Abstract: A method for determining a status of a user utilizing wireless earpieces includes performing sensor measurements of a user utilizing at least optical sensors of the wireless earpieces, wherein the optical sensors detect metabolic abnormalities of the user, analyzing the sensor measurements, determining the status of the user utilizing at least sensor measurements from the optical sensors of the wireless earpieces, and communicating an alert to the user in response to there being a change in the status of the user. A wireless earpiece or set of wireless earpieces with optical sensors for detecting metabolic abnormalities are also provided.

Abstract: A system, method, and wireless earpieces for managing power settings. Sensor measurements are performed utilizing a first sensor array of the wireless earpieces to detect light and motion. Sensor measurements are performed utilizing a second sensor array of the wireless earpieces to detect light and motion. The sensor measurements are analyzed from the first sensor array and the second sensor array. A determination is made whether a change event is detected in response to the sensor measurements. The change event is confirmed as detected. The wireless earpieces enter a full power mode in response to the change event being confirmed.

Abstract: A method of verifying an identity of a user using a set of earpieces includes communicating a first sound toward a tympanic membrane of the left ear, communicating a second sound toward a tympanic membrane of the right ear, receiving reflected sounds from an ear canal of the left ear, receiving reflected sounds from an ear canal of the right ear, comparing acoustic properties of the reflected sounds with acoustic properties stored in a memory device, and verifying the identity of the user if the acoustic properties of the reflected sounds match the stored acoustic properties.

Abstract: In some embodiments, a method for providing feedback through wireless earpieces, may have one or more of the following steps: (a) detecting a position of the wireless earpieces in ears of a user utilizing a number of contacts, (b) analyzing how to modify communications with the user based on the position, (c) communicating with the user utilizing the analysis, (d) adjusting an orientation of one or more speakers of the wireless earpieces in response to the position, and (e) adjusting a plurality of sensors in response to the position.

Abstract: An earpiece includes an earpiece housing, an intelligent control disposed within the ear piece housing, at least one audio input sensor operatively connected to the intelligent control, a transceiver operatively connected to the intelligent control, and a user interface operatively connected to the intelligent control and configured for receiving user input. The intelligent control is configured to receive voice input through the at least one audio input sensor and interpret the voice input to determine a voice command from a set of voice commands.

Abstract: A method for selective sound field environment processing for one or more wireless earpieces, each of the one or more wireless earpieces including comprising a plurality of microphones is provided. The method includes receiving audio input of a sound field environment from the plurality of microphones of each of the one or more wireless earpieces, identifying background noise in the sound field environment, identifying audio from at least one sound source within the sound field environment, processing the audio input using one or more processors of at least one of the wireless earpieces to reduce the background noise and processing the audio input using one or more processors of the at least one of the wireless earpieces to enhance the audio from the at least one sound source within the sound field environment to provide processed audio, and transducing the processed audio at one or more speakers of the one or more wireless earpieces.

Abstract: An earpiece includes an earpiece housing, at least one biometric sensor disposed within the earpiece, a wireless transceiver disposed within the earpiece for voice communications, an intelligent control operatively connected to the at least one biometric sensor and the wireless transceiver, a speaker operatively connected to the intelligent control, and at least one microphone operatively connected to the intelligent control. The earpiece is configured to monitor biometrics of a user using the at least one biometric sensor, communicate biometric data to the user, detect a crisis level event, and communicate occurrence of the crisis level event using the wireless transceiver.

Abstract: A system of wearable or personal area devices includes a first earpiece and a second ear piece each of the first ear piece and the second ear piece comprising an ear piece housing, an induction circuit disposed within the ear piece housing for short range communications, and a radio transceiver disposed within the ear piece housing for radio communications. The induction circuit of the first ear piece and the induction circuit of the second ear piece are adapted for communication there between using high bandwidth audio.

Abstract: An ear piece for use by an individual having an external auditory canal includes an earpiece housing configured for placement within the external auditory canal of the individual, a processor disposed within the ear piece housing, at least one microphone disposed within the earpiece housing wherein the at least one earpiece is positioned to detect ambient environmental sound, and at least one speaker disposed within the earpiece housing. The ear piece is configured to detect ambient environmental sound proximate the external auditory canal of the individual using the at least one microphone and reproduce the ambient environmental sound at the at least one speaker within the earpiece housing. The processor is further configured to modify the ambient environmental sound based on shape of the external auditory canal such that audio perception of the ambient environmental sound is as if the ear piece was not present.

Abstract: An earpiece includes an earpiece housing, a processor disposed within the earpiece housing, a gesture based interface operatively connected to the processor and configured to detect changes in an energy field associated with user gestures, and at least one sensor operatively connected to the processor for determining positioning of the ear piece. The processor is configured to interpret the changes in the energy field to determine the user gestures. The processor is configured to activate the ear piece based on the positioning of the ear piece.

Abstract: A system, method and one or more wireless earpieces for performing self-configuration. A user is identified utilizing the one or more wireless earpieces. Noises from an environment of the user are received utilizing the one or more wireless earpieces. An audio profile associated with the noises of the environment of the user is determined. The components of the one or more wireless earpieces are automatically configured in response to the audio profile and the user identified as utilizing the one or more wireless earpieces.

Abstract: An eyewear wearable includes an eyewear frame, a lens integrated into the eyewear frame, a display integrated with the lens, an intelligent control housing mounted at a behind-the-ear portion of the eyewear frame, an intelligent control with graphics support mounted within the intelligent control housing, a near field magnetic induction transceiver disposed within the intelligent control housing for communicating with an earpiece, the near field magnetic induction transceiver operatively connected to the intelligent control, and a cable between the intelligent control housing and the display.

Abstract: An intelligent wireless headset system in embodiments of the present invention may have one or more of the following features: (a) a left ear portion having at least one microphone and at least one speaker associated therewith, (b) a right ear portion having at least one microphone and at least one speaker associated therewith, (c) a connecting band between the left ear portion and the right ear portion, (d) a wireless radio transceiver disposed within the intelligent wireless headset, (e) a cellular transceiver disposed within the intelligent wireless headset, (f) a headset network capable of operably coupling the intelligent wireless headset with at least one device in the headset network, (g) sensors to collect biometric information, (h) a camera for collecting video information, (i) outer speakers located on the housing, and (j) a memory for storing biometric information.

Abstract: A method of providing audio feedback in response to a user performance using an earpiece includes steps of identifying a manual work operation to be performed by the user, wherein the identifying the manual work operation is performed by the earpiece, monitoring performance of the manual work operation by the user, wherein the monitoring the performance of the work operation is performed by the earpiece, generating 3D sound cues at the earpiece to assist in the performance of the manual work operation by the user, and outputting the 3D sound cues to the user at one or more speakers of the earpiece during the performance of the manual work operation by the user.

Abstract: An earpiece includes an earpiece housing sized and shaped to block an external auditory canal of a user, at least one microphone positioned to sense ambient sound, a speaker, and a processor disposed within the earpiece housing and operatively connected to each of the at least one microphone and the speaker, wherein the processor is configured to modify the ambient sound based on user preferences to produce modified ambient sound in a first mode of operation and to produce a second sound in response to a trigger condition. The second sound may be an unmodified version of the ambient sound. The second sound may be a modified version of the ambient sound which suppresses at least a portion of the ambient sound. The second sound may be a warning sound.

Abstract: A system and method for managing wireless earpieces. Circuitry of the wireless earpieces are powered utilizing a high-power mode in response to detecting a magnetic field is not applied to one or more of the wireless earpieces. The power sent to the circuitry of the wireless earpieces is altered to a low power mode in response to detecting the magnetic field is applied to one or more of the wireless earpieces.

Abstract: An earpiece includes an earpiece housing, a processor disposed within the housing and a sensor system associated with the earpiece housing, the sensor system operatively connected to the processor. The sensor system is configured to detect skin touches proximate the earpiece housing. The sensor system may include an emitter and a detector which may be a light emitters/light detectors or other types of emitters and detectors. The skin touches may be skin touches on an ear of the housing while the earpiece is positioned within the ear. The earpiece may further include a speaker and wherein the earpiece provides audio feedback through the speaker in response to the skin touches.

Abstract: An earpiece includes an earpiece housing, a processor disposed within the earpiece housing, and a gesture based interface operatively connected to the processor and configured to detect changes in an energy field associated with user gestures. The processor is configured to interpret the changes in the energy field to determine the user gestures.

Abstract: A method for improving biometric data by using a plurality of wearable devices on a network includes making a first measurement at a first wearable sensor at a first location on a body, making a second measurement at a second wearable sensor positioned at a second location on the body, and detecting an arterial pulse wave transmit time using the first measurement and the second measurement.

Abstract: A system, method and personal area network for communicating utilizing a wireless earpiece. Sensor measurements of a user are performed utilizing sensors of the wireless earpieces. The sensor measurements are analyzed. A determination is made whether the sensor measurements exceed two or more thresholds. An alert is communicated to the user in response to the two or more thresholds being exceeded.