JP2013015690A - Display unit - Google Patents

Abstract

A stereoscopic image can be provided to a user.
A rotating table having a rotating shaft, a driving unit for rotating the rotating table around the rotating shaft, and a plurality of light emitting elements arranged in a matrix are attached to the rotating unit. And a light emitting element array having a light emitting surface. This light emitting element array is configured in a planar shape, and a directivity control unit that shields light from a light emitting element other than a predetermined direction is mounted on the light emitting surface. By mounting the directivity control unit, the light emission from the light emitting element array is controlled not to reach only in a predetermined direction. The present technology can be applied to a stereoscopic image display device that displays a stereoscopic image.
[Selection] Figure 7

Description

  The present technology relates to a display device. Specifically, the present invention relates to a display device suitable for displaying an image three-dimensionally.

  A light beam reproduction type stereoscopic image display device that reproduces a stereoscopic image over the entire circumference of the subject based on 2D video information for stereoscopic image display, etc., which is obtained by capturing an image of the subject over the entire circumference or created by a computer. Proposals have been made.

  Patent Document 1 discloses a stereoscopic image display device. According to this stereoscopic image display apparatus, the light flux assigning means and the cylindrical two-dimensional pattern display means are provided. The light beam allocating means is provided on the front surface or the back surface of the display unit having a convex curved surface when viewed from the observer. The means has a plurality of openings, or has a curved surface in which lenses are formed in an array, and a light flux from a plurality of pixels of the display unit is assigned to each of the openings or lenses. The two-dimensional pattern display means displays the two-dimensional pattern on the display unit.

  According to this stereoscopic image display apparatus, it is possible to efficiently execute image mapping of a stereoscopic image that is easy to display a full motion video, and even if the viewpoint position is changed, the stereoscopic image does not break down and at a high resolution. A stereoscopic image can be displayed.

  Further, in Patent Document 2, a light emitting element is arranged in a large number of rows on a rod-shaped light emitter, and the light emitter is arranged on a spiral to form a display body. It has been proposed to form.

Japanese Patent Laid-Open No. 2004-177709 JP 2007-226103 A

  According to the stereoscopic image display device found in Patent Document 1, a plurality of openings are formed on a front surface or a rear surface of a display portion having a convex curved surface when viewed from an observer, or lenses are arranged in an array. A light beam assigning means having a curved surface formed in a shape. Since light bundles from a plurality of pixels of the display unit are assigned to each of the aperture and the lens, there is a possibility that practical image quality may not be obtained, and improvement in image quality is desired.

  In Patent Document 2, a three-dimensional image is provided by rotating a display body in which light emitters are arranged in a spiral shape. However, a three-dimensional distribution is formed by time division of a point light source. There is no concept of the concept of scanning and displaying a two-dimensional image at the viewpoint. According to Patent Document 2, it is difficult to provide a two-dimensional image so that it can be seen from the entire periphery in order to realize three-dimensionality by causing light emitters arranged three-dimensionally to emit light. In addition, signal processing may be complicated.

  When providing a stereoscopic image, it is desired to make the stereoscopic image visible from the entire periphery with good reproducibility without complicating the stereoscopic display mechanism.

  The present technology has been made in view of such a situation, and provides a stereoscopic image to a user so that the stereoscopic image can be viewed with good reproducibility.

  A display device according to an aspect of the present technology includes a rotating unit having a rotating shaft, a driving unit that rotates the rotating unit around the rotating shaft, and a plurality of display elements that are attached to the rotating unit. And a directional member for controlling the direction of light emitted from the display element is attached to the display unit.

  The directional member can block light from a direction other than a predetermined direction from the display element.

  The display unit may include a plurality of blocks, and the display elements may be driven in a line sequential manner in each block.

  The display unit may include a plurality of blocks, and the blocks may be arranged with a predetermined angle.

  The display unit may include a plurality of blocks, and one image may be formed from images provided in each of the plurality of blocks.

  The exterior body further includes an exterior body that does not rotate and is disposed outside the display section, and the exterior body includes a light shielding section that shields light from the display section. The display can be switched.

  The display unit may be controlled not to emit light during display switching in the display unit.

  The display unit may provide different images in a plurality of directions.

  The directional member is formed in a predetermined shape with the center of the display element as a focal point, and is formed in a vertical column shape so as to limit the direction of light emitted from the display element. Can do.

  The directivity member may be formed in a shape in which light shielding regions having different pitches are provided over a plurality of layers in each layer.

  In the display device according to one aspect of the present technology, a rotating unit having a rotating shaft, a driving unit that rotates the rotating unit around the rotating shaft, and a plurality of display elements are provided. A display unit is provided, and a directional member that controls the direction of light emitted from the display element is attached to the display unit.

  According to one aspect of the present technology, a stereoscopic image is provided to a user so that the stereoscopic image can be viewed with good reproducibility.

It is a figure which shows the structure of the display apparatus in 1st Embodiment. It is a figure which shows the internal structure of a display apparatus. It is a figure for demonstrating the structure of a two-dimensional light emitting element array. It is a figure for demonstrating the structure of a two-dimensional light emitting element array. It is a figure for demonstrating operation | movement of a display apparatus. It is a figure for demonstrating how to provide an image. It is a figure for demonstrating the structure of the two-dimensional light emitting element array in 2nd Embodiment. It is a figure which shows the structure of the display apparatus in 2nd Embodiment. It is a figure for demonstrating how to provide an image. It is a figure for demonstrating the structure of a two-dimensional light emitting element array. It is a figure for demonstrating the structure of the two-dimensional light emitting element array in 3rd Embodiment. It is a figure for demonstrating how to provide an image. It is a figure for demonstrating the structure of the two-dimensional light emitting element array in 4th Embodiment. It is a figure for demonstrating the timing of the display of an image. It is a figure for demonstrating how to provide an image. It is a figure for demonstrating the structure of the two-dimensional light emitting element array in 5th Embodiment. It is a figure for demonstrating the case where writing time is acquired by brightness | luminance control. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating a directivity control unit. It is a figure for demonstrating the structure of the two-dimensional light emitting element array in 6th Embodiment. It is a figure for demonstrating how to provide an image.

  Hereinafter, embodiments of the present technology will be described with reference to the drawings.

[Configuration of stereoscopic image display device]
FIG. 1 is a perspective view illustrating a configuration example of the stereoscopic image display apparatus 10. FIG. 2 is a perspective view showing an assembly example of the stereoscopic image display apparatus 10. The structure of the stereoscopic image display device 10 will be described with reference to FIGS. 1 and 2. The stereoscopic image display device 10 provides a user with a moving image or a still image in three dimensions. In addition, two-dimensional moving images and still images can be provided to the user regardless of three-dimensional. The stereoscopic image display apparatus 10 is a display apparatus that has an area where an image can be recognized within a 360-degree viewpoint range around the stereoscopic image display apparatus 10 and can provide images from a plurality of viewpoints (multi-viewpoints).

  In the following description, the stereoscopic image display apparatus 10 is based on 2D video information or the like (hereinafter simply referred to as video data Din) for displaying a stereoscopic image, which is obtained by capturing an image of a subject over the entire circumference or created by a computer. An example will be described in which a stereoscopic image is reproduced over the entire periphery of the subject.

  A stereoscopic image display apparatus 10 shown in FIGS. 1 and 2 constitutes an example of a light reproduction type stereoscopic image display apparatus, and includes a two-dimensional light emitting element array 101, a rotating part 104 with a slit, and an installation base 105 with a driving mechanism. I have. The rotation unit 104 includes an exterior body 41 with a slit and a turntable 42 with an air inlet. An exterior body 41 is attached on the turntable 42. The turntable 42 has a disk shape, and a rotation shaft 103 is provided at the center position thereof.

  The rotation shaft 103 is the rotation center of the turntable 42. The rotation shaft 103 is also made the rotation center of the exterior body 41. In the following description, the rotating shaft 103 of the rotating unit 104 will be described. The rotating shaft 103 is a rotating shaft of the rotating table 42 and the exterior body 41.

  An intake port 106 is provided at a predetermined position of the turntable 42, and is configured to take air into the exterior body 41. One or more two-dimensional light emitting element arrays 101 having a predetermined shape are provided inside the exterior body 41 on the turntable 42. The two-dimensional light emitting element array 101 has, for example, m rows × n columns of light emitting elements arranged in a matrix. As the light emitting element, a self light emitting element such as a light emitting diode, a laser diode, or an organic EL can be used.

  In the two-dimensional light emitting element array 101, a plurality of light emitting elements emit light according to the rotation of the rotating unit 104, and the light emission is controlled based on video data Din for stereoscopic images. The two-dimensional light-emitting element array 101 is, for example, a one-dimensional light-emitting element substrate # 1 in which a plurality of light-emitting elements are arranged (mounted) in a line shape on a small edge surface obtained by cutting a printed wiring board into a curved shape (for example, an arc shape). Has a laminated structure in which a plurality of layers are laminated along the rotation axis 103. With this configuration, the two-dimensional light emitting element array 101 having a light emitting surface having a curved surface shape (for example, an arc shape) can be easily configured. This form will be described as a first embodiment.

  The exterior body 41 attached so as to cover the two-dimensional light emitting element array 101 on the turntable 42 is configured in a cylindrical shape having a predetermined diameter φ and a predetermined height H. A slit 102 is provided at a predetermined position on the peripheral surface of the exterior body 41. The slit 102 is drilled in a direction parallel to the rotation axis 103 on the peripheral surface of the exterior body 41, and is fixed in front of the light emitting surface of the two-dimensional light emitting element array 101, thereby limiting the light emission angle to a predetermined range. .

  The top plate portion of the exterior body 41 has a fan structure, and is configured to exhaust the cooling air taken from the air inlet 106 of the turntable 42 to the outside. For example, a slight fan part 107 (exhaust port) such as a blade as an example of a cooling blade member is provided on the top plate part (upper part) of the outer body 41, and an air flow is created by using a rotation operation. Thus, heat generated from the two-dimensional light emitting element array 101 and its drive circuit is forcibly exhausted.

  The installation stand 105 is a part that rotatably supports the turntable 42. A bearing portion (not shown) is provided on the upper portion of the installation base 105. The bearing unit rotatably engages the rotating shaft 103 and supports the rotating unit 104. A motor 52 is provided inside the installation stand 105, and is configured to rotate the turntable 42 at a predetermined rotation (modulation) speed. For example, a direct connection type AC motor or the like is engaged with the lower end of the rotating shaft 103. The motor 52 is configured to transmit the rotational force directly to the rotation shaft 103 and rotate the rotation portion 104 at a predetermined modulation speed by rotating the rotation shaft 103.

  In the method shown in FIGS. 1 and 2, when power and video data Din are sent to the rotating unit 104, they are sent via the slip ring 51. The slip ring 51 is divided into a stationary part and a rotating part. The rotation side component is attached to the rotation shaft 103. A harness 53 (wiring cable) is connected to the stationary part. The two-dimensional light emitting element array 101 is connected to the rotation side component via another harness 54. A slider (not shown) is in electrical contact with the annular body between the stationary part and the rotating part. The slider constitutes a stationary part or a rotating part, and the annular body constitutes a rotating part or a stationary part. With this structure, externally supplied power and video data Din are transmitted to the two-dimensional light emitting element array 101 via the slip ring 51 in the installation stand 105.

  FIG. 3 is a diagram illustrating a configuration example of the one-dimensional light emitting element substrate # 1. The one-dimensional light emitting element substrate # 1 is formed by patterning a silver foil substrate (not shown) to form a wiring pattern, cutting the appearance of the printed wiring board 31 on which the wiring pattern is formed into a Y shape, and curving the inside (for example, a circle) It is formed by notching in an arc shape.

  In this example, a connector 34 having a wiring structure is formed on the opposite side of the curved portion. Further, positioning holes 32 and 33 are formed on both sides of the printed wiring board 31 of the one-dimensional light emitting element substrate #k. An IC 35 (semiconductor integrated circuit device) for serial / parallel conversion and a driver is mounted on a printed wiring board 31 that is Y-shaped in appearance and curved in the inside. Next, j rows of light emitting elements 20j are arranged in a line on the curved woven portion or the edge surface of the printed wiring board 31 on which the IC 35 is mounted. Further, a line-shaped lens member 109 is disposed on the front surface of the light emitting element 20j to form a one-dimensional light emitting element substrate # 1 (substrate).

  Only one n-dimensional light emitting element substrate # 1 is prepared. This is because the n-dimensional light-emitting element substrate # 1 is stacked to form the m-row × n-column two-dimensional light-emitting element array 101. FIG. 4 is a perspective view showing a stacking example of k one-dimensional light emitting element substrates #k (k = 1 to n). In this example, a two-dimensional light-emitting element array 101 having a curved shape in which a required number of one-dimensional light-emitting element substrates #k are stacked and j rows of light-emitting elements 20j are arranged in a line is manufactured.

  The two-dimensional light emitting element array 101 configured as described above is attached to a predetermined position of the rotating unit 104 shown in FIG. At this time, when the holes of the printed wiring board of the k one-dimensional light emitting element substrates #k are inserted into the rod-like positioning pins 83 protruding on the turntable 42, each one-dimensional light emitting element substrate #k is self A consistently positioned state is obtained. In order to maintain this state, the k one-dimensional light emitting element substrates # 1 to #n are attached so as to be stacked along the rotation shaft 103.

  In this example, the connection substrate 11 mounted on a predetermined substrate is erected on the turntable 42. The connection board 11 is provided with a connector having a plug-in structure for connection to a connector having a wiring structure of the one-dimensional light emitting element substrates # 1 to #n. The connector having the wiring structure of the one-dimensional light emitting element substrates # 1 to #n is fitted to the connector having the insertion structure of the connection board 11 described above, and k pieces of the one-dimensional light emitting element substrates # 1 to #n are connected to the connection board 11. Is done.

  In addition, the two-dimensional light emitting element array 101 is arranged between the rotation shaft 103 of the rotating unit 104 and the slit 102 of the exterior body 41 so that the curved light emitting surface (concave surface) faces the position of the slit 102. . The two-dimensional light emitting element array 101 is connected to a harness 54 from a rotation side component of the slip ring 51. A viewer detection sensor 81 is attached at a position where the outside can be seen from the inside of the exterior body 41. The viewer detection sensor 81 is attached to the connection board 11 described above via the arm member 82. The viewer detection sensor 81 is attached to one end of the arm member 82, and is used to detect the viewer who views the stereoscopic image outside the rotating unit 104 rotated by the motor 52 and to determine whether or not to view the viewer. However, in the case where such detection is not necessary, the viewer detection sensor 81 may be omitted.

  When the two-dimensional light emitting element array 101 is attached on the turntable 42, the exterior body 41 is attached so as to cover the two-dimensional light emitting element array 101 on the turntable 42. At this time, by fixing the slit 102 in front of the light emitting surface of the two-dimensional light emitting element array 101, the light emission angle can be limited to a predetermined range. As a result, the light emitting unit UI can be configured by the slits 102 on the peripheral surface of the outer package 41 and the two-dimensional light emitting element array 101 on the inner side.

  On the other hand, the installation stand 105 for rotatably supporting the turntable 42 is created. In this example, the slip ring 51 is provided on the upper portion of the installation base 105, and a bearing portion (not shown) is mounted. The bearing portion rotatably engages the rotating shaft 103 and supports the rotating portion 104. In addition to the slip ring 51, a motor 52, a control unit 55, an I / F board 56, a power supply unit 57, and the like are mounted in the installation base 105. The motor 52 is directly connected to the rotating shaft 103.

  The control unit 55 and the power supply unit 57 are connected to the fixed side component of the slip ring 51 via the harness 53. Thereby, in the installation stand 105, it is comprised so that the electric power and video data D1n supplied from the outside can be transmitted to the two-dimensional light emitting element array 101 via the slip ring 51. When the installation stand 105 is prepared, the rotating unit 104 to which the two-dimensional light emitting element array 101 is attached is attached to the installation stand 105. Thereby, the stereoscopic image display apparatus 10 is completed.

  FIG. 5 is a duplex diagram looking down from the direction of the rotation axis showing an example of the operation of the stereoscopic image display apparatus 10. In the drawing, the lens member 109 is omitted. The stereoscopic image display apparatus 10 shown in FIG. 5 employs a light beam reproduction method, and the rotation unit 104 rotates in the direction of arrow R (see FIG. 1) about the rotation axis 103 or in the opposite direction. It has a structure.

  In the stereoscopic image display device 10, a slit 102 parallel to the rotation shaft 103 is provided in the exterior body 41 in front of the light emitting surface of the two-dimensional light-emitting element array 101, and light emitted from the two-dimensional light-emitting element array 101 is emitted from the slit. It has a structure that does not leak from other parts. With this slit structure, the emission angle of the light emitted from each of the light emitting elements 201 to 212 of the two-dimensional light emitting element array 101 is greatly limited from the slit 102 in the left-right direction.

  In this example, the number of the light emitting elements 201 to 212 is m = 12 rows, but any number is possible. By these twelve light emitting elements 201 to 212, the light of the stereoscopic image formed with reference to the rotation axis 103 leaks out from the inside of the rotation unit 104 to the outside through the slit 102. Here, the direction of each of the twelve light emitting elements 201 to 212 and the slit 102 is indicated by a vector.

  A direction indicated by a line segment connecting the light emitting element 201 and the slit 102 is a direction of light leaking from the light emitting element 201 through the slit 102. Hereinafter, this direction is described as “vector 201V direction”. Hereinafter, similarly, a direction indicated by a line segment connecting the light emitting element 202 and the slit 102 is a direction of light leaking from the light emitting element 202 through the slit 102. This direction is described as “vector 202V direction”. For example, the light output from the light emitting element 201 passes through the slit 102 and is emitted in the direction of the vector 201V. The light output from the light emitting element 202 passes through the slit 102 and is emitted in the vector 202V direction.

  Thus, since the light of each light emitting element 201-212 is radiated | emitted in a different direction, the light ray reproduction | regeneration for one vertical line regulated by the slit 102 is attained. By rotating the rotation unit 104 having such a slit structure with respect to the viewpoint p, a cylindrical light beam reproduction surface can be formed. Further, the video data Din from the outside or the video data Din from the storage device such as the ROM inside the rotating unit is reflected on the light emitting unit UI of the two-dimensional light emitting element array 101 according to the rotational scanning angle with respect to the viewpoint p. Thus, it becomes possible to output an arbitrary reproduction beam.

  FIG. 6 is a diagram illustrating an example of the locus of the light emission point observed from the viewpoint p. When the rotating unit 104 having the light emitting unit UI is rotated at a constant speed and rotationally scanned with respect to the viewpoint p = 300, the light emitting elements observed from the viewpoint 300 are sequentially emitted from the light emitting elements 201 at time T intervals. , 203,... 212.

  A structure in which the locus of light emission points (black small circles in the figure) appears to form a plane, for example, is realized by adjusting the shape of the light emitting surface of the two-dimensional light emitting element array 101 and the position of the slit 102. For example, at time t = 0 shown in FIG. 6A, when the two-dimensional light emitting element array 101 is observed through the slit 102 at the viewpoint 300, light leaking from the light emitting element 201 is observed. At time t = T shown in FIG. 6B, when the two-dimensional light emitting element array 101 is observed through the slit 102 at the viewpoint 300, light leaking from the light emitting element 202 is observed. The first white small circle from the right side in the drawing indicates the light emitting point of the light emitting element 201.

  Although not shown, when the two-dimensional light emitting element array 101 is observed at the viewpoint 300 through the slit 102 at the time t = 2T, light leaking from the light emitting element 203 is observed, and at t = 3T, the light leaking from the light emitting element 204 is observed. Light exiting is observed, light leaking from the light emitting element 205 is observed at t = 4T, and light leaking from the light emitting element 206 is observed at t = 5T. Further, light leaking from the light emitting element 207 is observed at t = 6T, light leaking from the light emitting element 208 is observed at t = 7T, light leaking from the light emitting element 209 is observed at t = 8T, and t At 9T, light leaking from the light emitting element 210 is observed.

  When time elapses in this way and time t = 10T shown in FIG. 6C is reached and the two-dimensional light emitting element array 101 is observed through the slit 102 at the viewpoint 300, light leaking from the light emitting element 211 is observed. Similarly, when the two-dimensional light emitting element array 101 is observed at the viewpoint 300 through the slit 102 at time t = 11T shown in FIG. 6D, light leaking from the light emitting element 212 is observed.

  As described above, since light from the light emitting elements 201 to 212 is observed sequentially as time elapses, an image is projected in a portion where white small circles are arranged in one horizontal row as shown in FIG. 6D. The user can observe the image. In the stereoscopic image display device 10 having such a configuration, as described above, the viewpoint is generated by rotation (point 1), the parallax is generated by the directivity of information propagation (point 2), and the high-speed collective driving light emitting element is generated. By using an array (point 3), a stereoscopic image can be displayed.

  This is another embodiment for realizing point 1 and point 2, and alternative means for point 3 will be described below. In the following description, the configuration of the two-dimensional light-emitting element array 101 is changed, and other configurations can be basically configured in the same manner as the first embodiment. Explanations and illustrations of similar parts are omitted.

[Second Embodiment]
FIG. 7 is a diagram for explaining a configuration of the two-dimensional light emitting element array 101 in the second embodiment. The two-dimensional light emitting element array 500 shown in FIG. 7 includes a display body 501 and a directivity control unit 502. FIG. 7 shows a case where the two-dimensional light emitting element array 500 is viewed from the upper side (or the lower side). As the display body 501, a flat display such as a liquid crystal display or an organic EL display can be used. Although the description will be continued here as a flat display, the application range of the present embodiment is not limited to a flat display, and can be applied to a display (display body) having another shape.

  The directivity control unit 502 is provided on the display body 501 by processing or mounting the surface of the display body 501. The directivity control unit 502 can visually recognize an image displayed on the display body 501 when the display body 501 is viewed from a predetermined position. However, when the display body 501 is viewed from a position other than the predetermined position, the display body 501 is visible. Control is performed so that the image displayed on the screen 501 cannot be visually recognized.

  For example, the image displayed on the display body 501 can be visually recognized from the viewpoint 551, but cannot be viewed when the image displayed on the display body 501 is viewed from the viewpoint 552 shifted from the viewpoint 551 by the angle θ. The directivity control unit 502 that performs such control will be described later with reference to a plurality of embodiments. Here, description will be continued assuming that such control is performed.

  By using such directivity control unit 502, parallax generation (point 2) based on directivity of information propagation is realized. Also, with this configuration, it is possible to have a configuration in which it is not necessary to perform parallax generation based on the directivity of information propagation with the slits 102 that are necessary in the first embodiment. That is, by providing the directivity control unit 502 in the display unit 501, the shape of the display unit 501 does not need to be a shape that takes into account the slit 102. Therefore, the display unit 501 can be configured to be a flat surface or a curved shape, and the degree of freedom in the shape can be increased.

  Such a two-dimensional light emitting element array 500 is connected to the connection substrate 11 as shown in FIG. 8 instead of the two-dimensional light emitting element array 101. Since the connection substrate 11 is provided on the turntable 42, the two-dimensional light emitting element array 500 is configured to rotate about the rotation shaft 103 as a rotation axis. Thus, by rotating the two-dimensional light emitting element array 500, viewpoint generation (point 1) by rotation is realized.

  As described above, in the second embodiment, the rotating table 42 having the rotating shaft 103, the motor 52 for rotating the rotating table 42 around the rotating shaft 103, and the rotating table 42 are attached to the rotating table 42. The three-dimensional image display device 10 is configured by a light emitting element array 500 having a light emitting surface formed by arranging light emitting elements in a matrix. The light emitting element array 500 includes a planar display body 501, and a directivity control unit 502 that shields light from a light emitting element other than a predetermined direction is mounted on the light emitting surface of the light emitting element array 500. The

  In the case of the second embodiment, by using the directivity control unit 502, parallax generation based on the directivity of information propagation is realized. For this reason, in the first embodiment, the slit 102 that realizes the directivity of information propagation is eliminated. That is, when such a two-dimensional light emitting element array 500 is used, the slit 102 provided in the exterior body 41 of the rotating unit 104 can be eliminated, and a simple cylindrical shape can be formed.

  Further, the entire exterior body 41 is made of a transparent member, and only the portion where the two-dimensional light emitting element array 500 is visible is made of a transparent member, or the slit 102 is enlarged only where the two-dimensional light emitting element array 500 is visible. It is good also as a structure with the hole opened. That is, the exterior body 41 is configured so that the entire display unit of the two-dimensional light emitting element array 500 can be seen.

  Alternatively, it is possible to eliminate the exterior body 41 itself. However, since the two-dimensional light emitting element array 500 rotates, it is better to provide the exterior body 41 in order to avoid a danger such as a user coming into contact with the rotating two-dimensional light emitting element array 500. In some cases, it is configured as described above.

  Moreover, when the exterior body 41 is comprised with a transparent member, it is not necessary to make the exterior body 41 into the structure rotated. In other words, only the two-dimensional light emitting element array 500 can be rotated. Since the load applied to the motor 52 and the like is reduced to the extent that it is not necessary to rotate the exterior body 41 and the like, power consumption can be reduced.

By rotating the two-dimensional light emitting element array 500, a stereoscopic image can be provided to the user (observer). Please refer to FIG. FIG. 9 illustrates the position where the two-dimensional light emitting element array 500 is located at two times. The position of the two-dimensional light emitting element array 500 at time _{t 0,} the position of the two-dimensional light emitting element array 500 at time _{t 1} is in the positional relationship between a state of being rotated 180 degrees.

At time t _0, the image displayed on the two-dimensional light emitting element array 500 is visible from the viewpoint 551. Thereafter, the two-dimensional light emitting element array 500 is rotated, at time t _1, consisting of the viewpoint 552, the state in which the two-dimensional light emitting element image displayed on the array 500 appear. For example, if the image seen from the viewpoint 551 at the time t ₀ is an image when the car is viewed from the front, it is displayed on the two-dimensional light emitting element array 500 between the time t ₀ and the time t _1. When the image is rewritten, the image that can be seen from the viewpoint 552 at the time t ₁ can be the image when the car is viewed from behind.

In this way, the car can be displayed in three dimensions. Although not shown, if an image of the side of the vehicle is displayed between time t ₀ and time t ₁ , the side of the vehicle can be seen from a predetermined viewpoint. That is, when the user makes a round around the stereoscopic image display device 10, it is possible to provide the user with a stereoscopic image as if it has made a round around the car. To make this possible, it is necessary to switch the display at high speed.

  As shown in FIG. 10A, such a two-dimensional light emitting element array 500 can be configured so that the entire surface can be displayed collectively. In such a case, it is desirable to be able to switch images relatively quickly. As described above, when the image displayed on the two-dimensional light emitting element array 500 is, for example, an image viewed around the car, the image displayed on the two-dimensional light emitting element array 500 is rotated. It is necessary to configure so that it can be switched instantaneously.

  However, when such switching is difficult, as shown in FIG. 10B, one screen may be divided into M blocks, and drawing may be started simultaneously from the beginning of each block. By dividing into M blocks and starting drawing at the beginning of each block, drawing as a whole can be accelerated.

Here, it is assumed that the angular velocity ω, the period T = 2π / ω, the number of viewpoints (number of divisions) = N, and the number of display body pixel divisions H × V. In addition, the display time of one frame for each viewpoint is Tf = T / N
And The period T is
T ≦ 33ms
It is assumed that the value satisfies.

  As shown in FIG. 10A, when the entire screen of the two-dimensional light emitting element array 500 is displayed at once, the display holding time per pixel is Th = Tf. By displaying one frame image for each viewpoint, it is possible to provide a multi-view stereoscopic image that generates a light reproduction type image for each viewpoint.

When the horizontal scanning lines are sequentially displayed, if the scanning time per line is to, and the entire surface is scanned sequentially, the display delay time of the bottom line is
Td = t ₀ × H
It becomes. In order for the display after writing one screen to be distorted, the following conditions must be satisfied.
Td << Tobs = T / N

When it is difficult to satisfy this condition, it can be solved by dividing the block into M blocks as shown in FIG. 10B. That is, to relax this condition with respect to the scanning time, it is effective to divide the scanning line into M blocks and display N in N / M. It and, it is effective to reduce the number of viewpoints N to shorten the scanning time t ₀ per line.

Td = 0.006 × 33 ms when driving a full high-definition LCD television receiver at 240 Hz (to = 1.0 × 10 ⁻⁴ × 33 ms) and driving 600 scanning lines into 10 divisions, Td is 10% of Tobs If the following restrictions are set, N = 16 viewpoints can be set. Further, if the number of scanning line divisions is increased by high-speed driving, the number of viewpoints can be further increased.

  When the two-dimensional light emitting element array 500 is configured using the display body 501 and the directivity control unit 502 as in the second embodiment, the following effects can be expected. First, signal processing is facilitated by using a flat display. That is, when the curved two-dimensional light emitting element array 101 is used as in the first embodiment, signal processing is not performed so that an image is appropriately displayed in consideration of the curved display unit. However, if the two-dimensional light emitting element array 500 is flat (a shape close to a plane), a conventional display format can be applied, and signal processing becomes easy.

  Further, by forming such a two-dimensional light-emitting element array 500, modularization becomes easier than the two-dimensional light-emitting element array 101. In addition, by configuring the two-dimensional light emitting element array 500 in a plane, it is possible to provide an image even when the two-dimensional light emitting element array 500 is not rotated, that is, in a stationary state. In addition, by forming the two-dimensional light emitting element array 500 in a plane, it is possible to provide an image without distortion of peripheral pixels. Further, as described above, the exterior body 41 can be a transparent housing.

[About the third embodiment]
When one screen is divided into M blocks as shown in FIG. 10B, a configuration as shown in FIG. 11 can be adopted. However, although it is divided into M blocks, as in the case shown in FIG. The two-dimensional light emitting element array 600 shown in FIG. 11 is composed of two-dimensional light emitting element arrays 600-1 to 600-M obtained by dividing the two-dimensional light emitting element array 500 into M pieces.

  Although not shown in detail, the two-dimensional light emitting element array 600 shown in FIG. 11 includes a display body 601 and a directivity control unit 602 as in the second embodiment shown in FIG. For example, the two-dimensional light emitting element array 600-1 includes a display body 601-1 and a directivity control unit 602-1. The two-dimensional light emitting element array 600-2 includes a display body 601-2 and a directivity control unit 602. 2 and the two-dimensional light-emitting element array 600-M includes a display body 601-M and a directivity control unit 602-M.

  When the two-dimensional light emitting element array 600 divided into M blocks in this way is viewed from the top (or bottom), it is as shown in FIG. Also in the third embodiment, since the displays constituting each of the two-dimensional light emitting element arrays 600-1 to 600-M are configured in a plane, a liquid crystal display, an organic EL display, or the like already produced is used. Therefore, the cost can be reduced.

  The directivity control unit 602 attached to each two-dimensional light emitting element array 600 controls the image displayed on the attached two-dimensional light emitting element array 600 so that it can be seen only from a predetermined position. Is provided.

  For example, the image displayed on the display body 601-1 can be viewed from the viewpoint 651, but the image displayed on the display body 501 can be viewed from the viewpoint 652 that is shifted from the viewpoint 651 by the angle θ. It becomes impossible. Similarly, only the image displayed on the display body 601-2 can be visually recognized from the viewpoint 652, and only the image displayed on the display body 601-3 can be visually recognized from the viewpoint 653.

  Thus, the two-dimensional light emitting element array 600 is divided into a plurality (M) of blocks, and each block (two-dimensional light emitting element arrays 600-1 to 600-M) is arranged with a predetermined angle. ing.

  Such a two-dimensional light emitting element array 600 is connected to the connection substrate 11 instead of the two-dimensional light emitting element array 101 (not shown). By being connected to the connection substrate 11, the two-dimensional light emitting element array 600 is configured to rotate about the rotation shaft 103. As in the second embodiment, viewpoint generation is realized by rotation, and the directivity control unit 602 is used to realize parallax generation based on the directivity of information propagation. Therefore, in this case as well, as in the second embodiment, the exterior body 41 does not need the slit 102, and the slit 102 is not provided.

  Further, the entire exterior body 41 is formed of a transparent member, and the hole is formed of a transparent member only in a portion where the two-dimensional light emitting element array 600 is visible, or has a slit 102 enlarged only in a portion where the two-dimensional light emitting element array 600 is visible It is also possible to adopt a configuration in which is open. That is, the exterior body 41 may be configured so that the entire display unit of the two-dimensional light emitting element array 600 can be seen.

  Refer to FIG. 12 again. At the viewpoint 651, the image displayed on the two-dimensional light emitting element array 600-1 is visible. Since the two-dimensional light emitting element array 600 is rotating, at the same viewpoint 651, the image displayed on the two-dimensional light emitting element array 600-2 can be seen at the next time point. Further, at the next time, the image displayed on the two-dimensional light emitting element array 600-3 is in a state of being visible.

  As described above, the images viewed from the same viewpoint are configured so that the images sequentially presented from the two-dimensional light-emitting element array 600-1 to the two-dimensional light-emitting element array 600-M become one image. By using the afterimage, even if the image is supplied at a different time, it will appear to the user as a single picture. In this way, when an afterimage is used to provide a single image to the user, the following conditions must be satisfied.

  First, when the two-dimensional light-emitting element array 600 is divided into M blocks, θ = 2π / N is satisfied as a spiral angle constraint condition from the viewpoint. That is, the angle formed between the adjacent two-dimensional light emitting element arrays 600 is an angle satisfying this θ.

When horizontal block scanning is performed by the spiral display, one frame time is longer than the block display. The horizontal block display time is
Tb = T / N
1 frame display time is
Tf = Tb × M = TM / N
And the period T is
T ≦ 33ms
It is assumed that the value satisfies.

  When the entire screen of the two-dimensional light emitting element array 600 is displayed at once, the display holding time per pixel is Th = Tb. By displaying one frame image for each viewpoint, it is possible to provide a multi-view stereoscopic image that generates a light reproduction type image for each viewpoint.

When displaying sequentially with horizontal scanning lines in a horizontal block, assuming that the scanning time per line is to, when the entire surface is scanned sequentially, the display delay time of the bottom line is
Td = t ₀ × H / M
It becomes. In order for the display after writing one screen to be distorted, the following conditions must be satisfied.
Td << Tobs = T / (NM)
Since this restriction is equivalent to the above-described second embodiment, multi-viewpoint image display is possible as in the second embodiment.

  When the two-dimensional light-emitting element array 600 is configured using the display body 601 and the directivity control unit 602 as in the third embodiment and divided into M blocks, the following effects can be expected. First, signal processing is facilitated by using a flat display body. Further, it is possible to disperse the light emission luminance to the periphery.

  In addition, as shown in FIG. 11, when the two-dimensional light emitting element arrays 600-1 to 600-M are arranged by being shifted by a predetermined angle, as shown in FIG. Compared to the three-dimensional light emitting element array 500, it is difficult to receive wind resistance. Since the two-dimensional light emitting element array 600 is rotated within the exterior body 41, it is likely to receive air resistance. Therefore, since the resistance can be reduced by adopting a configuration that is difficult to receive air resistance, the power of the motor 52 for rotation can be weakened, and the power can be reduced.

  Further, since the two-dimensional light emitting element array 600 includes M two-dimensional light emitting element arrays 600-1 to 600-M, one of the two-dimensional light emitting element arrays 600, for example, two-dimensional light emitting elements array 600 is assumed. Even if the light emitting element array 600-1 is broken, the two-dimensional light emitting element array 600 can be continuously used by replacing only the two-dimensional light emitting element array 600-1. That is, it becomes possible to easily replace a defective module.

[About the fourth embodiment]
Next, as a fourth embodiment, a configuration of a two-dimensional light emitting element array that improves resolution will be described. FIG. 13 is a diagram showing a configuration of a two-dimensional light emitting element array in the fourth embodiment. The two-dimensional light emitting element array shown in FIG. 14 includes a two-dimensional light emitting element array 700-1, a two-dimensional light emitting element array 700-2, and a two-dimensional light emitting element array 700-3. Here, the description is continued by taking an example in which three two-dimensional light emitting element arrays are arranged, but three or more two-dimensional light emitting element arrays may be arranged.

  When three two-dimensional light emitting element arrays 700 are arranged, a triangle is formed by the arranged two-dimensional light emitting element arrays 700 as shown in FIG. Thus, each two-dimensional light-emitting element array 700 of the plurality of two-dimensional light-emitting element arrays 700 is installed in a different direction.

  One two-dimensional light emitting element array 700, for example, the two-dimensional light emitting element array 700-1, can have the same configuration as the two-dimensional light emitting element array 500 shown in FIG. That is, the two-dimensional light emitting element array 700 includes a display body 701 and a directivity control unit 702.

  Further, these three two-dimensional light emitting element arrays 700-1 to 700-3 are provided in the exterior body 41 so as to be rotated about the rotation shaft 103 as a rotation axis. The exterior body 41 is composed of a transparent casing. With this configuration, an image displayed on the two-dimensional light emitting element array 700-1 can be seen from the viewpoint 751, and an image displayed on the two-dimensional light emitting element array 700-2 from the viewpoint 752. From the viewpoint 753, the image displayed on the two-dimensional light emitting element array 700-3 can be seen.

  When the two-dimensional light emitting element array 700 is viewed from the viewpoint 751, first, an image displayed on the two-dimensional light emitting element array 700-1 is seen, and at the next time point, the two-dimensional light emitting element array 700-2 is viewed. The displayed image can be seen, and further, the image displayed on the two-dimensional light emitting element array 700-3 can be seen at the next time point. In this case, an image is displayed on each of the two-dimensional light emitting element arrays 700-1 to 700-3 at a timing as shown in FIG. 14, and an image as shown in FIG. 15 is provided to the user.

  Reference is first made to FIG. A part of the assigned image is displayed in the order of IMG1a, IMG2a, IMG3a,... From the drawing start line of the two-dimensional light emitting element array 700-1. When the time has elapsed by T / 3, a part of the assigned image is displayed in the order of IMG1b, IMG2b, IMG3b,... From the drawing start line of the two-dimensional light emitting element array 700-2. T represents the rotation period. Further, here, it is equivalent to the time until one completed image (image provided by the two-dimensional light emitting element arrays 700-1 to 700-3) is provided to the user.

  When the time further passes by T / 3, a part of the assigned image is displayed in the order of IMG1c, IMG2c, IMG3c,... From the drawing start line of the two-dimensional light emitting element array 700-3. By performing such display, first, IMG1a, IMG2a, IMG3a,... Displayed on the two-dimensional light emitting element array 700-1 are provided to the user located at the viewpoint 751, and T / 3 time has elapsed. Later, IMG1b, IMG2b, IMG3b,... Displayed on the two-dimensional light emitting element array 700-2 are provided, and IMG1c, IMG2c displayed on the two-dimensional light emitting element array 700-3 after a lapse of T / 3 hours. , IMG3c,... Is provided to provide one image.

  That is, one image is provided in a state divided into three times. Referring to FIG. 15, line a-1 displays an image corresponding to IMG1a, line b-1 displays an image corresponding to IMG1b, and line c-1 displays an image corresponding to IMG1c. To do. Similarly, line a-2 displays an image corresponding to IMG2a, line b-2 displays an image corresponding to IMG2b, and line c-2 displays an image corresponding to IMG2c. Thus, IMG1b is displayed on the line b-1 next to the line a-1 on which IMG1a is displayed, and IMG1c is displayed on the line c-1 next to the line b-1 on which IMG1b is displayed. .

  In this manner, the images displayed on the two-dimensional light emitting element array 700-2 and the two-dimensional light emitting element array 700-3 are interpolated between the images displayed on the two-dimensional light emitting element array 700-1. In other words, the two-dimensional light emitting element arrays 700-1 to 700-3 are each configured to display 1/3 of one image. By displaying one image on the plurality of two-dimensional light emitting element arrays 700, the resolution can be improved.

  In this manner, L (three in the above example) two-dimensional light emitting element arrays 700 are arranged on the rotation axis object, and the resolution is 1 corresponding to one image for each T / L with respect to the rotation period T. The resolution can be improved by sequentially displaying the thinned image of / L with respect to a predetermined viewpoint while shifting the pixels.

  Also in the fourth embodiment, since the two-dimensional light emitting element array 700 is configured by the display body 701 and the directivity control unit 702 as in the second embodiment, the signal is the same as in the second embodiment. Effects such as easy processing, modularization, 2D display even in a stationary state, no peripheral pixel distortion, and the use of a transparent housing can be expected. Furthermore, according to the fourth embodiment, the resolution can be improved.

[About the fifth embodiment]
Next, a fifth embodiment will be described. According to the fifth embodiment, for example, it is possible to use a two-dimensional light emitting element array that takes time (scanning time) to display an image. As described above, for example, in order to show different images from a plurality of viewpoints, it is necessary to switch images displayed for each viewpoint. To realize such switching, two-dimensional A certain level of performance is required for the configuration of the light emitting element array and the control unit for controlling the display thereof.

  An embodiment for enabling an image to be provided on the entire periphery even if a two-dimensional light emitting element array that cannot provide such performance will be described. FIG. 16 is a diagram showing a configuration of a two-dimensional light emitting element array in the fifth embodiment. The two-dimensional light emitting element array 800 shown in FIG. 16 has the same configuration as the two-dimensional light emitting element array 500 in the second embodiment. In the fifth embodiment, the exterior body 41 is configured to have a light shielding portion 831 as shown in FIG.

  The exterior body 41 does not rotate, and the two-dimensional light emitting element array 800 is configured to rotate within the exterior body 41. The portions other than the light shielding portion 831 of the exterior body 41 are configured by a transparent member or the like, and are configured so that an image displayed on the two-dimensional light emitting element array 800 can be seen. Alternatively, only the light shielding portion 831 is provided as the exterior body 41. The light shielding portion 831 is configured such that an image displayed on the two-dimensional light emitting element array 800 is not visible. The light shielding portion 831 is provided so that the light emitting surface of the two-dimensional light emitting element array 800 is not shown to the user during the time for rewriting the display of the two-dimensional light emitting element array 800.

  The display of the two-dimensional light emitting element array 800 is switched from when the two-dimensional light emitting element array 800 is hidden by the light shielding part 831, and the two-dimensional light emitting element array 800 is output from the light shielding part 831. When the two-dimensional light emitting element array 800 is visible, all the rewriting of the image is completed and the image is displayed on the two-dimensional light emitting element array 800. In this way, even when the two-dimensional light emitting element array 800 takes a long time for rewriting by making the two-dimensional light emitting element array 800 invisible to the user during the rewriting time, the user is in the middle of rewriting. It is possible to provide an image without showing the image.

  Since the exterior body 41 shown in FIG. 16 has one light-shielding portion 831, it corresponds to one rewrite. In order to cope with a plurality of rewrites, a plurality of light shielding portions 831 can be provided. As described above, by providing the light shielding portion 831, light can be shielded during the blanking period until the writing of one image signal is completed, and a good image is displayed by performing such light shielding. It becomes possible to do.

  Further, the writing time may be obtained by another method in which the exterior body 41 is not provided with the light shielding portion 831. FIG. 17 is a diagram for explaining a case where the writing time can be obtained by turning on / off the backlight. When the two-dimensional light emitting element array 800 is configured by a display element such as a liquid crystal and is provided with a backlight, the writing time of the two-dimensional light emitting element array 800 can be obtained by turning on and off the backlight.

  In FIG. 17, the upper row shows the image writing rate, and the lower row shows the light source luminance. Only when the image writing rate is 100%, it can be read that the backlight is turned on (the high original luminance is 100%). In the figure, T is the rotation period. During one round, the image writing rate has a time for changing from 0 to 100% and a time for maintaining 100%. While changing from 0 to 100%, the light source luminance is 0%, that is, the backlight is turned off, so that the user can visually recognize the image being written to the two-dimensional light emitting element array 800. Can not.

  While the writing rate becomes 100% and the state is maintained, the light source luminance is 100%, that is, the backlight is turned on, so that the user writes to the two-dimensional light emitting element array 800. The image can be visually recognized.

  In this way, by controlling on / off of the backlight of the liquid crystal display element or the like, light can be shielded during the time (blank period) until the writing of one image signal is completed. It is possible to display a good image by performing light shielding.

[Directivity control unit]
FIG. 18 is an enlarged view of the display body 501 and the directivity control unit 502. The display body 501 and the directivity control unit 502, the display body 601 and the directivity control unit 602, the display body 701 and the directivity control unit 702, and the display body 801 and the directivity control unit 802 are the same. A description will be given by taking 501 and the directivity control unit 502 as examples.

  The display body 501 is composed of R (Red), G (Green), and B (Blue) pixels. As shown in FIG. 19, the directivity control unit 502 includes a vertical slit provided so as to partition adjacent pixels. By forming the light blocking barriers vertically in a row from the display portion of the display body 501 to the front, directivity having a limited spread in the normal direction of the display portion can be provided.

  As the barrier cross-sectional shape of the directivity control unit 502, a flat structure can be applied, but a parabola or elliptical arc shape with a focus on the display pixel center of the display body 501 can also be applied like a lamp reflector. For example, when the intensity distribution of directivity of the directivity control unit 502 is illustrated, the directivity control unit 502 is configured to have directivity that maximizes the intensity in a very narrow angle range as shown in FIG. Is done.

  Such directivity control unit 502 is formed of a resin material or the like directly on the display body of the display body 501 or on a transparent substrate. In addition, the directivity control unit 502 may be configured so that transmission windows having a pitch different from that of the pixel array are arranged above the barrier so as to focus on a specific viewpoint.

  Furthermore, since the directivity control unit 502 is provided to control the direction of the emitted light with the light shielding function, the barrier of the directivity control unit 502 is set in the vertical direction parallel to the display unit of the display body 501 as shown in FIG. It is also possible to adopt a configuration in which a plurality of layers of light shielding regions are combined and replaced. That is, as shown in FIG. 21, by providing two upper and lower light shielding regions on the display body 501 at a pitch different from the pixel arrangement, the direction of the emitted light can be controlled with respect to a specific viewpoint.

  Furthermore, a directional film may be used as shown in FIG. This directional film has a directional intensity distribution as shown in FIG. The polar angle in the intensity distribution shown in FIG. 23 is wider than the intensity distribution shown in FIG. Therefore, although the directivity is low in accuracy, it can be used as the directivity control unit 502 when it may be configured simply.

  In this way, what kind of structure is used as the directivity control unit 502 is determined in consideration of various factors such as the relationship with the display body 501 and the degree of accuracy required. Is done. Further, the directivity control unit 502 given as an example here is an example, and the description is not limited to only these descriptions.

[About the sixth embodiment]
Next, a sixth embodiment will be described. FIG. 24 is a diagram showing a configuration of a two-dimensional light emitting element array in the sixth embodiment. Also in the sixth embodiment, the two-dimensional light emitting element array 900 is configured by a combination of the display body 901 and the directivity control unit 902. As shown in FIG. 24, four images for four viewpoints such as IMG1, IMG2, IMG3, and IMG4 are displayed on the display body 901 and combined with the directivity control unit 902, so that it can stand still in multiple directions. It is comprised so that the directivity of a light beam can be provided.

  When the two-dimensional light-emitting element array 900 is in a stationary state, IMG1 displayed on the display body 901 can be seen from the viewpoint 951, IMG2 displayed on the display body 901 can be seen from the viewpoint 952, and from the viewpoint 953, The IMG 3 displayed on the display body 901 can be seen, and the IMG 4 displayed on the display body 901 can be seen from the viewpoint 954.

  By rotating such a two-dimensional light emitting element array 900, it is possible to generate viewpoints in the surroundings. FIG. 25 is a diagram for explaining an image (IMG) that can be seen at each viewpoint when the two-dimensional light emitting element array 900 is rotated. When the two-dimensional light emitting element array 900 is located at the position A, the viewpoint 951 is in a state where IMG1 is visible, the viewpoint 952 is in a state where IMG2 is visible, and the viewpoint 953 is in a state where IMG3 is visible, At the viewpoint 954, IMG4 is visible.

  When the two-dimensional light emitting element array 900 is rotated and positioned at position B, IMG1 can be seen at viewpoint 952, IMG2 can be seen at viewpoint 953, IMG3 can be seen at viewpoint 954, and viewpoint 955 can be seen. IMG4 is visible. Further, when the two-dimensional light emitting element array 900 is rotated and positioned at position C, IMG1 can be seen at viewpoint 953, IMG2 can be seen at viewpoint 954, and IMG3 can be seen at viewpoint 955. At 956, IMG4 is visible.

  Thus, by rotating, an image displayed on the two-dimensional light emitting element array 900 is sequentially provided for each viewpoint. For example, in the viewpoint 954, IMG4 is provided when the two-dimensional light emitting element array 900 is located at the position A, and then IMG3 is provided because the two-dimensional light emitting element array 900 is located at the position B. . Further, at the next time, since the two-dimensional light emitting element array 900 is located at the position C, IMG2 is provided, and at the next time, the two-dimensional light emitting element array 900 is located at the position D, so that IMG1 is provided. The As described above, at a predetermined viewpoint, images corresponding to directions are sequentially provided to the user.

  Even in such a two-dimensional light emitting element array 900, it is not possible to secure the image rewriting time or to use the above-described directivity control unit by using the light shielding portion 831 described as the fifth embodiment. Is possible. Further, instead of providing directivity by shading, a configuration in which refraction, that is, directivity is provided using, for example, a lens may be used.

  By applying the above-described embodiment, there is a limitation depending on the embodiment, but it is possible to view an image displayed on the two-dimensional light emitting element array from any position of approximately 360 degrees. In addition, the images may be different images depending on the viewing position, or may be the same image. By using different images, different information can be provided to a plurality of viewpoints, and by using the same image, it is possible to view the same information from a plurality of viewpoints.

  When different images are used, for example, the entire shape of a product such as a car can be shown, and even if the user cannot see the actual product, it is easier to grasp the image of the product and improve the advertising effect. It becomes possible to make it. In addition, even if the images are the same, images can be provided and advertised in multiple directions at almost the same timing, so that they can be differentiated from other advertisements and can be advertised efficiently. It becomes possible.

  The embodiments of the present technology are not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present technology.

  In addition, this technique can also take the following structures.

(1)
A rotating part having a rotating shaft;
A drive unit that rotates the rotating unit around the rotation axis;
A display unit attached to the rotating unit and provided with a plurality of display elements;
A directional member that controls the direction of light emitted from the display element is attached to the display unit.
(2)
The display device according to (1), wherein the directional member blocks light from a direction other than a predetermined direction from the display element.
(3)
The display unit has a plurality of blocks,
The display device according to (1), wherein in each of the blocks, the display element is line-sequentially driven.
(4)
The display unit has a plurality of blocks,
The display device according to (1), wherein each of the blocks is arranged with a predetermined angle.
(5)
The display unit has a plurality of blocks,
The display device according to (1), wherein one image is formed from an image provided in each of the plurality of blocks.
(6)
It further includes an exterior body that is arranged outside the display unit and does not rotate,
The exterior body includes a light shielding portion that shields light from the display portion,
The display device according to any one of (1) to (5), wherein display of the display unit is switched while being blocked by the light blocking unit.
(7)
The display device according to any one of (1) to (5), wherein the display unit is controlled not to emit light during display switching in the display unit.
(8)
The display device according to any one of (1) to (7), wherein the display unit provides different images in a plurality of directions.
(9)
The directional member is formed in a predetermined shape with the center of the display element as a focal point, is formed in a vertical row, and has a shape that restricts the direction of light emitted from the display element (1) Thru | or the display apparatus in any one of (8).
(10)
The display device according to any one of (1) to (8), wherein the directional member has a shape in which light shielding regions having different pitches are provided across a plurality of layers in each layer.

  500 two-dimensional light emitting element array, 501 display body, 502 directivity control unit, 600 two-dimensional light emitting element array, 601 display body, 602 directivity control unit, 700 two-dimensional light emitting element array, 701 display body, 702 directivity control unit , 800 two-dimensional light emitting element array, 801 display body, 802 directivity control unit, 831 partial light shielding, 900 two-dimensional light emitting element array, 901 display body, 902 directivity control unit

Claims (10)

A rotating part having a rotating shaft;
A drive unit that rotates the rotating unit around the rotation axis;
A display unit attached to the rotating unit and provided with a plurality of display elements;
A directional member that controls the direction of light emitted from the display element is attached to the display unit. The display device according to claim 1, wherein the directional member blocks light from a direction other than a predetermined direction from the display element. The display unit has a plurality of blocks,
The display device according to claim 1, wherein the display element is line-sequentially driven in each block. The display unit has a plurality of blocks,
The display device according to claim 1, wherein each of the blocks is arranged with a predetermined angle. The display unit has a plurality of blocks,
The display device according to claim 1, wherein one image is formed from images provided in each of the plurality of blocks. It further includes an exterior body that is arranged outside the display unit and does not rotate,
The exterior body includes a light shielding portion that shields light from the display portion,
The display device according to claim 1, wherein display of the display unit is switched while being blocked by the light blocking unit. The display device according to claim 1, wherein the display unit is controlled not to emit light during display switching in the display unit. The display device according to claim 1, wherein the display unit provides different images in a plurality of directions. The directional member is formed in a predetermined shape with the center of the display element as a focal point, is formed in a vertical row, and has a shape that restricts the direction of light emitted from the display element. The display device described. The display device according to claim 1, wherein the directional member has a shape in which light shielding regions having different pitches are provided across a plurality of layers in each layer.

Images