Abstract: Identifiers or references to supplemental information or content regarding images may be steganographically encoded into the images. The identifiers or references may be encoded into least significant bits or less significant bits of pixels within the image that may be selected on any basis. The identifiers or references may include alphanumeric characters, bar codes, symbols or other features. When an image is captured of an image having one or more identifiers or references steganographically encoded therein, the identifiers or references may be interpreted, and the supplemental information or content may be accessed and displayed on a computer display. In some embodiments, the supplemental information or content may identify and relate to a commercial product expressed in an image, and may include a link to one or more pages or functions for purchasing the commercial product.

Abstract: An imaging device may be configured to monitor a field of view for various objects or events occurring therein. The imaging device may capture a plurality of images at various focal lengths, identify a region of interest including one or more semantic objects therein, and determine measures of the levels of blur or sharpness within the regions of interest of the images. Based on their respective focal lengths and measures of their respective levels of blur or sharpness, a focal length for capturing subsequent images with sufficient clarity may be predicted. The imaging device may be adjusted to capture images at the predicted focal length, and such images may be captured. Feedback for further adjustments to the imaging device may be identified by determining measures of the levels of blur or sharpness within the subsequently captured images.

Abstract: Depth information may be encoded into pixels of visual imaging data according to steganographic techniques. The depth information may be captured simultaneously with the visual imaging data, and one or more representative pixels may be identified within a region or sector of the visual imaging data according to a pixel traversal strategy. The depth information corresponding to the region or sector may be encoded into one or more least significant bits of the representative pixels, and a modified set of imaging data including the visual imaging data with the depth information encoded into the representative pixels may be stored in a data store and used for any relevant purpose.

Abstract: A grasp management system is described. The grasp management system may be configured to determine a grasp strategy for a robotic manipulator. Information about an initial state of an object may be accessed. Information about a final state of the object may also be accessed. The final state may enable a subsequent interaction with the object. An anticipated pose space may be determined that enables the subsequent interaction with the object. An initial pose for the robotic manipulator may be determined based at least in part on the anticipated pose space. The initial pose may be used by the robotic manipulator to grasp the object.

Abstract: Disclosed are various embodiments for providing dynamically generated summaries of media content, such as electronic books, audiobooks, audio series, video content series, and so on. An elapsed time since consumption of media content was ended is determined. A summary of a portion of the media content occurring prior to a point of resumption in the media content is dynamically generated. The content of the summary is selected according to a length of the elapsed time. The summary is presented via an output device.

Abstract: Techniques for automated quality control of containers and items are disclosed. Images of a container can be successively captured over time. A consolidated image can be generated from the captured images. A non-image representation of the consolidated image can be determined. The non-image representation can be used to determine whether the container satisfies a condition. An imaging system can include a visual reference object or an object sensor used to detect entry of the container into a view volume of an electronic camera. A motion system can transport the container into the view volume. Some examples operate in an automated-warehouse environment.

Abstract: A reflected light identification (RLID) system uses light to communicate stored information across long distances with minimal interference. The RLID system may include a light source that directs an incident light signal to an RLID structure, which then transmits an encoded light signal to a sensor. The RLID system may include a passive RLID structure (i.e., a structure that does not include power source) such as an RLID reflection surface that includes layered reflective films that reflect the incident light signal back in multiple reflections that serially encodes data. The RLID system may also include an active RLID structure (i.e., a structure that includes power source) that uses energy harvesting to extract and accumulate power from an incident light signal, and then uses the harvested energy to transmit a return signal.

Abstract: A set of earphones or other wearable or portable audio equipment may be configured to play relevant sound signals from a speaker provided within a cavity mounted about an ear of a user. The earphones may include one or more microphones for capturing acoustic energy within a vicinity of the earphones, or may be in communication with one or more external microphones. Where one or more of the microphones captures acoustic energy that includes a plurality of sound signals, the signals may be processed to identify one of the signals that is relevant to the user. The relevant signal may be reconstructed and amplified from the speaker, and all other signals may be ignored or attenuated. The signals may be further processed to determine any additional information regarding sources of the signals, including whether such signals are within a vicinity of the user, or may pose a risk to the user.

Abstract: Directed fragmentation of an unmanned aerial vehicle (UAV) is described. In one embodiment, the UAV includes various components, such one or more motors, batteries, sensors, a housing, casing or shell, and a payload for delivery. Additionally, the UAV includes a controller. The controller determines a flight path and controls a flight operation of the UAV. During the flight operation, the controller develops a release timing and a release location for one or more of the components based on the flight path, the flight conditions, and terrain topology information, among other factors. The controller can also detect a disruption in the flight operation of the UAV and, in response, direct fragmentation of one or more of the components apart from the UAV. In that way, a controlled, directed fragmentation of the UAV can be accomplished upon any disruption to the flight operation of the UAV.

Abstract: Directed fragmentation of an unmanned aerial vehicle (UAV) is described. In one embodiment, the UAV includes various components, such one or more motors, batteries, sensors, a housing, casing or shell, and a payload for delivery. Additionally, the UAV includes a flight controller and a fragmentation controller. The flight controller determines a flight path and controls a flight operation of the UAV. During the flight operation, the fragmentation controller develops a fragmentation sequence for one or more of the components based on the flight path, the flight conditions, and terrain topology information, among other factors. The fragmentation controller can also detect a disruption in the flight operation of the UAV and, in response, direct fragmentation of one or more of the components apart from the UAV. In that way, a controlled, directed fragmentation of the UAV can be accomplished upon any disruption to the flight operation of the UAV.

Abstract: Disclosed are various embodiments for providing dynamically generated summaries of media content, such as electronic books, audiobooks, audio series, video content series, and so on. A position in media content is determined based at least in part on input from a user. A summary of a portion of the media content is dynamically generated, where the portion of the media content begins or ends relative to the position. A summary of the portion of the media content is presented to the user via an output device.

Abstract: Disclosed are various embodiments for providing dynamically generated summaries of media content, such as electronic books, audiobooks, audio series, video content series, and so on. An elapsed time since consumption of media content was ended is determined. A summary of a portion of the media content occurring prior to a point of resumption in the media content is dynamically generated. The content of the summary is selected according to a length of the elapsed time. The summary is presented via an output device.

Abstract: An imaging device may be configured to monitor a field of view for various objects or events occurring therein. The imaging device may capture a plurality of images at various focal lengths, identify a region of interest including one or more semantic objects therein, and determine measures of the levels of blur or sharpness within the regions of interest of the images. Based on their respective focal lengths and measures of their respective levels of blur or sharpness, a focal length for capturing subsequent images with sufficient clarity may be predicted. The imaging device may be adjusted to capture images at the predicted focal length, and such images may be captured. Feedback for further adjustments to the imaging device may be identified by determining measures of the levels of blur or sharpness within the subsequently captured images.

Abstract: Blur metrics may be calculated for each of the image pixels of a digital image of a scene captured using an imaging device. The blur metrics may be indicative of the level of blur expressed in the digital image, and a blur image representative of the blur metrics may be generated. Subsequently, when another digital image is to be captured using the imaging device, pixel sensors corresponding to high blur metrics may be digitized at a high level of priority, or at a high rate, compared to pixel sensors corresponding to low blur metrics, which may be digitized at a low level of priority, or at a low rate. The blur images may be updated based on changes in blur observed in subsequent images, and different pixel sensors may be digitized at higher or lower levels of priority, or at higher or lower rates, based on the changes in blur.

Abstract: An imaging device may be configured to monitor a field of view for various objects or events occurring therein. The imaging device may capture a plurality of images at various focal lengths, identify a region of interest including one or more semantic objects therein, and determine measures of the levels of blur or sharpness within the regions of interest of the images. Based on their respective focal lengths and measures of their respective levels of blur or sharpness, a focal length for capturing subsequent images with sufficient clarity may be predicted. The imaging device may be adjusted to capture images at the predicted focal length, and such images may be captured. Feedback for further adjustments to the imaging device may be identified by determining measures of the levels of blur or sharpness within the subsequently captured images.

Abstract: Depth information may be encoded into pixels of visual imaging data according to steganographic techniques. The depth information may be captured simultaneously with the visual imaging data, and one or more representative pixels may be identified within a region or sector of the visual imaging data according to a pixel traversal strategy. The depth information corresponding to the region or sector may be encoded into one or more least significant bits of the representative pixels, and a modified set of imaging data including the visual imaging data with the depth information encoded into the representative pixels may be stored in a data store and used for any relevant purpose.

Abstract: Blur metrics may be calculated for each of the image pixels of a digital image of a scene captured using an imaging device. The blur metrics may be indicative of the level of blur expressed in the digital image, and a blur image representative of the blur metrics may be generated. Subsequently, when another digital image is to be captured using the imaging device, pixel sensors corresponding to high blur metrics may be digitized at a high level of priority, or at a high rate, compared to pixel sensors corresponding to low blur metrics, which may be digitized at a low level of priority, or at a low rate. The blur images may be updated based on changes in blur observed in subsequent images, and different pixel sensors may be digitized at higher or lower levels of priority, or at higher or lower rates, based on the changes in blur.