An interactive life system for increasing the safety of person in water having a base station configured to communicate with a remote node; the base station having a first controller having a first microcontroller; and a transceiver means; wherein the base station further includes an alert for alerting a monitor, a pager; a NOAA weather receiver; wherein the remote node comprises a second controller, a second transceiver, a GPS, a buoy, a panic button, a pressure transducer, a visual indicator, a vibrating motor, and a mount; wherein the second controller comprises a second microcontroller; wherein the panic button communicates with the base station; wherein the visual indicator includes light; wherein the vibrating motor includes a mechanical indicator; and where the monitee can wear the device on the wrist.

This invention is directed toward a body board, used for riding ocean waves, paddling through standing water, and other aquatic uses, which has one or more strings of optionally removable LED lights disposed in one or more channels that have been molded or routed into the top, bottom, or sides of the body board. The channels are, in one embodiment, removably covered with a water-resistant covering that can be opened to remove or exchange the LED lights. The body board also includes a cavity into which a battery (optionally, with a solar charger) is placed, where the battery powers the LED's, and means of controlling the LED's. The battery cavity, in the first embodiment, is also covered by a water-resistant covering that can be opened to access the battery for removal or replacement. In a second embodiment, the cover is permanent, allowing for a more waterproof cover.

This invention is directed toward a body board, used for riding ocean waves, paddling through standing water, and other aquatic uses, which has one or more strings of optionally removable LED lights disposed in one or more channels that have been molded or routed into the top, bottom, or sides of the body board. The channels are, in one embodiment, removably covered with a water-resistant covering that can be opened to remove or exchange the LED lights. The body board also includes a cavity into which a battery (optionally, with a solar charger) is placed, where the battery powers the LED's, and means of controlling the LED's. The battery cavity, in the first embodiment, is also covered by a water-resistant covering that can be opened to access the battery for removal or replacement. In a second embodiment, the cover is permanent, allowing for a more waterproof cover.

A buoy, and systems and methods for rescuing people isolated on large bodies of water are disclosed. The buoy includes a remotely activatable device that is activatable when a signal is received from a remote source. The activatable device may be a signaling device, or an assistance device that is deployable by the buoy to assist in rescuing a person. A marine communication system formed by a number of spaced apart rescue buoys is also provided. A message or key other information can be transmitted to every buoy in the network via communication with just one buoy. The methods for rescuing people isolated on large bodies of water involve providing the network of communication buoys that can receive communications from the isolated person's personal communication device, and then transmit a signal to remotely activate an activatable device in a buoy to assist in the rescue of the person.

A buoy, and systems and methods for rescuing people isolated on large bodies of water are disclosed. The buoy includes a remotely activatable device that is activatable when a signal is received from a remote source. The activatable device may be a signaling device, or an assistance device that is deployable by the buoy to assist in rescuing a person. A marine communication system formed by a number of spaced apart rescue buoys is also provided. A message or key other information can be transmitted to every buoy in the network via communication with just one buoy. The methods for rescuing people isolated on large bodies of water involve providing the network of communication buoys that can receive communications from the isolated person's personal communication device, and then transmit a signal to remotely activate an activatable device in a buoy to assist in the rescue of the person.

A radar system. The radar system may include a housing having a base for mounting on a marine vessel. The radar system may include a radar disposed inside the housing. The radar system may include an antenna coupled to the radar. The radar system may also include a lighting system having a light source, and where a portion of the lighting system is disposed inside the housing. The radar system may include a controller coupled to the lighting system.

A radar system. The radar system may include a housing having a base for mounting on a marine vessel. The radar system may include a radar disposed inside the housing. The radar system may include an antenna coupled to the radar. The radar system may also include a lighting system having a light source, and where a portion of the lighting system is disposed inside the housing. The radar system may include a controller coupled to the lighting system.

A motorized watercraft is a vehicle that is used to transport a user across the water. The motorized watercraft includes a floating board, a control unit, at least one electrically accessible system, a power source, and at least one conduit stringer. The floating board allows a user to float above the water. The at least one electrically accessible system may include a propulsion system, lights, or other features. The control unit is mounted to the deck of the floating board and is used to regulate the speed of the propulsion system and may be used to control lights which are mounted into the floating board. The power source is used to provide the energy needed for running the propulsion system and the lights. The conduit stringer runs through the floating board, strengthening the floating board and providing a channel through which wiring may run.

A motorized watercraft is a vehicle that is used to transport a user across the water. The motorized watercraft includes a floating board, a control unit, at least one electrically accessible system, a power source, and at least one conduit stringer. The floating board allows a user to float above the water. The at least one electrically accessible system may include a propulsion system, lights, or other features. The control unit is mounted to the deck of the floating board and is used to regulate the speed of the propulsion system and may be used to control lights which are mounted into the floating board. The power source is used to provide the energy needed for running the propulsion system and the lights. The conduit stringer runs through the floating board, strengthening the floating board and providing a channel through which wiring may run.

The present invention relates to a wearable universal wireless controller configured to generate control signals for controlling a plurality of devices without the need for hardware or software modification. Such controller comprises a plurality of stretch sensors and switch sensors associated with at least one glove or similar structure configured for being associated with a users' hand. The controller detects finger and hand movements and generates the appropriate communication signal based on values contained in a configuration table. The same wireless controller can control a plurality of devices without the need for reprogramming or mode selections.