KR20050088768A - A three-dimensional volumetric display device using rotation of light-emitting plates - Google Patents

Abstract

The present invention relates to a three-dimensional stereoscopic image output device using a rotating signboard, wherein the light emitting device is arranged and rotated on one surface, and rotated, and at this time, the three-dimensional image is cross-sectional and the position of the pixel of each cross-sectional image An image display controller which wirelessly receives data processed corresponding to an arrangement position, sequentially emits the corresponding light emitting element corresponding to the position of each pixel of each cross-sectional image, and detects the rotational speed of the display panel on a constant speed rotation of the display panel. On the basis of this it is characterized in that it comprises a rotation speed controller for adjusting the drive speed of the drive means of the sign. At this time, the external device (for example, computer) video signal adopts the structure of video signal transmitter and video signal receiver that transmits / receives wirelessly using infrared wireless communication or WIFI communication protocol communication method. A ball bearing is included to compensate for the rotational imbalance of the signboard. Therefore, it can display a three-dimensional texture without a separate optical device, and can be utilized as a variety of display devices from desktop format to large outdoor advertisement output.

Description

A Three-dimensional Volumetric Display Device Using Rotation Of Light-Emitting Plates}

The present invention relates to an image output apparatus, and more particularly, to a three-dimensional display using a rotating display board that can display a three-dimensional image by using the afterimage effect formed on the naked eye by rotating the display board for outputting a two-dimensional image. A stereoscopic image output device.

In general, three-dimensional stereoscopic images have been implemented through flat display devices, that is, structurally two-dimensional display devices. For example, the vertical pixel of a flat panel monitor is divided by an interlaced pattern for the right field of view and the left field of view, and then projected to each field of view using glasses or lenticular lenses made according to the refresh rate of the monitor. How to do is commercialized.

However, providing a three-dimensional image in such a manner is that in view of the first two-dimensional visualization method, there is a disadvantage in that it is not possible to provide a viewpoint of more than 180 degrees with respect to the plane.

In addition to these methods, holographic displays using laser light have been developed. Such a holographic display device pursues a stereoscopic image of an object to be displayed using characteristics of a laser beam, but the visible region has a disadvantage that it is limited to a two-dimensional plane like the conventional method mentioned above.

Accordingly, in order to realize a substantially volumetric image, a direct volume display (direct volume display) began to be conceptualized from late 1950 to early 1960.

Such direct volume image output is a method of encoding volume information on a flat screen or a light source and rotating the screen by the afterimage of the object, as if the light beam of the object is perceived from the volume. For example, U.S. Patent No. 2,967,905 (Hirsch, 1961) and U.S. Patent No. 3,140,415 (Ketchpel, 1964) use a method of directly injecting an electron beam of a Cathode Ray Tube onto a screen that rotates at high speed. Image output is implemented.

 In addition, a direct volume image output device capable of moving images using a high speed laser scanner and an LCD projector has been developed. For example, US Pat. Nos. 5,042,909 and 4,871,231 (Garcia et al.), US Pat. No. 5,854,613 (Soltan et al. 1998, US Pat. No. 5,148,310 (Batchko et al., 1992) and US Pat. No. 4,943,851 (Lang et al., 1990).

However, in the above-described inventions, since the number of pixels and the implementation color are limited by the color of the laser and the speed of the scanner, it has a disadvantage in that it cannot output a plurality of colors or more than 24 inches of images.

In addition, the above-described inventions have an operating structure based on image projection, and thus, there is a big disadvantage that the image cannot be implemented in the outdoor or sunlight with sunlight.

Meanwhile, due to the development of semiconductor / laser related technologies, solid-state (Downing et al. 1996, Kim et al. 1996; Leung et al. US Patent No. 5,745,197: published in 1998), Gas-state (Rowe et al., a volumetric image output device of US Pat. No. 4,063,233, 1977; Korevaar et al. US Pat. No. 4,881,068: published in 1989, is inadequate for commercialization in terms of image quality, but is still limited to experimental stages. It is becoming.

In addition, U.S. Patent No. 4,160,973 (Berlin et al., 1979) introduced a method of realizing a three-dimensional image by rotating the flat display device itself, which lacks an area of the display screen (planar structure constituting half of the rotation axis). ), The type of the light source, the data bandwidth, the response speed of the light source, the use of the controller is not enough to be practically used.

Accordingly, the present invention has been made in view of the above-described conventional problems, and a first object of the present invention is to adopt an electric display plate including a light emitting element of a high brightness organic / inorganic material, and to form a cross section of an object to be displayed. It is to provide a three-dimensional stereoscopic image output device using a rotation of an electric signboard having a structure for sequentially emitting and operating the light emitting device in correspondence with the position of the pixel distributed on the cross section of the object while rotating at the same time.

In addition, a second object of the present invention is to adopt a structure that intersects / arranges a plurality of signboards at the center of rotation, so that a three-dimensional stereoscopic image output apparatus using a signboard rotation capable of increasing the data bandwidth required for animation output by more than two times. To provide.

Objects of the present invention, a plurality of light emitting devices are arranged on one surface, the electric light plate is arranged upright; A main shaft connected across the center of the display board in the height direction; Driving means connected to the lower part of the main shaft so that the electric signboard can be rotated about the main shaft; An image signal transmitter which cross-sections a three-dimensional image and wirelessly transmits, as a signal, data processed by a pixel position of each cross-sectional image corresponding to each light emitting element array position; A video signal receiver wirelessly connected to the video signal transmitter to wirelessly receive each video signal; An encoder electrically connected to the video signal receiver to convert the video signal according to the light emitting code of the light emitting device; An image display controller electrically connected to the encoder and configured to sequentially emit light of a corresponding light emitting element corresponding to the position of each pixel of the cross-sectional image; A rotational speed controller electrically connected to a driving means to control the rotational speed of the signboard with a predetermined reference rotational speed so that the signboard is rotated at a constant rotational speed; And sensing means electrically connected to the rotational speed controller to transmit the sensed rotational speed data of the signboard to the rotational speed controller.

Here, the image signal receiver, the encoder, and the image display controller have a size corresponding to the rotation radius of the display board so as to be able to rotate together with the display board. It is preferable that the lower rotation plate is disposed on the coupled to the main shaft, the image signal receiver, the encoder and the image display controller is installed on the upper surface.

In addition, the video signal receiver, the encoder, and the image display controller may be divided into a plurality of circuits so that the rotational balance of each rotating plate and the electronic display plate is maintained, and symmetrically disposed about the center of rotation of the main shaft on the upper surface of the lower rotating plate.

The sensing means may also include a rotational reference optical beam irradiator which irradiates an optical beam to a plurality of rotational position optical sensors and optical sensors arranged symmetrically on an upper surface of the lower rotating plate and is synchronized with each other and electrically connected to the rotational speed controller. desirable.

In addition, the driving means is preferably an electric motor having a brushless structure.

The video signal transmitter and the video signal receiver preferably have a communication structure using any one of an infrared communication and a WIFI communication protocol.

In addition, it is preferable that an annular correction plate including a fluid flowing in accordance with movement for correction of rotational imbalance is further provided by being coupled to the main shaft to the lower portion of the lower rotation plate so that rotational balance of each rotation plate and the electric sign is maintained.

Here, a slip ring connected to an external power source and electrically connected to the driving means, the image signal receiver, the image display controller, and the encoder is provided at the outer circumference of the main shaft to supply power to the driving means, the image signal receiver, the image display controller, and the encoder. It is preferred to be provided.

In addition, it is preferable that a transparent protective film having a size corresponding to the corresponding radius of rotation is further installed so as to isolate the electric sign, the upper rotating plate, and the lower rotating plate from the outside.

In addition, a plurality of electronic signs 100 may be provided, and the plurality of electronic signs 100 may be driven independently of each other.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

Hereinafter, a 3D stereoscopic image output apparatus using a signboard rotation according to the present invention will be described with reference to the accompanying drawings.

1 is a configuration diagram of a 3D stereoscopic image output apparatus 1000 using a signboard rotation according to a first embodiment of the present invention. As illustrated in FIG. 1, the image output apparatus 1000 according to the present invention divides image data of an object to be displayed into a plurality of cross-sectional image data based on a cylindrical coordinate system, and positions pixels of the cross-sectional image data. A device capable of outputting / displaying a 3D image of a corresponding object while rotating the LED panel 100 with the corresponding light emission of each LED 110 corresponding to the position of the LEDs 110 arranged on the LED panel 100. to be.

To this end, the image output apparatus 1000 according to the present invention includes a rotation structure of the electronic display panel 100, a cross-sectional image output structure of the electronic display panel 100, and a control structure that controls the rotation and the image output of the electronic display panel 100. do. Here, the electronic display panel 100 has a quadrangular shape, and a plurality of light emitting elements 110 are arranged on the surface thereof. The surface of the light emitting plate 100 is matte black in order not to deteriorate the emission color of each light emitting device 110.

As the rotating structure of the electric sign 100, the main shaft 310 is connected to the center of the electric sign 100 in the height direction and axially coupled to the lower end of the main shaft 310 by the drive means and settled / fixed on the base 320 The electric motor 300 is disposed. At this time, it is preferable to use a brushless type electric motor 300 having a low torque and low driving noise since noise due to rotation is not required and rapid rotation is not required for image output.

In addition, the upper rotating plate 210 is disposed below the electronic display plate 100, and the lower rotating plate 220 is disposed below the upper rotating plate 210. Each of the rotating plates 210 and 220 is a disk structure having a radius corresponding to the radius of rotation of the light emitting plate 100, and the lower rotating plate 220 is disposed at a predetermined height difference from the upper rotating plate 210, and each of the rotating plates 210 and 220 has a main shaft. It is coupled to the 310 has a structure that is rotated together with the electronic sign 100.

In addition, as an image output structure of the electronic sign 100, an image signal transmitter 410 that receives image data from an external device (for example, a computer, etc.) (not shown) in which image data is stored and wirelessly transmits the image data as an image signal, and the corresponding image. An image signal receiver 420 is provided for wirelessly receiving a signal and transmitting the signal to the light emitting device 110. In this case, the video signal transmitter 410 is electrically connected to an external device (for example, a computer, etc.) in which video data is stored, and the video signal receiver 420 is installed on the upper surface of the lower rotating plate 220. Through the receiver 420, the light emitting device 110 of the electronic display panel 100 is provided to emit light based on the image signal, and in this case, the lower rotating plate (divided into a plurality of circuits for the rotational balance of the lower rotating plate 220) It is arranged symmetrically on the upper surface of 220). The wireless transmission / reception between the video signal transmitter 410 and the video signal receiver 420 is preferably an infrared communication method or a WIFI communication protocol method.

In addition, in order to control the image output, the image display receiver 500 is connected to the image display controller 500. The image display controller 500 is installed on the upper surface of the lower rotating plate 220 and is connected to the light emitting device 110 by an image signal transmission line 110a. The encoder 510 is connected to convert an external video signal according to the light emitting code of the light emitting device 110. As a result, an electrically control structure in which the light emitting device 110 may emit light is provided based on an external video signal, that is, 3D image data or animation sequence data.

However, as mentioned above, in order to balance the rotation of the upper rotating plate 210 and the electronic display plate 100 including the lower rotating plate 220, the image display controller 500 and the encoder 510 are divided into a plurality of circuits. Each of the image display controllers 500 and the encoders 510 divided as described above are disposed symmetrically on the upper surface of the lower rotating plate 220 so as to face each other. In this case, each image signal receiver 420 is symmetrically disposed outside the arrangement region of the image display controller 500 and the encoder 510.

In addition, the rotation speed controller 600 is provided to control the rotation of the electronic display plate 100. Rotational speed controller 600 is connected to the sensing means to measure the rotational speed of the electric sign 100, and to adjust the driving speed of the electric motor 300 based on this. As the sensing means, a rotational reference optical beam irradiator 620 having an operating structure synchronized with each other and a rotation position optical sensor 610 for receiving / detecting the optical beam of the rotational reference optical beam irradiator 620 are provided.

The rotational position optical sensor 610 is electrically connected to the rotational speed controller 600, and the rotational reference optical beam irradiator 620 is installed on the upper surface of the lower rotating plate 220 in the outer circumferential direction so as to rotate the optical position sensor 610. Optically corresponding to the rotational speed controller 600 provides a structure capable of measuring the rotational speed of the upper rotating plate 210 and the electronic display plate 100, including the lower rotating plate 220.

And the rotational speed controller 600 is connected to the electric motor 300 to measure the rotational speed and to adjust the driving speed of the electric motor 300 based on this. The rotation speed controller 600 is set as the reference rotation speed. And comparing the reference rotational speed with the reference rotational speed, and if the reference rotational speed is exceeded by reducing the drive speed of the electric motor 300, if less than the reference rotational speed by increasing the drive speed of the electric motor 300, 100) is always provided a structure that can run at a constant speed at a constant speed.

In addition, a slip ring 700 is installed at the outer circumference of the main shaft 310 to supply power to each controller, the image signal receiver 420, and the encoder 510 including each light emitting device 110 of the electronic display panel 100. . In addition, in order to isolate the electric sign 100 and the upper rotating plate 210 and the lower rotating plate 220 which rotate together with the outside, a transparent protective film 230 having a size corresponding to the corresponding radius of rotation is installed.

2 is a conceptual diagram illustrating a spatial operation principle of the output device 1000 illustrated in FIG. 1, and FIG. 3 is a conceptual diagram illustrating a temporal operation principle of the output apparatus 1000 illustrated in FIG. 1. First, as illustrated in FIG. 2, a cylindrical object is displayed in the polar coordinate system and the rectangular coordinate system. The object displayed in this way may be displayed in the cylindrical coordinate system shown on the right side of the rectangular coordinate system.

In this case, if there is a cylindrical object in the display area of the cylindrical coordinate system, dividing the space including the same in the circumferential direction k, the angle resolution pixel (Anglur Resolution) = 360 / k degrees. In the present invention, the case where the number of decomposition pixels is at least k = 200 is used, and θ is 2.4 °. At this time, if the planar pixels of the cross section of the object are m and n in the rectangular coordinate system, the volume in the cylindrical coordinate system may be expressed by the number of pixels of m × n × k = 200 × 200 × 200 = 8 × 10 ⁶ .

In general, since a three-dimensional object is represented in a three-dimensional rectangular coordinate system, it can be converted from a rectangular coordinate system to a cylindrical coordinate system using a mathematical algorithm such as Binear Interpolation.

As shown in FIG. 3, τ = 1 / f indicated as the rotation period of the electronic display panel 100. If the rotation speed f is 20 Hz, τ = 50 msec.

In order to reproduce the object presented as an example, when the position of the electric light plate 100 reaches φ as shown in FIG. 2, the image front surface corresponding to the cross section of the object is output. Due to the characteristics of the electronic sign 100, the image can be output only on one side. When the image arrives at the half phase φ + π, the image is output again to the plane corresponding to the object to form the rear side of the image. . The image of the object shown in FIG. 3 shows an image output method in time when k = 8 in FIG. 2.

4 is an exploded view illustrating the internal coupling relationship of the output device illustrated in FIG. 1, and FIGS. 5A and 5B are partially enlarged views illustrating an arrangement relationship of light emitting devices in the electronic display panel shown in FIG. 4. As shown in FIGS. 4, 5A, and 5B, the electronic display panel 100 is provided with a high luminance RGB light emitting device 110.

More preferably, it is possible to use an organic material light emitting device 110 by using the one that can output light evenly in the plane of 180 ° angle. In the present invention, a six-chip full spectrum high power RGB LED including both an RGB light emitting element 110 and a diffusion lens is used. In addition, it is possible to use the light emitting device 110 of the small (e.g., 5.5mm aperture) to large (10mm or larger aperture) of the visible region of more than 160 °, and the high-intensity LED used in jumbotron for large output 110).

At this time, the electroluminescent plate 100 is preferably matte black in order not to damage the light emitting color of the light emitting device (110). This also minimizes the reflection of external light by the electronic sign.

The arrangement of the light emitting device 110 may be closely arranged in a vertical / horizontal manner as in FIG. 5A, and in addition, as in FIG. 5B, in order to solve air resistance caused by the rotation of the light emitting plate 100. Columns can be arranged closely, and in the area corresponding to the horizontal column, an arrangement structure can be used in which an empty space is placed between each vertical column. In addition, the rotary structure is isolated from the outside by the protective film 230, it is possible to lower the air pressure inside the protective film 230 using an air pump (not shown).

In addition, the lower part of the lower rotating plate 220 is a position supporting the rotating structure of the electric sign 100 and each rotating plate (210,220). In addition, since the rotational structure and the structure of outputting the image are complex, the rotational balance is important for proper recognition of the image, and it is necessary to prevent the internal device from being damaged by the vibration caused by the imbalance. Therefore, in the present invention, the donut-shaped correction plate 800 that can correct the imbalance of rotation to prevent the shaking phenomenon due to the imbalance is placed / coupled to the main shaft 310 in the lower portion of the lower rotating plate 220.

The correction plate 800 is a structure in which a plurality of ball bearings (not shown) are included in an annular container (not shown) containing oil or a fluid, and serves to correct an imbalance of the rotating body to 1 Kg.

In addition, as mentioned above for the rotational balance, the image signal receiver 420, the image display controller 500, the encoder 510, etc. disposed under the lower rotating plate 220 are divided into a plurality of circuits of the same number and symmetric. Place it.

6 is an exploded configuration diagram of the output apparatus 1000 according to the second exemplary embodiment of the present invention. As illustrated in FIG. 6, a structure of a multi-display board 100 that outputs an image by intersecting two display boards 100 around the center of rotation of the main axis 310 is illustrated. The operation of this structure is the same as operating the single electronic sign 100 as mentioned above.

In the present invention, each of the light emitting plates 100 intersected with each other has a structure in which the light emitting devices 110 are arranged on two surfaces adjacent to each other on each of the light emitting plates 100 with respect to the rotation center of the main shaft 310.

As described above, the electric sign 100 of the multi-structure can divide a space designated as an address for data transmission into two independent electric signs 100, and accordingly, a structure capable of doubling the bandwidth of the information expression. Prepare.

In the three-dimensional stereoscopic image output apparatus 1000 using the rotation of the signboard 100 according to the present invention as described above, a structure in which a single signboard 100 is installed and a structure in which two signboards 100 are installed are illustrated. In addition, according to the complexity of the shape of the object to be implemented, the installation of the output device 1000 according to the present invention (for example, for advertising, movie screening, research), etc., the number of the electronic sign 100 can be used arbitrarily.

In addition, the installation structure of the electric motor 300 is illustrated, but in addition, various driving means such as a hydraulic motor, a precise step motor, and the like may be used.

In addition, although the structure of the electronic display panel 100 having the light emitting device 110 is illustrated, in addition to the electronic display panel 100, an LCD, a thin plate-type organic light emitting display device, and a PDP may be used.

And, of course, the sound output device may be added and used to output a sound corresponding to the image to be implemented.

According to the three-dimensional stereoscopic image output apparatus using the signboard rotation according to the present invention, by rotating the signboard to rotate at a high speed to form each plane of the image volume, by operating a plurality of light emitting elements constituting the volume independently In addition, the 3D volume image can be realized.

In addition, the adoption of a high-brightness LED light emitting device, there is an advantage that can be used for a wide range of image implementation from the size of the desktop format to outdoor billboards that require a large image output. In addition, by implementing an image using an RGB light emitting device such as an LED, there is no need for a separate optical correction device, and thus the structure is simple and there is an effect in producing and manufacturing.

In addition, when using multiple display boards arranged with two or more display boards, the refresh rate of the video can be increased in the representation of the video, and the control of the rotation structure and the video output structure is separated and the switching is adopted. Time can be reduced, and when the light emitting elements are arranged in three colors of RGB on each light emitting surface of the display board, the color can be diversified. In addition, when the color arrays are arranged alternately, the number of pixels of the image may be increased.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the spirit of the invention.

1 is a configuration diagram of a 3D stereoscopic image output apparatus using a signboard rotation according to a first embodiment of the present invention;

2 is a conceptual diagram showing a spatial operation principle of the output device shown in FIG.

3 is a conceptual diagram showing a time operation principle of the output device shown in FIG.

4 is an exploded configuration diagram showing the internal coupling relationship of the output device shown in FIG.

5A and 5B are partially enlarged views for showing an arrangement relationship of light emitting devices in the electronic display panel shown in FIG. 4;

6 is an exploded configuration diagram of an output device according to a second embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

100: an electronic board, 110: a light emitting element,

110a: video signal transmission line, 210: upper rotating plate

220: lower rotating plate, 230: protective film,

300: electric motor, 310: spindle,

410: video signal transmitter, 420: video signal receiver,

500: video display controller, 510: encoder,

600: rotational speed controller, 610: rotational position optical sensor,

620: rotation reference optical beam irradiator, 700: slip ring,

800: correction plate, 1000: video output device.

Claims (10)

A plurality of light emitting devices 110 are arranged on one surface thereof, and the electronic display panel 100 is placed upright; A main shaft 310 connected across the center of the display panel 100 in the height direction; Driving means connected to a lower portion of the main shaft 310 such that the electric sign 100 rotates about the main shaft 310; An image signal transmitter 410 which cross-sections a three-dimensional image and wirelessly transmits, as a signal, the processed data whose pixel positions correspond to the arrangement positions of the light emitting elements 110; A video signal receiver 420 wirelessly connected to the video signal transmitter 410 to wirelessly receive each video signal; An encoder (510) electrically connected to the video signal receiver (420) to convert the video signal according to a light emitting code of the light emitting device (110); An image display controller 500 electrically connected to the encoder 510 and controlling the light emitting device 110 to sequentially emit light corresponding to the position of each pixel of the cross-sectional image; A rotational speed controller 600 electrically connected to the driving means to control the rotational speed of the display panel 100 with a predetermined reference rotational speed so that the display panel 100 can be rotated at a constant rotational speed; And And sensing means electrically connected to the rotational speed controller 600 so as to transmit the sensed rotational speed data of the electronic display panel 100 to the rotational speed controller 600. 3. 3D stereoscopic image output device. The display apparatus of claim 1, wherein the image signal receiver 420, the encoder 510, and the image display controller 500 have a size corresponding to a rotation radius of the electronic display panel 100 so as to be co-rotated with the electronic display panel 100. An upper rotating plate 210 which is disposed below the electronic display plate 100 and coupled to the main shaft 310; And A lower rotating plate disposed at a lower portion of the upper rotating plate 210 and coupled to the main shaft 310, and having the image signal receiver 420, the encoder 510, and the image display controller 500 installed on an upper surface thereof. (220); 3D stereoscopic image output apparatus using a signboard rotation further comprises. The image signal receiver 420, the encoder 510, and the image display controller 500 are divided into a plurality of circuits so that the rotational balance of each of the rotating plates 210 and 220 and the electronic display panel 100 can be maintained. 3D stereoscopic image output apparatus using a signboard rotation, characterized in that the upper surface of the lower rotating plate 220 is disposed symmetrically around the center of rotation of the main axis (310). The rotation speed controller of claim 1, wherein the sensing unit irradiates an optical beam to a plurality of rotation position optical sensors 620 and the optical sensors symmetrically disposed on an upper surface of the lower rotating plate 220, and is synchronized with each other. And a rotation reference optical beam irradiator 610 electrically connected to the 600. The 3D stereoscopic image output apparatus according to claim 1, wherein the driving means is an electric motor having a brushless structure. The 3D stereoscopic image output according to claim 1, wherein the video signal transmitter 410 and the video signal receiver 420 have a communication structure using any one of an infrared communication and a WIFI communication protocol. Device. According to claim 1, wherein the rotating plate (210,220) and the annular correction plate 800 including a fluid flowing in accordance with the movement for the correction of the rotational imbalance so that the rotational balance of the light emitting plate 100 is maintained in the lower rotating plate 3D stereoscopic image output apparatus using a signboard rotation, characterized in that is further provided coupled to the main shaft 310 to the lower portion (220). The outer periphery of the main shaft 310 is connected to an external power source for supplying power to the driving means, the image signal receiver 420, the image display controller 500, and the encoder 510. And a slip ring 700 electrically connected to the driving means, the image signal receiver 420, the image display controller 500, and the encoder 510. According to claim 1, wherein the electric light plate 100, the upper rotating plate 210 and the lower rotating plate 220 is provided with a transparent protective film 230 having a size corresponding to the corresponding radius of rotation so as to isolate from the outside. Three-dimensional stereoscopic image output device using an electric sign rotation. The method of claim 1 or 2, wherein the electronic sign 100 is provided with a plurality, 3D stereoscopic image output apparatus using a rotating signboard, characterized in that each of the plurality of signboards 100 can be driven independently.