Methods and systems for intelligent use of off-peak bandwidth are disclosed. An example method can comprise receiving a request for content from a user device. The content server can transmit the content to the user device. Upon receiving a teardown command to suspend transmission of the content, after transmitting a first portion of the content to the user device, the content server can determine that playback of the content is likely to be resumed at a peak time. The content server can then pre-position a second portion of the content proximate to the user device prior to the peak time.

Methods and systems for intelligent use of off-peak bandwidth are disclosed. An example method can comprise receiving a request for content from a user device. The content server can transmit the content to the user device. Upon receiving a teardown command to suspend transmission of the content, after transmitting a first portion of the content to the user device, the content server can determine that playback of the content is likely to be resumed at a peak time. The content server can then pre-position a second portion of the content proximate to the user device prior to the peak time.

An entertainment system provides data to a common screen (e.g., cinema screen) and personal immersive reality devices. For example, a cinematic data distribution server communicates with multiple immersive output devices each configured for providing immersive output (e.g., a virtual reality output) based on a data signal. Each of the multiple immersive output devices is present within eyesight of a common display screen. The server configures the data signal based on digital cinematic master data that includes immersive reality data. The server transmits the data signal to the multiple immersive output devices contemporaneously with each other, and optionally contemporaneously with providing a coordinated audio-video signal for output via the common display screen and shared audio system.

An entertainment system provides data to a common screen (e.g., cinema screen) and personal immersive reality devices. For example, a cinematic data distribution server communicates with multiple immersive output devices each configured for providing immersive output (e.g., a virtual reality output) based on a data signal. Each of the multiple immersive output devices is present within eyesight of a common display screen. The server configures the data signal based on digital cinematic master data that includes immersive reality data. The server transmits the data signal to the multiple immersive output devices contemporaneously with each other, and optionally contemporaneously with providing a coordinated audio-video signal for output via the common display screen and shared audio system.

The present disclosure relates to a content delivery control apparatus, a content delivery control method, a program, and a content delivery system capable of achieving commonality of conditions associated with transcoding at the time of content delivery in different CDNs and supporting a standard upload interface. In a case in which definition information is stored in a metadata file, an original data stream is controlled on the basis of the definition information. Meanwhile, in a case in which access information for accessing the definition information is stored in the metadata file, then the definition information is requested on the basis of the access information, and transcoding of an original stream is controlled on the basis of the definition information received in response to the request. The present disclosure is applicable to a content delivery system that delivers a content using SDP.

A method and apparatus for transmitting adaptive video in real time using a content-aware neural network are disclosed. At least one embodiment provides a method performed by a server for transmitting an adaptive video in real time by using content-aware deep neural networks (DNNs), including downloading a video, encoding a downloaded video for each of at least one resolution, dividing an encoded video into video chunks of a predetermined size, training the content-aware DNNs by using encoded video, generating a configuration or manifest file containing information on trained content-aware DNNs and information on the encoded video, and transmitting the configuration file upon a request of a client.

Methods, computer readable media, and devices for automated routing based on content metadata are provided. One method may include receiving a user request for content with metadata from a client by a content distribution network (CDN), parsing the user request for content to generate an evaluation of the metadata, determining a routing decision representing a selection of one of a plurality of origin services for the user request for content based on the evaluation of the metadata, transmitting the user request for content to the selected one of the plurality of origin services based on the routing decision, receiving a response to the user request for content from the selected one of the plurality of origin services, and sending the response to the client.

The vehicle control system/method for adapting a control function based on a user profile may comprise: a gesture recognition module; a user profile module; a function control module; a processor; a non-transitory storage element coupled to the processor; encoded instructions stored in the non-transitory storage element, wherein the encoded instructions when implemented by the processor, configure the system to: identify a user; retrieve a user profile for the identified user; receive at a gesture recognition module, an input indicating a gesture from the user; identify a control function request corresponding to the gesture input; send a verification of the control function request; and receive at a function control module characteristics parsed from the user profile that effect the control function request by the user profile module to adapt a control function command for an adapted control function output by the function control module.

The vehicle control system/method for adapting a control function based on a user profile may comprise: a gesture recognition module; a user profile module; a function control module; a processor; a non-transitory storage element coupled to the processor; encoded instructions stored in the non-transitory storage element, wherein the encoded instructions when implemented by the processor, configure the system to: identify a user; retrieve a user profile for the identified user; receive at a gesture recognition module, an input indicating a gesture from the user; identify a control function request corresponding to the gesture input; send a verification of the control function request; and receive at a function control module characteristics parsed from the user profile that effect the control function request by the user profile module to adapt a control function command for an adapted control function output by the function control module.

The vehicle control system/method for adapting a control function based on a user profile may comprise: a gesture recognition module; a user profile module; a function control module; a processor; a non-transitory storage element coupled to the processor; encoded instructions stored in the non-transitory storage element, wherein the encoded instructions when implemented by the processor, configure the system to: identify a user; retrieve a user profile for the identified user; receive at a gesture recognition module, an input indicating a gesture from the user; identify a control function request corresponding to the gesture input; send a verification of the control function request; and receive at a function control module characteristics parsed from the user profile that effect the control function request by the user profile module to adapt a control function command for an adapted control function output by the function control module.