In one example, a device for retrieving media data includes a memory configured to store media data, and a processor implemented in circuitry and configured to: process a descriptor of a manifest file of media content including the media data, the descriptor corresponding to an adaptation set of the media content and including data representative of a box of file level information that describes a property of a track of a media file of the media content including media data of the adaptation set, determine whether to retrieve the media data of the adaptation set according to the data representative of the file level information, and in response to determining to retrieve the media data, send a request to retrieve the media data.

This present disclosure describes a system and methods for integrated multistreaming of media with graphical overlays. At least one method includes a multistream service and graphical overlays hosted by a server infrastructure; a user configuring both the multistream service and graphical overlays on the server infrastructure; a user playing video games on a computer, using broadcasting software to authenticate with the server infrastructure; the broadcasting software capturing video of the user's computer session; the software retrieving the user's custom graphical overlay from the server infrastructure, encoding the video signal and graphical overlay; the software using the same aforementioned authentication to upload the encoded video to a multistream service, and the multistream service streaming the user's encoded video simultaneously to multiple streaming services.

A fault-tolerant, cloud-based system can comprise a redundancy control unit capable of switching between transcoded video streams output by two or more transcoders. The redundancy control unit outputs a manifest from one of the transcoded streams and, upon detecting a fault in the stream, can modify the manifest to switch to another of the transcoded video streams. The redundancy control unit can further modify the manifest to flag the discontinuity in the video stream, which allows the player to switch to the new transcoding video stream without error. Other embodiments can include additional redundancies to help provide additional fault tolerance.

One example method of operation may include identifying data traffic on one or more ports of a switch, determining whether a protocol specific packet type is identified on any of the one or more ports, assigning one or more first ports with data traffic to a first protocol when the protocol specific packet type is identified, and assigning one or more second ports with data traffic to a second protocol different from the first protocol.

A method and system for identifying social trends are provided. The method includes collecting multimedia content from a plurality of data sources; gathering environmental variables related to the collected multimedia content; extracting visual elements from the collected multimedia content; generating at least one signature for each extracted visual element; generating at least one cluster of visual elements by clustering at least similar signatures generated for the extracted visual elements; correlating environmental variables related to visual elements in the at least one cluster; determining at least one social trend by associating the correlated environmental variables with the at least one cluster.

A system for dynamic, secure, real-time, data streaming leveraging quantum computing is provided. The system may include a receiver and router, a plurality of short-term servers, a mid-term database, a k-nearest neighbor number identifier and a quantum random number generator. The receiver and router may receive a request to stream a data element from a source location to an end location. The receiver and router may retrieve the requested data element from one of the short-term servers, the mid-term database and/or the source location. Once the data element is retrieved, the data element may be indexed by the k-nearest neighbor number identifier. The quantum random number generator may tag the data element with a quantum-resilient random number. Based on the random number, a short-term server may be selected. The data element may be forwarded to the selected short-term servers. The short-term storage may stream the data element to the end location.

The technology described herein relates to implementing an adaptive bitrate (ABR) algorithm at edge nodes. A method for implementing an ABR algorithm at an edge node may include receiving at the edge node a request for a video segment from a client according to the client’s ABR algorithm, the request indicating a quality. A weighted sum score for each of a set of qualities may be computed based on a quality score and a fairness score using the ABR algorithm at the edge node, the qualities including at least the requested quality and another quality. A modified request may be generated in response to the weighted sum score for the other quality being better than the weighted sum score for the requested quality. The modified request may be sent to a server. The video segment in the other quality may be received from the server and provided to a client.

A cable distribution system includes a head end connected to a plurality of customer devices through a transmission network that provides data suitable for the plurality of customer devices. A traffic monitoring system receives from a customer support device a first data request for a parameter of one of the plurality of customer devices. The traffic monitoring system provides a second data request for the parameter of the one of said plurality of customer devices to a customer premise equipment management system in response to receiving the first data request. The traffic monitoring system receiving a first data response including the parameter from the customer premise equipment management system in response to providing the second data request to the customer premise equipment management system. The traffic monitoring system providing a second data response including the parameter from the traffic management system to the customer support device in response to receiving the first data response.

Embodiments of the present disclosure relate to workload-based dynamic throttling of video processing functions. Systems and methods are disclosed that dynamically throttle video processing and/or streaming based on a workload. Live video is captured from one or more sources (e.g., cameras) and stored. The video is then provided to a video processing engine and a video streaming engine. The video processing engine may perform one or more operations such as object detection, object tracking, and object classification to produce characterization data (e.g., bounding boxes, object trajectories, alerts, object labels, object counts, boundary crossings, intersection highlighting, etc.). System resource usage and performance of the video processing and streaming are monitored to produce workload data (e.g., metrics). Based on the policies and the workload data, the video streaming and/or processing is dynamically reconfigured by adjusting parameters provided to the video streaming and processing engines.

Methods and systems for providing content to communication session participants are disclosed. In exemplary methods, at least one source can be monitored. Content relevant to a communication session having one or more participants can be identified from the at least one source. Additionally, the content can be provided as a part of the communication session in a format compatible with the communication session.