The present invention relates to an enhanced electronic diving mask with various image enhancement hardware and software integrated with a diving mask, whereby images may be enhanced to enable a diver to achieve greater visibility and clearer vision while underwater. Notably, the present invention combines techniques that have previously been used in connection with internal patient surgical procedures, so that medical instrument imaging technology used inside the human body may for the first time be used to afford divers clearer vision, more visibility and greater safety.

The present invention relates to an enhanced electronic diving mask with various image enhancement hardware and software integrated with a diving mask, whereby images may be enhanced to enable a diver to achieve greater visibility and clearer vision while underwater. Notably, the present invention combines techniques that have previously been used in connection with internal patient surgical procedures, so that medical instrument imaging technology used inside the human body may for the first time be used to afford divers clearer vision, more visibility and greater safety.

The present invention relates to a floatable breathing device. The floatable breathing device a head unit, a mask and a snorkel. The head unit general includes an ornamental shaped outer housing, an insulated housing positioned within the outer housing and having an ornamental shape and buoyant properties, and a head receiving section provided between the outer housing and the insulated housing and contoured to a human head. The mask extends from the outer housing, while the snorkel extends through and exits a portion of the head unit above a predetermined waterline.

The invention relates to a diving mask (10) comprising a telecommunication system (190) configured to allow the establishment of one-way or two-way light communication, specifically according to a communication protocol of the Li-fi type. For this purpose, the telecommunication system (190) comprises a light communication module (150) comprising at least one light source (151) and an electronic control board (156) for controlling said at least one light source (151) so as to emit a light signal of which the amplitude is modulated as a function of an electronic signal encoded by said electronic control board (156). The invention also relates to an underwater light communication method (200).

The invention relates to a diving mask (10) comprising a telecommunication system (190) configured to allow the establishment of one-way or two-way light communication, specifically according to a communication protocol of the Li-fi type. For this purpose, the telecommunication system (190) comprises a light communication module (150) comprising at least one light source (151) and an electronic control board (156) for controlling said at least one light source (151) so as to emit a light signal of which the amplitude is modulated as a function of an electronic signal encoded by said electronic control board (156). The invention also relates to an underwater light communication method (200).

A head up display system includes first and second optical waveguides. A bracket holds the optical waveguides in a spaced-apart fixed relationship to one another such that their optical axes are separated by a distance of 63.5-65 millimeters. The optical waveguides are angularly disposed with respect to one another to produce a binocular image whose focal plane is located out at a distance of 2-4 meters. The bracket also specifically positions the optical waveguides adjacent to a transparent face plate of a dive helmet or dive mask.

A head up display system includes first and second optical waveguides. A bracket holds the optical waveguides in a spaced-apart fixed relationship to one another such that their optical axes are separated by a distance of 63.5-65 millimeters. The optical waveguides are angularly disposed with respect to one another to produce a binocular image whose focal plane is located out at a distance of 2-4 meters. The bracket also specifically positions the optical waveguides adjacent to a transparent face plate of a dive helmet or dive mask.

A head up display system includes first and second optical waveguides. A bracket holds the optical waveguides in a spaced-apart fixed relationship to one another such that their optical axes are separated by a distance of 63.5-65 millimeters. The optical waveguides are angularly disposed with respect to one another to produce a binocular image whose focal plane is located out at a distance of 2-4 meters. The bracket also specifically positions the optical waveguides adjacent to a transparent face plate of a dive helmet or dive mask.

A head up display system includes first and second optical waveguides. A bracket holds the optical waveguides in a spaced-apart fixed relationship to one another such that their optical axes are separated by a distance of 63.5-65 millimeters. The optical waveguides are angularly disposed with respect to one another to produce a binocular image whose focal plane is located out at a distance of 2-4 meters. The bracket also specifically positions the optical waveguides adjacent to a transparent face plate of a dive helmet or dive mask.

A digital vision system for use in turbid, dark or stained water is disclosed. Turbid water is opaque to the optical wavelengths viewable by humans but is transparent to near infrared (NIR) light. Using NIR wavelength illumination in turbid water allows viewing of objects that would otherwise not be visible through turbid water. NIR light is used to illuminate an area to be viewed. Video cameras comprising optical filters receive the NIR light reflected from objects in the camera field of view, producing camera video signals that may be processed and communicated to projector that convert the video signals to independent optical output video that is projected to the eye of the at optical frequencies viewable by humans. The user is thus provided with a real time vision system that allows the diver to visualize objects otherwise not visible using white light illumination.