Abstract: A bottle assembly has a bottle and a removable cap. The cap includes a nozzle and a vent arrangement. The vent arrangement can include a vent conduit that extends into an air cavity present at the bottom of the bottle assembly when the bottle assembly is inverted. The vent arrangement allows for pressure equalization within the bottom assembly in response to liquid being dispensed from the bottle assembly to permit high flow rates of the dispensed liquid without squeezing of the bottle.

Abstract: Stray light in a metering structure is controlled by surrounding with a rigid shield an elongated length of a strut and supporting on the rigid shield a surface finish which is highly absorptive of light. The strut is thermally decoupled from the rigid shield using a plurality of insulating web layers comprising a multi-layer insulation (MLI) system disposed between the strut and the rigid shield. The MLI in such scenarios (1) thermally isolates the strut from the shield (2) serves as a support structure to support the rigid shield on the strut, and (3) absorbs thermally induced mechanical stresses as between the rigid shield and the strut.

Abstract: Graphic elements may be rendered on an interface. An original view of a user interface is presented on at least one display. The user interface initially includes content presented on one or more of a first layer, a second layer, and a third layer. In response to receiving a first input, the user interface in presented in an edit view that includes presenting a menu that includes a plurality of selectable graphic elements. A second input is received that selects a graphic element of the plurality of selectable graphic elements, and third input is received to exit the edit view and present an updated version of the original view. The updated view includes the content presented on the one or more of the first layer, the second layer, and the third layer and the selected graphic element presented on the second layer.

Abstract: The present invention relates to an improved process for the application of an electroluminescent light system. The present invention is also directed to an electroluminescent light system prepared by the process.

Abstract: A computing device detects a press of a global shortcut key simultaneously with a first press and release of a modifier key. In response thereto, an operation is initiated in a non-default display region. The operation might be displaying a user interface element in the non-default display region. The computing device can also detect a second press and release of the modifier key simultaneously with the press of the global shortcut key. In response thereto, the operation can be initiated in a second display region, such as a default display region. The second press and release of the modifier key can be detected within a predetermined period of time following the detection of the first press and release of the modifier key. The operation might be simultaneously initiated in multiple display regions, such as sharing a region that encompasses the non-default display region and one or more other display regions.

Abstract: A computing device detects a press of a global shortcut key simultaneously with a first press and release of a modifier key. In response thereto, an operation is initiated in a non-default display region. The operation might be displaying a user interface element in the non-default display region. The computing device can also detect a second press and release of the modifier key simultaneously with the press of the global shortcut key. In response thereto, the operation can be initiated in a second display region, such as a default display region. The second press and release of the modifier key can be detected within a predetermined period of time following the detection of the first press and release of the modifier key. The operation might be simultaneously initiated in multiple display regions, such as sharing a region that encompasses the non-default display region and one or more other display regions.

Abstract: A foldable computing device provides user interface (“UI”) transitions and optimizations while operating in a productivity mode. When the foldable computing device is operating in productivity mode, it can present a UI below a hardware keyboard placed over a display region and occluding only a top portion of the display region or a software keyboard presented in the display region occluding only the top portion of the display region. If the hardware keyboard or the software keyboard occlude only the bottom of the display region, a UI can be shown above the hardware keyboard or the software keyboard. The foldable computing device can adjust the position of UI windows that are occluded when the hardware or software keyboard is placed on the display region. The foldable computing device can move the UI windows back to their original positions if the hardware or software keyboard no longer occlude the display region.

Abstract: A foldable computing device can be configured to provide a user interface (UI) optimization that enables an application window to be presented in a predictable location when an application is launched, a UI optimization that enables an application window to be moved to an active display area, a UI optimization that enables a modal UI element to be presented in such a way that it does not overlap a seam on the device, a UI optimization that enables an image presented by the device to be adjusted to maintain a view of the focal point of the image across device posture or orientation changes, a UI optimization that enables the device to transition between UI modes optimized for front-facing and world-facing image capture, and/or a UI optimization that enables the device to provide a UI for instructing a user to flip the device when a biometric sensor is in use.

Abstract: A foldable computing device can be configured to provide a user interface (UI) optimization that enables an application window to be presented in a predictable location when an application is launched, a UI optimization that enables an application window to be moved to an active display area, a UI optimization that enables a modal UI element to be presented in such a way that it does not overlap a seam on the device, a UI optimization that enables an image presented by the device to be adjusted to maintain a view of the focal point of the image across device posture or orientation changes, a UI optimization that enables the device to transition between UI modes optimized for front-facing and world-facing image capture, and/or a UI optimization that enables the device to provide a UI for instructing a user to flip the device when a biometric sensor is in use.

Abstract: A foldable computing device is disclosed that is configured to determine a user interface (UI) component rendering mode based on content occlusion and a prediction of user intent. The foldable computing device is configured to increase, maintain, or reduce prominence of a UI component based whether and where the UI component occludes an underlying application window or other existing UI. The foldable device may also determine an existing UI component's rendering mode based on an anticipated location of an application window associated with an application that was just launched. Furthermore, the foldable device may predict what a user is going to do with the application window, including causing any future occlusion, and adjust the UI component's rendering mode accordingly.

Abstract: In embodiments, a Wearable Cardiac Defibrillator (WCD) system is configured to be worn by an ambulatory patient. The WCD system includes a main user interface (UI) output device that can output an image, sound or vibration as a main message about a condition of the patient or the WCD system. The patient may further carry a peripheral device that can also output an image, sound or vibration as a peripheral message about the condition. The peripheral message may mirror the main message at least in part, amplify it, and so on. The availability of the peripheral message provides the patient with the opportunity to better perceive the main message, and the flexibility to receive and react to it discreetly, learn more about the condition, and so on.

Abstract: A bendable computing device can operate in a single display region mode when the device is in an unbent posture and can operate in a multiple display region mode when the device is in a bent posture. The multiple display region mode subdivides the bendable screen of the bendable computing device into a first display region and a second display region. When operating in the multiple display region mode, the bendable computing device can display an artificial hardware seam between the first display region and the second display region. User input gestures originating at the artificial hardware seam or terminating at the artificial hardware seam can be utilized to provide various types of functionality. Various types of functionality can also be provided when the bendable computing device detects that it has transitioned from an unbent posture to a bent posture or from a bent posture to an unbent posture.

Abstract: A foldable computing device can be configured to provide a user interface (UI) optimization that enables an application window to be presented in a predictable location when an application is launched, a UI optimization that enables an application window to be moved to an active display area, a UI optimization that enables a modal UI element to be presented in such a way that it does not overlap a seam on the device, a UI optimization that enables an image presented by the device to be adjusted to maintain a view of the focal point of the image across device posture or orientation changes, a UI optimization that enables the device to transition between UI modes optimized for front-facing and world-facing image capture, and/or a UI optimization that enables the device to provide a UI for instructing a user to flip the device when a biometric sensor is in use.

Abstract: In embodiments, a Wearable Cardiac Defibrillator (WCD) system is configured to be worn by an ambulatory patient. The WCD system includes a main user interface (UI) output device that can output an image, sound or vibration as a main message about a condition of the patient or the WCD system. The patient may further carry a peripheral device that can also output an image, sound or vibration as a peripheral message about the condition. The peripheral message may mirror the main message at least in part, amplify it, and so on. The availability of the peripheral message provides the patient with the opportunity to better perceive the main message, and the flexibility to receive and react to it discreetly, learn more about the condition, and so on.

Abstract: A foldable computing device provides user interface (“UI”) transitions and optimizations while operating in a productivity mode. When the foldable computing device is operating in productivity mode, it can present a UI below a hardware keyboard placed over a display region and occluding only a top portion of the display region or a software keyboard presented in the display region occluding only the top portion of the display region. If the hardware keyboard or the software keyboard occlude only the bottom of the display region, a UI can be shown above the hardware keyboard or the software keyboard. The foldable computing device can adjust the position of UI windows that are occluded when the hardware or software keyboard is placed on the display region. The foldable computing device can move the UI windows back to their original positions if the hardware or software keyboard no longer occlude the display region.

Abstract: A bendable computing device can operate in a single display region mode when the device is in an unbent posture and can operate in a multiple display region mode when the device is in a bent posture. The multiple display region mode subdivides the bendable screen of the bendable computing device into a first display region and a second display region. When operating in the multiple display region mode, the bendable computing device can display an artificial hardware seam between the first display region and the second display region. User input gestures originating at the artificial hardware seam or terminating at the artificial hardware seam can be utilized to provide various types of functionality. Various types of functionality can also be provided when the bendable computing device detects that it has transitioned from an unbent posture to a bent posture or from a bent posture to an unbent posture.

Abstract: A foldable computing device can be configured to provide a user interface (UI) optimization that enables an application window to be presented in a predictable location when an application is launched, a UI optimization that enables an application window to be moved to an active display area, a UI optimization that enables a modal UI element to be presented in such a way that it does not overlap a seam on the device, a UI optimization that enables an image presented by the device to be adjusted to maintain a view of the focal point of the image across device posture or orientation changes, a UI optimization that enables the device to transition between UI modes optimized for front-facing and world-facing image capture, and/or a UI optimization that enables the device to provide a UI for instructing a user to flip the device when a biometric sensor is in use.

Abstract: A computing device implements global keyboard shortcuts targeting a specific display region using repeated key presses, targeting a specific display region using chorded modifier keys, targeting a specific display region using a single modifier key, targeting a specific display region based on user activity, targeting multiple display regions, or targeting a specific display region using multi-modal input. Other types of global keyboard shortcuts for targeting specific display regions might also be provided by other embodiments.

Abstract: Technologies are disclosed herein that enable a foldable computing device having multiple screen regions to perform an inter-region user interface (UI) operation in response to an intra-region UI gesture. For example, a UI gesture that begins and ends within a first region may be used to move a window from the first region to the second region. The disclosed technologies address the technical problems described above by providing succinct, accurate UI gestures that cause foldable computing devices to perform inter-region UI operations. The disclosed technologies further address the technical problems described above by combining different types of UI gestures to increase gesture accuracy and expressiveness of inter-region UI operations.

Abstract: A foldable computing device is disclosed that is configured to determine a user interface (UI) component rendering mode based on content occlusion and a prediction of user intent. The foldable computing device is configured to increase, maintain, or reduce prominence of a UI component based whether and where the UI component occludes an underlying application window or other existing UI. The foldable device may also determine an existing UI component's rendering mode based on an anticipated location of an application window associated with an application that was just launched. Furthermore, the foldable device may predict what a user is going to do with the application window, including causing any future occlusion, and adjust the UI component's rendering mode accordingly.