At a computer-enabled imaging device, a workflow including a plurality of time-stamped images is obtained. Each time-stamped image has a respective time point at which the respective time-stamped image was obtained. A first plurality of time-stamped accelerometer interval readings and a first plurality of time-stamped interval gyroscope readings are acquired, each of the readings having a respective time point at which the respective reading was acquired. A first real-time translational and rotational trajectory of the first computer-enabled imaging device is thereby obtained. Time-stamped coordinates of feature points in the first workflow are acquired at a plurality of time points during which the time-stamped images were acquired. A first dataset including the workflow, time-stamped coordinates, the real-time translational and rotational trajectory, and translational movement of the coordinates of the feature points is communicated to a data processing and display system for image processing and analysis.

Techniques and systems for identifying objects using gaze tracking techniques are described. A computing system may determine or infer that an individual is requesting to identify an object that is unknown to the individual based at least partly on images of the individual, images of a scene including the object, or both. In some cases, images of the individual may be used to determine a gaze path of the individual and the unknown object may be within the gaze path of the individual. Additionally, a computing system may send a request to identify the object to at least one individual. One or more of the responses received from the at least one individual may be provided in order to identify the object.

The invention provides a system and a method for an otitis media database constructing. The steps of method comprise: First, receiving a plurality of tympanic membrane images, wherein the tympanic membrane images are ear infection in different types. Second, choosing one of the tympanic membrane images, then classifying into a plurality of anatomic regions based on a plurality of tissue types. Coding each of anatomic regions with a numerical number to describe its morbid condition, and obtaining an eigenvalue through collecting the numerical number of each anatomic region. Furthermore, repeatedly choosing other one of tympanic membrane images until each tympanic membrane image obtaining the eigenvalue. And obtaining a matrix through collecting the eigenvalue of each tympanic membrane image, then generating an otitis media database.

An application executing on a mobile device generates a geo-positional query including a time stamp representing the time of the query. The application can be, for example, an augmented reality application, a pointing search application, or a mapping application that searches based on geolocation and/or physical proximity. The query can include, in addition to a location, one or more of a direction, orientation, and camera field of view of the mobile device. A system processes the query to return a time-based state of an object and/or location addressed by the mobile device at the time of the query. The system can use the time stamp to identify which objects may have been located at a certain location at a certain time and/or to identify the state of located objects at a certain time. For example, the state of an electronic billboard can identify an advertisement displayed at the time.

An application executing on a mobile device generates a geo-positional query including a time stamp representing the time of the query. The application can be, for example, an augmented reality application, a pointing search application, or a mapping application that searches based on geolocation and/or physical proximity. The query can include, in addition to a location, one or more of a direction, orientation, and camera field of view of the mobile device. A system processes the query to return a time-based state of an object and/or location addressed by the mobile device at the time of the query. The system can use the time stamp to identify which objects may have been located at a certain location at a certain time and/or to identify the state of located objects at a certain time. For example, the state of an electronic billboard can identify an advertisement displayed at the time.

An identifier based glyph search is described. In one or more embodiments, a search input is analyzed in a digital medium environment to generate search tokens and locate a font. The search tokens are compared to identifiers within the font, and corresponding identifiers are used to locate and retrieve particular glyphs from within the font. The retrieved glyphs are ordered and configured for output or display. The resulting glyph results include a variety of glyphs that are related to the search input, and may provide alternative related glyphs even where a user knows an exact identifier associated with a glyph. This technique may be iterated to accommodate changing search inputs and allows users to easily find desired glyphs with minimal effort and without the need for specialized knowledge regarding the identifiers of particular glyphs.

A method of selecting graphic or video files having corresponding locators used to locate such graphic or video files using a computer. Identifiers are created by searching an area within a web page near a graphic or video file for searchable identification terms and searching an area within a web page near links to a graphic or video for searchable identification terms. The identifiers are stored in a database. User requests for graphic or video file content are received and the database of identifiers is searched to find graphic and video files corresponding criteria of the user. Graphic or video file content is then provided to the user.

A mesh of existing infrastructures is usable to identify user identities and communications devices with physical objects (e.g., transportation vehicles, apparel, etc.). A system can receive image data representative of images of physical objects captured (e.g., by a camera) at locations. The system can also receive signal data representative of signals from communications devices. Based on time data and location data associated with the image data and the signal data, the system can, after multiple iterations, determine whether one of the physical objects is correlated with one of the communications devices. In response to a correlation, the system can store in a record data (e.g., a container, database, etc.) data elements representative of the physical object and a second data element associated with the communications device.

A mesh of existing infrastructures is usable to identify user identities and communications devices with physical objects (e.g., transportation vehicles, apparel, etc.). A system can receive image data representative of images of physical objects captured (e.g., by a camera) at locations. The system can also receive signal data representative of signals from communications devices. Based on time data and location data associated with the image data and the signal data, the system can, after multiple iterations, determine whether one of the physical objects is correlated with one of the communications devices. In response to a correlation, the system can store in a record data (e.g., a container, database, etc.) data elements representative of the physical object and a second data element associated with the communications device.

In some embodiments, image input data is received from multiple sources. The received image input data may then be aggregated and mapped to create a set of image input data. An event in the set of image input data may be automatically detected, such as by being triggered by a rule and an associated tag. An image mining result database may be updated by adding an entry to the database identifying each detected event and the triggering rule. An indication associated with the image mining result database may then be transmitted to a plurality of risk applications.