Computing systems and related methods are provided for discovery of undefined user movements. Sensor data associated with one or more sensors of a wearable device can be obtained and input into one or more machine-learned models that have been trained to learn a continuous embedding space based at least in part on one or more target criteria. Data indicative of a position of the sensor data within the continuous embedding space can be obtained as an output of the one or more machine-learned models. A functionality associated with the position of the sensor data within the continuous embedding space can be determined. The functionality associated with the position of the sensor data within the continuous embedding space can be initiated.

A system of an insulated conductor integrated into a base fabric layer for a garment, the system comprising: a set of wall fibres interlaced with one another to form a wall structure defining a cavity along a length, the set of wall fibres comprising nonconductive material; at least one conductive fibre miming along the length within the cavity, such that the set of wall fibres of the wall structure encloses the at least one conductive fibre in order to electrically insulate the at least one conductive fibre from an environment along the length external to the cavity; and a set of base fibres interlaced with one another to form the base fabric layer, the base fabric layer having a first side adjacent with a first fibred interconnection to the wall structure and a second side adjacent with a second fibered interconnection to the wall structure.

A stable conductive myocardial patch with a negative Poisson's ratio structure is provided. The preparation method includes preparing a myocardial patch substrate with concave polygons as the structural units by weaving or knitting, and then a conductive coating is coated on the surface of the substrate. Alternatively, the yarns can be processed into conductive coated yarns first, and then used as the raw material to weave or knit a stable conductive myocardial patch with a negative Poisson's ratio structure. The prepared myocardial patch has a relative resistance change of less than 5% at 50% tensile strain. When the strain of the structural units is within 50%, the fabric exhibits a negative Poisson's ratio structure, which expands in the perpendicular direction of the tensile load. The fabric exhibits a negative Poisson's ratio effect and anisotropy of Young's modulus, which matches the mechanical behavior of natural myocardium.

A cylindrical structure including a first cloth including a piezoelectric thread that generates an electric potential from external energy, a second cloth including a piezoelectric thread that generates an electric potential from external energy, and a connection portion connecting the first cloth and the second cloth, wherein the first cloth and the second cloth forms a side face of the cylindrical structure.

A cylindrical structure including a first cloth including a piezoelectric thread that generates an electric potential from external energy, a second cloth including a piezoelectric thread that generates an electric potential from external energy, and a connection portion connecting the first cloth and the second cloth, wherein the first cloth and the second cloth forms a side face of the cylindrical structure.

A fabric material with an electrode wiring includes: a fabric material body with stretchability; a first electrode portion that is disposed on a surface or in the interior of the fabric material body, and that includes a conductive linear body; a first wiring portion that is disposed on the surface or in the interior of the fabric material body so as to be electrically connected to the first electrode portion, and that includes a conductive linear body; a second electrode portion that is disposed on the surface or in the interior of the fabric material body, and that includes a conductive linear body; and a second wiring portion that is disposed on the surface or in the interior of the fabric material body so as to be electrically connected to the second electrode portion, and that includes a conductive linear body. In the fabric material with an electrode wiring, a resistance value between the first electrode portion and the second electrode portion is varied by stretching the fabric material with an electrode wiring.

A fabric material with an electrode wiring includes: a fabric material body with stretchability; a first electrode portion that is disposed on a surface or in the interior of the fabric material body, and that includes a conductive linear body; a first wiring portion that is disposed on the surface or in the interior of the fabric material body so as to be electrically connected to the first electrode portion, and that includes a conductive linear body; a second electrode portion that is disposed on the surface or in the interior of the fabric material body, and that includes a conductive linear body; and a second wiring portion that is disposed on the surface or in the interior of the fabric material body so as to be electrically connected to the second electrode portion, and that includes a conductive linear body. In the fabric material with an electrode wiring, a resistance value between the first electrode portion and the second electrode portion is varied by stretching the fabric material with an electrode wiring.

In electrical stimulation fitness wear, multiple electrode parts 30 are provided in a clothing portion, at positions that respectively face multiple target body parts such as to be respectively in proximity to the multiple target body parts, so as to provide electrical stimulation to the multiple target body parts, and the multiple electrode parts 30 each have a surface formed of a conductive polymer fabric 31. Multiple electrical cables 36 respectively connect the multiple electrode parts 30 to a connection part of a control unit electrically. The multiple electrode parts 30 include a first electrode part 30 to which a first electrical cable 36 is connected and a second electrode part 30 to which a second electrical cable 36 is connected. The first electrode part 30 and the second electrode part 30 are provided at separate positions such that a current can be applied to a certain body part between the electrodes.

In electrical stimulation fitness wear, multiple electrode parts 30 are provided in a clothing portion, at positions that respectively face multiple target body parts such as to be respectively in proximity to the multiple target body parts, so as to provide electrical stimulation to the multiple target body parts, and the multiple electrode parts 30 each have a surface formed of a conductive polymer fabric 31. Multiple electrical cables 36 respectively connect the multiple electrode parts 30 to a connection part of a control unit electrically. The multiple electrode parts 30 include a first electrode part 30 to which a first electrical cable 36 is connected and a second electrode part 30 to which a second electrical cable 36 is connected. The first electrode part 30 and the second electrode part 30 are provided at separate positions such that a current can be applied to a certain body part between the electrodes.

Embodiments of the invention disclosed herein are directed to articles of clothing that allow for monitoring of different analytes (e.g., electrolytes and molecules) in human sweat during fitness activity, while training, or simply in everyday life. The clothing includes a sensor system completely integrated in textile such that every sensing part is made of textile fibers. The clothing is able to control, collect, analyze, and expel the sweat over time. The textile sensor allows a spontaneous absorption of body sweat directly from the skin, while it is produced, using the hydrophilic natural properties of the textile. Then, once adsorbed, the flux of sweat is controlled and guided through the textile using a gradient of the textile's hydrophilic properties. The sweat guided through the textile is analyzed through an electrochemical sensor woven into the textile. Finally, the sweat is collected in a reservoir and expelled for evaporation.