KR20020036371A - Method for 3-Dimensional Messaging Using 3D Display System and The System - Google Patents

Abstract

PURPOSE: A three-dimensional messaging device is provided to convert a message inputted through a user interface into a three-dimensional text, and to display the three-dimensional text, so as to transmit the message to other people with the three-dimensional text. CONSTITUTION: A message input unit(201) inputs data of a message to be displayed and a predetermined parameter. A user interface(202) converts the inputted data and the parameter into a system control signal and data. An image generator(203) converts the data inputted from the user interface(202) into multi-point text data of a three-dimensional image. An image synthesizer(204) overlaps the multi-point text data with an input image background to be displayed, and generates single three-dimensional image data. A display controller(205) inputs the single three-dimensional image data, and controls the data to be output to a display.

Description

Method and apparatus for 3D messaging using 3D display system {Method for 3-Dimensional Messaging Using 3D Display System and The System}

The present invention relates to a three-dimensional messaging method and apparatus using a three-dimensional display system, and more particularly, to a method and apparatus for three-dimensionally generating a text message to be delivered on the existing three-dimensional stereoscopic image background.

FIG. 1 is a known 3D image display method, which receives multiview image data from multiple cameras, performs signal processing on a multiview video encoder / decoder, multiplexer / demultiplexer, and is displayed through a display controller. A three-dimensional display method is shown. In practice, there are various methods of representing a 3D image, such as a holography method, a moving aperture method, a focused laser array (FLA) method, and an optical plate method. In particular, the method that has been in the spotlight recently is a lenticular method as the optical plate method is already commercialized and expected to be widely spread in the future.

Hereinafter, the general expression principle of the 3D image will be described. The difference between two-dimensional and three-dimensional images is the difference in how much a person can perceive depth. In other words, the three-dimensional feeling of human being is described as the interaction between the physiological phenomenon and the brain when the eyes perceive things. Human eyes basically have very different physiological characteristics depending on the direction and location of objects, parallax, angle and perspective. It is also a very complex feature that includes things like size, height, contrast, shading, overlap, color, brightness, saturation, and various psychological thoughts such as the geometric and optical characteristics of the object and the climate and atmospheric conditions when viewing the object. Have Among these various features, parallax is the most important factor for feeling 3D images.

Parallax is divided into moving and binocular movements. Movement refers to a parallax that gradually changes from the point of view of an object. Both eyes are spatial parallaxes created by the difference in image formed by the distance between the two eyes. Say. In order to express the simplest three-dimensional image using these characteristics, two cameras are arranged at the same intervals as the two eyes of our eyes, photographed on the screen, and then each of them is reflected in the corresponding eyes. This has the same effect as bringing stereo music to both ears. At this time, it is especially important to change the color, brightness, etc., or to shine alternately in time to achieve a greater effect. This method is already widespread in many products shown through glasses. The method of expressing three-dimensional effect in the closest way to the human visual characteristics by using two cameras has the same effect as we stand in a fixed position, so the image simply shows a depth three-dimensional effect. In addition, this method is not only inconvenient, but also increases eye fatigue due to the need to use glasses. In order to solve the discomfort caused by fixing the eyes, the multi-view image method is to move the screen in real time according to the movement of the eyes and to take a picture while moving the image.

Like this, a multi-view image is a method that produces the effect similar to that of our moving method, which is the least uncomfortable. In particular, as the viewpoint increases, the screen becomes closer to the actual stereoscopic screen. In the case of a multi-view image, when the viewpoint is moved, the other side of the object is seen, and thus it is not necessary to fix the line of sight as in the case of viewing a stereoscopic image. The way of viewing stereoscopic images without changing the optical characteristics of the left and right eyes is to create a field of view where the images of the left and right eyes converge. There are two ways to express such a thing: an optical plate such as a lenticular method, a parallax barrier method, a holographic method, and a combination of various optical components such as a prism, a lens, and a reflector. Is formed.

In this case, the convergence ranges of the images corresponding to each viewpoint should not be overlapped with each other, but the distances between the eyes should be formed again in the space divided by an integer less than the number of images. Regardless of the viewing position, the viewing area should be formed continuously, so that it can be formed compared to the space of infinite interval. Currently, the most researched method of autostereoscopic 3D imaging method is an optical plate type as described above. The optical plate type includes a projection type for projecting an image onto an optical plate by a projector and a contact type with an image arranged under the optical plate. The lenticular method is a representative type of a contact type capable of displaying images in three dimensions and again.

Holographic screens are a type of optical component having the characteristics of a spherical reflector or a diffuser plate manufactured by a holographic method. Holographic screens are often used as projections, and the projection and viewing area are located on the same side of the screen as the reflection type. The opposite side is called the transmissive type. A holographic screen is characterized by high efficiency of illumination light and the ability of multiple people to view stereoscopic or multi-view images at the same time. However, it is difficult to produce a screen capable of displaying color images, and has a disadvantage in that mass production is difficult.

In addition to the above-described method, there are a number of ways to produce a three-dimensional effect, and all three-dimensional display apparatuses used in these methods output and display an image received from a camera in three dimensions through a display apparatus. As described above, the present invention enables a user to superimpose data desired by the user in addition to the broadcast or playback screen, thereby further increasing the added value of the 3D stereoscopic image. No introduction.

Accordingly, an object of the present invention is to provide a three-dimensional messaging method that is excellent in visual effect and excellent message delivery ability by escaping the existing monotonous three-dimensional image method without the three-dimensional message delivery function as described above.

1 is a schematic diagram of a multi-view three-dimensional system

2 is a three-dimensional messaging device block diagram of the present invention.

3 is a process diagram illustrating a three-dimensional messaging method of the present invention.

3D stereoscopic imaging apparatus of the present invention

Message input means for inputting data and predetermined parameters of a message to be displayed, a user interface for converting the received data and parameters into system control signals and data, and data received from the user interface for three-dimensional image Image generating means for converting to multi-view text data, image synthesizing means for generating a single three-dimensional image data by superimposing the multi-view text data of the converted three-dimensional image on the input image background to be displayed, and the synthesized single And display control means for receiving the 3D image data and controlling the output to the display means.

The three-dimensional stereoscopic imaging apparatus of the present invention as described above will be described in more detail with reference to FIG. 2.

Reference numeral 201 denotes a text input means for receiving a message to be displayed by the user, and receives various parameters from the user, including message content, size, location, type, display time and duration, and the like.

Data and parameters received from the text input device 201 are converted into control signals and data including the timing of the system in the user interface 202.

The data received from the user interface is converted into multi-view text data having a three-dimensional effect by the image generating means 203. In this case, it is preferable that the multi-view text image has a three-dimensional effect at various viewpoints even when the viewpoint is changed by using the text image as the base image of the three-dimensional cuboid.

The image generating means 203 is a means for generating an image having a three-dimensional effect by overlapping the text to be synthesized with the three-dimensional multi-view image. In order to obtain three-dimensional text, it is necessary to obtain multi-view three-dimensional text data in the same manner as that of acquiring a multiview image. In the case of video, however, it is difficult to create a multi-view video from an image at a point in time because there is too much data, but it can only be obtained in real time from an actual multi-view image acquisition device. The text data obtained by using a device such as a multi-view image acquisition device in space in which the letters (ie, three-dimensional letters, for example, "ga") of the multi-view area of the space becomes a three-dimensional text image. Therefore, it is not necessary to obtain a text image of the corresponding point of view in real time, and may be stored in advance in a ROM table or may be obtained by a predetermined calculation method because there is a certain rule between 1D letters and 3D letters. This simplifies implementation and makes it easy to get a corresponding three-dimensional multiview text image. That is, the corresponding 3D text image can be obtained based on the input text. To explain this in more detail, all texts are obtained in advance with the means of acquiring 3D images, and in the case of Hangul, it is a combination of consonants and vowels. You can get a text image of a viewpoint and combine it with a combination of left and right consonants and vowels to get a text image of the viewpoint. In this case, the calculated value can be stored in the ROM. If you want to reduce the ROM size, save only the left and right multi-view data of consonants and vowels and use the combination of consonants and vowels to make the final 3D multi-view text data You can also get English can be made without distinction, and other languages can be obtained on the same principle. The pre-stored value can be the output of the image generating means by receiving the reference text input to the device and reading the corresponding data from the ROM table. In addition, a method of calculating three-dimensional text data rather than a ROM table method may be obtained by substituting the corresponding formula. In this case, the calculation formula may be applied differently according to the inter-view interval camera condition of the image input acquisition apparatus. As described above, the multi-view text generating apparatus is characterized in that data can be obtained in advance unlike an image.

The image synthesizing means 204 includes data processed from the input means 207 and 208 of the existing three-dimensional imaging apparatus, the input means 201, the user interface unit 202, and the image generating means constituting the present invention. The 3D test image (text image) obtained through 203 is input and overlayed on the existing input image background at a corresponding position to synthesize a single completed 3D image data. Since the conventional imaging apparatus is sufficient to apply what is already known, a detailed description thereof will be omitted.

The display controller 205 is known and does not require any particular limitation. However, the output of the image synthesizing means 204 is required to be input according to the display controller used.

As the three-dimensional display means for outputting a message by the display controller, various various devices of known type may be applied. This includes a display device using a lenticular method or a display device using a holographic image. However, the display controller 205 is required to be changed according to the display means, and the image generating means 203 and the image synthesizing means 204 may be changed in some ways.

The present invention also includes a three-dimensional messaging method using a three-dimensional display system. 3 is a flowchart illustrating a messaging method of the present invention, wherein the messaging method of the present invention comprises the steps of inputting data and predetermined parameters of a message to be displayed on an input device (S301), and inputting the data and predetermined parameters to a system; Converting the control signal and the data (S302), converting the converted data into multi-view text data for giving a three-dimensional effect (S303), and converting the converted multi-view 3 onto the existing input image background. Synthesizing the dimensional text data to generate a single three-dimensional image data (S304), and displaying the single three-dimensional image data through a display apparatus under the control of a display controller (S305). do.

Preferably, the control signal of step 302 includes a signal for the user to receive a command to display after a predetermined time to display after the elapsed time. Such a function may be processed by the user interface 302 and may be displayed by inputting parameters to the display controller 305.

Also preferably, the control signal includes a signal for designating the position and shape of the text to be displayed.

According to the present invention, the same function can be added to a two-dimensional display device such as an HDTV in the step of converting and displaying data input by a user into three-dimensional text. In this case, just spray two-dimensional text data. That is, it is possible to omit the three-dimensional text image generating means in FIG.

The present invention is received from the camera input unit to the existing display device of the three-dimensional image

By converting a message received through a user interface rather than data into 3D text and displaying the message, the message can be delivered to the other person as 3D text. By applying the present invention to a three-dimensional terminal it is possible to increase the additional value by simply overlapping the data desired by the user in addition to the broadcast or playback screen.

Also, when the present invention is applied to HDTV, only two-dimensional messaging function can be used, and it can be applied to all devices capable of three-dimensional display including a three-dimensional information terminal, thereby communicating to the user, three-dimensional visual effect, and additional product value. Can be promoted.

Claims (6)

In the 3D stereoscopic image device, Message input means for inputting data of a message to be displayed and predetermined parameters; A user interface for converting the received data and parameters into system control signals and data; Image generating means for converting data received from the user interface unit into multi-view text data of a 3D image; Image synthesizing means for generating a single three-dimensional image data by superimposing multi-view text data of the converted three-dimensional image on an input image background to be displayed; And display control means for receiving the synthesized single 3D image data and controlling the output to the display means. The three-dimensional messaging device according to claim 1, wherein the display means comprises a lenticular or holographic method. In the text message display method using a three-dimensional stereoscopic image, Inputting data of a message to be displayed and predetermined parameters into an input device; Converting the input data and predetermined parameters into system control signals and data; Converting the converted data into multi-view text data to give a three-dimensional effect; Generating a single three-dimensional image data by synthesizing the converted multi-view three-dimensional text data on an existing input image background; And displaying the single 3D image data through a display device under the control of a display controller. The 3D messaging method of claim 3, wherein the control signal includes a signal that the user receives a command to display after a predetermined time and displays the same after the elapsed time. 4. The method of claim 3, wherein the control signal includes a signal for designating a position and shape of text to be displayed. The 3D messaging method using a 3D display system according to claim 3, wherein the image by the multi-view text data is a 3D cuboid raised image as a base image.