Abstract: A physiological monitoring system can use physiological wearable monitors to collect and/or detect various parameters, such as cough, wheeze, heart rate, skin temperature, activity, respiration rate, skin impedance, electro-cardiogram data, blood pressure, galvanic skin response, and the like. One or more of these parameters, or other such parameters, may be used in methods in the fields of lung cancer, physiotherapy, monitoring disabled or challenged individuals, monitoring end of life conditions, monitoring breathing gas usage, monitoring patients and individual wellness, data acquisition, athletic sports monitoring, athletic sports entertainment, virtual reality feedback, telemedicine, hospital aid, illness detection and its severity, and public service, as examples. Such methods can use data from one or more wearable devices with the appropriate data processing to present the user or healthcare provider with the appropriate analysis.

Abstract: A monitoring and alerting system can be used in any condition with a respiration component. Respiratory symptoms as well as supporting physiological functions are tracked against the user's baseline and alerts the user when there is a worsening trend. The system is self-contained in a wearable that detects and logs the signals, analyzes them and generates alerts. The wearable is untethered during use and may be attached to the body in various manners, such as with adhesives, clothing, clips, belts, chains, necklaces, ear pieces, clothing circuits or the like. Information can further be transmitted both wirelessly and via wire to devices, cloud storage, or the like.

Abstract: A wearable and/or a wearable mount solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The adhesive layer can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.

Abstract: A physiological monitoring system can use physiological wearable monitors to collect and/or detect various parameters, such as cough, wheeze, heart rate, skin temperature, activity, respiration rate, skin impedance, electro-cardiogram data, blood pressure, galvanic skin response, and the like. One or more of these parameters, or other such parameters, may be used in methods in the fields of lung cancer, physiotherapy, monitoring disabled or challenged individuals, monitoring end of life conditions, monitoring breathing gas usage, monitoring patients and individual wellness, data acquisition, athletic sports monitoring, athletic sports entertainment, virtual reality feedback, telemedicine, hospital aid, illness detection and its severity, and public service, as examples. Such methods can use data from one or more wearable devices with the appropriate data processing to present the user or healthcare provider with the appropriate analysis.

Abstract: Disclosed are methods and systems for generating a customized garment design. The method, when executed by a processor, comprises first receiving user data, generating at least one user signal, identifying a preferred garment category by analyzing the user data, retrieving related third-party data and public data, and retrieving features for the identified garment category from a database. For features associated with cuts and fabrics, preferred cut values and preferred fabric values are identified based on previously received data, and corresponding value scores computed. For other features, preferred feature values are identified, and corresponding value scores computed. One or more feature sets are generated by selecting a preferred value for each feature, where an associated feature set score is computed based on the value scores and one or more score adjustments. A customized garment design is generated by selecting a feature set with a high feature set score.

Abstract: The technology disclosed relates to methods usable for determining measurements for custom clothing manufacture, including receiving a raw image of a clothing article and a scale reference, and applying perspective correction to adjust the raw image to produce an adjusted image. The method also includes determining a scale reference from the adjusted image, for use with a line measurement tool; and receiving user inputs that positions ends of the line measurement tool on measurement reference positions on the adjusted image of the clothing article. The method further includes generating multiple clothing article distances between the measurement reference positions on the adjusted image of the clothing article using the line measurement tool; and storing at least three clothing article distances for use in producing a custom clothing article with a fit based on the favorite clothing article in the raw image.

Abstract: A wearable and/or a wearable mount solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The adhesive layer can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.

Abstract: The technology disclosed relates to methods usable for determining measurements for custom clothing manufacture, including receiving a raw image of a clothing article and a scale reference, and applying perspective correction to adjust the raw image to produce an adjusted image. The method also includes determining a scale reference from the adjusted image, for use with a line measurement tool; and receiving user inputs that positions ends of the line measurement tool on measurement reference positions on the adjusted image of the clothing article. The method further includes generating multiple clothing article distances between the measurement reference positions on the adjusted image of the clothing article using the line measurement tool; and storing at least three clothing article distances for use in producing a custom clothing article with a fit based on the favorite clothing article in the raw image.

Abstract: A monitoring and alerting system can be used in any condition with a respiration component. Respiratory symptoms as well as supporting physiological functions are tracked against the user's baseline and alerts the user when there is a worsening trend. The system is self-contained in a wearable that detects and logs the signals, analyzes them and generates alerts. The wearable is untethered during use and may be attached to the body in various manners, such as with adhesives, clothing, clips, belts, chains, necklaces, ear pieces, clothing circuits or the like. Information can further be transmitted both wirelessly and via wire to devices, cloud storage, or the like.