Abstract: In one embodiment, a system includes, but is not limited to, an aviation head-mounted communication device including at least: a speaker, a physiological sensor configured to obtain physiological data, and a wireless communication interface; and a smartphone, a smartwatch, or tablet device wirelessly linked to the wireless communication interface and configured to receive the physiological data and output the physiological data on a display.
Abstract: In one embodiment, a system includes, but is not limited to, an aviation head-mounted communication device including at least: a speaker, a physiological sensor configured to obtain physiological data, and a wireless communication interface; and a smartphone, a smartwatch, or tablet device wirelessly linked to the wireless communication interface and configured to receive the physiological data and output the physiological data on a display.
Abstract: A system and process for an oxygen flow control system for supplemental oxygen is provided, including a system with an optical flow sensor and 3-way solenoid that operate to detect inhalation and deliver a microburst of oxygen that is electronically controlled based on one or more parameters.
Type:
Application
Filed:
April 21, 2022
Publication date:
November 3, 2022
Applicant:
Seabeck Holdings, LLC
Inventors:
James J Ruttler, James L Ruttler, Zuzana E Melherova
Abstract: In one embodiment, a system includes, but is not limited to, an aviation head-mounted communication device including at least: a speaker, a physiological sensor configured to obtain physiological data, and a wireless communication interface; and a smartphone, a smartwatch, or tablet device wirelessly linked to the wireless communication interface and configured to receive the physiological data and output the physiological data on a display.
Abstract: In one embodiment, an aviation communication headset includes, but is not limited to, at least one microphone; one or more speakers; one or more physiological sensors operable to monitor one or more health parameters of a wearer; and at least one control unit operable to perform operations including at least: obtaining one or more values from the one or more physiological sensors; and outputting information regarding the one or more values via the one or more speakers.
Abstract: In one embodiment, an aviation communication headset includes, but is not limited to, at least one microphone; one or more speakers; one or more physiological sensors operable to monitor one or more health parameters of a wearer; and at least one control unit operable to perform operations including at least: obtaining one or more values from the one or more physiological sensors; and outputting information regarding the one or more values via the one or more speakers.
Abstract: In one embodiment, an aviation communication headset includes, but is not limited to, at least one microphone; one or more speakers; one or more docks configured to interface with one or more eyepieces; and at least one control unit operable to perform operations including at least: detecting a presence of one or more eyepieces at the one or more docks; and outputting aviation flight information via the one or more docks for display on the one or more eyepieces.