A low power force detection system includes variable capacitors, a drive sense module, and a processing module. A drive sense circuit of the drive sense module is operable to provide an analog and frequency domain signal to a variable capacitor. The drive sense circuit is further operable to detect a characteristic of the variable capacitor based on the analog and frequency domain signal and to generate a representative signal of the characteristic. The processing module is operable to generate a digital value based on the representative and to write the digital value to memory.

Implementations are directed to a pressure-sensing device including a pressure-sensitive sheet, one or more pressure-sensitive input regions disposed along the pressure-sensitive sheet including a first conductive thread including a first length in contact with the pressure-sensitive sheet, and a second conductive thread including a second length in contact with the pressure-sensitive sheet. At least a first portion of the first length of the first conductive thread passes through the pressure-sensitive sheet through a first hole in the pressure-sensitive sheet at a first location and a second portion of the second length of the second conductive thread passes through the pressure-sensitive sheet through a second hole in the pressure-sensitive sheet at a second location.

A system for analysis of user gait and to provide correction in form of haptic and visual feedback. This system comprises a motion and force sensors and a haptic actuator embedded in the user shoe insoles in communication with a smart-phone based analysis application, configured to calculate motion and orientation of the user feet in relation to the value, location and distribution of ground reaction forces measured by sensors located in the shoe insoles and after analysis of said forces and motion, to provide haptic feedback to the user foot instructing about the location (and timing) of pressure the user must apply to achieve an optimal gait.

An intelligent shoe comprises one or more sensorial devices configured to generate sensorial signals to instruct a wearer to walk along a pedestrian path. The intelligent shoe is configured to cause a current location of the wearer to be determined and to obtain a pedestrian path between the current location and the destination location. The intelligent shoe then causes the one or more sensorial devices to generate sensorial signals, instructing the wearer to move along the pedestrian path.

A force detection system includes first and second sets of pressure sensors, memory, and a processing module. The first set of pressure sensors are in an insole of a shoe and the second set of pressure sensors are in an outsole of a shoe. The processing module receives first data regarding the first set of pressure sensors and generates a first digital representation of the first data. The processing module also receives second data regarding the second set of pressure sensors and generates a second digital representation of the second data. The processing module also writes the first and second digital representations to the memory.

An article of apparel providing dynamic support for an appendage of a person is discussed herein. The article of apparel can include a support garment control device configured to provide dynamic support. The support garment control device can include a control lace coupled to a support portion of the article of apparel. In an example, the support garment control device configured to apply a first tension on the control lace, lock the support garment control device at the first tension to inhibit movement of the control lace in response to detecting a change in movement of the person, and unlock the support garment control device after a pre-determined event subsequent to the change in movement of the person.

A biometric sensor includes a body surface sensor and an e-field signal transmitter. The body surface sensor create a drive-sense signal at a first frequency based on one or more sensing parameters. When operably coupled to a body via one or more electrodes, the body surface sensor provides the drive-sense signal to the body and detects an effect on the drive-sense signal based on electrical characteristics of the body. The body surface sensor generate a data signal based on the detected effect, wherein the data signal represents the body’s electrical characteristics. The e-field signal transmitter generates an outbound signal reference at a second frequency based on the data signal and one or more transmit parameters. The e-field transmitter drives the outbound reference signal to the body, wherein the outbound reference signal is transmitted within at least a portion of the body as an outbound e-field signal at the second frequency.

A cycling shoe assembly is basically provided with a cleat and a shoe. The cycling shoe is configured to be coupled to the cleat. In one configuration, the cycling shoe has a first connector that is configured to be electrically connected to a pedal in a coupled state where the cleat is coupled with the pedal. In another configuration, the cleat has a second connector that is configured to be electrically connected to a pedal in a coupled state where the cleat is coupled with the pedal.

A cycling shoe system is basically includes an upper, a sole, a closure, an actuator, a communicator and a controller. The upper has a first portion, a second portion, and an opening between the first portion and the second portion. The sole is attached to the upper. The closure is coupled between the first portion and the second portion. The actuator is operatively coupled to the closure to adjust a relative position of the first portion and the second portion. The communicator is configured to receive at least one of bicycle information and user information. The controller is configured to control the actuator to adjust a tightening force applied by the closure to a target tightening force based on at least one of the bicycle information and the user information.

Presented are intelligent electronic footwear and apparel with controller-automated features, methods for making/operating such footwear and apparel, and control systems for executing automated features of such footwear and apparel. A method for operating an intelligent electronic shoe (IES) includes receiving, e.g., via a controller through a wireless communications device from a GPS satellite service, location data of a user. The controller also receives, e.g., from a backend server-class computer or other remote computing node, location data for a target object or site, such as a virtual shoe hidden at a virtual spot. The controller retrieves or predicts path plan data including a derived route for traversing from the user's location to the target's location within a geographic area. The controller then transmits command signals to a navigation alert system mounted to the IES's shoe structure to output visual, audio, and/or tactile cues that guide the user along the derived route.