KR20120115633A - 3d camera systeam - Google Patents

Abstract

PURPOSE: A 3D camera system is provided to frequently select a desired angle when a user watches a moving picture, thereby enabling the user to watch actions of actors/actresses and movies at various angles. CONSTITUTION: A photographing unit includes digital moving picture cameras. A controller is connected to a system unit. Software is installed in the system unit to control a photographing device of a 3D camera system and store and reproduce photographed data. The system unit includes a data unit and a CPU(Central Processing Unit). A display unit displays a photographed image. An input unit inputs and selects text data. [Reference numerals] (AA) Photographing unit; (BB) Control unit; (CC) Display unit; (DD) System unit; (EE) CPU; (FF) Data unit; (GG) Input unit

Description

3D camera system {3D camera systeam}

The 3D camera system of the present invention is a technology related to a camera system for producing an image, that is, simultaneously photographing an object or a place from various angles and storing the data in an electronic storage medium in real time, and during playback, real-time shooting videos of various angles. As a technology configured to be viewed from various angles, it is similar to a virtual reality video technology, commonly referred to as VR, but the technology of the present invention uses a video file that captures a scene of a real reality and a person or object of a reality from various angles simultaneously. The difference is that it plays

It is a technology that is developed according to the development of storage memory technology by using a digital video camera that is commonly known and storing data on electronic storage media such as hard disks and memory in real time. And background technologies are the driving technologies.

If you want to see the objects or scenery taken from various angles while watching a video, you must have multiple people to take real-time shots or install multiple cameras at the same time and control them simultaneously. It is cumbersome to install in many places, and if the surroundings are taken around the object from all directions, a problem occurs in which the photographer or the camera is photographed together with the photographing object. In addition, during the playback of the video viewers usually have to look at the unilaterally showing the image, there is a problem that it is not easy to see by changing the angle whenever the viewer needs the screen immediately on the monitor, the present invention is a video or video of the object or landscape It makes it possible to shoot easily, conveniently and accurately from various angles at the same time, and improves the disadvantage that the opposite photographer or camera is simultaneously taken when shooting an object from the front, rear, left, and right of the object when shooting an object. It aims to solve the video of various angles in real time by changing the scene instantly.

To solve the above problems, the simultaneous recording of digital video cameras capable of photographing various angles of the camera assembly unit cam1 provided in the dragonfly eye camera device (FIG. 2) and the rotating camera device (FIG. 4) of the present invention. With the configuration of the shooting, the problem of the simultaneous shooting and the rotation of the rotating camera device (Fig. 4) by solving the problem of unnecessary mutual shooting of the camera facing each other due to the rotation of the shooting object, and real-time various angle image realization technology during playback The problem of real-time viewing was solved by dividing the captured video files and configuring the software program of the electronic media which preloaded the neighboring files.

You can open a new chapter in a game or a movie. For example, instead of watching the actor's one-sided appearance when watching a video, you can select the angle that the viewer wants to watch from time to time and watch the actor's acting and movie from various angles. In addition, it provides a device and technology that can shoot, so that the world of stereoscopic virtual reality can be merged with the screen of the real world to create a new chapter for making various movies.

1 is a block diagram of a 3D camera system.
2: is an illustration of a dragonfly eye camera device of the 3D camera system
3 is a cross-sectional view of the dragonfly eye camera device of the 3D camera system
4 is a cross-sectional view of a rotating camera device of the 3D camera system.
5 is an exemplary view from above of one rotating camera device of a 3D camera system.
6 is an exemplary view of rotating three rotary camera device of the 3D camera system
7 is a side view of a rotating camera device of the 3D camera system
8 is an exemplary view of a 3D camera system.
9: FIG. 9 is an exemplary view from above of two rotary camera devices of a 3D camera system, which operates with a rotation and a remote controller.
10: FIG. 10 is a diagram illustrating a method of executing and viewing photographing files of a 3D camera system. In the monitor, file 18 is being executed and the peripheral files 10, 11, 12, 17, 19, 24, 25, and 26 are displayed. Preloaded file.

The 3D camera system of the present invention is composed of a photographing unit, a control unit, a system unit, and a display unit and an input unit (the system unit includes a data unit and a CPU) as shown in FIG. 1. As follows.

1 is a block diagram of a 3D camera system for solving the above problems, and is connected to a photographing unit consisting of a digital video camera (cam10) capable of simultaneous shooting and connected to the controller to make a smooth connection with the system unit and the present invention Programmed software is installed to control the shooting device of the 3D camera system and to save and play back the recorded data in each file. A display unit configured to connect to the system unit, and a keyboard for inputting and selecting photographic data, driving cameras, controlling performance of each device of the present invention, and inputting and selecting options for driving an embedded program. It consists of an input section consisting of a mouse.

2 and 3 illustrate examples and cross-sectional views of a dragonfly eye camera device, and a camera assembly unit cam1 composed of a circular sphere and a digital camera configured to collect an object or a landscape at various angles by gathering it here. ) And a controller (cont1) for transmitting the photographed data to the system unit, and a system unit (com1) including a CPU and a data unit for storing and controlling data, respectively, connected to the system unit and an image displayed in connection with the display unit. Monitor (mon1) and each camera and data files configured to be viewed is configured to control by using a key and a mouse manually at the input unit, assuming that the real thing to shoot any object of the present invention dragonfly eye camera device to any indoor playground If you start to shoot on the floor or ceiling of the camera, the digital video camera (cam1) of each camera assembly (cam1) 10) They shoot various angles and landscapes at the same time in the installed place such as the playground or ceiling, and the data of these images are stored in the data part of the system part, that is, the electronic storage medium through the controller (cont1). These files are files that can be immediately reproduced and displayed or processed. The display unit can view the entire digital video camera of the photographing unit and is configured to enlarge and view images of individual cameras to facilitate the operation of the 3D camera system of the present invention. It is configured to be able to.

Figure 4 is a cross-sectional view of the rotating camera device of the present invention 3D camera system, the device is configured to shoot the front and rear, left and right of the object at the same time while rotating the object around when shooting the object to shoot the object to shoot Although already described above, when the camera is installed in the front, rear, left, and right of the object to shoot the shooting object to solve the disadvantage that the opposite camera is photographed to the camera facing each other as a rotating camera device of the present invention 3D camera system Is a columnar camera assembly (cam1) bent in an ellipse so as to be suitable for capturing the upper, lower, left, and right sides of the object to be photographed, and each digital video camera (cam10) provided therebetween at regular intervals from top to bottom. For regular illumination at top and bottom Site L10 and each digital video camera cam10 are connected to a device controller cont1 for smooth connection with the system unit com1, and the controller cont1 is connected to the system unit com1. com1) is programmed software, which is a program according to the driving needs of the 3D camera system of the present invention to control the shooting and shooting timing of the shooting unit, the rotation speed of the rotating camera device, lighting, etc. The control unit deletes and edits the display unit, and is configured to control the display method. The system unit com1 is configured to be connected to the monitor mon1 and the input unit. 3D camera system of the present invention is composed of a battery (ba1) which is provided integrally with the unit (com1) and is provided in the camera assembly unit to supply the necessary power The rotating camera device of FIG. 4 is configured to be driven, and a lower portion of the camera assembly cam1 is provided with a wheel r10 connected to the motor mo1 to run on a rail, and a rail r1 is naturally below the wheel. And a sensor (se10) is provided between the wheel and the bottom of the camera assembly (cam1), and is configured to recognize a position mark (se20) installed on the rail plate (p1). According to an option selected by the user, the sensor se10 detects the position mark se20 and captures the image at the corresponding position. For example, the position mark se20 is provided between the rails r1 at regular intervals. Displayed by a unique number or name, and configured to be photographed only on a unique position mark (se20) according to the option set by the user, the recorded image data digital files are assigned to each position mark (se20). It is stored in the 3D camera system storage device of the present invention under the name and configured to be divided into individual files, and is configured to adjust the speed of the camera assembly unit (cam1) of the rotating camera device of the present invention 3D camera system as needed. The camera assembly unit cam1 can be combined into a plurality of units such as two (FIG. 9) or three (FIG. 6) to improve the efficiency of shooting. That is, the camera assembly unit (cam1) is rotated once on the rail. Since the number of cuts compared to the time and the three camera sets (cam1) are rotated and the number of cuts compared to the time to shoot differ in the efficiency of the work and the naturalness of the operation of the screen, the camera set unit (cam1) It is configured to control the number and speed of the head.

For example, the rail plate p1 and the rail r1 of the rotating camera device (FIG. 4) of the present invention 3D camera system are installed around the bottom of the object to be photographed and rotated on the rail r1. The camera assembly (cam1) of the camera device (FIG. 4) is configured to shoot while rotating, the ON and OFF operation and the rotation speed of the camera assembly (cam1) by the input unit (key1) composed of a keyboard and a mouse, such as input of text data and data selection. It is configured to adjust the necessary matters for the overall operation of the rotating camera device (Fig. 4) and the camera assembly (cam1) has a feature that is configured to operate the input unit (key1) with a remote control (remo1) while rotating on the rail. 3D stereoscopic view of files that have been shot and edited

The method of viewing and driving is programmed to load nearby related files when playing each recorded video file. That is, the data recorded and stored according to the present invention is edited and processed, and if necessary, the programming process for compression and playback is performed. The loading process of video data is processed as a plurality of data loadings, and the images captured at the same time, that is, the frames of video files photographed at the same time are programmed to be reproduced, thereby creating a 3D video produced by the technology of the present invention. However, as a way to prevent fast loading and memory incubation, each video file is cut and played with a small amount of data loading, but divided into a screening screen file and a preloaded peripheral file, and preloading is a memory allocated for screening at any time. Reading data in advance By the frame number of each video file or divided by the running time so that each image taken in the same time zone can be loaded and screened at the same time. Files 11, 12, 17, 19, 24, 25, and 26 are preloaded so that they can be shown as main files at any time. In this process, the number of preloaded files or the file loading size is programmed and If the user selects a certain part of the movie screen of the movie and drags the screen in the desired direction, the video file corresponding to the dragged distance value is displayed on the main screen. If the model is standing in front of you and is looking at the scene, the neighboring files of the model's front file, In other words, files of various angles (up, down, left, and right) of the model are preloaded at the same time as the file being shown as the main file and the viewer can drag the screen by selecting the video screen to the left or right while watching the front scene. When the distance on the screen is arbitrarily determined, the video of the data corresponding to the value corresponding to the value is programmed to be displayed according to the direction so that the viewer can watch the video of the actual movement of various angles including the back of the model in real time at any time. It is programmed to watch the scenes in three dimensions, and in this process, the user can adjust the number of preloading and the loading size according to the state of the computer's memory in order to reduce the data incubation caused by simultaneous preloading of the video, that is, overuse of memory. Are programmed to If the viewer adjusts the number of video preloads to 8, 8 videos of the neighboring files are preloaded at the same time in 8 directions of up, down, left, and right based on the main video file currently being shown, and the loading size is the video size set by the user. It is configured to load a certain amount according to a certain time or a number of screen frames before and after the point of view, so as to reduce the error of memory and use of unnecessary parts and to facilitate the smooth playback of the video. When all the scenes are selected, the preloaded video data is screened so that the 3D stereoscopic video of the 3D camera system of the present invention can be viewed.

cam1: Camera Set Cam10: Digital Video Camera
com1: System part so1: Power socket
mon1: monitor h1: data part
L10: light cont1: controller
ba1: battery mo1: motor
r10: wheel r1: rail
se10: sensor se20: position mark
p1: rail plate remo1: remote control
key1: Input unit cpu1: CPU

Claims (5)

The 3D camera system of the present invention is a photographing unit consisting of digital video cameras (cam10) configured to enable simultaneous shooting and a controller connected to the system to form a smooth connection with the system unit connected to the photographing apparatus of the present invention 3D camera system A software program installed to control the data, and to store and play back the recorded data in each file, and having a data portion for storing data and a system portion composed of a CPU, a display portion configured for viewing images taken in connection thereto; and It is connected to the system unit and consists of an input unit consisting of a keyboard and a mouse for inputting text data and selecting data.
The dragonfly eye camera device (Fig. 2) of the present invention 3D camera system is a camera assembly unit (cam1) consisting of a circular sphere and the digital video cameras (cam10) and each configured to be gathered here to shoot an object or a landscape from various angles, respectively The controller (cont1) which transmits the captured data to the system unit and the data unit for storing and controlling the data and the system unit (com1) including the CPU and the image unit connected to it so that you can see the displayed image. The configured monitor mon1 and each camera and data file are characterized in that they are configured to be manually controlled at the input unit by using a key and a mouse. The rotating camera device (Fig. 4) of the present invention 3D camera system is configured to be bent in an ellipse so as to be able to simultaneously shoot the front, rear, left and right of the object while rotating the object when shooting the object of the rotating camera device (Fig. 4) The camera assembly unit cam1 and each of the digital video cameras cam10 provided at regular intervals from the top to the bottom thereof, and the light L10 provided at the top and the bottom at a constant interval therebetween, respectively. Digital video camera (cam10) is connected to the controller (cont1), the controller is connected to the system unit (com1), the system unit (com1) is configured to be connected to the monitor (mon1) and the input unit and the camera assembly (cam1) Rotating camera of the present invention 3D camera system is composed of a battery (ba1) is provided in the lower part of the system unit (com1) is integrally provided and also provided in the camera assembly to supply the necessary power Tooth (FIG. 4) is configured to be driven, and a lower portion of the camera assembly cam1 is provided with a wheel r10 connected to the motor mo1 to run on the rail, and a rail r1 is provided below the wheel. A sensor (se10) is provided at the bottom of the camera assembly unit (cam1) and configured to recognize a position mark (se20) installed on the rail plate (p1). se10) has a feature that is configured to recognize and shoot at the location. The driving and viewing of the video file recorded by the 3D camera system of the present invention is to load and play the related files while the neighboring files are loaded and played while playing each recorded video file. As a way to organize and prevent fast loading of video data and memory incubation, each video file is programmed to allow the user to adjust the arbitrary amount of time and frame loading in the program as needed. The camera assembly part cam1 of the rotation camera apparatus (FIG. 4) has a characteristic comprised so that it may be installed on the rail r1 in multiple numbers.

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