Abstract: An exemplary computing device is configured to obtain a first set of control points used to generate a first panoramic image from a first locus point. The computing device is further configured to identify a second set of control points based upon which a second panoramic image is to be generated from a second locus point different from the first locus point. The identifying of the second set of control points is based on the first set of control points that were used to generate the first panoramic image from the first locus point. Based on the second set of control points, the computing device is also configured to generate the second panoramic image from the second locus point. Corresponding methods and systems are also disclosed.

Abstract: Embodiments described herein provide for the leveraging of edge-based resources (e.g., processing, memory, storage, and/or other resources of one or more Multi-Access/Mobile Edge Computing devices (“MECs”), such as MECs associated with a radio access network (“RAN”) of a wireless network) to process data from and/or provide instructions to microcontroller devices, System on Chip (“SoC”) devices, configurable logic boards, Internet of Things (“IoT”) devices, and/or other types of devices or systems. For example, embodiments described herein may provide for the creation and configuration of logical devices or systems based on one or more microcontrollers, SoC devices, etc., edge-based processing of sensor data and/or other types of data received or generated by the microcontrollers, SoC devices, etc., and the generation of instructions to control physical devices communicatively coupled to the microcontrollers, SoC devices, etc.

Abstract: Embodiments described herein provide for the leveraging of edge-based resources (e.g., processing, memory, storage, and/or other resources of one or more Multi-Access/Mobile Edge Computing devices (“MECs”), such as MECs associated with a radio access network (“RAN”) of a wireless network) to process data from and/or provide instructions to microcontroller devices, System on Chip (“SoC”) devices, configurable logic boards, Internet of Things (“IoT”) devices, and/or other types of devices or systems. For example, embodiments described herein may provide for the creation and configuration of logical devices or systems based on one or more microcontrollers, SoC devices, etc., edge-based processing of sensor data and/or other types of data received or generated by the microcontrollers, SoC devices, etc., and the generation of instructions to control physical devices communicatively coupled to the microcontrollers, SoC devices, etc.

Abstract: Embodiments described herein provide for the leveraging of edge-based resources (e.g., processing, memory, storage, and/or other resources of one or more Multi-Access/Mobile Edge Computing devices (“MECs”), such as MECs associated with a radio access network (“RAN”) of a wireless network) to process data from and/or provide instructions to microcontroller devices, System on Chip (“SoC”) devices, configurable logic boards, Internet of Things (“IoT”) devices, and/or other types of devices or systems. For example, embodiments described herein may provide for the creation and configuration of logical devices or systems based on one or more microcontrollers, SoC devices, etc., edge-based processing of sensor data and/or other types of data received or generated by the microcontrollers, SoC devices, etc., and the generation of instructions to control physical devices communicatively coupled to the microcontrollers, SoC devices, etc.

Abstract: Embodiments described herein provide for the leveraging of edge-based resources (e.g., processing, memory, storage, and/or other resources of one or more Multi-Access/Mobile Edge Computing devices (“MECs”), such as MECs associated with a radio access network (“RAN”) of a wireless network) to process data from and/or provide instructions to microcontroller devices, System on Chip (“SoC”) devices, configurable logic boards, Internet of Things (“IoT”) devices, and/or other types of devices or systems. For example, embodiments described herein may provide for the creation and configuration of logical devices or systems based on one or more microcontrollers, SoC devices, etc., edge-based processing of sensor data and/or other types of data received or generated by the microcontrollers, SoC devices, etc., and the generation of instructions to control physical devices communicatively coupled to the microcontrollers, SoC devices, etc.

Abstract: An exemplary computing device is configured to obtain a first set of control points used to generate a first panoramic image from a first locus point. The computing device is further configured to identify a second set of control points based upon which a second panoramic image is to be generated from a second locus point different from the first locus point. The identifying of the second set of control points is based on the first set of control points that were used to generate the first panoramic image from the first locus point. Based on the second set of control points, the computing device is also configured to generate the second panoramic image from the second locus point. Corresponding methods and systems are also disclosed.

Abstract: An exemplary image stitching recovery system detects a failed attempt by an image stitching system to generate a first panoramic image in a target location image set that includes a plurality of panoramic images each depicting a target location from a different respective locus point. The image stitching recovery system identifies a particular locus point at which a second panoramic image within the target location image set has been successfully generated, and identifies, based on a second set of control points that were used by the image stitching system to successfully generate the second panoramic image at the particular locus point, a first set of control points based upon which the first panoramic image is to be successfully generated. Subsequently, the image stitching recovery system directs the image stitching system to generate, based on the first set of control points, the first panoramic image in the target location image set.

Abstract: An exemplary depth capture system emits a first structured light pattern onto a surface of an object included in a real-world scene using a first structured light emitter included within the depth capture system. The depth capture system also emits, concurrently with the emitting of the first structured light pattern, a second structured light pattern onto the surface of the object using a second structured light emitter included within the depth capture system. The emitting of the second structured light pattern is different than the emitting of the first structured light pattern. The depth capture system detects the first and second structured light patterns using one or more optical sensors included within the depth capture system. Based on the detection of the structured light patterns, the depth capture system generates depth data representative of the surface of the object included in the real-world scene.

Abstract: An exemplary method includes a media content provider system acquiring, from a plurality of capture devices physically disposed at different vantage points in relation to a scene, a distinct set of two-dimensional (2D) color data and depth data (2D data) for each capture device included in the plurality of capture devices, each distinct set of 2D data representing a distinct unmeshed view of the scene as captured from a respective vantage point of a respective capture device included in the plurality of capture devices, acquiring metadata for each distinct set of 2D data, packaging each distinct set of 2D data into a transport stream such that the transport stream includes data representing each distinct unmeshed view of the scene as captured from each respective vantage point of each respective capture device, and providing the metadata and the transport stream for streaming to a media player device.

Abstract: An exemplary image stitching recovery system detects a failed attempt by an image stitching system to generate a first panoramic image in a target location image set that includes a plurality of panoramic images each depicting a target location from a different respective locus point. The image stitching recovery system identifies a particular locus point at which a second panoramic image within the target location image set has been successfully generated, and identifies, based on a second set of control points that were used by the image stitching system to successfully generate the second panoramic image at the particular locus point, a first set of control points based upon which the first panoramic image is to be successfully generated. Subsequently, the image stitching recovery system directs the image stitching system to generate, based on the first set of control points, the first panoramic image in the target location image set.

Abstract: An exemplary depth data generation system accesses first and second depth maps of a real-world scene, the depth maps independently captured using first and second depth map capture techniques, respectively. The first and second depth maps include, respectively, first and second depth data points both representative of a same physical point on a surface of an object in the real-world scene. Based on the first and second depth map capture techniques and based on an attribute of the surface of the object, the system assigns a first confidence value to the first depth data point and a second confidence value to the second depth data point. Based on the first and second confidence values, the system converges the first and second depth maps to form a converged depth map of the real-world scene that includes a third depth data point representing the physical point on the surface of the object.

Abstract: An exemplary virtual object presentation system accesses depth data for surfaces of a three-dimensional (“3D”) virtual object. The system determines, based on the depth data, a set of element configuration operations that, when performed by field formation elements included within an array of reconfigurable field formation elements, form a field in accordance with the depth data. Specifically, the field formed is to be haptically perceptible to a user using a field perception apparatus. The system may direct the field formation elements included within the array of reconfigurable field formation elements to perform the set of element configuration operations to thereby form the haptically perceptible field. In this way, the array of reconfigurable field formation elements generates a haptically perceptible virtual object representative of the 3D virtual object for perception by the user using the field perception apparatus. Corresponding methods are also disclosed.

Abstract: An augmented reality projection device includes an image sensor having a field of view into a real-world environment, a spatial sensor configured to detect a location and an orientation of the device in the environment, and a projector configured to project content onto a physical surface within the environment. The device determines the location and orientation of the device based on sensor output from the spatial sensor, and determines that a virtual target object is included within the field of view of the image sensor based on the determined location and orientation and based on a particular target object profile from a library of predetermined target object profiles. The device identifies content associated with the virtual target object and directs the projector to project the content onto the physical surface within the environment, the physical surface associated with the virtual target object. Corresponding methods and systems are also disclosed.

Abstract: An exemplary method includes a media content provider system acquiring, from a plurality of capture devices physically disposed at different vantage points in relation to a scene, a distinct set of two-dimensional (2D) color data and depth data (2D data) for each capture device included in the plurality of capture devices, each distinct set of 2D data representing a distinct unmeshed view of the scene as captured from a respective vantage point of a respective capture device included in the plurality of capture devices, acquiring metadata for each distinct set of 2D data, packaging each distinct set of 2D data into a transport stream such that the transport stream includes data representing each distinct unmeshed view of the scene as captured from each respective vantage point of each respective capture device, and providing the metadata and the transport stream for streaming to a media player device.

Abstract: An exemplary method includes a virtual reality media provider system acquiring, from a plurality of capture devices physically disposed at different vantage points in relation to a scene, a distinct set of two-dimensional (2D) color data and depth data (2D data) for each capture device included in the plurality of capture devices, each distinct set of 2D data representing a distinct unmeshed view of the scene from a respective vantage point of a respective capture device included in the plurality of capture devices, acquiring metadata for each distinct set of 2D data, packaging each distinct set of 2D data into a transport stream such that the transport stream includes data representing each distinct unmeshed view of the scene from each respective vantage point of each respective capture device, and providing the metadata and the transport stream for streaming to a media player device.

Abstract: An augmented reality projection device includes an image sensor having a field of view into a real-world environment, a spatial sensor configured to detect a location and an orientation of the device in the environment, and a projector configured to project content onto a physical surface within the environment. The device determines the location and orientation of the device based on sensor output from the spatial sensor, and determines that a virtual target object is included within the field of view of the image sensor based on the determined location and orientation and based on a particular target object profile from a library of predetermined target object profiles. The device identifies content associated with the virtual target object and directs the projector to project the content onto the physical surface within the environment, the physical surface associated with the virtual target object. Corresponding methods and systems are also disclosed.

Abstract: An augmented reality presentation system directs a sensor included within an augmented reality projection device to capture an image of a portion of a real-world environment included within a field of view of the sensor. As the sensor captures the image, the system determines that a target object located within the real-world environment is included within the field of view of the sensor, and identifies augmented reality content associated with the target object. As the sensor continues capturing the image, the system directs a projector included within the augmented reality projection device to project the augmented reality content onto a physical surface within the real-world environment and associated with the target object. The physical surface is physically detached from the augmented reality projection device and is included within the field of view of the sensor while the augmented reality content is projected onto the physical surface.

Abstract: An augmented reality presentation system directs a sensor included within an augmented reality projection device to capture an image of a portion of a real-world environment included within a field of view of the sensor. As the sensor captures the image, the system determines that a target object located within the real-world environment is included within the field of view of the sensor, and identifies augmented reality content associated with the target object. As the sensor continues capturing the image, the system directs a projector included within the augmented reality projection device to project the augmented reality content onto a physical surface within the real-world environment and associated with the target object. The physical surface is physically detached from the augmented reality projection device and is included within the field of view of the sensor while the augmented reality content is projected onto the physical surface.

Abstract: An exemplary depth data generation system accesses first and second depth maps of a real-world scene, the depth maps independently captured using first and second depth map capture techniques, respectively. The first and second depth maps include, respectively, first and second depth data points both representative of a same physical point on a surface of an object in the real-world scene. Based on the first and second depth map capture techniques and based on an attribute of the surface of the object, the system assigns a first confidence value to the first depth data point and a second confidence value to the second depth data point. Based on the first and second confidence values, the system converges the first and second depth maps to form a converged depth map of the real-world scene that includes a third depth data point representing the physical point on the surface of the object.

Abstract: An exemplary virtual object presentation system accesses depth data for surfaces of a three-dimensional (“3D”) virtual object. The system determines, based on the depth data, a set of element configuration operations that, when performed by field formation elements included within an array of reconfigurable field formation elements, form a field in accordance with the depth data. Specifically, the field formed is to be haptically perceptible to a user using a field perception apparatus. The system may direct the field formation elements included within the array of reconfigurable field formation elements to perform the set of element configuration operations to thereby form the haptically perceptible field. In this way, the array of reconfigurable field formation elements generates a haptically perceptible virtual object representative of the 3D virtual object for perception by the user using the field perception apparatus. Corresponding methods are also disclosed.