Abstract: A system, according to various embodiments, includes eyewear (or any other suitable wearable device) that includes at least one environmental pollution monitoring sensor (e.g., at least one light pollution, air pollution, radioactive pollution, thermal pollution, and/or noise pollution sensor) that may be used to monitor the presence of environmental pollution adjacent a wearer of the eyewear. The system may further include one or more health monitoring sensors to determine the health effects of the environmental pollution on the wearer. In certain circumstances, the system may alert the user to potentially harmful environmental conditions, or convey preventative healthcare advice to the wearer.

Abstract: A system, according to various embodiments, includes eyewear (or any other suitable wearable device) that includes at least one environmental pollution monitoring sensor (e.g., at least one light pollution, air pollution, radioactive pollution, thermal pollution, and/or noise pollution sensor) that may be used to monitor the presence of environmental pollution adjacent a wearer of the eyewear. The system may further include one or more health monitoring sensors to determine the health effects of the environmental pollution on the wearer. In certain circumstances, the system may alert the user to potentially harmful environmental conditions, or convey preventative healthcare advice to the wearer.

Abstract: A computer-implemented method of detecting physiological attributes of a wearer of a computerized wearable device having one or more sensors comprises (1) using the information from the one or more sensors to assess the physiology of the wearer; and (2) notifying the wearer of the wearer's physiology. In various embodiments, the method involves using the wearable device to determine the wearer's current posture, balance, alertness, and/or physical state and comparing the current posture, balance, alertness and/or physical state to at least one baseline measurement. For example, the system may measure a baseline posture to determine when the wearer's current posture deviates from the baseline posture, and notify the wearer so that the wearer may improve his or her posture. In other embodiments, the computerized wearable device may detect one or more of the wearer's physiological characteristics (e.g., oxygen levels, pulse rate, pupil size, etc.) and determine the wearer's alertness level.

Abstract: Eyewear or any other suitable wearable device may include one or more sensors for monitoring the gait of an individual. Information from the one or more sensors is analyzed to identify one or more medical conditions associated with the individual or to assess an individual's recovery from a particular injury or medical procedure.

Abstract: A wearable device includes at least one sensor for obtaining a unique identifier from the wearer when the wearer and for transmitting the unique identifier to one or more computer processors for use in determining whether the wearer is a particular individual. The wearable device may also include a wireless communications device for transmitting a signal (e.g., to a remote computing device) that confirms the identity of the wearer as the particular individual. A remote computing device, or other device, or individual, may then, based at least in part on receiving the signal, grant wearer access to a computer program, computing system, and/or a particular physical space.

Abstract: A tracking system, in various embodiments, is configured to measure an athlete's performance based at least in part on magnetic field measurements taken by one or more magnetometers. In a particular embodiment, the system comprises one or more magnetometers (e.g., that may be embedded in one or more wearable devices, such as eyewear) and at least one magnet disposed on a portion of the athlete or their equipment. The system is configured to receive magnetic field information associated with the at least one magnet using the one or more magnetometers and determine the performance data based at least in part on the magnetic field information.

Abstract: A system, according to various embodiments, includes eyewear (or any other suitable wearable device) that includes one or more sensors (e.g., one or more accelerometers, magnetometers, position sensors, gyroscopes, and/or other suitable sensors) that may be used to monitor the gait of an individual (e.g., by monitoring the movement of the user's head, or other portions of the user's body, as the user ambulates). The system may further include one or more suitable computing devices for analyzing the individual's gait. This information may then be used, for example, to: (1) identify one or more medical conditions associated with the individual; (2) assess the fit of a prosthetic device worn by the individual, and/or (3) assess an individual's recovery from a particular injury or medical procedure.

Abstract: A computer-implemented method of detecting physiological attributes of a wearer of a computerized wearable device having one or more sensors comprises (1) using the information from the one or more sensors to assess the physiology of the wearer; and (2) notifying the wearer of the wearer's physiology. In various embodiments, the method involves using the wearable device to determine the wearer's current posture, balance, alertness, and/or physical state and comparing the current posture, balance, alertness and/or physical state to at least one baseline measurement. For example, the system may measure a baseline posture to determine when the wearer's current posture deviates from the baseline posture, and notify the wearer so that the wearer may improve his or her posture. In other embodiments, the computerized wearable device may detect one or more of the wearer's physiological characteristics (e.g., oxygen levels, pulse rate, pupil size, etc.) and determine the wearer's alertness level.

Abstract: A tracking system, in various embodiments, is configured to measure an athlete's performance based at least in part on magnetic field measurements taken by one or more magnetometers. In a particular embodiment, the system comprises one or more magnetometers (e.g., that may be embedded in one or more wearable devices, such as eyewear) and at least one magnet disposed on a portion of the athlete or their equipment. The system is configured to receive magnetic field information associated with the at least one magnet using the one or more magnetometers and determine the performance data based at least in part on the magnetic field information.

Abstract: A computer-implemented method of detecting physiological attributes of a wearer of a computerized wearable device having one or more sensors comprises (1) using the information from the one or more sensors to assess the physiology of the wearer; and (2) notifying the wearer of the wearer's physiology. In various embodiments, the method involves using the wearable device to determine the wearer's current posture, balance, alertness, and/or physical state and comparing the current posture, balance, alertness and/or physical state to at least one baseline measurement. For example, the system may measure a baseline posture to determine when the wearer's current posture deviates from the baseline posture, and notify the wearer so that the wearer may improve his or her posture. In other embodiments, the computerized wearable device may detect one or more of the wearer's physiological characteristics (e.g., oxygen levels, pulse rate, pupil size, etc.) and determine the wearer's alertness level.

Abstract: A wearable device includes at least one sensor for obtaining a unique identifier from the wearer when the wearer and for transmitting the unique identifier to one or more computer processors for use in determining whether the wearer is a particular individual. The wearable device may also include a wireless communications device for transmitting a signal (e.g., to a remote computing device) that confirms the identity of the wearer as the particular individual. A remote computing device, or other device, or individual, may then, based at least in part on receiving the signal, grant wearer access to a computer program, computing system, and/or a particular physical space.

Abstract: A winter sports tracking system, in various embodiments, is configured to measure winter sports athlete speed, heading, distance traveled, acceleration, and other motion related measurements based at least in part on magnetic field measurements taken by one or more magnetometers. In a particular embodiment, the system comprises one or more magnetometers (e.g., that may be embedded in one or more wearable devices, such as eyewear) and at least one magnet disposed on a portion of the winter sports athlete or their equipment. The system is configured to receive magnetic field information associated with the at least one magnet using the one or more magnetometers and determine the speed and other data based at least in part on the magnetic field information. In various embodiments, the system is configured to track movement and speed of a skier or snowboarder.

Abstract: Eyewear, according to various embodiments, comprises at least one biometric sensor that is adapted for taking a biometric reading from the wearer when the wearer is operatively wearing the eyewear and for transmitting the results of the biometric reading to one or more computer processors for use in determining whether the wearer is a particular individual. The eyewear may also include a wireless communications device for transmitting a signal (e.g., to a remote computing device) that confirms the identity of the wearer as the particular individual. A remote computing device, or other device, or individual, may then, based at least in part on receiving the signal, grant wearer access to a computer program, computing system, and/or a particular physical space.

Abstract: A computer-implemented method, and related system, for monitoring the wellbeing of an individual by providing eyewear that includes at least one sensor for monitoring the motion of the user. In various embodiments, the system receives data generated by the at least one sensor, uses the data to determine the user's movements using the received data, and compares the user's movements to previously established movement patterns of the user. If the system detects one or more inconsistencies between the user's current movements as compared to the previously established movement patterns of the user, the system may notify the user or a third party of the detected one or more inconsistencies. The system may similarly monitor a user's compliance with a medical regime and notify the user or a third party of the user's compliance with the regime.

Abstract: A computer-implemented method, and related system, for monitoring the wellbeing of an individual by providing eyewear that includes at least one sensor for monitoring the motion of the user. In various embodiments, the system receives data generated by the at least one sensor, uses the data to determine the user's movements using the received data, and compares the user's movements to previously established movement patterns of the user. If the system detects one or more inconsistencies between the user's current movements as compared to the previously established movement patterns of the user, the system may notify the user or a third party of the detected one or more inconsistencies. The system may similarly monitor a user's compliance with a medical regime and notify the user or a third party of the user's compliance with the regime.

Abstract: Eyewear, according to various embodiments, comprises at least one biometric sensor that is adapted for taking a biometric reading from the wearer when the wearer is operatively wearing the eyewear and for transmitting the results of the biometric reading to one or more computer processors for use in determining whether the wearer is a particular individual. The eyewear may also include a wireless communications device for transmitting a signal (e.g., to a remote computing device) that confirms the identity of the wearer as the particular individual. A remote computing device, or other device, or individual, may then, based at least in part on receiving the signal, grant wearer access to a computer program, computing system, and/or a particular physical space.

Abstract: Eyewear, according to various embodiments, comprises at least one biometric sensor that is adapted for taking a biometric reading from the wearer when the wearer is operatively wearing the eyewear and for transmitting the results of the biometric reading to one or more computer processors for use in determining whether the wearer is a particular individual. The one or more processors may be embodied within the eyewear, and the eyewear may also include a wireless communications device for transmitting a signal (e.g., to a remote computing device) that confirms the identity of the wearer as the particular individual. A remote computing device, or other device, or individual, may then, based at least in part on receiving the signal, grant wearer access to a computer program, computing system, and/or a particular physical space.

Abstract: A vehicle tracking system, in various embodiments, is configured to measure vehicle speed, heading, distance travelled, acceleration, and other motion related measurements based at least in part on magnetic field measurements taken by one or more magnetometers. In a particular embodiment, the system comprises one or more magnetometers (e.g., that may be embedded in one or more wearable devices, such as eyewear) and at least one magnet disposed on a portion of the vehicle such as the vehicle's wheel. The system is configured to receive magnetic field information associated with the at least one magnet using the one or more magnetometers and determine the speed and other data based at least in part on the magnetic field information. In various embodiments, the system is configured to track movement and speed of a bicycle.

Abstract: A winter sports tracking system, in various embodiments, is configured to measure winter sports athlete speed, heading, distance travelled, acceleration, and other motion related measurements based at least in part on magnetic field measurements taken by one or more magnetometers. In a particular embodiment, the system comprises one or more magnetometers (e.g., that may be embedded in one or more wearable devices, such as eyewear) and at least one magnet disposed on a portion of the winter sports athlete or their equipment. The system is configured to receive magnetic field information associated with the at least one magnet using the one or more magnetometers and determine the speed and other data based at least in part on the magnetic field information. In various embodiments, the system is configured to track movement and speed of a skier or snowboarder.

Abstract: A computer-implemented method, and related system, for monitoring the wellbeing of an individual by providing eyewear that includes at least one sensor for monitoring the motion of the user. In various embodiments, the system receives data generated by the at least one sensor, uses the data to determine the user's movements using the received data, and compares the user's movements to previously established movement patterns of the user. If the system detects one or more inconsistencies between the user's current movements as compared to the previously established movement patterns of the user, the system may notify the user or a third party of the detected one or more inconsistencies. The system may similarly monitor a user's compliance with a medical regime and notify the user or a third party of the user's compliance with the regime.