Abstract: 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.

Abstract: 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.

Abstract: Disclosed embodiments describe techniques for body part biomarker and consistency pattern generation using motion analysis. Sensors are attached to a body part of an individual, where the sensors enable collection of motion data of the body part, and where the sensors include at least one inertial measurement unit (IMU) and at least one sensor determining muscle activation. Data is collected from the sensors, where the sensors provide electrical information based on a microexpression of movement of the body part during a movement performance protocol. Processors are used to analyze the electrical information from the sensors. Biomarker information for the individual is generated using the analyzing of the electrical information from the movement performance protocol. Additional data is collected from a subsequent attaching of sensors to the body part of the individual and the additional data is analyzed. Consistency pattern information is generated from the biomarkers.

Abstract: Techniques for energy production are disclosed. A kinetic fabric for use in a kinetically-activated energy production system is implemented. The kinetic fabric comprises a three-dimensional, layer-based flexible matrix that regains shape after deformation. The fabric further comprises a kinetically activated energy source layer supported between layers of the flexible matrix. The fabric further includes a flexible electrical connection that provides an electrical path between the energy source layer and a terminal on the flexible matrix. The kinetic fabric is deformed with mechanical agitation, and energy is harvested from the energy source layer through the terminal on the flexible matrix. Various embodiments are disclosed including flags, moving vehicles, and shade structures, among others.

Abstract: Disclosed embodiments describe techniques for motion analysis based on human body mounted sensors. The motion analysis is based on human body mounted sensors using mapping and motion analysis. The wearable sensors include inertial measurement sensors, muscle activation sensors, stretch sensors, or linear displacement sensors. Data is obtained from two or more sensors attached to a body part of an individual, where the two or more sensors enable collection of motion data of the body part, and where the two or more sensors include at least one inertial measurement unit (IMU) and at least one sensor determining muscle activation. The data is processed to determine locations of each of the two or more sensors. The locations of each of the two or more sensors are mapped into a coordinate reference system. The mapping is provided to a motion analysis system. Additional data is obtained to further calculate body part motion.

Abstract: Disclosed embodiments describe techniques for motion analysis based on human body mounted sensors. The motion analysis enables diagnosis and treatment using mapping and motion analysis. The wearable sensors include inertial measurement sensors, muscle activation sensors, stretch sensors, or linear displacement sensors. Data is obtained from two or more sensors attached to a body part of an individual, where the two or more sensors enable collection of motion data of the body part, and where the two or more sensors include at least one inertial measurement unit (IMU) and at least one sensor determining muscle activation. The locations of each of the two or more sensors are mapped into a coordinate reference system, based on the data. Motion of the human body is calculated based on the mapping. A movement signature is determined based on the calculated motion. The movement signature is used to analyze a movement disorder of the individual.

Abstract: Disclosed embodiments describe techniques for body part motion analysis. A stretch sensor is attached to a body part. Tape can be applied to the body part, and the stretch sensor can be attached to the tape using connectors, hooks, snaps, or Velcro™. The stretch sensor changes electrical characteristics as it stretches. A sensor coupled to the stretch sensor collects changes in electrical characteristics based on motion of the body part. A communication unit provides information from the sensor to a receiving unit. Motion of the body part is shown on a display. The displayed body part can be an animation and can be displayed in the context of an overall body. The stretch sensor is used for measuring body part motion. An inertial measurement unit provides augmented motion information. The stretch sensor senses muscle activities such as muscle activation and deformation and provides movement angle, force and torque evaluation.

Abstract: 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.

Abstract: 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.

Abstract: Disclosed embodiments describe techniques for body part motion analysis using kinematics. Two or more sensors, which include stretch sensors or inertial sensors, are attached to a body part of an individual. The two or more sensors enable collection of motion data of the body part. Data is collected from the two or more sensors, where the two or more sensors provide electrical information based on a micro-expression of movement of the body part. One or more processors are used for analyzing the electrical information from the two or more sensors. A movement biomarker is generated for the individual, using the electrical information that was analyzed. Subsequent data is collected from a subsequent attaching of the sensors to a body part. The subsequent data is analyzed to generate a longitudinal movement biomarker for the individual. The longitudinal movement biomarker can be used for clinical evaluation or treatment planning.

Abstract: Disclosed embodiments describe techniques for body analysis based on wearable sensors on an individual. The body analysis is based on movement assessment metric usage. The wearable sensors include muscle activity sensors, skeletal movement sensors, stretch sensors, inertial measurement sensors, or linear displacement sensors. Data is obtained from a wearable muscle activity sensor. Muscle activity over a time period is determined using the data obtained from the wearable muscle activity sensor. A movement assessment metric is calculated based on the muscle activity over the time period. The movement assessment can include body posture symmetry. The movement assessment metric is output, where the outputting can include displaying an animation of the muscle activity in a context of an overall body. The movement assessment can comprise an ergonomic assessment for the individual.

Abstract: Techniques for energy production are disclosed. A kinetic fabric for use in a kinetically-activated energy production system is implemented. The kinetic fabric comprises a three-dimensional, layer-based flexible matrix that regains shape after deformation. The fabric further comprises a kinetically activated energy source layer supported between layers of the flexible matrix. The fabric further includes a flexible electrical connection that provides an electrical path between the energy source layer and a terminal on the flexible matrix. The kinetic fabric is deformed with mechanical agitation, and energy is harvested from the energy source layer through the terminal on the flexible matrix. Various embodiments are disclosed including flags, moving vehicles, and shade structures, among others.

Abstract: 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.

Abstract: 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.

Abstract: Disclosed embodiments describe techniques for body part motion analysis using kinematics. Two or more sensors, which include stretch sensors or inertial sensors, are attached to a body part of an individual. The two or more sensors enable collection of motion data of the body part. Data is collected from the two or more sensors, where the two or more sensors provide electrical information based on a micro-expression of movement of the body part. One or more processors are used for analyzing the electrical information from the two or more sensors to generate a kinematic phase pattern. The kinematic phase pattern is rendered as part of a kinematic sequence, where the rendering is displayed visually. The rendering includes an animation and enables additional kinematic analysis. The two or more sensors capture two or more modalities of body part motion.

Abstract: 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.

Abstract: This document describes techniques using, and objects embodying, a haptic feedback mechanism for an interactive garment. A wearable interactive garment (e.g., a jacket, shirt, or pants) may include various sensors that can sense user interactions in the form of single or multi-touch-input (e.g., gestures). A haptic feedback mechanism is integrated within the interactive garment and includes a vibration source (e.g., a vibration motor) and a transmission structure coupled to the vibration source. A controller is configured to control the haptic feedback mechanism to provide haptic feedback by causing the vibration source to distribute vibration to multiple vibration points within the transmission structure.

Abstract: 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.

Abstract: In one aspect, a modular sensing apparatus will be described. The modular sensing apparatus includes a flexible substrate and multiple sensors. The flexible substrate is reconfigurable into different shapes that conform to differently shaped structures. The multiple sensors are positioned on the substrate. Various embodiments relate to software, devices and/or systems that involve or communicate with the modular sensing apparatus.

Abstract: This document describes an interactive object with multiple electronics modules. An interactive object (e.g., a garment) includes a grid or array of conductive thread woven into the interactive object, and an internal electronics module coupled to the grid of conductive thread. The internal electronics module includes a first subset of electronic components, such as sensing circuitry configured to detect touch-input to the grid of conductive thread. An external electronics module that includes a second subset of electronic components (e.g., a microprocessor, power source, or network interface) is removably coupled to the interactive object via a communication interface. The communication interface enables communication between the internal electronics module and the external electronics module when the external electronics module is coupled to the interactive object.