Systems and methods for detecting gestures of a swimmer in an aquatic environment such as a flume pool. In one embodiment, a pool system includes a set of cameras, one of which is an overhead camera positioned above the water in the pool to capture images of a swimmer. The system also includes computer processors, such as a GPU, CPU, and game engine which implement a computer vision platform. The processors are configured to receive images from the cameras, determine the swimmer's body position from the images, detect a defined gesture in the swimmer's body position, and in response to detecting the defined gesture, invoking a corresponding control operation of the flume pool, such as controlling water flow through the pool or updating an interface display which is projected onto the interior surfaces of the pool.

Systems and methods for detecting gestures of a swimmer in an aquatic environment such as a flume pool. In one embodiment, a pool system includes a set of cameras, one of which is an overhead camera positioned above the water in the pool to capture images of a swimmer. The system also includes computer processors, such as a GPU, CPU, and game engine which implement a computer vision platform. The processors are configured to receive images from the cameras, determine the swimmer's body position from the images, detect a defined gesture in the swimmer's body position, and in response to detecting the defined gesture, invoking a corresponding control operation of the flume pool, such as controlling water flow through the pool or updating an interface display which is projected onto the interior surfaces of the pool.

A waterproof housing for a digital device includes a lens mount system having a threaded aperture provided on the housing, a lens arrangement including an optical lens coupled to a threaded collar, and a positioning assembly for fixedly locating the lens arrangement to the housing at a predetermined rotational engagement position of the threaded collar to the threaded aperture. The positioning assembly includes a releasable locking pin that is located in the housing adjacent to the threaded aperture, and a recess in a mounting surface of the lens arrangement for receiving a locking end of the pin when the lens arrangement and the housing are positioned at the predetermined engagement position. At this position, an optical feature of the lens arrangement is located at a predetermined desired distance from an optical plane of a camera of a digital device positioned within the housing.

An underwater image projection system submerged in a body of water and projecting an image within the body of water. The system includes a submerged projection element, a light source steering device, a user interface, and a controller. The submerged projecting element includes a projecting light source that projects an image within the body of water. The light source steering device directs light from the projecting light source. The user interface receives data input from a user including at least one of an input of the image and instructions for displaying the image. The controller retrieves the data input from the user interface, accesses image data corresponding to the image, and controls the projecting light source and the light source steering device to project the image onto a target surface within the body of water based on the data input from the user interface.

A photographic objective lens (100), comprising a first lens (110), a second lens (120), a third lens (130), a fourth lens (140), a fifth lens (150), a sixth lens (160) and a seventh lens (170) sequentially arranged along a transmission direction of incident light. The first lens (110) is a meniscus negative lens and comprises a first curved surface (111) and a second curved surface (112); the second lens (120) is a positive lens and comprises a third curved surface (121) and a fourth curved surface (122); the third lens (130) is a meniscus negative lens and comprises a fifth curved surface (131) and a sixth curved surface (132); the fourth lens (140) is a positive lens and comprises a seventh curved surface (141) and an eighth curved surface (142); the fifth lens (150) is a double-concave negative lens and comprises a ninth curved surface (151) and a tenth curved surface (152); the sixth lens (160) is a meniscus positive lens and comprises an eleventh curved surface (161) and a twelfth curved surface (162); and the seventh lens (170) is a double-concave positive lens and comprises a thirteenth curved surface (171) and a fourteenth curved surface (172). The photographic objective lens (100) mentioned above can be directly used for underwater photography, has no need of a sealing box and is simple in terms of view finding and large in view finder coverage, and an underwater field-of-view angle thereof reaches 62 degrees.

An underwater image projection system submerged in a body of water and projecting an image within said body of water is provided having an enclosure with a lens assembly. A projection element has a light source projecting an image within the body of water from the projection element with an at least one light source steering the image. A system controller is coupled to and controls the projected light source, the projected light source steering device and the further image steering device. A user inputs image data to the controller through the user input device and the controller interprets the image data into a set of image control variables and executes control of the projected light source and image source and further image steering device in coordination and projects the image through the projection element to project from underwater a static or animated image on an underwater surface of the body of water.

An underwater image projection system submerged in a body of water and projecting an image within said body of water is provided having an enclosure with a lens assembly. A projection element has a light source projecting an image within the body of water from the projection element with an at least one light source steering the image. A system controller is coupled to and controls the projected light source, the projected light source steering device and the further image steering device. A user inputs image data to the controller through the user input device and the controller interprets the image data into a set of image control variables and executes control of the projected light source and image source and further image steering device in coordination and projects the image through the projection element to project from underwater a static or animated image on an underwater surface of the body of water.

A waterproof housing for a digital device includes a lens mount system having a threaded aperture provided on the housing, a lens arrangement including an optical lens coupled to a threaded collar, and a positioning assembly for fixedly locating the lens arrangement to the housing at a predetermined rotational engagement position of the threaded collar to the threaded aperture. The positioning assembly includes a releasable locking pin that is located in the housing adjacent to the threaded aperture, and a recess in a mounting surface of the lens arrangement for receiving a locking end of the pin when the lens arrangement and the housing are positioned at the predetermined engagement position. At this position, an optical feature of the lens arrangement is located at a predetermined desired distance from an optical plane of a camera of a digital device positioned within the housing.