This document describes two-layer interactive textiles. In one or more implementations, the interactive textile includes a top textile layer and a bottom textile layer. Conductive threads are woven into the top textile layer and the bottom textile layer. When the top textile layer is combined with the bottom textile layer, the conductive threads from each layer form a capacitive touch sensor that is configured to detect touch-input. The bottom textile layer is not visible and couples the capacitive through sensor to electronic components, such as a controller, a wireless interface, an output device (e.g., an LED, a display, or speaker), and so forth.

Disclosed are systems or apparatuses and methods for forming a junction between conductive fibers that are incorporated into a fabric. Briefly, one method includes the steps of removing insulation from two intersecting individually insulated conductive fibers to expose the individually conductive fibers, bringing the exposed individually conductive fibers into contact with each other at a junction point, and forming a molecular bond between the conductive fibers at the junction point. Also disclosed are systems for forming a junction between conductive fibers that are incorporated into a fabric. In this regard, one embodiment of such a system can include a first apparatus that removes insulation from two intersecting individually insulated conductive fibers to expose the individually conductive fibers, a second apparatus that brings the exposed individually conductive fibers into contact with each other at a junction point, and a third apparatus that aids in formation of a molecular bond between the conductive fibers at the junction point.

Techniques for fabric adhesion to an apparatus are described. According to one or more embodiments, an apparatus is laminated with fabric utilizing one or more fabric layers. In at least some embodiments, multiple adhesive zones are defined on a fabric layer. Each adhesive zone, for instance, has a particular set of properties, such as a particular location on a fabric layer, a particular adhesive thickness, a particular adhesive type, and so forth. In at least some embodiments, different adhesive zones differ from one another based on one or more of their respective properties and thus enable different fabric characteristics to be specified at different adhesive zones.

An item of clothing includes an electrical load that consumes more electrical energy in a first operating mode than in a second operating mode, a sensor, and a controller. The sensor is configured to identify whether the item of clothing is being worn. The controller is configured to switch the electrical load to the second operating mode when the item of clothing is not being worn.

The present invention concerns a textile motherboard (TMB) that incorporates at least a central processing unit (CPU) or a peripheral or a combination thereof. The textile of the garment is utilized as substrate to conform the TMB. The TMB may exhibit multiple-layer structures, VIAs, and routings composed of textile material capable of transmitting signals between CPU and a means to register information, or between the CPU and the combination of peripherals, which are incorporated into the TMB by using known textile manipulation techniques. Every component is modular and interchangeable and connects to the TMB utilizing textile connectors.