A display system for an article of footwear includes a display device with an optoelectronic display, a control module that is configured to communicate with the display device, and a power source. The display system has a visual characteristic that is configured to correspond with a gait cycle of a user wearing the article of footwear.

A display system for an article of footwear includes a display device with an optoelectronic display, a control module that is configured to communicate with the display device, and a power source. The display system has a visual characteristic that is configured to correspond with a gait cycle of a user wearing the article of footwear.

A system comprising a body wearable unit, with one or more cameras, a control system, and an electrical power source and a method for generating wearer data using the system, wherein the method comprises monitoring with one or more cameras a user wearing the wearable unit and providing a related camera signal; generating wearer data based on the related camera signal, wherein the wearer data comprise one or more of (i) wearer posture related data and (ii) wearer movement related data.

A system comprising a body wearable unit, with one or more cameras, a control system, and an electrical power source and a method for generating wearer data using the system, wherein the method comprises monitoring with one or more cameras a user wearing the wearable unit and providing a related camera signal; generating wearer data based on the related camera signal, wherein the wearer data comprise one or more of (i) wearer posture related data and (ii) wearer movement related data.

A capacitive pressure detection insole is disclosed. The capacitive pressure detection insole includes a plurality of capacitive sensing nodes and an operating chip. When the capacitive pressure detection insole is subjected to a pressure provided by a foot of a user, the capacitive pressure detection insole uses the plurality of capacitive sensing nodes to sense a plurality of capacitance variations corresponding to a plurality of detection positions of the foot respectively. The operating chip receives the plurality of capacitance variations from the plurality of capacitive sensing nodes and obtains a pressure distribution information corresponding to the plurality of detection positions of the foot to determine a motion physiological status information of the foot of the user.

A system, method, and computer program product for calibrating force sensors is provided. The force sensors can be provided in a wearable device worn by a user underfoot. A force sensing apparatus has a plurality of apparatus force sensors and a charging unit. The charging unit can charge an energy storage device of the wearable device when the wearable device is received on the upper surface of the apparatus. The force sensing apparatus can sense a force applied to the upper surface of the apparatus when the wearable device is worn by a user while standing on the upper surface of the apparatus. At the same time, the force sensors in the wearable device can generate sensor readings. The system can determine a calibration model for the device force sensors by comparing the force values from the apparatus force sensors and the device force sensors in the wearable device.

A system, method, and computer program product for calibrating force sensors is provided. The force sensors can be provided in a wearable device worn by a user underfoot. A force sensing apparatus has a plurality of apparatus force sensors and a charging unit. The charging unit can charge an energy storage device of the wearable device when the wearable device is received on the upper surface of the apparatus. The force sensing apparatus can sense a force applied to the upper surface of the apparatus when the wearable device is worn by a user while standing on the upper surface of the apparatus. At the same time, the force sensors in the wearable device can generate sensor readings. The system can determine a calibration model for the device force sensors by comparing the force values from the apparatus force sensors and the device force sensors in the wearable device.

A position sensing assembly for a tensioning system designed to provide tension to a lace, cord, or other type of strand is disclosed. The tensioning system includes a reel member configured to rotate about a central axis and the position sensing assembly. The position sensing assembly includes a shaft, an indicator tab, and an optical sensing unit. The position sensing assembly assists in controlling the degree to which the strand is tightened and loosened. The position sensing assembly prevents tightening of the strand when the strand is meant to be loosened.

A position sensing assembly for a tensioning system designed to provide tension to a lace, cord, or other type of strand is disclosed. The tensioning system includes a reel member configured to rotate about a central axis and the position sensing assembly. The position sensing assembly includes a shaft, an indicator tab, and an optical sensing unit. The position sensing assembly assists in controlling the degree to which the strand is tightened and loosened. The position sensing assembly prevents tightening of the strand when the strand is meant to be loosened.

Smart insoles provide comfort and support while analyzing gait, improving posture and alignment, and tracking fitness metrics. Raw data from the smart insoles is fed into normative data algorithms to create a unique user report in real-time. A mobile app associated with the smart insole connects users to caregivers, articles, and personalized exercises. Monitoring of these parameters is used for managing chronic pain and sedentary lifestyle. The smart insole is a smart wearable device with a mobile app to monitor and manage chronic pain, which is an effective strategy in reducing foot pain and increasing physical activity.