JP2018201584A - Water ar recording program and water ar goggle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a completely new underwater AR goggles and an underwater AR recording program for underwater AR goggles. An underwater AR recording program for an image display device used in an underwater AR goggles, wherein the image display device is an AR image based on an underwater image obtained by shooting with a camera of the image display device. An underwater AR recording program that functions as a display control unit to be displayed on a display of a display device and a recording control unit to record video data corresponding to the AR video displayed on the display is provided. [Selection diagram] FIG. 1B

Description

  The present invention relates to an underwater AR recording program and an underwater AR goggles.

  There are many underwater goggles (Patent Document 1, etc.), but all of them only expect to see underwater.

Japanese Patent Laid-Open No. 11-253577

  It is an object of the present invention to provide a completely new underwater AR goggles and an underwater AR recording program for underwater AR goggles that have never existed.

According to one aspect of the present invention, there is provided an underwater AR recording program for an image display device used for underwater AR goggles, wherein the image display device is based on an underwater image obtained by photographing with a camera of the image display device. An underwater AR recording program is provided that functions as a display control unit that displays an AR video on a display of the video display device and a recording control unit that records video data corresponding to the AR video displayed on the display.
According to this configuration, the AR video based on the underwater video can be displayed as well as displayed.

The recording control unit may record the video data in response to a predetermined user operation.
As a specific example, the predetermined user operation may be an operation on a part of the video display device, an operation on a part of the underwater goggles, or an operation on a device connected to the video display device.
According to this configuration, the AR video can be easily recorded at a desired timing by the user performing a predetermined operation.

The recording control unit may record the video data in response to a predetermined image being captured by the camera.
As a specific example, the predetermined image may be a user's hand or a marker having a specific color or shape.
According to this configuration, an AR video can be easily recorded at a desired timing by causing the camera to capture a predetermined image.

The recording control unit may record the video data in response to detection of a sound wave having a predetermined frequency.
As a specific example, the sound wave of the predetermined frequency may be a voice of a user, or a sound generated from a device connected to the video display device or an underwater device.
According to this configuration, an AR video can be easily recorded at a desired timing by generating a sound wave having a predetermined frequency.

The recording control unit may record the video data in response to sensing a predetermined pattern of vibration.
According to this configuration, an AR video can be easily recorded at a desired timing by applying a predetermined pattern of vibration.

Further, according to another aspect of the present invention, the apparatus includes an underwater goggles and a video display device disposed in front of the underwater goggles, wherein the video display device includes a display, a camera, a memory, and the camera. A display control unit that displays on the display an AR video based on an underwater video obtained by shooting, and a recording control unit that records video data corresponding to the AR video displayed on the display in the memory. Underwater AR goggles are provided.
With this configuration, it is possible not only to display but also record the AR video based on the underwater video.

  An entirely new underwater AR goggles and underwater AR recording program for underwater AR goggles that can not only display but also record AR images based on underwater images are provided.

The external view of the underwater AR goggles which concerns on one Embodiment. The disassembled perspective view of the underwater AR goggles which concerns on one Embodiment. FIG. 2 is a block diagram showing a schematic configuration of a video display device 300. FIG. 3 is a block diagram showing a specific first configuration example of the video display apparatus 300. The block diagram which shows the 2nd specific structural example of the video display apparatus 300. FIG. FIG. 6 is a block diagram showing a specific third configuration example of the video display apparatus 300. FIG. 10 is a block diagram showing a fourth specific configuration example of the video display apparatus 300.

  Embodiments according to the present invention will be specifically described below with reference to the drawings.

  1A and 1B are an external view and an exploded perspective view of an underwater AR goggle according to an embodiment, respectively. This underwater AR goggles includes an underwater goggles 100, a Fresnel lens 200, a video display device 300, a frame unit 400, and a casing 500.

  The underwater goggles 100 are worn on the user's head. The underwater goggles 100 are formed with an open window 101, and a window is provided in front of the eyes of the user (hereinafter simply referred to as a wearer) wearing the underwater goggles 100 on the head (the point of view of the wearer, the same applies hereinafter). Part 101 is located. The window portion 101 is provided with a Fresnel lens 200. As an example, a glass surface may be fitted to the window portion 101, and the Fresnel lens 200 may be attached to the glass surface. As another example, a glass surface having a function as the Fresnel lens 200 may be fitted to the window portion 101. The glass surface may be monocular or binocular.

  The underwater goggles 100 have a waterproof function so that water does not enter between the wearer's eyes and the Fresnel lens 200 (inside the Fresnel lens 200) even if the wearer dives underwater.

  The video display device 300 is disposed on the front side of the Fresnel lens 200. The video display device 300 has the camera 2 provided at, for example, a corner portion on the front surface, and photographs the front of the underwater AR goggles. The video display device 300 has a display (not shown in FIGS. 1A and 1B) of the same size as that of the Fresnel lens 200 provided on the rear surface. Is displayed.

  The focal position of the AR image displayed on the display is adjusted by the Fresnel lens 200 so as to match the position of the wearer's eye. As a result, the video display device 300 is disposed close to the eyes, but the wearer can view the AR video displayed on the display in a focused state and can enjoy the AR video underwater. .

  The video display device 300 has a waterproof function, the display can display an AR video even in water, and the camera 2 can take a picture in water. In the present embodiment, the video display device 300 has the camera 2. However, the video display device 300 having a display and the camera 2 may be separate.

  The casing 500 includes a front surface 501, an upper surface 502, a side surface 503, and a lower surface 504, and covers the video display device 300 fitted inside the frame part 400. The Fresnel lens 200 is also located in the casing 500.

  A photographing window 510 is provided on the front surface 501 of the casing 500 at a position corresponding to the camera 2, more specifically, in front of the camera 2. The photographing window 510 may be an opening or a transparent member. Accordingly, the camera 2 can photograph the front side of the underwater AR goggles through the photographing window 510, and the camera 2 can photograph the underwater when the wearer dives in the water.

  In addition, a slit 520 (gap) is provided at one or more positions of the casing 500. When the slit 520 is not provided, buoyancy due to the air in the casing 500 is generated when the wearer dives in the water, and it may be difficult for the wearer to dive in the water. In addition, it may be difficult for the wearer to get on the water due to the weight of the water accumulated in the casing 500 when the wearer gets out of the water. On the other hand, by providing the slit 520 in the casing 500, air and water can move smoothly inside and outside the casing 500 through the slit 520, and it becomes easy for the wearer to dive into the water or get out of the water.

  The slits 520 are desirably provided on the upper surface 502 and the lower surface 504 of the casing 500. When the wearer dives in water, air in the casing 500 escapes from the slit 520 on the upper surface 502 and water flows into the casing 500 from the slit 520 on the lower surface 504. In addition, when the wearer gets out of the water, air flows into the casing 500 from the slit 520 on the upper surface 502 and water accumulated in the casing 500 escapes from the slit 520 on the lower surface 504. Of course, there is no restriction | limiting in the position which provides the slit 520, For example, you may provide in the side 503. FIG.

  The underwater AR goggles may be an integrated device as a whole, or may be configured by combining a plurality of parts. In the latter case, the video display device 300 is a smartphone and can be combined with the underwater goggles 100 provided with the Fresnel lens 200, the frame unit 400, and the casing 500. Note that the video display device 300 does not necessarily have a waterproof function. In this case, the video display device 300 may not be submerged by providing the frame unit 400 with a waterproof function. Further, when the video display device 300 has a waterproof function, the frame portion 400 may be omitted.

Hereinafter, the video display device 300 will be described in detail.
FIG. 2 is a block diagram illustrating a schematic configuration of the video display device 300. The video display device 300 includes a memory 3 and a control unit 4 in addition to the display 1 and the camera 2 described above. The control unit 4 includes a display control unit 41 and a recording control unit 42. Although all or a part of each part in the control unit 4 may be implemented by hardware, in the following, the video display device 300 is a smartphone, and each part in the control unit 4 is realized by software. . In this case, each unit is realized by activation of the specific application, that is, when the processor of the video display device 300 executes the underwater AR recording program.

  The display control unit 41 causes the display 1 to display an AR video based on a video obtained by photographing with the camera 2 (an underwater video when the wearer is underwater). As a specific example, the display control unit 41 may generate an AR video by superimposing a prepared video on an underwater video obtained by shooting with the camera 2. The video prepared in advance can be related to the sea such as fish and seaweed.

  The recording control unit 42 records video data corresponding to the AR video displayed on the display 1 in the memory 3. The video data may represent a moving image or a still image. Further, the video data to be recorded may be the AR video itself displayed on the display 1 or may be appropriately compressed or image processed. The recording control unit 42 may start recording when the display control unit 41 starts displaying the AR video, or may automatically perform recording (without an instruction from the wearer) at regular intervals. Alternatively, recording may be started in synchronization with some trigger. When recording is started in synchronization with a trigger, for example, there are the following modes.

  FIG. 3 is a block diagram illustrating a specific first configuration example of the video display device 300. In this example, the recording control unit 42 records video data in response to a predetermined user operation, and the video display device 300 includes the operation receiving unit 5.

  The operation reception unit 5 may be a button provided at an edge portion of the video display device 300 that is a smartphone. Then, the recording control unit 42 records video data triggered by the wearer pressing the button. The configuration may be such that the wearer can press the button directly, or the wearer presses a portion different from the underwater AR goggles video display device 300 (for example, a part of the casing 500 or the underwater goggles 100). A configuration in which a button provided on the video display device 300 is indirectly pressed may be employed.

  Alternatively, the operation reception unit 5 may be a touch panel. Then, the recording control unit 42 records video data triggered by the wearer touching the touch panel. The display control unit 41 may display a predetermined icon on the display 1 and may be triggered by the wearer touching the icon.

  Further, the operation receiving unit 5 may not be a user interface such as a button or a touch panel. For example, an external device (not shown) may be connected to the video display device 300, and the operation reception unit 5 may acquire that the operation has been performed on the external device as a trigger.

  The external device may be provided with a button pressed by the wearer. The external device may be a snorkel equipped with a pressure sensor. In this case, the pressure sensor may detect that the wearer has applied a specific pattern of pressure such as biting the mouthpiece three times, and the operation reception unit 5 of the video display device 300 may acquire the detection result as a trigger.

  FIG. 4 is a block diagram showing a specific second configuration example of the video display device 300. In this example, the recording control unit 42 records video data in response to a predetermined image being captured by the camera 2, and the control unit 4 in the video display device 300 has an image recognition unit 43. .

  For example, the image recognition unit 43 analyzes an underwater video obtained by photographing with the camera 2 and recognizes a predetermined image. Then, the recording control unit 42 records video data triggered by the recognition of the predetermined image by the image recognition unit 43. The predetermined image is, for example, a pre-registered wearer's hand or a marker having a specific color or shape. When the marker is used, it is desirable that the color be blue or purple because a short wavelength color is easily recognized in water.

  FIG. 5 is a block diagram showing a specific third configuration example of the video display apparatus 300. In this example, the recording control unit 42 records video data in response to detection of a sound wave having a predetermined frequency, and the control unit 4 in the video display device 300 includes a sound wave detection unit 44.

  The sound wave detection unit 44 analyzes sound waves detected by a sound sensor such as a microphone in the video display device 300, for example, and detects that a predetermined frequency is included. Then, the recording control unit 42 records video data triggered by the detection of the predetermined frequency by the sound wave detection unit 44. The sound wave of a predetermined frequency may be generated from, for example, a wearable terminal device (not shown) connected to the video display device 300 or a device installed in water. The sound wave having a predetermined frequency may be a wearer's voice registered in advance. In this case, a snorkel equipped with a sound sensor may be connected to the video display device 300.

  FIG. 6 is a block diagram illustrating a fourth specific configuration example of the video display device 300. In this example, the recording control unit 42 records video data in response to sensing of a predetermined pattern of vibration, and the video display device 300 includes the vibration sensor 6, and the control unit 4 in the video display device 300. Has a vibration sensing unit 45.

  The vibration sensor 6 detects vibration applied to the video display device 300. The vibration sensing unit 45 senses that the detected vibration is a predetermined pattern of vibration. Then, the recording control unit 42 records video data triggered by the vibration sensing unit 45 sensing a predetermined pattern of vibrations.

  In each of the specific examples described above, the recording control unit 42 may record the video data corresponding to the AR video at the time when a certain trigger is detected, or the video data after a predetermined time has elapsed since the trigger was detected. It may be recorded. Further, when the recording control unit 42 records video data as a moving image, the recording may be terminated after a predetermined time has elapsed from the start of recording, or the recording may be terminated in synchronization with some trigger as in the recording start. Good. These predetermined times may be fixed values determined in advance or may be set by the user. Further, two or more of the specific examples may be combined.

  When an external device is connected to the video display device 300, a wired connection or a wireless connection may be used. In the case of a wireless connection, a connection that facilitates underwater communication, such as a sound wave of a specific frequency or a blinking pattern of light, may be used.

  As described above, in this embodiment, the Fresnel lens 200 is provided between the eye of the wearer and the video display device 300 in this embodiment. Accordingly, the wearer can view the video displayed on the display 1 of the video display device 300 in a focused state.

  Further, the video display device 300 is provided with a display control unit 41 and a recording control unit 42. As a result, not only the underwater AR video can be displayed but also recorded, and the wearer's enjoyment is improved. In addition, underwater AR video can be easily recorded at an arbitrary timing by user operation, image detection, sound wave detection, vibration detection, and the like.

  The embodiment described above is described for the purpose of enabling the person having ordinary knowledge in the technical field to which the present invention belongs to implement the present invention. Various modifications of the above embodiment can be naturally made by those skilled in the art, and the technical idea of the present invention can be applied to other embodiments. Therefore, the present invention should not be limited to the described embodiments, but should be the widest scope according to the technical idea defined by the claims.

DESCRIPTION OF SYMBOLS 100 Underwater goggles 101 Window part 200 Fresnel lens 300 Image | video display apparatus 400 Frame part 500 Casing 501 Front surface 502 Upper surface 503 Side surface 504 Lower surface 510 Shooting window 520 Slit 1 Display 2 Camera 3 Memory 4 Control part 41 Display control part 42 Recording control part 43 Image Recognition unit 44 Sound wave detection unit 45 Vibration detection unit 5 Operation reception unit 6 Vibration sensor

Claims (9)

An underwater AR recording program for a video display device used for underwater AR goggles,
The video display device;
A display control unit for displaying an AR image based on an underwater image obtained by photographing by a camera of the image display device on a display of the image display device;
An underwater AR recording program that functions as a recording control unit that records video data corresponding to the AR video displayed on the display.   The underwater AR recording program according to claim 1, wherein the recording control unit records the video data in response to a predetermined user operation.   The underwater AR according to claim 2, wherein the predetermined user operation is an operation on a part of the video display device, an operation on a part of the underwater AR goggles, or an operation on a device connected to the video display device. Recording program.   The underwater AR recording program according to claim 1, wherein the recording control unit records the video data in response to a predetermined image being captured by the camera.   The underwater AR recording program according to claim 4, wherein the predetermined image is a user's hand or a marker having a specific color or shape.   The underwater AR recording program according to claim 1, wherein the recording control unit records the video data in response to detection of a sound wave having a predetermined frequency.   The underwater AR recording program according to claim 6, wherein the sound wave having the predetermined frequency is a voice of a user, or a sound generated from a device connected to the video display device or a device in water.   The underwater AR recording program according to claim 1, wherein the recording control unit records the video data in response to sensing of a predetermined pattern of vibration. Underwater goggles,
An image display device disposed on the front side of the underwater goggles,
The video display device
Display,
A camera,
Memory,
A display control unit for displaying an AR image based on an underwater image obtained by photographing by the camera on the display;
An underwater AR goggle comprising: a recording control unit that records video data corresponding to the AR video displayed on the display in the memory.