A gesture recognition device configured to detect a gesture performed by a user to actuate a motor of a closure mechanism of an article of footwear. The gesture recognition device may include a sensor unit with an accelerometer sensor, and an analysis unit in operative communication with the sensor unit. The analysis unit may be configured to execute a gesture confirmation algorithm to confirm or reject possible gesture event data received from the sensor unit as a true gesture event. If the gesture confirmation algorithm confirms the possible gesture event data as a true gesture event, the analysis unit may output a signal to actuate the motor.

Systems and methods described herein include receiving, by a processor, one or more data files from an ultrasound shear wave elastography apparatus configured to capture viscoelastic tissue properties in an area of a subject using ultrasound shear wave electrography, processing the one or more data files to compute viscoelastic tissue parameters related to the area of the subject, compiling the viscoelastic tissue parameters and one or more associated data file identifiers to generate a processed data file, wherein the one or more associated data file identifiers includes at least one of: user characteristics, exercise characteristics, a footwear type, or an apparel type, and generating a recommendation report, wherein the recommendation report includes a footwear recommendation selected based on one or more trends from the viscoelastic tissue parameters.

An article of apparel, a system, and methods include a structural material configured to enable the article of footwear to the worn on a body. A wireless transmission circuit is included and a piezoelectric generator is positioned with respect to the structural material in a configuration to be flexed to induce a voltage signal output. A voltage sensor is configured to sense the voltage profile and output a sensor signal indicative of the voltage profile. An electronic data storage, coupled to the voltage sensor, is configured to store voltage profile information based on the sensor data. A comparator, coupled to the electronic data storage, is configured to identify a change in the voltage profile information over time. The wireless transmission circuit is configured to transmit data indicative of a physical status of the article of footwear based on the change in the voltage profile information over time.

Provided is an insole-type electronic device wherein the electronic module is not susceptible to impact and/or load due to walking or running. The insole-type electronic device is an electronic device wherein an electronic module has been incorporated in the insole that is laid on the midsole of a shoe and contacts the sole of the foot. The insole-type electronic device has an insole body with the shape of a normal insole. Said insole body has a heel-protecting part that extends upward from the back end of the heel section of the insole body along the perimeter of the back end of the heel section. Additionally, the insole-type electronic device has an electronic module that is housed in the heel-protecting part.

Stability footwear (e.g., a pair of therapeutic shoes) may include at least one stabilizing member, stabilizer, and/or outrigger on a lateral (outer or inner) side of a shoe, substantially adjacent to a sole of a shoe. A stabilizer may be positioned proximate a surface on which the sole rests and extending anywhere from a front, substantially a toe, to a heel of a shoe. The stabilizing member, stabilizer, and/or outrigger may reduce undesired foot roll and consequential ankle injuries and/or falls, by providing additional lateral support that does not compromise mobility or performance of the user.

Stability footwear (e.g., a pair of therapeutic shoes) may include at least one stabilizing member, stabilizer, and/or outrigger on a lateral (outer or inner) side of a shoe, substantially adjacent to a sole of a shoe. A stabilizer may be positioned proximate a surface on which the sole rests and extending anywhere from a front, substantially a toe, to a heel of a shoe. The stabilizing member, stabilizer, and/or outrigger may reduce undesired foot roll and consequential ankle injuries and/or falls, by providing additional lateral support that does not compromise mobility or performance of the user.

A system for measuring power output of a runner is disclosed. In some embodiments the system comprises a first sensor component including a first sensor, microprocessor, and a signal transceiver; a second sensor component including a second sensor and a signal transmitter; wherein the first sensor is configured to measure a vertical velocity and horizontal velocity, the second sensor is configured to measure the slope angle of a foot of the runner during a stance phase of the foot, the signal transmitter configured to send slope angle data, the signal transceiver configured to receive the slope angle data from the signal transmitter, and the microprocessor has computing instructions configured to calculate a power output based on the vertical velocity, horizontal velocity, and slope angle data.

An athlete monitoring system includes body position beacons, a localized radar system, a foot force detection system, and a processing module. The beacons are positioned at various locations on the body of the athlete. The localized radar system creates a localized radar coordinate system in which the athlete is positioned and, at a first sampling rate, produces frames of body position data based on determining location of the beacons within the localized radar coordinate system. The foot force detection system generates frames of left foot force data and frames of right foot force data. The processing module correlates the frames of body position data, the frames of left foot force data, and the frames of right foot force data to produce integrated ground-body interaction data and athletic movement data.

An athlete monitoring system includes body position beacons, a localized radar system, a foot force detection system, and a processing module. The beacons are positioned at various locations on the body of the athlete. The localized radar system creates a localized radar coordinate system in which the athlete is positioned and, at a first sampling rate, produces frames of body position data based on determining location of the beacons within the localized radar coordinate system. The foot force detection system generates frames of left foot force data and frames of right foot force data. The processing module correlates the frames of body position data, the frames of left foot force data, and the frames of right foot force data to produce integrated ground-body interaction data and athletic movement data.

A foot force detection system includes variable capacitors, drive sense circuits, a processing module, and a power unit. A drive sense circuit supplies a reference signal to the variable capacitor. It then generates a sensed signal regarding a characteristic of the variable capacitor based on the reference signal. It then converts the sensed signal into a digital signal. The processing module generates a digital impedance value for the variable capacitor based on the digital signal and writes the digital impedance value in memory. The power unit include a battery and a power harvesting circuit, where the battery and/or the power harvesting circuit provide power for the foot force detection system.