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 wearable article, system, and methods may include a structure configured to enclose a human body part. A first antenna, positioned with respect to the structure, is tuned to communicate, while the wearable article is being worn, according to a first wireless communication modality with a first external antenna. A second antenna, positioned with respect to the structure, is tuned to communicate according to a second wireless communication modality with a second external antenna different than the first external N antenna, the second communication modality being different than the first communication modality. A transceiver, coupled to at least one of the first antenna and the second antenna, is configured to communicate via one of the first and second antennas based, at least in part, on the one of the first and second antennas coining into wireless communication contact with a corresponding one of the first and second external antennas.

A multilayer insole for removable placement in an article of footwear, the multilayer insole including a bottom insole layer having a top side, a top insole layer having an underside, an intermediate layer that is (a) an insole material layer, (b) a flexible circuit layer or (c) a bonding region for joining the bottom insole layer with the top insole layer, a location data receiving means for receiving an input signal relating to a location of the insole, and a location data transmitting means for transmitting an output signal relating to the location of the insole, wherein the location data receiving means and the location data transmitting means are both integrally associated with the multilayer insole. Also provided are a unitary insole, data transfer systems with methods involving the different insoles and methods of manufacturing the different insoles.

A monitoring system includes one or more wireless nodes forming a wireless mesh network; a user activity sensor including a wireless mesh transceiver adapted to communicate with the one or more wireless nodes using the wireless mesh network; and a digital monitoring agent coupled to the wireless transceiver through the wireless mesh network to request assistance from a third party based on the user activity sensor.

A system includes a shoe and a pod. The pod is disposed at the shoe and includes a positioning component and an altimeter. The positioning component determines a first geodetic location of the shoe at a first time, whereas the altimeter determines a first elevation of the shoe at the first time. The first positioning component additionally determines a second geodetic location of the shoe at a second time and generate shoe distance data based on the first geodetic location and the second geodetic location. The altimeter additionally determines a second elevation of the shoe at the second time. The positioning component additionally determines a total distance traveled based on the shoe distance data, the first elevation and the second elevation.

Systems and methods for sports analytics are disclosed. A system for evaluating athletic performance can include wearable sensor devices configured to be removably coupled to an athlete's body during athletic performance, and one or more equipment-mountable sensor devices configured to be coupled to reference objects adjacent to an athletic performance site such as a goal or equipment. A computing device can be communicatively coupled to the wearable sensor device(s) and the equipment-mountable sensor device(s). The computing device is configured to receive sensor data from each of the sensor device(s) and to determine at least one performance parameter.

The enclosed describes a sensor pad for wearing on a human body. The sensor pad is configured to be in contact with a substrate having a contoured surface, such as a surface of the body. The sensor pad comprises at least a sensor layer and a stiffener layer. The sensor layer comprises a surface area defining a sensing area configured to measure value at a plurality of locations of the sensing area. The stiffener layer is couples to the surface area of the sensor layer. The stiffener layer has a micro-cut pattern to reduce mechanical resistance of the stiffener layer. The micro-cut pattern facilitates the stiffener layer in stretching or compressing in one or more predefined directions, enabling the stiffener lay to conform to the contoured surface of the substrate.

The enclosed describes a sensor pad for wearing on a human body. The sensor pad is configured to be in contact with a substrate having a contoured surface, such as a surface of the body. The sensor pad comprises at least a sensor layer and a stiffener layer. The sensor layer comprises a surface area defining a sensing area configured to measure value at a plurality of locations of the sensing area. The stiffener layer is couples to the surface area of the sensor layer. The stiffener layer has a micro-cut pattern to reduce mechanical resistance of the stiffener layer. The micro-cut pattern facilitates the stiffener layer in stretching or compressing in one or more predefined directions, enabling the stiffener lay to conform to the contoured surface of the substrate.

A shoe with enhanced wireless signal transmission includes a shoe body, a wireless circuit module, and a metal conductive component. The shoe body includes an upper, a midsole that is disposed below the upper, and an outsole that is disposed below the midsole. The wireless circuit module is disposed on the midsole and includes a transmission segment that is configured to transmit a wireless signal, and a grounding segment that is configured to provide grounding for the transmission segment. The metal conductive component is disposed on the shoe body and is electrically connected to the grounding segment, wherein a length of the metal conductive component ranges from 20 mm to 100 mm, and a width of the metal conducting component ranges from 20 mm to 110 mm.

A shoe with enhanced wireless signal transmission includes a shoe body, a wireless circuit module, and a metal conductive component. The shoe body includes an upper, a midsole that is disposed below the upper, and an outsole that is disposed below the midsole. The wireless circuit module is disposed on the midsole and includes a transmission segment that is configured to transmit a wireless signal, and a grounding segment that is configured to provide grounding for the transmission segment. The metal conductive component is disposed on the shoe body and is electrically connected to the grounding segment, wherein a length of the metal conductive component ranges from 20 mm to 100 mm, and a width of the metal conducting component ranges from 20 mm to 110 mm.