an outline of a polarized glasses type stereoscopic image display device.
[0005]
The stereoscopic image display device a is disposed on a front surface of the liquid crystal panel section b as a liquid crystal panel section b as image display means and polarization control means for dividing image information displayed on the liquid crystal panel section b and controlling a polarization direction. And a split wavelength plate filter section c. In the liquid crystal panel section b, a pair of transparent support bases f and g are arranged between a pair of polarizers d and e, and pixels R, G, and B are formed between the pair of transparent support bases f and g. Pixel liquid crystal section h is provided. Then, a split wavelength plate filter section c is disposed on the front side of the liquid crystal panel section b. The split wavelength plate filter section c has a structure in which split wavelength plates j, j,... Are arranged on one surface of the transparent protective substrate i, for example, every other line.
[0006]
In the stereoscopic image display device a described above, the liquid crystal panel unit b displays image information corresponding to parallax. For example, a right-eye image and a left-eye image are alternately displayed for each line. .. Of the divided wavelength plate filter section c are provided corresponding to the lines for displaying the image for the right eye, and rotate the linearly polarized light emitted from the liquid crystal panel section b. Accordingly, in the image for the left eye, the linearly polarized light emitted from the liquid crystal panel part b is directly emitted from the divided wave plate filter part c, and the image for the right eye is the image for the left eye by the action of the divided wave plates j, j,. Linearly polarized light orthogonal to the linearly polarized light.
[0007]
Then, when observing the image displayed by the stereoscopic image display device a, the observer observes through the polarizing glasses k. The portion corresponding to the left eye of the polarizing glasses k transmits only linearly polarized light from the liquid crystal panel portion b, and the portion corresponding to the right eye transmits only linearly polarized light orthogonal to the linearly polarized light from the liquid crystal panel portion b. It is configured. Therefore, the light of the image for the left eye is incident on the left eye of the observer through the polarized glasses k, and the light of the image for the right eye is incident on the right eye through the polarized glasses. The observer can see a stereoscopic image.
[0008]
An outline of the principle of the above-described stereoscopic image observation will be described with reference to FIG.
[0009]
In FIG. 25, with respect to the liquid crystal panel section b, the image for each line is deformed and shown, and the lines lR, lR,... Of the right-eye image and the lines lL, lL,. Are alternately formed for each line, and other elements of the liquid crystal panel portion b are not shown. Regarding the split wavelength plate filter section c, a portion where the split wavelength plates j, j,... And a portion where the split wavelength plates j, j,. It is shown alternately within the same plate thickness, and other elements of the split wavelength plate filter section c are not shown. The polarizing glasses k are not shown.
[0010]
In FIG. 25, mR indicates the observer's eye at an appropriate observation position, and mI indicates the observer's eye at an inappropriate observation position.
[0011]
As shown by the solid arrow in FIG. 25, the line of the image for the right eye passes through the split polarizers j, j,... Of the split polarizer filter unit c from the observer's eye mR at an appropriate position. , and only the lines lL1, lL2,... of the image for the left eye pass through the portion of the divided polarizing plate filter portion c where the divided polarizing plates j, j,.・ ・ Only can be seen. Therefore, a normal stereoscopic image can be observed from an appropriate observation position.
[0012]
However, from the eye mI located at one of the positions separated from the appropriate observation position, as shown by the dashed arrow, the line lR1 of the image for the right eye passes through the divided wave plates j, j,. At the same time, the line lL1 of the image for the left eye can be seen, or the line lL1 of the image for the left eye and the line lR2 of the image for the right eye can be seen through a portion where the divided wave plates j, j,. Or That is, two types of images having different parallaxes are simultaneously incident on each eye, and as a result, not only the stereoscopic effect of the image is lost, but also the color is blurred and the image becomes unclear. .
[0013]
In the portable stereoscopic image display device as described above, since the distance between the optimal observation position and the image display surface is short, a small displacement of the observation position causes a large difference in the quality of an observable image. Problem.
[0014]
Since conventional polarized glasses are worn directly by the observer, the distance between the observation position and the image display surface tends to fluctuate. This involved the trouble of requiring time and effort for position adjustment.
[0015]
In addition, when the stereoscopic image is not observed, since the polarizing glasses are removed, there is a fear of loss or damage.
[0016]
Accordingly, an object of the present invention is to make it possible to always observe a high-quality stereoscopic image while keeping the positional relationship of the polarizing glasses with respect to the image display surface almost constant when viewing a stereoscopic image with a stereoscopic image display device of the polarizing glasses type. And
[0017]
[Means for Solving the Problems]
In order to solve the above-described problems, the polarizing glasses device for a stereoscopic image display device of the present invention includes an attachment unit detachably attached to an image display unit of the stereoscopic image display device at one end of the support arm, Polarized glasses are supported at the other end.
[0018]
Therefore, in the polarizing glasses apparatus for a three-dimensional image display device of the present invention, the polarizing glasses are supported by the support arm attached to the image display unit, so that the positional relationship of the polarizing glasses with respect to the image display unit does not greatly change. .
[0019]
Further, in order to solve the above-described problem, the stereoscopic image display device of the present invention has an image display device that displays image information corresponding to parallax and an image that has a polarization control unit that divides the image information and controls a polarization direction. A display arm is provided with a support arm provided so as to be housed and protrudable, and polarized glasses supported at the tip of the support arm at a predetermined distance from the image display section in a state where the support arm is projected from the image display section. And face each other.
[0020]
Therefore, in the stereoscopic image display device of the present invention, since the polarized glasses are opposed to the image display unit via the support arm provided on the image display unit, the positional relationship of the polarized glasses with respect to the image display unit is greatly deviated. There is no.
[0021]
Further, the support arm may always be present together with the stereoscopic image display device.
[0022]
When the stereoscopic image is not observed, the polarizing glasses can be flipped up or stored and used, so that there is no problem.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the details of the stereoscopic image display device and the polarizing glasses device for the stereoscopic image display device of the present invention will be described with reference to the accompanying drawings.
[0024]
An outline of the present invention will be described with reference to FIGS.
[0025]
FIG. 1 shows an outline of a polarized glasses device for a stereoscopic image display device of the present invention.
[0026]
The polarized glasses device 1 for a stereoscopic image display device (hereinafter, referred to as a “polarized glasses device”) includes a support arm 2, a mounting unit 3, and polarized glasses 4. Attachment means 3 is provided at one end of the support arm 2, and polarized glasses 4 are provided at the other end of the support arm 2. The polarizing glasses device 1 is attached to the image display unit 6 of the stereoscopic image display device 5 by the attaching means 2.
[0027]
The three-dimensional image display device 5 displays a three-dimensional image by a glasses-type three-dimensional image display technique, and the image display unit 6 has the same configuration as the three-dimensional image display device a shown in FIG. And the description is omitted. That is, similar to the liquid crystal panel unit b in FIG. 24, the image information is divided and the polarization direction is divided by an image display unit (not shown) that displays image information corresponding to parallax and the split wavelength plate filter unit c in FIG. (Not shown). In the present invention, the image display means is not limited to the liquid crystal display panel unit, and does not matter the display method as long as it can display image information corresponding to parallax.
[0028]
Regarding the use of the stereoscopic image display device 5, for example, a portable personal computer (hereinafter, referred to as a “notebook personal computer”), a portable DVD (Digital Versatile Disk) player, or the like is provided with a display unit and used. Although it is assumed that electronic devices are intended to be used, it can also be applied to liquid crystal televisions that can be easily moved indoors and desktop personal computers equipped with liquid crystal displays. Of course, these devices are also included in the stereoscopic image display device of the present invention.
[0029]
The attachment means 3 may be any means that can be easily attached to and detached from the image display unit 6. For example, a clip-type one, that is, one in which two holding pieces rotatably connected to each other are urged by a spring so that the tips of the two pieces are pressed against each other, is attached to and detached from the image display unit 6. Although simple and preferable, it is needless to say that the present invention is not limited to the clip type, and other types may be used as long as they can be easily attached to and detached from the image display unit 6.
[0030]
The support arm 2 may be any as long as it can provide a predetermined space between the image display unit 6, more specifically, the image display unit or the polarization control unit and the polarizing glasses 4. In other words, even if it is stretchable or foldable, it may be any as long as it has a predetermined length in a state where it is extended to its maximum length or in a straightened state.
[0031]
The connecting portion 7 between the support arm 2 and the mounting means 3 may be such that the angle between the support arm 2 and the mounting means 3 can be changed, or the angle cannot be changed. However, the ability to change the angle between the support arm 2 and the mounting means 3 is more convenient for adjusting the position of the polarizing glasses 4. When the angle can be changed, the angle between the support arm 2 and the mounting means 3 is adjusted, and then the fastening screw is tightened to prevent the angle from being easily changed, or As shown in the hinge mechanism between the image display unit and the main unit of the notebook personal computer, a shaft provided on one of the support arm 2 and the mounting means 3 is wound around a leaf spring provided on the other and has an arbitrary angle. It is preferable that the set angle is not easily changed by providing a spring bearing mechanism for stabilizing the position.
[0032]
The polarizing glasses 4 are supported by the other end of the support arm 2, but may be supported in a detachable manner or in a non-removable manner. Further, the angle of the polarizing glasses 4 with respect to the support arm 2 may be adjustable or may not be adjustable. When the polarizing glasses 4 are detachably supported on the other end of the support arm 2, for example, a clip may be provided at the other end of the support arm 2, and the polarizing glasses 4 may be sandwiched between the clips. In this case, if the clip is provided so as to be adjustable in angle with respect to the support arm 2, the angle of the polarizing glasses 4 with respect to the support arm 2 can be adjusted.
[0033]
By attaching the attaching means 3 of the polarizing glasses apparatus 1 to the image display unit 6 of the stereoscopic image display device 5 (see the two-dot chain line in FIG. 1), the image display surface of the image display unit 6 (of the image display means) The polarizing glasses 4 can be positioned at a predetermined position with respect to the surface or the surface of the polarization control means.
[0034]
FIG. 2 shows the outline of the stereoscopic image display device of the present invention.
[0035]
The three-dimensional image display device 8 according to the present invention displays a three-dimensional image by the glasses-type three-dimensional image display technology, and the image display unit 9 has the same configuration as the three-dimensional image display device a shown in FIG. Detailed illustration and description are omitted. That is, similar to the liquid crystal panel unit b in FIG. 24, the image information is divided and the polarization direction is divided by an image display unit (not shown) that displays image information corresponding to parallax and the split wavelength plate filter unit c in FIG. (Not shown). In the present invention, the image display means is not limited to the liquid crystal display panel unit, and does not matter the display method as long as it can display image information corresponding to parallax.
[0036]
The use of the stereoscopic image display device 8 includes, for example, a portable personal computer (hereinafter, referred to as a “notebook personal computer”), a portable DVD (Digital Versatile Disk) playback device, or the like, and a portable unit. Although it is assumed that electronic devices are intended to be used, it can also be applied to liquid crystal televisions that can be easily moved indoors and desktop personal computers equipped with liquid crystal displays. Of course, these devices are also included in the stereoscopic image display device of the present invention.
[0037]
The stereoscopic image display device 8 includes a support arm 10 and polarized glasses 11.
[0038]
The support arm 10 is provided on the image display unit 9 so as to be freely stored and projected. That is, the configuration is such that it can take two states: a state protruding from the image display unit 9 as shown by a solid line in FIG. 2 and a state stored in the image display unit 9 as shown by a two-dot chain line in FIG. Have been. As the shape of the support arm 10, various shapes such as a rod shape, a plate shape, and a pantograph shape can be applied. Further, the shape may be fixed or deformable. For example, a so-called rod antenna, in which two or more rods are telescopically combined, a two or more foldable arm piece, or the like whose shape changes between a used state and a stored state, or use It does not matter if the shape does not change between the state and the housed state. However, since the storage space 12a that can be secured in the image display unit 9 is limited, a deformable one is preferable.
[0039]
The polarizing glasses 11 may be removable or non-removable with respect to the support arm 10, but are preferably removable in order to secure the storage space 12b during storage. In other words, it is easier to separate the support arm 10 and the polarizing glasses 11 and secure a separate storage space for each, than to secure a space for storing a large object in which the supporting arm 10 and the polarizing glasses 11 are integrated. It is.
[0040]
The polarizing glasses 11 may or may not be angle-adjustable with respect to the support arm 10, but it is preferable to be able to adjust the angle in order to find an angle at which an image can be easily viewed.
[0041]
In the three-dimensional image display device 8 described above, the polarized glasses 11 are projected from the image display unit 9 (see the solid line in FIG. 2) so that the support arms 10 protrude from the image display unit 9. Surface or the surface of the polarization control means). When the stereoscopic image is not viewed, the support arm 10 and the polarizing glasses 11 are stored in the image display unit 9 as shown by the two-dot chain line in FIG. Can be prevented.
[0042]
Next, an embodiment of the polarized glasses device for a stereoscopic image display device of the present invention will be described with reference to the accompanying drawings.
[0043]
3 and 4 show a first embodiment of the polarized glasses device for a stereoscopic image display device of the present invention.
[0044]
The polarizing glasses device 20 includes a support arm 21, mounting means 22, and polarizing glasses 23.
[0045]
The support arm 21 has a thin rod shape and is made of metal or synthetic resin. Attachment means 22 is provided at one end of the support arm 21, and polarized glasses 23 are detachably supported at the other end of the support arm 21.
[0046]
The attachment means 22 is of a clip type, and two holding members 22a, 22a are rotatably connected at a central portion like a normal clothespin, and sandwich the rotation fulcrum of the holding members 22a, 22a. Thus, one part is formed as holding pieces 22b, 22b, and the other part is formed as knob pieces 22c, 22c. The holding pieces 22b and 22b are urged by a torsion coil spring (not shown) so that the tips of the holding pieces 22b and 22b are pressed against each other.
[0047]
The support arm 21 and the mounting means 22 are connected by a ball joint 24. The ball joint 24 includes a sphere 24a formed on one holding member 22a of the mounting means 22, a sphere 24b formed at one end of the support arm 21, and a ball receiver 24c rotatably receiving the two spheres 24a and 24b. Consisting of The spherical body 24a is formed integrally with a tip of a fulcrum shaft 24d protruding from a knob piece 22c of one of the holding members 22a of the mounting means 22.
[0048]
The ball receiver 24c has a substantially cylindrical shape with a short length in the axial direction, and has spherical concave portions 24e and 24f for receiving the two spheres 24a and 24b. The spherical recess 24e opens at one end of the ball receiver 24c, and the spherical recess 24f opens at the other end of the ball receiver 24c. A slit 24g is formed in the other end of the ball receiver 24c along the axial direction, and the slit 24g extends to the spherical recess 24f.
[0049]
The sphere 24a provided on the mounting means 22 is rotatably fitted in the spherical recess 24e within a certain range, and the sphere 24b provided at one end of the support arm 21 is fixed in the spherical recess 24f within a certain range. To be rotatably fitted. Thus, the support arm 21 and the mounting means 22 are connected via the ball joint 24. Note that the ball receiver 24c is formed of a material such that a fixed frictional force acts between the ball receivers 24a and 24b while rotatably supporting the balls 24a and 24b. For example, if it is formed of plastics having slipperiness and elasticity, such as nylon resin, and the inner diameter of the spherical recesses 24e, 24f is set to a size that can receive the spheres 24a, 24b tightly, the mounting is performed by applying a little force. The angle between the means 22, the ball joint 24 and the support arm 21 can be changed, but if the force is removed, the angle cannot be easily changed by the weight of the polarizing glasses 23. it can. Note that this does not mean that the material of the ball receiver 24c is limited to nylon resin.
[0050]
At the other end of the support arm 21, a pair of glasses support members 25 is provided, on which the polarizing glasses 23 are detachably supported.
[0051]
The glasses support member 25 has two holding pieces 25a, 25a connected at one end. The surface spacing between the two holding pieces 25a is equal to or slightly smaller than the thickness of the polarizing glasses 23. In particular, the distance between the tips of the holding pieces 25a, 25a is formed smaller than the thickness of the polarizing glasses 23. The glasses support member 25 is formed of a material having elasticity, and is preferably formed of a transparent material or an inconspicuous color. For example, it is preferably formed of transparent plastics such as a polycarbonate resin or an acrylic resin, or a black or gray coating.
[0052]
The glasses support member 25 is supported at the other end of the support arm 21 via a ball joint 26. The ball joint 26 has the same configuration as the ball joint 24 described above. That is, a sphere (not shown) formed at the other end of the support arm 21, a sphere (not shown) formed at the tip of a fulcrum shaft 26a protruding from the glasses support member 25, and the two spheres can be separately rotated. And a ball receiver 26b having two spherical concave portions (not shown) which are received in a proper state. A slit 26c similar to the slit 24g is formed at the end of the ball receiver 26b on the side of the spectacle support member 25, which communicates with a spherical recess provided in the spectacle support 25 for receiving a sphere.
[0053]
Then, the sphere provided on the other end of the support arm 21 and the sphere provided on the glasses support member 25 are rotatably received in respective spherical concave portions of the ball receiver 26b, and the other end of the support arm 21 is provided. The eyeglass supporting member 25 is supported by the camera.
[0054]
The polarizing glasses 23 are formed of a thin transparent plate material, and are formed such that linearly polarized light passes through light beams orthogonal to each other in the left half and the right half.
[0055]
FIG. 3 shows a state of use of the polarizing glasses device 20. FIG. 3 shows an example in which a notebook computer is used as the stereoscopic image display device.
[0056]
When viewing a stereoscopic image using the polarized glasses device 20, the image display unit 27a of the notebook computer 27 is opened at a predetermined angle with respect to the main unit 27b, and the image display surface 27c is set at an angle that is easy to see. Then, a force is applied so that the knob pieces 22c, 22c of the attachment means 22 are brought closer to each other, and the distance between the holding pieces 22b is increased. Then, the holding pieces 22b, 22b were positioned so as to sandwich the center of the upper edge of the housing 27d of the image display unit 27c from the front and rear with the holding pieces 22b, 22b, and the knob pieces 22c, 22c were brought closer to each other. When the force is removed, the holding pieces 22b and 22b are urged to approach each other by the force of a not-shown torsion coil spring. Thus, the polarizing glasses device 20 is attached to the notebook computer 27. Note that the polarizing glasses 23 are sandwiched between the two holding pieces 25a and 25a by inserting the central portion of the upper edge portion between the two holding pieces 25a of the glasses support member 25. Thereby, it is supported by the other end of the support arm 21 via the glasses support member 25. When the polarizing glasses device 20 is not used, it is more convenient to store the polarizing glasses 23 with the polarizing glasses 23 removed from the support arm 21, but when using the polarizing glasses device 23, support the polarizing glasses 23 before attaching the support arm 21 to the image display device. The supporting arm 21 may be supported by the supporting arm 21 after the supporting arm 21 is attached to the image display device.
[0057]
Then, after the polarizing glasses device 20 is attached to the notebook computer 27, the support arm 21 is moved by the ball joint 24 in the left-right direction, that is, the directions of arrows L and R in FIG. 3 and the up-down direction, that is, the arrows U and D in FIG. In the state in which the polarized glasses 23 (glasses supporting member 25) are moved in the front-rear direction, that is, in the directions indicated by arrows F and B in FIG. 3 and the bank direction, that is, in the state facing the image display surface 27a by the ball joint 26. The position and the direction of the polarizing glasses 23 are adjusted so that the image is rotated in the rotating direction (the directions of arrows BL and BR in FIG. 3) and the image on the image display surface 27c is most easily viewed. The slits 24g and 26c are formed in the ball joints 24 and 26, so that the support arm 21 moves along the slit 24g, and the fulcrum shaft 26a provided on the glasses support member 25 moves along the slit 26c. 3, the angle formed between the support arm 21 and the mounting means 22 and the angle formed between the support arm 21 and the polarizing glasses 23 can be increased.
[0058]
Then, the observer M can observe a stereoscopic image by viewing the image display surface 27c of the image display unit 27a through the polarizing glasses 23.
[0059]
Although the length of the support arm 21 is invariable, modified examples in which the length of the support arm is variable are shown in FIGS.
[0060]
The polarized glasses apparatus 20A shown in FIG. 5 differs from the polarized glasses apparatus 20 in that the support arm 21A can be extended and contracted, and is otherwise the same as the polarized glasses apparatus 20. Accordingly, the configuration of the support arm 21A will be described in detail, and the other portions will be denoted by the same reference numerals as those of the same portions in the polarized glasses apparatus 20, and description thereof will be omitted.
[0061]
The support arm 21A is composed of two parts 28a, 28b. The portion 28a is a pipe-shaped sheath, and the mounting means 22 is coupled to the base end of the sheath 28a via a ball joint 24. The portion 28b is a thin rod-shaped sliding portion, and is slidably coupled to the sheath portion 28a. The glasses support member 25 is connected to the tip of the sliding portion 28b via a ball joint 26.
[0062]
Then, as shown in FIG. 5 (a), with the sliding portion 28b pulled out from the sheath portion 28a, a predetermined distance for keeping the polarizing glasses 23 at a predetermined distance from the image display surface of the image display portion. Length. By adjusting the thickness of the base end of the sliding portion 28b, that is, the end opposite to the end to which the spectacles supporting member 25 is connected, the sliding is more than the state shown in FIG. The moving portion 28b is not pulled out of the sheath portion 28a, and an appropriate frictional force acts between the sliding portion 28b and the sheath portion 28a. It is configured not to be drawn into the inside 28a.
[0063]
Then, if a force is applied from the state shown in FIG. 5A so as to push the sliding portion 28b slightly more toward the sheath portion 28a, the sliding position in the pulled-out position, that is, the state shown in FIG. The frictional force between the sliding part 28b and the sheath 28a at the position of the moving part 28b is eliminated, and as shown in FIG. 5B, most of the sliding part 28b is housed in the sheath 28a. . As shown in FIG. 5 (b), if the polarizing glasses 23 are removed from the support arm 28A and stored as needed in a state where the length of the support arm 21A is shortened, there is no bulk in the stored state.
[0064]
The polarized glasses apparatus 20B shown in FIG. 6 is different from the polarized glasses apparatus 20 in that the support arm 21B is freely foldable, and is otherwise the same as the polarized glasses apparatus 20. Therefore, the configuration of the support arm 21B will be described in detail, and the other portions will be denoted by the same reference numerals as those of the same portions in the polarized glasses apparatus 20, and description thereof will be omitted.
[0065]
The support arm 21B is composed of two parts 29,30. The parts 29 and 30 are approximately the same length, and the mounting means 22 is connected to the base end of the part 29 via a ball joint 24. In addition, a spectacles supporting member 25 is supported at a tip end of the portion 30 via a ball joint 26.
[0066]
As can be seen from the enlarged drawing portion of FIG. 6A, hinge pieces 29a and 30a are protruded from the distal end of the portion 29 and the proximal end of the portion 30, respectively, and these hinge pieces 29a and 30a are overlapped. In this state, a screw shaft portion (not shown) of the tightening screw 31 is inserted into the two hinge pieces 29a and 30a and screwed into the nut 32. In addition, the projections (not shown) extending radially are formed on the surfaces of the hinge pieces 29a and 30a facing each other, and the friction between the hinge piece 29a and the hinge piece 30a when tightened by the tightening screw 31. The power is to be increased.
[0067]
In the polarizing glasses apparatus 20B, when used, as shown in FIG. 6A, the portions 29 and 30 of the support arm 21B are made to be in a straight line. In addition, when not in use, particularly when stored, as shown in FIG. 6B, the support arms 21B are folded so that the portions 29 and 30 overlap. Note that when the portions 29 and 30 of the support arm 21B are folded or extended, the tightening screw 31 is loosened. When the extended or folded state is to be maintained, the tightening screw 31 is tightened. Then, the screw shaft portion is strongly screwed into the nut 32 so that the hinge pieces 29a and 30a are strongly pressed.
[0068]
7 to 10 show a polarized glasses apparatus for a stereoscopic image display apparatus according to a second embodiment 40 of the present invention.
[0069]
The polarizing glasses device 40 includes a support arm 41, a mounting means 42 provided at one end of the support arm 41, and polarizing glasses 43 supported at the other end of the support arm 41.
[0070]
The support arm 41 is formed to be extendable and contractible. The support arm 41 includes a sheath portion 44 and a sliding portion 45 connected to the sheath portion 44 so as to be housed and pulled out. The sheath portion 44 has a thick band shape that is long in the front-rear direction and thin in the up and down direction, and has a housing concave portion 44a that is open at the tip over substantially the entire length of the sheath portion 44. A supported part 46 extending left and right is integrally formed at the base end of the sheath part 44, and the supported part 46 penetrates the supported part 46 left and right and protrudes from both ends of the supported part 46. A supported shaft (not shown) is fixed.
[0071]
The sliding portion 45 includes a band portion 45a having a long band shape in the front-rear direction, and a support portion 45b fixed to a tip end of the band portion 45a. The support portion 45b is thicker and wider than the band plate portion 45a, and its tip is slightly curved downward. A support shaft (not shown), which penetrates the support portion 45b from side to side and protrudes from both ends, is fixed to the distal end of the support portion 45b.
[0072]
Then, the band plate portion 45a of the sliding portion 45 is slidably coupled to the housing concave portion 44a of the sheath portion 44. As a result, when the support arm 41 is not used, as shown in FIG. 7, the band plate portion 45 a of the sliding portion 45 is entirely stored in the storage recess 44 a of the sheath portion 44. As shown in FIG. 10, the strip portion 45 a of the sliding portion 45 is in a state of being pulled out most from the sheath portion 44. In the state shown in FIG. 10, the band plate portion 45 a of the sliding portion 45 is prevented from being further pulled out of the sheath portion 44 by a stopper (not shown).
[0073]
The attachment means 42 includes two holding pieces 47 and 48. The holding pieces 47, 48 are provided with main pieces 47a, 48a facing each other while being separated from each other back and forth, and upper pieces 47b, 48b projecting obliquely upward from the upper edges of the main pieces 47a, 48a in a direction approaching each other. The piece 48 further includes a guide piece 48c projecting obliquely downward from the lower edge of the main piece portion 48a and away from the holding piece 47. The tips of the upper pieces 47b, 48b of the two holding pieces 47, 48 are rotatably connected to each other, and the lower edges of the main pieces 47a, 48a are formed by a resilient means (not shown), for example, a torsion coil spring. They are urged in a direction to approach each other. In a state where the main pieces 47a and 48a face each other substantially in parallel, a stopper (not shown) prevents the main pieces 47a and 48a from approaching further (see FIG. 9). At this time, the interval between the main piece portions 47a and 48a is slightly smaller than the thickness of the image display portion sandwiched therebetween, so that excessive stress is not applied to the image display portion when attached to the image display portion. That is to ensure.
[0074]
The upper end surface of one of the holding pieces 47 is cut out except for the side end, and the shaft support portions 49, 49 are formed on both sides of the cutout portion. A supported portion 46 provided at the base end of the support arm 41 is located between the shaft supporting portions 49, 49. Further, a supported shaft (not shown) protruding from both ends of the supported portion 46 is supported by the shaft supporting portion. It is rotatably supported by 49,49. When the angle between the support arm 41 and the mounting means 42 is changed by rotating the support arm 41, appropriate friction between the shaft supports 49, 49 and the supported shaft is maintained so that the angle is maintained. It is good to make resistance occur. As a means for generating such frictional resistance, a known means may be employed. For example, a means called a spring bearing in which a leaf spring is wound around the peripheral surface of the supported shaft can be employed.
[0075]
The polarizing glasses 43 have substantially the same configuration as the polarizing glasses 23 in the first embodiment, and are supported by the distal end of the support arm 41 via the glasses support member 50. The glasses support member 50 is formed by integrally forming a glasses support portion 51 and a supported portion 52. The spectacles support portion 51 is formed by two plate-shaped sandwiching pieces 51a, 51a integrally connected at the upper end, facing in parallel at an interval. The distance between the holding pieces 51a and 51a is equal to or slightly smaller than the thickness of the polarizing glasses 43, and the distance between the tips of the holding pieces 51a and 51a is smaller than the thickness of the polarizing glasses 43. Have been. The supported portion 52 is formed to protrude from the upper end of the spectacles supporting portion 51, and has two shaft supporting portions 52a, 52a separated from each other in the left and right directions. Then, a knob piece 52b is protruded laterally from one of the shaft support portions 52a.
[0076]
The eyeglass supporting member 50 is pivotally connected to the support shaft (not shown), in which the shaft supporting portions 52a and 52a protrude from both ends of the supporting portion 45b provided at the distal end of the supporting arm 41, so that the supporting arm 41 is Supported at the tip. Similar to the connection between the support arm 41 and the mounting means 42, the connection between the support arm 41 and the spectacle support member 50 is also performed between the support shafts 52a, 52a and the support shaft of the support portion 45b. It is preferable that an appropriate frictional resistance is generated between the support arms 41 so that the eyeglass support member 50 can be maintained at a desired angle with respect to the support arm 41.
[0077]
By inserting the center of the upper edge of the polarizing glasses 43 between the two holding pieces 51a, 51a of the glasses support member 50, the polarizing glasses 43 are sandwiched between the two holding pieces 51a, 51a. Accordingly, the supporting arm 41 supports the other end of the supporting arm 41 via the glasses supporting member 50.
[0078]
FIG. 10 shows a use state of the polarizing glasses device 40. Here, an example is shown in which the stereoscopic image display device is a notebook computer 53.
[0079]
When viewing a stereoscopic image using the polarizing glasses device 40, first, the image display unit 53a of the notebook computer 53 is opened at a desired angle with respect to the main unit 53b, and the upper side of the housing 53c of the image display unit 53a is opened. Attachment means 42 is attached to substantially the center of the. Specifically, the guide piece 48c of the holding piece 48 of the mounting means 42 is applied to the rear edge of the upper side of the housing 53c, and the main piece 47a of the holding piece 47 is applied to the front edge of the housing 53c. In this state, the mounting means 42 is pushed downward. Due to the pushing force, the interval between the holding pieces 47 and 48 is slightly widened, and the upper side of the housing 53c is sandwiched between the main piece 47a of the holding piece 47 and the main piece 48a of the holding piece 48 from front and rear. In this state, the attaching means 42 is attached to the upper side of the image display section 53a by the urging force of the urging means acting on the holding pieces 47 and 48.
[0080]
Then, the sliding portion 45 of the support arm 41 is pulled out from the sheath portion 44 to the draw-out limit (see the state shown in FIG. 10), and the angle of the support arm 41 with respect to the mounting means 42 and the angle of the polarizing glasses 43 with respect to the support arm 41 are adjusted. Then, the position and angle of the polarizing glasses 43 are adjusted to positions and angles at which the image displayed on the image display unit 53a is easy to see. The polarized glasses 43 may be supported by the glasses support member 50 before attaching the support arm 41 to the image display unit 53a, or may be supported by the glasses support member 50 after attaching the support arm 41 to the image display unit 53a. ,both are fine. When it is necessary to view the image on the image display unit 53a without passing through the polarizing glasses 43 while observing the stereoscopic image, the polarizing glasses 43 are set in a so-called flipped-up state as shown by a two-dot chain line in FIG. Thus, the image on the image display unit 53a can be temporarily observed without passing through the polarizing glasses 43. When changing the angle of the polarizing glasses 43 with respect to the support arm 41, it is preferable to twist the knob 52b while picking it with a finger. Since the knob piece 52b is provided on the extension of the rotation fulcrum axis of the glasses supporting member 50, the angle of the polarizing glasses 43 can be easily changed.
[0081]
Then, when the observation of the stereoscopic image has been completed, the attachment means 42 can be easily removed from the image display section 53a by pulling it upward, and the sliding section 45 of the support arm 41 is inserted into the sheath section 44. It is stored (see the state shown in FIG. 7), and if necessary, the polarizing glasses 43 are detached from the glasses supporting member 50, and the supporting arm 41 (with the attaching means 42 and the glasses supporting portion 50) and the polarizing glasses 43 are placed in an appropriate place. It may be stored and stored in
[0082]
11 to 13 show a first embodiment of the stereoscopic image display device of the present invention. Note that this embodiment shows an example in which the present invention is applied to a notebook computer.
[0083]
The notebook personal computer 60 includes a polarizing glasses unit 61 configured to be housed and pulled out. The polarizing glasses section 61 includes a support arm 62 and polarizing glasses 63. The polarized glasses 63 are supported by the distal end of the support arm 62 via the universal joint 64.
[0084]
The support arm 62 is configured to be housed and pulled out of the housing 65 a of the image display unit 65. An angle adjuster 62a is provided at the base end of the support arm 62. When the support arm 62 is pulled out from the housing 65a of the image display unit 65 (see FIG. 11), the angle adjuster 62a is mounted on the housing. 65a.
[0085]
The rear surface of the housing 65a of the image display unit 65, that is, a portion near the upper edge opposite to the surface on which the image display surface 65b is exposed is slightly protruded rearward, and glasses are provided inside the protruded portion. A storage section 65c is formed.
[0086]
When observing an image displayed on the image display unit 65 of the notebook computer 60 as a stereoscopic image, the image display unit 65 is opened at a predetermined angle with respect to the main unit 66, and the support arm 62 is displayed on the image display. The support arm 62 is pulled out from the housing 65a of the unit 65 and the support arm 62 is rotated by the angle adjustment unit 62a in the direction of arrow UD in FIG. 11 so that the support arm 62 has a predetermined angle with respect to the image display unit 65. Further, the polarizing glasses 63 are rotated by the universal joint 64 in the directions of arrows FB and LR in FIG. 11 to set the position and angle of the polarizing glasses 63 on the image display surface 65 b of the image display unit 65. Is adjusted to a position and an angle suitable for observing the image displayed as a stereoscopic image.
[0087]
Then, when the observation of the stereoscopic image is completed and the polarized glasses section 61 is stored, both the support arm 62 and the polarized glasses 63 are oriented in the same direction as the direction in which the rear surface of the housing 65a of the image display section 65 extends (see FIG. 13). ), The support arm 62 and the polarizing glasses 63 are housed in the housing 65a of the image display unit. Finally, the support arm 62 is stored in the housing 65a of the image display unit 65, and the polarized glasses 63 are stored in the glasses storage unit 65c of the housing 65a of the image display unit 65 ( See FIG. 12).
[0088]
FIG. 14 shows a modification 60A of the first embodiment. In this modified example 60A, the support arm 62A is different from the support arm 60 according to the above-described embodiment, and the other parts are the same as in the above-described embodiment 60. Therefore, the same portions as those in the above-described embodiment 60 are denoted by the same reference numerals as those in the above-described embodiments, and the description is omitted.
[0089]
Although not shown in detail, the support arm 62A is a so-called rod antenna type telescopic which comprises a sheath portion and a sliding portion which can be freely inserted into and removed from the sheath portion, similarly to the support arm 21A shown in FIG. It is configured as such. Therefore, by storing the sliding portion in the sheath portion when storing, as shown in FIG. 14, the storage space for the support arm 62A in the housing 65a of the image display portion 65 can be small. Will be.
[0090]
15 to 17 show a second embodiment of the stereoscopic image display device of the present invention. This embodiment also applies the present invention to a notebook computer.
[0091]
The notebook computer 70 includes a polarizing glasses unit 71. The polarizing glasses section 71 includes a supporting arm 74 provided in a housing 73 of the image display section 72 of the notebook computer 70 so as to be housed and pulled out freely, and polarizing glasses 75 supported at the tip of the supporting arm 74.
[0092]
The support arm 74 is constituted by two telescopic arms 76 provided on both left and right sides of the housing 73 of the image display unit 72. The telescopic arm portion 76 is formed by connecting a large number of thin wires 76a, 76a,... In a pantograph shape by rotating fulcrums 76b, 76b,..., And used wires 76a, 76a,. Is shorter as it is used in a portion closer to the distal end, and therefore, the width of the telescopic arm portion 76 becomes narrower toward the distal end. The ends 76ae of the wire located at the base end are moved vertically to the bottom of a vertically long arm storage recess 73a formed on both sides of the housing 73 of the image display unit 72 so as to open to the front. Supported as possible. The ends 76ae and 76ae move up and down in response to the expansion and contraction of the telescopic arm 76, and are moved by stopper means (not shown) in a state where the telescopic arm 76 extends to a predetermined position (see FIG. 15). The telescopic arm 76 is prevented from extending any further.
[0093]
Glasses holding means 77, 77 for supporting the polarized glasses 71 are supported at the distal ends of the telescopic arms 76, 76. The glasses holding means 77, 77 have insertion grooves 77a, 77a on the surfaces facing each other.
[0094]
The polarizing glasses 75 have substantially the same configuration as the polarizing glasses 23, 43, 63, etc. described in the above embodiments, and both side edges thereof are inserted into the insertion grooves 77a, 77a of the glasses holding means 77, 77. By being inserted, it is supported by the tip of the support arm 74.
[0095]
In the notebook computer 70, when the polarizing glasses 71 are not used, as shown in FIG. 17, the telescopic arms 76, 76 are provided on the housing 73 of the image display 72 in a folded state. The polarizing glasses 75 are also housed in the eyeglass housing recess 73b formed so as to open to the side surface of the housing 73.
[0096]
When the polarizing glasses 71 are used, that is, when an image displayed on the image display surface 72a of the image display 72 is observed as a stereoscopic image, the telescopic arms 76, 76 are moved from the arm storage recesses 73a, 73a. The polarizing glasses 75 are pulled out and extended (see FIG. 16), and the polarizing glasses 75 are supported by the glasses holding means 77, 77 provided at the tip thereof (see FIG. 15). Thereby, the position and the angle are set so that the polarized glasses 75 can observe the image displayed on the image display surface 72a as a stereoscopic image.
[0097]
FIG. 18 and FIG. 19 show a third embodiment of the stereoscopic image apparatus of the present invention. In this embodiment, a polarizing glasses unit similar to the polarizing glasses unit 71 according to the second embodiment is retrofitted to a stereoscopic image display device.
[0098]
The polarizing glasses section 81 of the notebook computer 80 includes a supporting arm 82 and polarizing glasses 83, and the supporting arm 83 includes two extendable arm sections 84, 84. The telescopic arm 84 is formed by connecting a large number of thin wires 84a, 84a,... In a pantograph manner by rotating fulcrum portions 84b, 84b,..., And the wires 84a, 84a,. Is shorter as it is used in a portion closer to the distal end, so that the width of the telescopic arm portion 84 becomes narrower toward the distal end. The ends 84ae of the wire located at the base end are supported by the bottom of a vertically long box-shaped storage housing 85 so as to be vertically movable. The end portions 84ae and 84ae move up and down in response to the expansion and contraction of the telescopic arm 84, and are moved by stopper means (not shown) in a state where the telescopic arm 84 is extended to a predetermined position (see FIG. 19). The telescopic arm 84 is prevented from extending further.
[0099]
Glasses holding means 86 for supporting the polarized glasses 83 are supported at the distal ends of the telescopic arms 84. The glasses holding means 86, 86 have the same structure as the glasses holding means 77, 77 in the second embodiment, and have insertion grooves 86a, 86a.
[0100]
The storage cases 85 are fixed to both sides of the case 88 of the image display unit 87 of the notebook computer 80 by appropriate means, whereby the support arm 82 is incorporated into the notebook computer 80.
[0101]
The polarizing glasses 83 have substantially the same configuration as the polarizing glasses 23, 43, 63, 75, etc. described in each of the above-described embodiments, and both side edges thereof have the insertion grooves 86a of the glasses holding means 86, 86, By being inserted into 86 a, it is supported by the tip of the support arm 82.
[0102]
When the polarizing glasses 81 are used, that is, when the image displayed on the image display surface 87a of the image display 87 is observed as a stereoscopic image, the telescopic arms 84, 84 are moved from the housings 85, 85. The glasses are pulled out and extended (see FIG. 19), and the polarized glasses 83 are supported by the glasses holding means 86 provided at the tip thereof. Thus, the position and the angle are set so that the polarized glasses 83 can observe the image displayed on the image display surface 87a as a stereoscopic image.
[0103]
When the polarizing glasses 81 are not used, the polarizing glasses 83 are removed from the support arm 82, and the telescopic arms 84, 84 are stored in the storage housings 85, 85 in a folded state.
[0104]
In the third embodiment as described above, the polarizing glasses unit 81 can be retrofitted to a notebook personal computer that was not originally planned to be equipped with the polarizing glasses apparatus.
[0105]
20 to 22 show a stereoscopic image display device according to a fourth embodiment of the present invention. This embodiment also applies the present invention to a notebook computer.
[0106]
The notebook personal computer 90 includes polarizing glasses 91, and the polarizing glasses 91 includes a support arm 92 and polarizing glasses 93.
[0107]
The support arm 92 is formed of a material having spring elasticity, for example, a steel plate and formed in a strip shape. A storage section 96 is formed at the upper end on the rear side of the housing 95 of the image display section 94 of the notebook computer 90. A winding shaft 96a is arranged in the storage section 96. The winding shaft 96a is urged by urging means (not shown), for example, a helical spring or the like, so as to rotate in the winding direction, that is, in the direction of arrow T in FIG. The base end of the support arm 92 is fixed to the winding shaft 96a.
[0108]
The support arm 92 is pulled out of the storage section 96 through the gate 97. The gate 97 has a slit 97a formed in an arc shape projecting downward when viewed toward the image display surface 94a of the image display unit 94, and the support arm 92 is pulled out from the slit 97a. The slit 97a is formed between a bench part 97b integrated with the storage part 96 and a brake body 98 rotatably supported by the storage part 96.
[0109]
The brake body 98 is rotatably supported on the storage section 96 by a shaft 98a on the upper side of the bench part 97b, and two arm pieces of a torsion coil spring 99 having a coil part supported on the shaft 98a are spring-loaded on the brake body 98. By elastically contacting the portion 98b and the spring hook portion 96b of the storage portion 96, the distal end portion 98c is urged to rotate in the direction in which the tip portion 98c contacts the bench portion 97b, that is, in the direction of arrow R in FIG. Therefore, when no force is applied to the brake body 98, the support arm 92 is clamped between the distal end 98 c of the brake body 98 and the bench 97 b by the urging force of the torsion coil spring 99, Although the force for rotating the winding shaft 96a in the winding direction, that is, the direction indicated by the arrow T in FIG. 22 is urged, the support arm 92 is not wound around the winding shaft 96a.
[0110]
The polarizing glasses 93 basically have polarization directions orthogonal to each other at the left and right halves, similarly to the polarizing glasses 23, 43, 63, 75, and 83 described in the above embodiments. Two linearly polarized lights are configured to be transmitted separately, and an insertion groove is formed in a portion near the upper end on the rear surface. That is, the arc-shaped supported member 100 that is curved downward is fixed to the back surface of the polarizing glasses 93, that is, the portion near the upper end of the surface facing the image display surface 94a of the image display unit 94. 100 has an insertion groove 100a.
[0111]
When using the polarizing glasses unit 91 in the notebook computer 90, that is, when observing an image displayed on the image display surface 94a of the image display unit 94 as a stereoscopic image, the brake body provided in the storage unit 96 is used. The rear end portion 98 is pressed downward (see the arrow D in FIG. 21), and the brake body 98 is rotated in the direction opposite to the direction of the arrow R in FIG. 21 (see the two-dot chain line in FIG. 21). The holding of the support arm 92 between the tip 98c of the body 98 and the bench 97b is released. In this state, after almost completely pulling out the support arm 92 from the storage portion 96 and excluding the force pressing the brake body 98 in the direction of arrow D, the brake body 98 is again supported by the distal end portion 98c and the bench portion 97b. The arm 92 is pinched (see FIGS. 20 and 21), and the state where the support arm 92 is pulled out of the storage portion is maintained.
[0112]
The leading end of the support arm 92 pulled out as described above is inserted into the insertion groove 100a of the polarizing glasses 93, and the polarizing glasses 93 are supported by the tip of the supporting arm 92. By fully pulling out the support arm 92 as described above, the distance between the tip of the support arm 92 and the image display surface 94a of the image display unit 94 is always constant. By supporting the 93, the polarized glasses 93 can be positioned at a position suitable for observing an image displayed on the image display surface 94a as a stereoscopic image.
[0113]
Further, although the support arm 92 has a thin band-plate shape, it is maintained in a state of being curved in the width direction by the slit 97a and the insertion groove 100a, and therefore has sufficient rigidity to support the polarizing glasses 93. Can be kept.
[0114]
After the observation of the stereoscopic image is completed, the polarizing glasses 93 are removed from the supporting arms 92 by pulling out the tips of the supporting arms 92 from the insertion grooves 100a of the polarizing glasses 93, and the brake body 98 is turned in the direction opposite to the direction of arrow R in FIG. By pivoting in the direction, the holding of the support arm 92 by the brake body 98 and the bench part 97b is released. Accordingly, if the urging force on the winding shaft 96a is sufficiently strong, the winding shaft 96a is rotated by the urging force in the direction of arrow T in FIG. Is not strong enough, the take-up shaft 96a rotates in the direction of arrow T and winds up the support arm 92 as the observer pushes the support arm 92 into the storage section 96. Thus, the support arm 92 is stored in the storage section 96 (see FIG. 22). When the support arm 92 is wound around the winding shaft 96a, it is wound in a curved state.
[0115]
FIG. 23 shows a modification of the fourth embodiment. This modification differs from the fourth embodiment only in the method of storing the support arm 92, and the other parts are the same as the respective parts in the fourth embodiment. Therefore, only the different portions will be described in detail, and other portions will be omitted from the drawings, or the same reference numerals will be given to the same portions as those in the fourth embodiment, and the description will be omitted. .
[0116]
In the image display section 94A of the notebook personal computer 90A according to this modification, a flat storage space 102 is formed on the back side of the liquid crystal panel section 101, and the support arm 92 is stored in the storage space 102 when not in use. Is done. A gate 97 is disposed at the upper end of the storage space 102, and the support arm 92 is pulled out from a slit 97a provided in the gate 97, as in the fourth embodiment.
[0117]
In the notebook personal computer 90A according to this modification, the storage space 102 for storing the support arm 92 can be flattened, so that there is no need to form a large projection on the back surface of the image display unit 94A, and the image The back surface of the display unit 94A can be clearly arranged.
[0118]
The shape and structure of each part in each of the above-described embodiments are merely examples of the specific embodiments performed when carrying out the present invention, and the technical scope of the present invention is limited. It must not be interpreted.
[0119]
【The invention's effect】
As is apparent from the above description, the polarizing glasses apparatus for a stereoscopic image display device according to the present invention includes image display means for displaying image information corresponding to parallax, and polarization control for dividing the image information and controlling the polarization direction. A polarizing glasses device for a stereoscopic image display device for attaching polarizing glasses to a stereoscopic image display device having an image display unit having means, wherein the mounting means is detachably attached to one end of the support arm to the image display unit. , And polarized glasses are supported on the other end of the support arm.
[0120]
Therefore, in the polarizing glasses device for an image display device of the present invention, the polarizing glasses can be attached to the stereoscopic image display device to observe a stereoscopic image, and the polarizing glasses are supported by the support arm attached to the image display unit. Therefore, the positional relationship of the polarized glasses with respect to the image display unit does not greatly change, and the observation image is unlikely to be degraded due to the improper position of the polarized glasses.
[0121]
In the invention described in claim 2, the length of the support arm is variable between the use state and the storage state, so that the space for storage can be reduced.
[0122]
According to the third aspect of the present invention, since the angle between the support arm and the mounting means is variable, the position of the polarizing glasses with respect to the image display unit can be easily adjusted.
[0123]
In the invention described in claim 4, the angle between the support arm and the polarizing glasses is variable, so that the angle of the polarizing glasses with respect to the image display unit can be easily adjusted.
[0124]
According to the fifth aspect of the invention, when observing the image display unit without passing through the polarizing glasses, the polarizing glasses are supported by the variable angle mechanism that enables the polarizing glasses to be flipped up to a position substantially parallel to the support arm. Since the polarized glasses are supported on the arm, the polarized glasses do not become an obstacle when observing the image display unit without observing the stereoscopic image.
[0125]
In the invention described in claim 6, since the polarizing glasses are detachable from the support arm, storage and storage suitable for the support arm and the polarizing glasses can be performed.
[0126]
The three-dimensional image display device of the present invention includes: an image display unit that displays image information corresponding to parallax; an image display unit having polarization control unit that divides the image information to control a polarization direction; A supporting arm provided so as to be retractable and protruding from the image display unit is provided. Polarized glasses supported at the tip of the support arm with the support arm protruding from the image display unit at a predetermined distance from the image display unit. It is characterized by being opposed to each other.
[0127]
Therefore, in the stereoscopic image display device of the present invention, since the polarized glasses are opposed to the image display unit via the support arm provided on the image display unit, the positional relationship of the polarized glasses with respect to the image display unit is greatly deviated. Therefore, the deterioration of the observed image due to the improper position of the polarized glasses is unlikely to occur.
[0128]
Further, since the support arm is always present together with the three-dimensional image display device, it is possible to prevent the support arm from being lost or the support arm from being improperly managed and damaged.
[0129]
In the invention described in claim 8, since the support arm and the image display unit are connected via the angle adjusting mechanism, the position of the polarized glasses with respect to the image display unit can be easily adjusted.
[0130]
According to the ninth aspect of the present invention, since the angle between the support arm and the polarizing glasses is variable, the angle of the polarizing glasses with respect to the image display unit can be easily adjusted.
[0131]
According to the tenth aspect of the present invention, when observing the image display unit without passing through the polarizing glasses, the polarizing glasses are supported by an angle changing mechanism that enables the polarizing glasses to be flipped up to a position substantially parallel to the support arm. Since the polarized glasses are supported on the arm, the polarized glasses do not become an obstacle when observing the image display unit without observing the stereoscopic image.
[0132]
According to the invention described in claim 11, since the polarized glasses are supported by the support arm via the variable angle mechanism that can rotate the polarized glasses in a direction away from and approaching the image display unit, The angle in the vertical direction of the polarizing glasses with respect to the image display unit can be easily adjusted.
[0133]
According to the twelfth aspect of the present invention, since the polarized glasses are supported by the support arm via the angle variable mechanism that can rotate the polarized glasses in a direction in which both ends are separated from and approach to the image display unit, In addition, the angle of the polarized glasses with respect to the image display unit in the horizontal direction can be easily adjusted.
[0134]
In the invention described in claim 13, the support arm is composed of a pair of pantograph-shaped arms provided on both sides of a housing of the image display unit so as to be extendable and contractible, and the polarizing glasses are configured to include the pair of pantograph-shaped arms. The support arm can be stored in a small storage space because it is detachably attached to the tip of the section.
[0135]
In addition, since the position of the tip of the pantograph-shaped arm portion in the pulled-out state is substantially constant, the position of the polarizing glasses can be stabilized.
[0136]
According to the invention as set forth in claim 14, the support arm has a rod-like shape that can be housed and pulled out of the housing of the image display unit, and the polarized glasses are provided at the tip of the support arm. Since the glasses are supported so that the angle can be adjusted and the glasses housing section for housing the polarizing glasses is provided in the housing of the image display section, the angle of the polarizing glasses with respect to the image display section can be easily adjusted.
[0137]
In addition, since the storage section of the polarizing glasses is provided in the housing of the image display section, it is possible to avoid losing the polarizing glasses or losing proper management of the polarizing glasses and damaging the polarizing glasses. Can be.
[0138]
According to the invention described in claim 15, the support arm is formed to be extendable and retractable, and is stored in the housing of the image display unit in the most contracted state. Therefore, the storage space for the support arm provided in the housing of the image display unit can be small.
[0139]
In the invention described in claim 16, the support arm is made of a metal band plate that can be housed and pulled out of the housing of the image display unit, and has a width when pulled out of the housing. Since the shape is stabilized by being curved in the direction, the structure of the support arm is simplified.
[0140]
In the invention described in claim 17, the support arm is stored in the housing in a wound state, so that the storage space for the support arm can be reduced.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an outline of a polarized glasses device for a stereoscopic image display device of the present invention.
FIG. 2 is a diagram illustrating an outline of a stereoscopic image display device of the present invention.
FIG. 3 shows the first embodiment of the polarizing glasses device for a stereoscopic image display device of the present invention, together with FIGS. 4 to 6, and is a perspective view showing a use state.
FIG. 4 is a perspective view showing a state in which polarized glasses are removed from a support arm.
5A and 5B are perspective views showing a modified example in which the support arm is configured to be extendable and contractible, wherein FIG. 5A shows an extended state and FIG. 5B shows a contracted state.
FIG. 6 is a perspective view showing a modified example in which the support arm is configured to be freely foldable, wherein (a) shows an extended state and (b) shows a folded state.
FIG. 7 shows a second embodiment of the polarizing glasses device for a stereoscopic image device of the present invention together with FIGS. 8 to 10, and FIG. 7 is a perspective view showing the whole.
FIG. 8 is an enlarged perspective view showing a mounting means.
FIG. 9 is an enlarged perspective view showing polarized glasses and a glasses support member.
FIG. 10 is a perspective view showing a use state.
11 shows a first embodiment of the stereoscopic image display device of the present invention together with FIGS. 12 to 14, and is a perspective view showing a use state. FIG.
FIG. 12 is a perspective view showing a state in which a polarizing glasses unit is stored.
FIG. 13 is a perspective view showing a state in which the polarizing glasses unit is being housed.
FIG. 14 is a perspective view showing a state in which a polarizing glasses unit is stored in a modification.
FIG. 15 shows a second embodiment of the stereoscopic image display device of the present invention together with FIGS. 16 and 17, and is a perspective view showing a use state.
FIG. 16 is a perspective view showing a state in which polarized glasses are removed from the support arm.
FIG. 17 is a perspective view showing a state in which a support arm and polarized glasses are stored.
FIG. 18 shows a third embodiment of the stereoscopic image display device of the present invention together with FIG. 19, and is a perspective view showing a state before a polarizing glasses section is provided.
FIG. 19 is a perspective view showing a use state.
20 shows a stereoscopic image display apparatus according to a fourth embodiment of the present invention, together with FIGS. 21 to 23, and is a perspective view showing a use state. FIG.
FIG. 21 is an enlarged sectional view of a main part in a use state.
FIG. 22 is an enlarged cross-sectional view of a main part in a state where a support arm is stored.
FIG. 23 is an enlarged cross-sectional view of a main part in a state where a support arm is stored, showing a modification.
FIG. 24 is a schematic exploded perspective view of a stereoscopic image display device for explaining the principle of observing a stereoscopic image.
FIG. 25 is a schematic diagram for explaining a problem relating to a position at which a stereoscopic image is observed.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Polarized glasses apparatus, 2 ... Support arm, 3 ... Mounting means, 4 ... Polarized glasses, 5 ... Stereoscopic image display apparatus, 6 ... Image display section, 8 ... Stereoscopic image display apparatus, 9 ... Image display section, 10 ... Support Arm, 11: polarized glasses, 12b: storage space (glasses storage section), 20: polarized glasses device, 21: support arm, 23: polarized glasses, 27: notebook computer (stereoscopic image display device), 27a: image display unit , 20A: Polarized glasses device, 21A: Support arm, 20B: Polarized glasses device, 21B: Support arm, 40: Polarized glasses device, 41: Support arm, 42: Mounting means, 43: Polarized glasses, 50: Glasses support member ( Angle variable mechanism), 53: Notebook personal computer (stereoscopic image display device), 53a: Image display unit, 60: Notebook personal computer (stereoscopic image display device), 62: Support arm, 62a: Angle adjusting unit (Angle adjuster) ), 64: universal joint (variable angle mechanism), 63: polarized glasses, 65: image display unit, 65c: glasses storage unit, 60A: notebook computer (stereoscopic image display device), 62A: support arm, 70: notebook type Personal computer (stereoscopic image display device), 72: image display unit, 73: housing, 73b: glasses storage recess (glasses storage unit), 74: support arm, 75: polarized glasses, 76: telescopic arm (pantograph-shaped arm) ), 80: notebook personal computer (stereoscopic image display device), 82: support arm, 83: polarized glasses, 84: telescopic arm (pantograph-shaped arm), 87: image display, 88: housing, 90: notebook Type personal computer (stereoscopic image display device), 92: Support arm, 93: Polarized glasses, 94: Image display unit, 95: Housing, 90A: Notebook type personal computer (stereoscopic image display device), 94A The image display unit

Claims (17)

Stereoscopic image display for attaching polarizing glasses to a stereoscopic image display device including an image display unit that displays image information corresponding to parallax and an image display unit that has a polarization control unit that divides the image information and controls a polarization direction A polarized glasses device for the device,
A polarizing glasses device for a stereoscopic image display device, comprising: mounting means detachably mounted on the image display unit at one end of the support arm, and polarizing glasses supported on the other end of the support arm. The polarizing glasses device for a stereoscopic image display device according to claim 1, wherein the length of the support arm is variable between a use state and a storage state. The polarizing glasses device for a stereoscopic image display device according to claim 1, wherein an angle between the support arm and the mounting means is variable. The polarizing glasses apparatus of claim 1, wherein an angle between the supporting arm and the polarizing glasses is variable. When viewing the image display section without passing through the polarizing glasses, the polarizing glasses are supported on the support arm by an angle variable mechanism that enables the polarizing glasses to be flipped up to a position almost parallel to the support arm. The polarized glasses device for a stereoscopic image display device according to claim 4. The polarizing glasses device for a stereoscopic image display device according to claim 1, wherein the polarizing glasses are detachable from the support arm. An image display unit that displays image information corresponding to parallax and an image display unit that has polarization control means for dividing the image information and controlling a polarization direction, and polarizing glasses,
A support arm is provided on the image display unit so as to be freely retractable,
A stereoscopic image display device, wherein the polarized glasses supported on the tip of the support arm are opposed to the image display unit at a predetermined interval in a state where the support arm is protruded from the image display unit. . The stereoscopic image display device according to claim 7, wherein the support arm and the image display unit are connected via an angle adjustment mechanism. The stereoscopic image display device according to claim 7, wherein an angle between the support arm and the polarizing glasses is variable. When viewing the image display section without passing through the polarizing glasses, the polarizing glasses are supported on the support arm by an angle variable mechanism that enables the polarizing glasses to be flipped up to a position almost parallel to the support arm. The three-dimensional image display device according to claim 9. The stereoscopic image display according to claim 9, wherein the polarizing glasses are supported on a supporting arm via an angle variable mechanism that can rotate the polarizing glasses in a direction away from and approaching the image display unit. apparatus. The stereoscopic image according to claim 9, wherein the polarizing glasses are supported on a supporting arm via an angle variable mechanism that can rotate the polarizing glasses in a direction in which both ends thereof can be separated from and approach to the image display unit. Display device. The supporting arm includes a pair of pantograph-shaped arms provided on both sides of the housing of the image display unit so as to be extendable and contractible, and the polarizing glasses are detachably attached to tips of the pair of pantograph-shaped arms. The three-dimensional image display device according to claim 7, wherein: The support arm has a rod shape that can be housed and pulled out of the housing of the image display unit,
The polarizing glasses are supported at the tip of the support arm so as to be adjustable in angle,
The stereoscopic image display device according to claim 7, wherein a glasses storage unit that stores polarized glasses is provided in a housing of the image display unit. 15. The three-dimensional image display device according to claim 14, wherein the support arm is formed so as to be extendable and contracted in a housing of the image display unit in a most contracted state. The support arm is formed of a metal band plate that can be housed and pulled out of the housing of the image display unit, and is bent in the width direction in a state where the support arm is pulled out from the housing and the shape is stabilized. The three-dimensional image display device according to claim 7, wherein: 17. The three-dimensional image display device according to claim 16, wherein the support arm is stored in the housing in a wound state.

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