Patent application number | Description | Published |
20140333666 | INTERACTIONS OF VIRTUAL OBJECTS WITH SURFACES - Embodiments are disclosed that relate to operating a user interface on an augmented reality computing device comprising a display system. For example, one disclosed embodiment includes displaying a virtual object via the display system as free-floating, detecting a trigger to display the object as attached to a surface, and, in response to the trigger, displaying the virtual object as attached to the surface via the display system. The method may further include detecting a trigger to detach the virtual object from the surface and, in response to the trigger to detach the virtual object from the surface, detaching the virtual object from the surface and displaying the virtual object as free-floating. | 11-13-2014 |
20140347390 | BODY-LOCKED PLACEMENT OF AUGMENTED REALITY OBJECTS - Embodiments are disclosed that relate to placing virtual objects in an augmented reality environment. For example, one disclosed embodiment provides a method comprising receiving sensor data comprising one or more of motion data, location data, and orientation data from one or more sensors located on a head-mounted display device, and based upon the motion data, determining a body-locking direction vector that is based upon an estimated direction in which a body of a user is facing. The method further comprises positioning a displayed virtual object based on the body-locking direction vector. | 11-27-2014 |
20150206321 | AUTOMATED CONTENT SCROLLING - Methods for controlling the display of content as the content is being viewed by an end user of a head-mounted display device (HMD) are described. In some embodiments, an HMD may display the content using a virtual content reader for reading the content. The content may comprise text and/or images, such as text or images associated with an electronic book, an electronic magazine, a word processing document, a webpage, or an email. The virtual content reader may provide automated content scrolling based on a rate at which the end user reads a portion of the displayed content on the virtual content reader. In one embodiment, an HMD may combine automatic scrolling of content displayed on the virtual content reader with user controlled scrolling (e.g., via head tracking of the end user of the HMD). | 07-23-2015 |
20150212576 | RADIAL SELECTION BY VESTIBULO-OCULAR REFLEX FIXATION - Methods for enabling hands-free selection of objects within an augmented reality environment are described. In some embodiments, an object may be selected by an end user of a head-mounted display device (HMD) based on detecting a vestibulo-ocular reflex (VOR) with the end user's eyes while the end user is gazing at the object and performing a particular head movement for selecting the object. The object selected may comprise a real object or a virtual object. The end user may select the object by gazing at the object for a first time period and then performing a particular head movement in which the VOR is detected for one or both of the end user's eyes. In one embodiment, the particular head movement may involve the end user moving their head away from a direction of the object at a particular head speed while gazing at the object. | 07-30-2015 |
20150254905 | FIXED SIZE AUGMENTED REALITY OBJECTS - An example wearable display system includes a controller, a left display to display a left-eye augmented reality image with a left-eye display size at left-eye display coordinates, and a right display to display a right-eye augmented reality image with a right-eye display size at right-eye display coordinates, the left-eye and right-eye augmented reality images collectively forming an augmented reality object perceivable at an apparent real world depth by a wearer of the display system. The controller sets the left-eye display coordinates relative to the right-eye display coordinates as a function of the apparent real world depth of the augmented reality object. The function maintains an aspect of the left-eye and right-eye display sizes throughout a non-scaling range of apparent real world depths of the augmented reality object, and the function scales the left-eye and right-eye display sizes with changing apparent real world depth outside the non-scaling range. | 09-10-2015 |
20150261318 | GESTURE PARAMETER TUNING - Embodiments are disclosed herein that relate to tuning gesture recognition characteristics for a device configured to receive gesture-based user inputs. For example, one disclosed embodiment provides a head-mounted display device including a plurality of sensors, a display configured to present a user interface, a logic machine, and a storage machine that holds instructions executable by the logic machine to detect a gesture based upon information received from a first sensor of the plurality of sensors, perform an action in response to detecting the gesture, and determine whether the gesture matches an intended gesture input. The instructions are further executable to update a gesture parameter that defines the intended gesture input if it is determined that the gesture detected does not match the intended gesture input. | 09-17-2015 |
20150317834 | DETERMINING COORDINATE FRAMES IN A DYNAMIC ENVIRONMENT - Embodiments are disclosed for methods and systems of distinguishing movements of features in a physical environment. For example, on a head-mounted display device, one embodiment of a method includes obtaining a representation of real-world features in two or more coordinate frames and obtaining motion data from one or more sensors external to the head-mounted display device. The method further includes distinguishing features in one coordinate frame from features in another coordinate frame based upon the motion data. | 11-05-2015 |
20150331240 | Assisted Viewing Of Web-Based Resources - Assisted viewing of web-based resources by an end user of a head-mounted display device (HMD) is described. An HMD may display content from web-based resources using a see-through display while tracking eye and head movement of the end user viewing the content within an augmented reality environment. Active view regions within the see-through display are identified based on tracking information including eye gaze data and head direction data. The web-based resources are analyzed to identify content and display elements. The analysis is correlated with the active view regions to identify the underlying content that is a desired point of focus of a corresponding active view region, as well as to identify the display elements corresponding to that content. A web-based resource is modified based on the correlation. The content from the web-based resource is displayed based on the modifications to assist the end user in viewing the web-based resource. | 11-19-2015 |