Abstract: A system and method for establishing a gaming session via cloud services with a first device, receiving information at the first device to establish a connection with a second device, and receiving at the first device instructions from the second device via the connection, wherein the instructions control an aspect of the gaming session.

Abstract: Wearable devices having a primary and secondary power source are disclosed, wherein the secondary power sources are located in links of a band portion of the wearable device and the secondary power sources provide a secondary source of power beyond that provided by the primary power source. One exemplary wrist-wearable device includes a centralized processor pod having a primary power source, a wireless communication radio, and one or more sensors. The exemplary wrist-wearable device further includes a band with a plurality of links. Each of the plurality of links can include a secondary power source. The exemplary wrist-wearable device further includes communicative pathways that can be configured to convey at least power and data between the links and centralized processor pod. The communicative pathways can be configured to convey power from the secondary sources of power to the centralized processor pod beyond the power provided by the primary power source.

Abstract: An airpot beverage dispenser having a body with a beverage cavity, a lid with lower and upper lid portions, a bellows within the upper lid portion, an actuator for compressing the bellows to increase the pressure of trapped air in the bellows, a duckbill valve, a skirt valve extending fully around the duckbill valve, and a spout. The skirt valve is movable into sealing engagement with a lid lower wall to define an air flow path from the bellows to the beverage cavity, and when the pressure of the trapped air in the bellows is sufficiently increased, the duckbill valve opens and passes the trapped air to the beverage cavity to force beverage out the spout. When the spout is moved to a stored position and the dispenser is in a locked state, the skirt valve serves as a relief valve to prevent over pressure in the beverage cavity.

Abstract: Systems, devices, and methods relate to generation of augmented images using virtual content that is part of an augmented reality presentation and images of a scene captured via an image sensor. A wearable heads-up display (WHUD) may present an augmented reality presentation with virtual content projected into a field of view of a scene, while an image sensor captures images of the scene. The image sensor may be part of the WHUD or part of a separate device, for instance part of a smartphone. A wearer may view a scene via the WHUD and capture an image of all or a portion of the scene, for instance via a camera of either the WHUD or a separate device. An application monitors the virtual content and can generate an augmented image, which can be transmitted/printed, replicating the augmented reality experience and/or adding customized messages to the resulting augmented image.

Abstract: Systems, articles, and methods for surface electromyography (“EMG”) sensors that combine elements from traditional capacitive and resistive EMG sensors are described. For example, capacitive EMG sensors that are adapted to resistively couple to a user's skin are described. Resistive coupling between a sensor electrode and the user's skin is galvanically isolated from the sensor circuitry by a discrete component capacitor included downstream from the sensor electrode. The combination of a resistively coupled electrode and a discrete component capacitor provides the respective benefits of traditional resistive and capacitive (respectively) EMG sensor designs while mitigating respective drawbacks of each approach. A wearable EMG device that provides a component of a human-electronics interface and incorporates such capacitive EMG sensors is also described.

Abstract: Wearable electronic devices that employ one or more contact sensors (e.g., capacitive sensors and/or biometric sensors) are described. Contact sensors include electromyography sensors and/or capacitive touch sensors. Capacitive touch sensors include single-frequency capacitive touch sensors, recently-proposed swept frequency capacitive touch sensors, and a generalized version of swept frequency capacitive touch sensors referred to as multi-frequency capacitive touch sensors. The contact sensors are integrated into various devices, including generic watchstraps that may be substituted for the existing watchstrap in any wristwatch design, generic watch back-plates that may be substituted for the existing back-plate in any wristwatch design, and wearable electromyography devices that provide gesture-based control in a human-electronics interface.

Abstract: Wearable devices for sensing neuromuscular signals using a small number of sensor pairs are disclosed. One example wrist-wearable device includes eight pairs of neuromuscular-signal sensors. Each pair of neuromuscular-signal sensors is positioned over a portion of a wrist of a user while the wrist-wearable device is worn by the user. Each pair of neuromuscular-signal sensors further includes a first and second electrodes configured to be used as a differential sensor of neuromuscular signals travelling through the wrist of the user, and electrical signal-processing circuitry configured to amplify and filter neuromuscular signals received from the first and second electrodes to produce processed neuromuscular signals. The wrist-wearable device also includes a shared ground electrode configured to ground both the first and second electrodes.

Abstract: Wearable devices having a primary and secondary power source are disclosed, wherein the secondary power sources are located in links of a band portion of the wearable device and the secondary power sources provide a secondary source of power beyond that provided by the primary power source. One exemplary wrist-wearable device includes a centralized processor pod having a primary power source, a wireless communication radio, and one or more sensors. The exemplary wrist-wearable device further includes a band with a plurality of links. Each of the plurality of links can include a secondary power source. The exemplary wrist-wearable device further includes communicative pathways that can be configured to convey at least power and data between the links and centralized processor pod. The communicative pathways can be configured to convey power from the secondary sources of power to the centralized processor pod beyond the power provided by the primary power source.

Abstract: An airpot beverage dispenser having a body with a beverage cavity, a lid with lower and upper lid portions, a bellows within the upper lid portion, an actuator for compressing the bellows to increase the pressure of trapped air in the bellows, a duckbill valve, a skirt valve extending fully around the duckbill valve, and a spout. The skirt valve is movable into sealing engagement with a lid lower wall to define an air flow path from the bellows to the beverage cavity, and when the pressure of the trapped air in the bellows is sufficiently increased, the duckbill valve opens and passes the trapped air to the beverage cavity to force beverage out the spout. When the spout is moved to a stored position and the dispenser is in a locked state, the skirt valve serves as a relief valve to prevent over pressure in the beverage cavity.

Abstract: Wearable electronic devices that employ techniques for routing signals between components are described. An exemplary wearable electronic device includes a set of pod structures with each pod structure positioned adjacent and physically coupled to at least one other pod structure. The set of pod structures includes multiple sensor pods and at least one processor pod. Each sensor pod includes an on-board sensor to in use detect user-effected inputs and provide signals in response to the user-effected inputs. The signals are serially routed via successive ones of adjacent pod structures by respective communicative pathways until the signals are routed from the sensor pods to the processor pod. A processor on-board the processor pod processes the signals. Systems, articles, and methods for routing electrical signals and/or optical signals, including analog signals and/or digital signals, between pod structures are described.

Abstract: An airpot beverage dispenser having a body with a beverage cavity, a lid with lower and upper lid portions, a bellows within the upper lid portion, an actuator for compressing the bellows to increase the pressure of trapped air in the bellows, a duckbill valve, a skirt valve extending fully around the duckbill valve, and a spout. The skirt valve is movable into sealing engagement with a lid lower wall to define an air flow path from the bellows to the beverage cavity, and when the pressure of the trapped air in the bellows is sufficiently increased, the duckbill valve opens and passes the trapped air to the beverage cavity to force beverage out the spout. When the spout is moved to a stored position and the dispenser is in a locked state, the skirt valve serves as a relief valve to prevent over pressure in the beverage cavity.

Abstract: Systems, devices, and methods are disclosed for enabling private communication between head-mounted displays. A first user dons a first head-mounted display. The first head-mounted display authenticates that the first user is authorized to view information displayed by the first head-mounted display. In response to positive authentication, the first head-mounted display displays the information to the first user. The first user inputs a selection command via an input interface, such as, for example, gazing at particular information, to select some of the displayed information. The first head-mounted display generates a message based on the user selection, which may be encrypted by the first head-mounted display prior to transmission. The first head-mounted display transmits the message to a second head-mounted display, such that the second head-mounted display displays the message to an eye of a second user wearing the second head-mounted display.

Abstract: Systems, articles, and methods for improved capacitive electromyography (“EMG”) sensors are described. The improved capacitive EMG sensors include one or more sensor electrode(s) that is/are coated with a protective barrier formed of a material that has a relative permittivity ?r of about 10 or more. The protective barrier shields the sensor electrode(s) from moisture, sweat, skin oils, etc. while advantageously contributing to a large capacitance between the sensor electrode(s) and the user's body. In this way, the improved capacitive EMG sensors provide enhanced robustness against variations in skin and/or environmental conditions. Such improved capacitive EMG sensors are particularly well-suited for use in wearable EMG devices that may be worn by a user for an extended period of time and/or under a variety of skin and/or environmental conditions. A wearable EMG device that provides a component of a human-electronics interface and incorporates such improved capacitive EMG sensors is described.

Abstract: Systems, devices and methods that enable a user to access and interact with content displayed on a portable electronic display in an inconspicuous, hands-free manner are described. There is disclosed a completely wearable system comprising a wearable muscle interface device and a wearable head-mounted display, as well as methods for using the wearable system to effect interactions between the user and content displayed on the wearable head-mounted display. The wearable muscle interface device includes muscle activity sensors worn on an arm of the user to detect muscle activity generated when the user performs a physical gesture. The wearable system is adapted to recognize a plurality of gestures made by the user and, in response to each recognized gesture, to effect one or more interaction(s) with content displayed on the wearable head-mounted display.

Abstract: Systems, articles, and methods for surface electromyography (“EMG”) sensors that combine elements from traditional capacitive and resistive EMG sensors are described. For example, capacitive EMG sensors that are adapted to resistively couple to a user's skin are described. Resistive coupling between a sensor electrode and the user's skin is galvanically isolated from the sensor circuitry by a discrete component capacitor included downstream from the sensor electrode. The combination of a resistively coupled electrode and a discrete component capacitor provides the respective benefits of traditional resistive and capacitive (respectively) EMG sensor designs while mitigating respective drawbacks of each approach. A wearable EMG device that provides a component of a human-electronics interface and incorporates such capacitive EMG sensors is also described.

Abstract: Wearable electronic devices having a selfie camera are described herein. The wearable electronic devices include a body defining an aperture that is sized and shaped to receive a finger of a user. The wearable electronic device also includes a processor housed in the body, an input device arranged on an outer surface of the body and communicatively coupled to the processor to receive an input from a second finger of the user, an optical sensor to capture an image in response to the input from the second finger of the user, a transmitter communicatively coupled to the processor to transmit the image to an external electronic device, and optionally a power source communicatively coupled to the processor and the transmitter to provide power to at least the processor and the transmitter.

Abstract: Systems, devices, and methods relate to generation of augmented images using virtual content that is part of an augmented reality presentation and images of a scene captured via an image sensor. A wearable heads-up display (WHUD) may present an augmented reality presentation with virtual content projected into a field of view of a scene, while an image sensor captures images of the scene. The image sensor may be part of the WHUD or part of a separate device, for instance part of a smartphone. A wearer may view a scene via the WHUD and capture an image of all or a portion of the scene, for instance via a camera of either the WHUD or a separate device. An application monitors the virtual content and can generate an augmented image, which can be transmitted/printed, replicating the augmented reality experience and/or adding customized messages to the resulting augmented image.

Abstract: Systems, devices and methods that enable a user to access and interact with content displayed on a portable electronic display in an inconspicuous, hands-free manner are described. There is disclosed a completely wearable system comprising a wearable muscle interface device and a wearable head-mounted display, as well as methods for using the wearable system to effect interactions between the user and content displayed on the wearable head-mounted display. The wearable muscle interface device includes muscle activity sensors worn on an arm of the user to detect muscle activity generated when the user performs a physical gesture. The wearable system is adapted to recognize a plurality of gestures made by the user and, in response to each recognized gesture, to effect one or more interaction(s) with content displayed on the wearable head-mounted display.

Abstract: Systems, articles, and methods for improved capacitive electromyography (“EMG”) sensors are described. The improved capacitive EMG sensors include one or more sensor electrode(s) that is/are coated with a protective barrier formed of a material that has a relative permittivity ?r of about 10 or more. The protective barrier shields the sensor electrode(s) from moisture, sweat, skin oils, etc. while advantageously contributing to a large capacitance between the sensor electrode(s) and the user's body. In this way, the improved capacitive EMG sensors provide enhanced robustness against variations in skin and/or environmental conditions. Such improved capacitive EMG sensors are particularly well-suited for use in wearable EMG devices that may be worn by a user for an extended period of time and/or under a variety of skin and/or environmental conditions. A wearable EMG device that provides a component of a human-electronics interface and incorporates such improved capacitive EMG sensors is described.

Abstract: Systems, articles, and methods for improved capacitive electromyography (“EMG”) sensors are described. The improved capacitive EMG sensors include one or more sensor electrode(s) that is/are coated with a protective barrier formed of a material that has a relative permittivity ?r of about 10 or more. The protective barrier shields the sensor electrode(s) from moisture, sweat, skin oils, etc. while advantageously contributing to a large capacitance between the sensor electrode(s) and the user's body. In this way, the improved capacitive EMG sensors provide enhanced robustness against variations in skin and/or environmental conditions. Such improved capacitive EMG sensors are particularly well-suited for use in wearable EMG devices that may be worn by a user for an extended period of time and/or under a variety of skin and/or environmental conditions. A wearable EMG device that provides a component of a human-electronics interface and incorporates such improved capacitive EMG sensors is described.