JPH08211834A - Three-dimensional illumination device - Google Patents

Abstract

PURPOSE: To provide a three-dimensional illumination device capable of displaying a stereoscopic pattern visible from the optional direction. CONSTITUTION: This device is provided with a three-dimensional display means 10 constituted of laminatedly arranging plural plane display elements 11a-11n, incorporating light emitting bodies 12, arranged in matrix on an X-Y plane at prescribed intervals in the direction of a Z axis orthogonally intersecting the planes, and the light emitting bodies 12 in respective plane display elements 11a-11n are turned on/off, and the prescribed stereoscopic pattern is displayed in the three-dimensional display means 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional lighting device, and more specifically, to enable viewing of the displayed object from any direction such as front, rear, left and right and up and down. The present invention relates to the three-dimensional lighting device.

[0002]

2. Description of the Related Art A typical example of an illumination device is a neon sign used in electronic bulletin boards and advertising billboards. The electronic bulletin board has a display unit in which light-emitting bodies such as LEDs (light-emitting diodes) and light bulbs are arranged in a matrix, and by applying X-axis data and Y-axis data to the display unit, desired characters and figures can be displayed. Is displayed.

[0003]

However, since the display is essentially a two-dimensional plane, the viewing direction is limited. For this reason, the display unit is usually arranged in a direction in which there is a lot of traffic, but when the installation position is a 360-degree field of view such as the rooftop of a building, the back side is wasted. Will end up.

Further, recently, due to the progress of the video technology, the screen of a television or the like has been enlarged and a three-dimensional stereoscopic image has become possible. However, this is only within the screen, for example, the screen. The image is not visible even from the back side.

The present invention has been made in view of such a conventional situation, and an object thereof is to provide a three-dimensional lighting device which allows a display object to be viewed from any direction centering on the display object. It is in.

[0006]

In order to achieve the above object, the present invention provides a plurality of flat display elements including light-emitters arranged according to a predetermined arrangement on an XY plane, which is orthogonal to the plane. A stereoscopic display means arranged in a stacked manner with a predetermined interval in the axial direction, and by causing the light-emitting body in each of the planar display elements to blink, a predetermined stereoscopic figure is displayed in the stereoscopic display means. Is characterized by.

In this case, as the display control means of the three-dimensional display means, a three-dimensional shape recognition means for recognizing a three-dimensional figure to be displayed as three-dimensional data, and the three-dimensional data corresponding to each of the two-dimensional display elements are provided. It is preferable to include a data conversion unit for converting into two-dimensional data, and a light emission drive unit for blinking the light emitter in each of the flat display elements based on the two-dimensional data.

The three-dimensional shape recognizing means is preferably a computer graphic drawing means,
The three-dimensional data is represented as point data along at least the outer shape of the three-dimensional figure. Further, the luminous body is supported in the flat display element by a transparent supporting means, and a light emitting diode or a low pressure neon tube is suitable as the luminous body.

[0009]

According to the above construction, the light-emitting bodies are arranged in, for example, a matrix on the flat display element, and a plurality of the flat display elements are stacked and stacked at a predetermined interval. By blinking the light-emitting bodies in association with each other, a desired three-dimensional figure is displayed so as to stand out.

It should be noted that a three-dimensional figure is drawn by computer graphic to obtain its three-dimensional data, and the three-dimensional data corresponds to each plane display element.
It is possible to display not only a still image but also a moving image by converting the data into dimension data and controlling the blinking of the light emitters belonging to each planar display element based on the data.

[0011]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 schematically shows the configuration of this three-dimensional lighting device. According to this, the three-dimensional lighting device is provided with the three-dimensional display means 10 that allows the displayed figure (including characters) to be viewed from each direction.

The stereoscopic display means 10 is composed of an assembly of a plurality of flat display elements 11 _{1 to} 11 _n . That is, each of the plane display elements 11 _{1 to} 11 _n includes the light emitting bodies 12 arranged in a matrix on the XY plane, and is stacked with a predetermined interval in the direction orthogonal to the XY plane. Are piled up in a shape.

It is preferable that the light emitting bodies 12 are arranged in the same arrangement in each of the flat display elements 11 _{1 to} 11 _n , but the arrangement may be changed for each flat display element in some cases. Further, the arrangement interval of each of the planar display elements 11 _{1 to} 11 _n and the interval between the light emitters 12 are appropriately set depending on the size of the stereoscopic display means 10 and the resolution of the stereoscopic figure to be displayed.

In this embodiment, each plane display element 11 ₁ ...
11 _n has a transparent support substrate 13 made of glass or synthetic resin, and a hole or the like is formed in the support substrate 13 to attach the light emitting body 12. However, as shown in FIG. , For example, transparent columns 1 arranged vertically
The light-emitting body 12 may be attached to 4 in a dumpling shape.

Instead of the pillar 14, a plurality of light emitting bodies 12 may be linearly suspended by, for example, a wire or a Tegs material which is satisfactory in strength and does not hinder the visual field.

Various light sources can be used for the light emitter 12. For example, when the scale is small and only one color is required, a light bulb of about 1 to 10 W is used. In the case of color display, red, green, and blue as the three primary colors are required, which is not preferable in terms of power consumption in a light bulb. Therefore, use of a two-color LED can be considered. According to this, red,
It can express three colors, green and yellow, and consumes less power.

If the power consumption is further reduced, the low pressure neon tube is most suitable. The low-pressure neon tube is relatively easy to develop color and consumes low power, which is advantageous when more brightness is required and when a large number of light emitters 12 are required.

A low pressure neon tube is used for the light emitter 12 of FIG. That is, the light emitting body 12 includes three low pressure neon tubes 15a, 15 that emit red, green and blue colors, respectively.
b and 15c are housed in the same milky white bulb 16 together with the matrix control board 17 and their respective transformers 18a, 18b and 18c, and a desired color can be obtained by controlling the light emission amount of each neon tube. I try to be able to develop color. 2A is a vertical cross section of the light emitting body 12, and FIG. 2B is a horizontal cross section thereof.

The light emission drive units 20 _{1 to} 20 _n are connected to the flat display elements 11 _{1 to} 11 _n , respectively, as shown in FIG.
Shows the circuit configuration. According to this, each light emission drive unit 20 has a plurality of X address wirings 21 and a plurality of Y address wirings 22 corresponding to the XY matrix of each plane display element, and extends across each intersection. Therefore, the light emitter 12 is connected.

Therefore, when the X address wiring 21 and the Y address wiring 22 are selected and brought into conduction, the light-emitting body 12 at the intersection point thereof is turned on. As the lighting control method, for example, there is a dynamic scan lighting control method in which the X address wiring 21 is scanned at a constant time interval, and a predetermined Y address wiring 22 is energized in synchronization with the scanning.

Although the light emission drive section 20 of FIG. 3 is assumed to be the monochromatic light emitting body 12, the XY address wiring 2 is used for color display of the three primary colors.
In addition to 1 and 22, wiring for each of the three primary color light emitting elements will be added.

As described above, each of the light emission drive units 20 _{1 to} 20
by controlling the _n, by causing the light emitter 12 belonging to the flat display element 11 ₁ to 11 _n are turned in association with the light emitting body 12 of the flat display element 11 adjacent this stereoscopic display unit 1
A desired figure, for example, a figure such as an animal or a character, can be displayed so as to be three-dimensionally displayed at 0. In this embodiment, it is displayed by applying a computer graphic (CG) technique. ing.

That is, as shown in FIG. 1, this embodiment is provided with a drawing means (CAD) 30 as a three-dimensional solid figure creating means, and the solid figure drawn by the drawing means 30 is CG data. The conversion unit 31 converts the data serially or in parallel into three-dimensional data to be output to the outside.

In this case, the three-dimensional data (X, Y,
Z) is expressed as point data along at least the outline of the drawn three-dimensional figure, but may include internal data surrounded by the outline. In addition, the sampling density of the three-dimensional data is the light emitting body 12 and each flat display element 11 _1.
It is determined by the relationship with the arrangement interval of 11 _n .

Unlike this embodiment, instead of the drawing means (CAD) 30 described above, a contour of a three-dimensional object is traced by, for example, a pen (pointer) having a light emitting portion, and the movement trajectory of the light emitting portion at that time is traced. You may use the figure recognition means which makes the three-dimensional figure by catching with a several camera. Furthermore, the three-dimensional data of the three-dimensional drawing may be obtained from the plan view and side view of the three-dimensional drawing created by the two-dimensional drawing means.

In any case, the three-dimensional data obtained by the CG data conversion unit 31 is transferred serially or in parallel to the main control unit 32, and in the main control unit 32, the plane display elements 11 _{1 to} 11 are displayed. 2 for each _n
Converted to dimensional data.

That is, each of the flat display elements 11 _{1 to} 11 _n is regarded as the Z-axis position, and the data belonging to the Z-axis position are collected to collect each flat display element 11 _1.
To 11 _n are transferred to the terminal control units 33 _{1 to} 33 _n .

Here, for example, each of the plane display elements 11 ₁ to ₁ 1
In 1 _n, the arrangement of the light emitting bodies 12 in the XY direction is 40 rows 4
If there are 30 flat display elements 11 in the 0th column, each light emitter 12 has three-dimensional data (Xp, Yq, Zn) (where p, q = 1 to 40, n =). 1-3
0).

Therefore, from the main control unit 32 to each of the terminal control units 33 _{1 to} 33 _n , (Xp, Yq, Z ₁ ), (X
p, Yq, Z ₂ ), (Xp, Yq, Z ₃ ) ... (Xp, Y
q, Z ₃₀ ) will be transferred. This data is represented in three dimensions, the terminal control unit 33 ₁
Viewed from ~ 33 _n, Z is constant substantially two-dimensional data. In the case of serial transfer, the packet method may be adopted.

Then, the two-dimensional data are displayed in the data display conversion units 34 _{1 to} 34 _n in the XY for display of the light emitter 12.
After being converted into data, it is given to the light emission drive units 20 _{1 to} 20 _n .

As a result, each plane display element 11 _{1 to} 11 is displayed.
Each Z-axis cross section of the three-dimensional figure drawn by the drawing means 30 is displayed on each of the XY display surfaces of _n , and the whole three-dimensional figure is displayed on the three-dimensional display means 10 so as to stand out. Become. In this display, it is possible to arbitrarily select whether to display only the outer shape of the three-dimensional figure or to display even the inside of the three-dimensional figure.

The stereoscopic display means 10 of the above embodiment is
The flat display elements 11 _{1 to} 11 _n of the same size are overlapped with each other and formed in a cubic shape as a whole, but as a stereoscopic display means applied to the present invention, other than this, it is shown in FIG. So that a large number of luminous bodies 1
3D display means 10 formed by suspending 2 in a dumpling shape
As shown in FIG. 5A or FIG. 5, a stereoscopic display unit 10b in which a large number of light emitting bodies 12 are similarly suspended in a body of a triangular prism, for example, is illustrated.

By changing the size and shape of each flat display element, instead of hanging it in a dumpling shape,
The stereoscopic display means may be constructed in a cylindrical shape or a triangular prism shape as a whole. In any case, even in such a stereoscopic display means 10a, 10b, desired figures, symbols, etc. can be stereoscopically displayed therein by the lighting control means.

[0034]

As described above, according to the present invention,
Stereoscopic display means in which a plurality of flat display elements including light emitting elements arranged according to a predetermined arrangement on the XY plane are arranged in a stack at predetermined intervals in the Z-axis direction orthogonal to the plane, By blinking the light-emitting body in each of the planar display elements, a three-dimensional figure that can be seen from any direction is displayed, and it is possible to make more people interested. Alternatively, it has various uses such as an object for exhibition.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing the configuration of an embodiment of a three-dimensional lighting device according to the present invention.

FIG. 2 is a sectional view showing an example of a light emitting body applied to the same embodiment.

FIG. 3 is a circuit diagram showing an example of a light emission drive unit that controls blinking of the light emitter.

FIG. 4 is a schematic perspective view showing a modified example of the stereoscopic display means applied to the present invention.

FIG. 5 is a schematic perspective view showing another modified example of the stereoscopic display means applied to the present invention.

[Explanation of symbols]

10, 10a, 10b stereoscopic display unit 11 ₁ ~11n plane display element 12 the light emitter 13 supporting substrate 14 posts 15a~15c low pressure neon tube 20 ₁ ~20n emission driver 30 drawing means (CAD) 31 CG data converter 32 main control Section 33 _{1 to} 33n terminal control section 34 _{1 to} 34n data display conversion section

Claims (5)

[Claims] 1. A solid body in which a plurality of flat display elements including light-emitters arranged in a predetermined array on an XY plane are arranged in a stack at predetermined intervals in the Z-axis direction orthogonal to the plane. A stereoscopic lighting device comprising display means, wherein a predetermined stereoscopic figure is displayed in the stereoscopic display means by blinking the light-emitting body in each flat display element. 2. A three-dimensional shape recognition means for recognizing a three-dimensional figure to be displayed as three-dimensional data, and a data conversion section for converting the three-dimensional data into corresponding two-dimensional data for each plane display element. The three-dimensional illumination device according to claim 1, further comprising a light emission drive unit that blinks the light emitters in each of the flat display elements based on two-dimensional data. 3. The three-dimensional shape recognition means is composed of a computer graphic drawing means, and the three-dimensional data is represented as point data along at least the outer shape of the three-dimensional figure. The three-dimensional lighting device described in. 4. The three-dimensional illumination device according to claim 1, wherein the luminous body is supported in the flat display element by a transparent supporting means. 5. The three-dimensional lighting device according to claim 1, wherein the light emitter is a light emitting diode or a low pressure neon tube.