JPH0414086A - Stereoscopic display device - Google Patents

Abstract

PURPOSE:To view a three-dimensional shape concretely and instantly from various view points by many people by arranging a plenty of picture display elements in a plane state and making each element vertically move to an arranging plane based on a three-dimensional information. CONSTITUTION:An arithmetic processing device 6 fetches a shape datum from a three-dimensional data storing device 9, develops it by a co-ordinate transformation means, and finds the transformation amount of the linear stepping motor 21 of the respective picture display elements 2 to drive the motor. And the light emitting element 24 of the element 2 is made to emit light at a specified color lightness through a light emitting element controller 5 according to color and brightness data, and a stereoscopic display in which the view point is on an upper surface can be executed. The view point is changed by rotating a track ball 8, so that the expansion of one part can be executed by pushing the expansion or the zoom button of a key pad 7 and the operation of the three-dimensional shape can be executed by inverse transformation by pushing the tip of the element 2 while pushing an up or a down button.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a three-dimensional display device that expresses a three-dimensional shape, which is suitable for a three-dimensional design stem or the like.

The present invention provides a three-dimensional display device that expresses a three-dimensional shape, in which a large number of image display elements are arranged in a plane, and each image display element is moved perpendicularly to the arrangement plane based on three-dimensional information. By changing the arrangement plane, it is possible for many people to instantly and concretely view a three-dimensional shape from various viewpoints.

[Prior art] Conventional methods for displaying three-dimensional images include (1)
A system that displays images on a normal two-dimensional display and whose viewpoint can be changed by input operations, (2) 3D display using holography, and (3) displays two images for the left eye and right eye on a two-dimensional display, etc. , 3D images that can be viewed separately using liquid crystal shutter glasses, polarized glasses, and colored glasses have been proposed.

``Problems to be Solved by the Invention However, the three-dimensional image display methods of the above-mentioned conventional techniques each have the following problems.

In the two-dimensional display (1), even though it is a three-dimensional display, it is a two-dimensional display, so it is difficult to obtain a three-dimensional effect, and the viewpoint in one display is fixed to one. It is difficult to grasp the specific shape.

In (2) holography, first a special film must be created, which makes it difficult to provide dynamic and instantaneous images.

(3) Three-dimensional display using glasses has the disadvantages of having to prepare glasses and putting them on and taking them off every time you work, and that it can only be viewed by one person or a small number of people. be.

Furthermore, in designs using two-dimensional displays, the idea of direct manipulation, in which what is displayed is manipulated as it is, is widely accepted, and pointing is now being done using manual means such as mice, tablets, and touch screens. However, the above conventional (1)
, (2), and (3), it was difficult to perform pointing operations on any of the two-dimensional image displays.

The present invention was created to solve the above-mentioned problems, and allows many people to concretely view a three-dimensional shape from various viewpoints instantly, and also allows many people to manipulate the three-dimensional shape. An object of the present invention is to provide a stereoscopic display device that facilitates pointing.

[Means for Solving the Problems] A first configuration of the three-dimensional display device of the present invention for achieving the above object is as follows: A large number of image display elements are arranged in a two-dimensional manner, and the surface image display elements are arranged in a two-dimensional manner. Each of the image display elements is provided with means for moving in a direction perpendicular to the array surface, and the shape of the array surface is changed by instructing each of the image display elements to move an amount based on three-dimensional information, thereby creating a three-dimensional image. It is characterized by expressing shape.

A second configuration of the stereoscopic display device of the present invention for achieving the above object is characterized in that, in the first configuration, each of the image display elements is provided with a pointing sensor.

[Operation] The present invention moves a large number of image display elements arranged in a two-dimensional manner perpendicularly to the arrangement plane based on three-dimensional information, and changes the arrangement plane, thereby making a three-dimensional shape concrete. to allow many people to view it from various viewpoints at the same time. Additionally, each image display element is provided with a pointing sensor to enable direct manipulation of its three-dimensional shape.

[Embodiments] Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

FIG. 1 is a perspective view of a stereoscopic display device showing the configuration of a first embodiment of the present invention, and FIG. 2 is a perspective view of one image display element constituting the stereoscopic display device. In this embodiment, a large number of image display elements 2 are arranged in a two-dimensional array on a large substrate l. In the rotation, an example is shown in which image display elements 2 of 8 x 8 vertically x horizontally are arranged at equal intervals.
Practically, for example, an arrangement of about 200×640 is suitable.

As shown in FIG. 2, the image display element 2 has a pressure gauge 23 attached to the tip of a shaft part 22 that is moved up and down a predetermined distance by a linear stepping motor 21. ), blue (B), and blue (B). The bottom of the linear stepping motor 21 is attached to a small board 25 that has a hole in the center for the shaft part 22 to pass through, and the signal lines, control lines, etc. of the stepping motor 2+, pressure gauge 231, and light emitting element 24 are connected to the small board 25. Each lead wire 21 is connected to the terminal 25a.
+L or using cables 23a, 241. If the maximum amount of movement of the shaft portion 22 is large, spiral wires with a large amount of expansion and contraction may be used as the cables 23a and 24a, or an electrode may be provided on the shaft portion 22 and a wire corresponding to the electrode may be provided on the small substrate 25 side. It is also possible to provide a contact and make sliding contact during vertical movement to establish an electrical connection with the terminal 25a. In this case, it is preferable to provide an amplification means on the pressure gauge 23 side to transmit and receive the weak detection signal of the pressure gauge 23.

On the small substrate 25, a drive circuit for the light emitting element 24 and a drive circuit for the linear stepping motor 2I are mounted as necessary. The light emitting element 24 may be one that has light emitting parts for R, G, and B, but may also be one that can produce any color by combining the three colors of RGB into one, or one that can produce a single color.

FIG. 3 is a block diagram showing an example of use of the stereoscopic display device of the first embodiment. This usage example shows an example in which the present invention is used in place of a conventional display as a means of expressing three-dimensional data in a system having a computer or the like.

In the configuration of this system, 3 is the stereoscopic display device of the first embodiment, 4 is a linear stepping motor drive device, and 5 is a linear stepping motor drive device.
6 is a light emitting element control device, 6 is an arithmetic processing unit, 7 is a keypad for operation input, 8 is a track hole for manual operation, and 9 is a three-dimensional data storage device.

In the stereoscopic display device 3, the coordinate axes of the two-dimensional array plane of the image display cables 2 are the X and Y axes, and the directional axis perpendicular to the array plane is the Z axis. The three-dimensional data storage device 9 stores three-dimensional shape data of a three-dimensional shape created using the same method as CAD (computer aided design). This three-dimensional shape data generally includes vector data representing the line segments that make up the three-dimensional shape, and the color and color of the surfaces made up of the line segments.
It consists of brightness data. The arithmetic processing device 6 has a coordinate conversion means, and calculates each coordinate position (X, Y,
Z) and color/luminance. As a result, the arithmetic processing device 6 outputs the stepping motor drive device 4 from its output section.
The X and Y coordinate designation signals for specifying the image display element 2 and the variable designation signal for instructing the amount of movement in the Z direction are sent to the light emitting element control device 5. Sends out the specified X and Y coordinate designation signal and its color/luminance signal.

Upon receiving the above signals, the stepping motor drive device 4 holds a variable for each image display element 2, and also sends a drive signal to each image display element 2 to drive the linear stepping motor 21 (FIG. 2) in accordance with the variable. Send out. In addition, the light emitting element control device 5 holds color/luminance signals for each image display element 2, and for example, the light emitting elements 24 provided thereon are displayed with the color/luminance instructed by scanning each line (see FIG. 2). to emit light. Note that the linear stepping motor 21 may be driven by controlling each line in order to reduce the number of connected lines, or by providing a drive circuit for each image element 2 and controlling by holding variables. It's okay. Regarding the driving of the light emitting elements 24, each image display element 2
This can be done by providing a drive circuit for each.

The pressure gauge 23 of each image display element 2 of the stereoscopic display device 3 (
The output of FIG. 2) is input as a pressure gauge input to the arithmetic processing unit 6 through its input section. Further, the keypad 7 has a "down button,""up" button, "enlarge" button, "zoom" button, etc., and inputs selection information such as an operation mode to the arithmetic processing device 6 through its human power section. Further, the trackball 8 inputs a rotational variable for moving the viewpoint to the arithmetic processing unit 6 through its input section.

The operation and effect of the first embodiment configured as above will be described.

Hereinafter, an example in which a passenger car is designed using the system shown in FIG. 3 will be described. Figure 4(a).

(b) is a perspective view showing an example of stereoscopic display of the stereoscopic display device 3. First, the stereoscopic display operation will be described.

The three-dimensional shape data of the vehicle body for display is obtained by retrieving standard shape data stored in the three-dimensional data storage device 9. The arithmetic processing unit 6 develops the retrieved three-dimensional shape data of the vehicle body using its coordinate conversion means, and converts the data to the linear stepping motor 21 (second
The variable (movement amount) in the figure) is determined, and the stepping motor drive device is caused to drive the variable (movement amount). Further, the light emitting elements 24 (FIG. 2) of each image display element 2 are set to a predetermined color via the light emitting element control device 5 according to the color/luminance data of the vehicle body.

Make it glow brightly. In this way, for example, as shown in FIG.
It is possible to perform a three-dimensional display using the top surface of the vehicle as a viewpoint. However, this three-dimensional display cannot represent horizontally recessed parts of the car body, such as tire houses. Therefore, by rotating the trackball 8, the viewpoint of the vehicle body shape is changed in accordance with the rotational variable, and the vehicle body shape is developed and displayed three-dimensionally with the lateral direction as the viewpoint, for example, as shown in FIG. 4(b). In addition, if the details are unclear due to the resolution, you can press the "Enlarge" button or "Zoom" button on the keypad 8 and press the tip of the image display element 2 to indicate the part to be enlarged. A part of the vehicle (for example, a tire house) is enlarged and expanded to create a three-dimensional display. The magnification rate at this time is determined by the period during which the button is pressed. The stereoscopic display device 3 may be installed on a desk or the like with the array surface of the image display elements 2 horizontal, or may be placed on a wall or the like with the array surface vertical. In this way, it becomes possible to instantly see a three-dimensional shape concretely and figuratively. Also,
Since it is a concrete three-dimensional display, it is also possible to observe from various angles (viewpoints) in one display.

Next, the operation of the three-dimensionally displayed shape will be described. If you want to make changes to the lines or surfaces of the vehicle body shape, press the tip of the image display element 2 while pressing the "up" or "down" button on the keypad 7. This pressing is detected by the pressure gauge 23 (FIG. 2) and inputted to the arithmetic processing unit 6, which then outputs the information to each corresponding image display element 2.
The object is instructed to move accordingly, and the three-dimensional shape data is changed by inverse transformation. This allows easy manipulation of three-dimensional shapes, that is, direct manipulation. By using this function, it is also possible to create new three-dimensional shape data from nothing.

FIG. 5 is a sectional view showing the configuration of a stereoscopic display device according to a second embodiment of the present invention. Similarly to the first embodiment, the stereoscopic display device 3' of this embodiment is constructed by arranging image display elements 2' in an array on a large substrate 1. However, in the image display element 2' of this embodiment, only the pointing sensor 23 is provided at the tip of the shaft portion 22 that is moved up and down by the linear stepping motor 2I, and instead of the light emitting element, the surface thereof is covered with a white rubber film. It is attached to a flexible screen 31 large enough to cover the array surface formed by et al. Furthermore, instead of emitting light from each light emitting element, a projector 10 is installed above the screen 31.
A is provided, and color and luminance signals are projected and expressed. A pressure sensor may be used as the pointing sensor, but it must be structured so that no tension is applied to the screen, such as by storing it in a recess. In this respect, it is preferable to use a magnetic sensor and operate it by bringing a magnetic pen close to the sensor.

FIG. 6 is a block diagram showing an example of use of the stereoscopic display device 3' of the second embodiment, and corresponds to FIG. 3.

As described above, in this embodiment, the projector 10a is provided above the stereoscopic display device 3'. This projector I
Oa is controlled by the display device 10b and projects the color/luminance signal for each image display element output from the arithmetic processing device 6 onto the screen 31. Each member with the same reference numeral other than the above is constructed and functions in the same manner as in the first embodiment. According to the second embodiment, a three-dimensional display with smooth contours can be performed.

In any of the embodiments, the object of the present invention can be achieved even if the three-dimensional shape is expressed by light emission or projection, or only by natural light. In addition, the pointing sensors installed on each image display element are not limited to pressure gauges and magnetic sensors, but various sensors such as optical sensors using special light, mechanical contacts, and pressure sensors other than pressure gauges are used. It is possible. As described above, the present invention can be applied in various ways and can take various embodiments in accordance with its gist.

``Effects of the Invention'' As is clear from the above explanation, the 3D display device of the present invention not only allows concrete and immediate 3D display, but also allows 3D shapes to be viewed from various angles, making it easy to understand 3D shapes. The original shape can be expressed.Furthermore, according to the second aspect of the invention, since a pointing sensor is provided at the tip of the image display element, it becomes possible to directly manipulate the three-dimensional shape.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing the configuration of a first embodiment of the present invention, FIG. 2 is a perspective view of an image display element of the above embodiment, and FIG. 3 is a block diagram showing an example of use of the first embodiment. Figure 4 (a
), (b) are perspective views showing a three-dimensional display example of the first embodiment, FIG. 5 is a perspective view showing the configuration of a second embodiment of the present invention, and FIG. 6 is a perspective view of the second embodiment of the invention. It is a block diagram showing an example of use of.

Claims (2)

[Claims] (1) A large number of image display elements are arranged in a two-dimensional manner, each of the image display elements is provided with means for moving the image display elements in a direction perpendicular to the arrangement plane, and the image display elements are displayed based on three-dimensional information. A three-dimensional display device characterized in that a three-dimensional shape is expressed by instructing each of the display elements to move an amount to change the shape of the array surface. (2) The stereoscopic display device according to claim 1, wherein each of the image display elements is provided with a pointing sensor.