This document describes techniques and apparatuses for connecting an electronic component to an interactive textile. Loose conductive threads of the interactive textile are collected and organized into a ribbon with a pitch that matches a corresponding pitch of connection points of the electronic component. Next, non-conductive material of the conductive threads of the ribbon are stripped to expose the conductive wires of the conductive threads. After stripping the non-conductive material from the conductive threads of the ribbon, the connection points of the electronic component are bonded to the conductive wires of the ribbon. The conductive threads proximate the ribbon are then sealed using a UV-curable or heat-curable epoxy, and the electronic component and the ribbon are encapsulated to the interactive textile with a water-resistant material, such as plastic or polymer.

A personal protection system including a surgical garment that may be mounted to a helmet including an electrically powered assembly, such as a fan. The garment includes a shell adapted for being disposed over the helmet of the personal protection system. The garment also includes a transparent face shield coupled to the shell and positioned so that, when the garment is disposed over the helmet, the face shield is located in front of the face of the individual. The garment may includes two fastening features spaced apart from one another for releasably securing the shell to the helmet and a conductor that extends between the two fastening features.

An item such as a fabric-based item or other item may have one or more actuators. An actuator may have a conductive strand of material. A control circuit may supply a current to the conductive strand that induces a length change in the conductive strand due to ohmic heating and associated thermal expansion effects. The control circuit may be used to activate the actuator in response to user input that is supplied to an associated input device such as a switch, capacitive sensor, force sensor, light-based sensor, or other input component. The fabric-based item may include fabric such as woven fabric or knit fabric. Strands of conductive material may serve as signals paths for supplying current to conductive strands in actuators. Magnetic-field-based actuators may be formed by coiling conductive strands around tubular support structures such as piping in fabric-based items.

Provided is a garment comprising fabric and at least one seam, said garment comprising at least one vibrotactile actuator configured for producing a vibrational pattern based on audio and/or messaging information provided by an information signal from an external device. The vibrotactile actuator is contained within the seam. Also provided is a system, circuit and method for transmitting audio and/or messaging information to a user. The system comprises the garment, the external device, and a conversion unit comprising a microcontroller that converts the audio and/or messaging information into a driving signal to be provided to the vibrotactile actuator. The circuit comprises the microcontroller and the vibrotactile actuators coupled to one another by a ribbon of a flexible material. The method evaluates the delay between the vibrational pattern produced by the vibrotactile actuator and acoustic and/or visual signals produced by the external device based on the audio and/or messaging information.

This document describes techniques using, and objects embodying, an interactive fabric which is configured to sense user interactions in the form of single or multi-touch-input (e.g., gestures). The interactive fabric may be integrated into a wearable interactive garment (e.g., a jacket, shirt, or pants) that is coupled (e.g., via a wired or wireless connection) to a gesture manager. The gesture manager may be implemented at the interactive garment, or remote from the interactive garment, such as at a computing device that is wirelessly paired with the interactive garment and/or at a remote cloud based service. Generally, the gesture manager recognizes user interactions to the interactive fabric, and in response, triggers various different types of functionality, such as answering a phone call, sending a text message, creating a journal entry, and so forth.

A system provides ultra-wideband (UWB) positioning. The system exchanges ranging signals at a first rate between a UWB beacon and a UWB tag. The system then determines movement or location information of the UWB tag; and select, based on the movement or location information, a second rate for exchanging subsequent ranging signals between the UWB beacon and the UWB tag. The system then exchanges the subsequent ranging signals at the second rate between the UWB beacon and the UWB tag.

A real-time motion capture system and garment includes a wearable activity monitor that may be a pair of denim jeans. The wearable activity monitor includes multiple sensors such as accelerometers, gyrometers, magnetometers disposed within the seams of the garment. A microprocessor and wireless transmitter) communicate the motion data to an external device. The microprocessor and wireless transmitter may be included within one of the seams. An elastically stretchable ribbon or a flexible ribbon such as a kapton ribbon or a ribbon formed of textile, electrically couples the sensors and microprocessor and is also disposed inside the seams and the components within the seam are coated with a waterproof coating. The external device can store the data or display and analyze the data real-time, and may communicate the data to a further electronic device.

A conductive tape formed by laying a conductive pathway on a tape layer is disclosed. Various apparatus and methods for laying conductive pathways to form conductive tape are disclosed. The conductive pathways may be laid by varying the lateral position of the conductive pathway on the tape substrate. Such patterns all stretchable conductive tape to be realized. Multiple conductive pathways may be laid in the tape and the lateral separation of the pathways in the tape may vary. In some embodiments the pathways are formed from conductive yarn or by printing or laying conductive ink.

A therapeutic apparel article is configured with a supple wearable fabric article that can be configured over limb or nub of an amputated limb. The therapeutic apparel article is configured with a plurality of nodes for detachably attaching vibrating devices thereto. In addition, a control unit having a power source may be detachably attached to the wearable fabric article. A conductive network may extend from the control unit and/or the power source to provide electrical power to the nodes and the vibrating devices attached. A user may attach vibrating devices to various nodes of the wearable fabric article as desired. In addition, the vibrating devices and the control unit can be detached from the wearable fabric article to enable the wearable fabric article to be washed.

Systems and methods for interactive objects including illuminated surfaces are provided. An interactive object includes a flexible substrate comprising a soft material that is non-transmissive to light. The interactive object includes a plurality of holes extending from an inside surface of the flexible substrate to an outside surface of the flexible substrate to form a light-transmissive pattern at one or more locations of the flexible substrate. An illuminated surface is positioned adjacent to the inside surface of the flexible substrate with its front surface extending along at least a portion of the inside surface of the flexible substrate at the one or more locations including the plurality of holes. The interactive object includes one or more electronic components electrically coupled to the illuminated surface to control the illuminated surface to provide a visual output.