Abstract: An information handling system input device coordinates presentation of keyboard augmentation panels proximate a keyboard resting on a horizontally-disposed touchscreen display. The keyboard augmentation panels relate keyboard and other inputs to an application active on the information handling system to enhance end user interactions. A keyboard augmentation module tracks the keyboard position on the touchscreen display to adapt content presentation in the keyboard augmentation panels based upon expected end user inputs. In other embodiments, other physical devices are augmented to have hybrid graphical interfaces that enhance multi-hand end user interactions.

Abstract: An information handling system input device coordinates presentation of keyboard augmentation panels proximate a keyboard resting on a horizontally-disposed touchscreen display. The keyboard augmentation panels relate keyboard and other inputs to an application active on the information handling system to enhance end user interactions. A keyboard augmentation module tracks the keyboard position on the touchscreen display to adapt content presentation in the keyboard augmentation panels based upon expected end user inputs. In other embodiments, other physical devices are augmented to have hybrid graphical interfaces that enhance multi-hand end user interactions.

Abstract: The present invention provides a system or method for displaying rich presentation taskbar buttons for a corresponding application. In one example, the rich presentation taskbar button may receive content from an application through a programming interface. The present invention further relates to a system and method for displaying a rich presentation taskbar button and for displaying and/or dismissing a thumbnail of an application window associated with the rich presentation taskbar button. The present invention may further include a system and method of pinning the thumbnail on a display or dismissing a thumbnail. The present invention also relates to a system and method for displaying multiple taskbar buttons in a taskbar including controlling the size of individual taskbar buttons, consolidating taskbar buttons and placing taskbar buttons into an overflow based on the type of taskbar button in the taskbar.

Abstract: A totem device accepts inputs from an end user and communicates the inputs to an information handling system through a capacitive mat by moving an interactive portion of the totem relative to a main portion. In one embodiment, the capacitive mat integrates a display that presents input images proximate the totem, such as a volume gauge or mouse keys. Interactive portions include compressible materials that alter surface area pressed against a capacitive mat when pressed upon and plungers that move independent of a main body to press. In one embodiment, a camera captures images of the totem to enhance the distinguishing of inputs.

Abstract: Identifying characteristics integrated in a totem and detected by a capacitive display mat are applied to perform functions in response to end user inputs. Identifying characteristics include capacitive feet integrated in a totem bottom surface with identifying features including varying capacitive values for the feet, varying pad sizes and shapes, varying pad patterns and varying capacitive oscillation frequencies. In one embodiment, the surface area of the totem in contact with the capacitive mat varies depending upon the pressure placed on the totem to alter the shape of a compressible material disposed at the bottom surface.

Abstract: The present invention provides a system or method for displaying rich presentation taskbar buttons for a corresponding application. In one example, the rich presentation taskbar button may receive content from an application through a programming interface. The present invention further relates to a system and method for displaying a rich presentation taskbar button and for displaying and/or dismissing a thumbnail of an application window associated with the rich presentation taskbar button. The present invention may further include a system and method of pinning the thumbnail on a display or dismissing a thumbnail. The present invention also relates to a system and method for displaying multiple taskbar buttons in a taskbar including controlling the size of individual taskbar buttons, consolidating taskbar buttons and placing taskbar buttons into an overflow based on the type of taskbar button in the taskbar.

Abstract: A totem device accepts inputs from an end user and communicates the inputs to an information handling system through a capacitive mat by moving an interactive portion of the totem relative to a main portion. In one embodiment, the capacitive mat integrates a display that presents input images proximate the totem, such as a volume gauge or mouse keys. Interactive portions include compressible materials that alter surface area pressed against a capacitive mat when pressed upon and plungers that move independent of a main body to press. In one embodiment, a camera captures images of the totem to enhance the distinguishing of inputs.

Abstract: An expansion device couples to a capacitive mat disposed on a desktop surface and communicates power and data through the capacitive mat to perform functions in support of an information handling system. For example, the expansion device powers an inductive charger to charge a peripheral device, accepts end user touch inputs with a capacitive touch sensor, presents visual information at an integrated display in response to pixel values provided by the information handling system though the capacitive mat.

Abstract: Visual images projected on a projection surface by a projector provide an interactive user interface having end user inputs detected by a detection device, such as a depth camera. The detection device monitors projected images initiated in response to user inputs to determine calibration deviations, such as by comparing the distance between where a user makes an input and where the input is projected. Calibration is performed to align the projected outputs and detected inputs. The calibration may include a coordinate system anchored by its origin to a physical reference point of the projection surface, such as a display mat or desktop edge.

Abstract: A totem device accepts inputs from an end user and communicates the inputs to an information handling system through a capacitive mat by moving an interactive portion of the totem relative to a main portion. In one embodiment, the capacitive mat integrates a display that presents input images proximate the totem, such as a volume gauge or mouse keys. Interactive portions include compressible materials that alter surface area pressed against a capacitive mat when pressed upon and plungers that move independent of a main body to press. In one embodiment, a camera captures images of the totem to enhance the distinguishing of inputs.

Abstract: A non-linear user interface display presented at a desktop conforms to dimensions of a user detected by a depth camera, such as by presenting the user interface along an arc having a radius determined from a reach of the user detected by the depth camera. Windows presented in the arc vary in size based upon their position relative to a user focus, such as by detecting a user gaze direction or by comparing position to a central display mat. User gestures control presentation of visual images in the arc, such rotating visual image windows in a circular manner around the arc radius and to different orientations in the arc relative to the user.

Abstract: Identifying characteristics integrated in a totem and detected by a capacitive display mat are applied to perform functions in response to end user inputs. Identifying characteristics include capacitive feet integrated in a totem bottom surface with identifying features including varying capacitive values for the feet, varying pad sizes and shapes, varying pad patterns and varying capacitive oscillation frequencies. In one embodiment, the surface area of the totem in contact with the capacitive mat varies depending upon the pressure placed on the totem to alter the shape of a compressible material disposed at the bottom surface.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: An augmented virtual reality is provided by composite visual information generated at goggles and a display viewed through the goggles. Positional cues at the display and/or goggles provide the relative position of the display to the goggles so that an end user primarily views the display through the goggles at the position of the display. The goggles provide peripheral visual images to support the display visual images and to support end user interactions with input devices used for controlling display and goggle visual images.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: Projected input and output devices adapt o a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.

Abstract: Projected input and output devices adapt to a desktop environment by sensing objects at the desktop environment and altering projected light in response to the sensed objects. For instance, projection of input and output devices is altered to limit illumination against and end user's hands or other objects disposed at a projection surface. End user hand positions and motions are detected to provide gesture support for adapting a projection work space, and configurations of projected devices are stored so that an end user can rapidly recreate a projected desktop. A projector scan adjusts to limit traces across inactive portions of the display surface and to increase traces at predetermined areas, such as video windows.