Disclosed is a wearable step counter system comprising a garment for a wearer's legs, a capacitive electrode and a microcontroller, said garment comprising a textile fabric portion, said capacitive electrode comprising an electrically conductive yarn woven into said textile fabric portion, said textile fabric portion being arranged on said garment for providing a parasitic capacitive coupling between said capacitive electrode and a wearer's leg, said microcontroller being electrically connected to said capacitive electrode for evaluating said parasitic capacitive coupling so that the relative movement between the wearer's legs is detected by the microcontroller.

Braided composite yarns including one or more functional components such as conductors and one or more structural components such as para-aramid fibers, and methods of manufacture therefor. Bundles of at least one functional component and at least one structural component undergo simultaneous parallel winding under tension onto a single bobbin prior to braiding, thus reducing the mechanical loading forces on the functional components in the final yarn. The yarns can be engineered with application-specific electrical, electronic, electromagnetic, or physical properties that enable their use as electronic components or sensors, and attached to or incorporated into active textiles and composite substrates. The yarns can be directly soldered to without prior removal of insulation or other yarn components. Some yarns, such as those for use as inductors, can include a core with desired electrical properties.

An inputting fingertip sleeve includes a sleeve and an inputting end. The sleeve has a curved linear structure. The inputting end is fixed on the sleeve. The inputting end includes a plurality of graphenes. A material of the sleeve is conductive, can be metal, alloy or conductive polymer. The inputting end is electrically connected with the sleeve.

A fabric-based item may include a housing that is covered in fabric. Areas of the fabric may overlap input circuitry such as button switches, touch sensors, force sensors, proximity sensors, and other sensing circuitry and may overlap other components such as light-emitting components and haptic output devices. The fabric-based item may include control circuitry that gathers user input from the input circuitry and wireless communications circuitry that the control circuitry uses to transmit remote control commands and other wireless signals in response information from the input circuitry. The fabric-based item may have a weight that is located in the housing to orient the housing in a desired direction when the housing rests on a surface. A movable weight may tilt the housing in response to proximity sensor signals or other input. Portions of the fabric may overlap light-emitting components and optical fiber configured to emit light.

Flexible electronically functional fibers are described that allow for the placement of electronic functionality in traditional fabrics. The fibers can be interwoven with natural fibers to produce electrically functional fabrics and devices that can retain their original appearance.

A fabric-based item may include fabric formed from intertwined strands of material. The fabric may include first and second fabric layers that at least partially surround a pocket. Initially, the pocket may be completely enclosed by the first and second layers of fabric. A shim may be placed in the pocket before the pocket is closed. An opening may be formed in the first layer of fabric to expose a conductive strand in the pocket. The shim may prevent the cutting tool from cutting all the way through to the second layer of fabric. After cutting the hole in the first layer of fabric, the shim may be removed and an electrical component may be soldered to the conductive strand in the pocket. A polymer material may be injected into the pocket to encapsulate the electrical component. The polymer material may interlock with the surrounding pocket walls.

Three-dimensional weaving, knitting, or braiding tools may be used to create three-dimensional fabric (24) with internal pockets (56). The pockets (56) may be shaped to receive electrical components such as switch electrodes (46A, 46B) for a switch (18). The fabric (24) may have adjacent first and second layers that are interposed between the switch electrodes (46A, 46B). The switch electrodes (46A, 46B) may be biased apart using magnets (46A-1, 46B-1) or other biasing structure. In a region of the fabric (24) that overlaps the first and second switch electrodes (46A, 46B), the first and second layers of fabric may be disconnected from each other. This allows the first and second layers to pull away from each other so that the electrodes (46A, 46B) are separated by the biasing force from the biasing structure. The switch (18) can be closed by pressing the electrodes (46A, 46B) together.

Apparatus, comprising fabric (62) formed from fibers (74); and an electrical component (20) having first and second perpendicular fiber guiding structures, wherein a first of the fibers is soldered in the first fiber guiding structure and a second of the fibers is soldered in the second fiber guiding structure.

A touch-sensitive textile device that is configured to detect the occurrence of a touch, the location of a touch, and/or the force of a touch on the touch-sensitive textile device. In some embodiments, the touch-sensitive textile device includes a first set of conductive threads oriented along a first direction, and a second set of conductive threads interwoven with the first set of conductive threads and oriented along a second direction. The device may also include a sensing circuit that is operatively coupled to the first and second set of conductive threads. The sensing circuit may be configured to apply a drive signal to the first and second set of conductive threads. The sensing circuit may also be configured to detect a touch or near touch based on a variation in an electrical measurement using the first or second set of conductive threads.

A fabric for producing an induced electromagnetic field in the presence of a human body to reduce endogenous pain, includes a non-conductive base fabric, a plurality of parallel, spaced apart electrically conducting carbon fibers interspersed in the base fabric constituting approximately 3% of the weight of the fabric, and a plurality of parallel, spaced apart electrically conducting silver fibers interspersed in the base fabric constituting approximately 6% of the weight of the fabric, and being in parallel, spaced apart relation to the electrically conducting carbon fibers.