The present disclosure provides methods, devices, systems, and storage mediums for live broadcast detection and data processing. In one exemplary embodiments, a user terminal device cooperates with a server and a camera device in a live broadcast system. The terminal device turns towards the camera device and outputs detection content within a detection time. It can be determined whether live broadcast content uploaded/captured by the camera device includes the detection content captured by the camera device within the detection time. If the detection content is found in the live broadcast content, it can be determined that unauthorized live broadcasting exists. Accordingly, corresponding measures can be taken to stop the unauthorized live broadcasting in a timely manner, which helps improve the security of user information.

Methods and apparatus for distributing content using a spectrum generation device. In one embodiment, digital content is received via a time-multiplexed network transport (such as Gigabit Ethernet), and converted to frequency channels suitable for transmission over a content distribution (e.g., Hybrid Fiber Coaxial (HFC)) network. In one variant, the conversion is performed using digital domain processing performed by a full spectrum generation device. Additionally, methods and apparatus for selectively adding, removing, and/or changing digital content from the full spectrum device are also disclosed. Various aspects of the present invention enable physical (infrastructure) consolidation, and software-implemented remote management of content distribution.

Methods and apparatus for distributing content using a spectrum generation device. In one embodiment, digital content is received via a time-multiplexed network transport (such as Gigabit Ethernet), and converted to frequency channels suitable for transmission over a content distribution (e.g., Hybrid Fiber Coaxial (HFC)) network. In one variant, the conversion is performed using digital domain processing performed by a full spectrum generation device. Additionally, methods and apparatus for selectively adding, removing, and/or changing digital content from the full spectrum device are also disclosed. Various aspects of the present invention enable physical (infrastructure) consolidation, and software-implemented remote management of content distribution.

A transmitting method for transmitting contents using a broadcast wave and a communication path comprises: including content information in application control information when transmitting the contents using both the broadcast wave and the communication path, the content information being information for synchronizing a content transmitted by using the broadcast wave with a content transmitted by using the communication path at a reception side that receives the contents and being related to the content transmitted by using the communication path; and transmitting the application control information by using at least the broadcast wave in the broadcast wave and the communication path. As a result, a contents transmitting method is provided for enabling a quick access to contents through communication when the contents are reproduced by a combination of broadcast and communication on the receiving side.

Methods and systems for improved detection of audio transmissions are provided. In one embodiment, a method is provided that includes receiving an audio signal containing an audio transmission. The audio transmission may contain a predetermined portion that was initially generated based on an expected sequence of complex-valued signals. A real portion of the expected sequence of complex-valued signals may be compared to the received audio signal to identify a first portion of the received audio signal. A complex portion of the expected sequence may be compared to portions of the received audio signal near the first portion of the received audio signal to identify a second portion of the received audio signal. An arrival time of the audio transmission may be determined based on the second portion of the received audio signal.

Methods and systems for improved detection of audio transmissions are provided. In one embodiment, a method is provided that includes receiving an audio signal containing an audio transmission. The audio transmission may contain a predetermined portion that was initially generated based on an expected sequence of complex-valued signals. A real portion of the expected sequence of complex-valued signals may be compared to the received audio signal to identify a first portion of the received audio signal. A complex portion of the expected sequence may be compared to portions of the received audio signal near the first portion of the received audio signal to identify a second portion of the received audio signal. An arrival time of the audio transmission may be determined based on the second portion of the received audio signal.

Example apparatus disclosed herein determine that an output media signal from a monitored media device corresponds to at least a first media signal from a first source device in communication with the monitored media device, and a second media signal from a second source device in communication with the monitored media device. Disclosed example apparatus also access motion data reported by one or more of a first accelerometer associated with a first remote control device, a second accelerometer associated with a second remote control device, a third accelerometer associated with a third remote control device, the first remote control device associated with the first source device, the second remote control device associated with the second source device, the third remote control device associated with the monitored media device. Disclosed example apparatus also identify, based on the motion data, a source of the output media signal from the monitored media device.

Example apparatus disclosed herein determine that an output media signal from a monitored media device corresponds to at least a first media signal from a first source device in communication with the monitored media device, and a second media signal from a second source device in communication with the monitored media device. Disclosed example apparatus also access motion data reported by one or more of a first accelerometer associated with a first remote control device, a second accelerometer associated with a second remote control device, a third accelerometer associated with a third remote control device, the first remote control device associated with the first source device, the second remote control device associated with the second source device, the third remote control device associated with the monitored media device. Disclosed example apparatus also identify, based on the motion data, a source of the output media signal from the monitored media device.

An over-air media server obtains first media content, including external content stored in a location external to the over-air media server, and delivers it for broadcast via on-air broadcast chain. A streaming media server is in communication with the over-air media server and a streaming broadcast chain. The streaming media server operates in a synchronized mode, during which it delivers, under control of the over-air media server, second media content to a streaming broadcast chain. The streaming server transitions from the synchronized mode to an independent mode, during which it delivers the second media content to the streaming broadcast chain independent of control by over-air media server. While operating in the independent mode the streaming media server obtains the second media content, including obtaining external content, from the same location from which over-air media server obtains its external content. The second media content is delivered to the streaming broadcast chain independent of control by the over-air media server.

An over-air media server obtains first media content, including external content stored in a location external to the over-air media server, and delivers it for broadcast via on-air broadcast chain. A streaming media server is in communication with the over-air media server and a streaming broadcast chain. The streaming media server operates in a synchronized mode, during which it delivers, under control of the over-air media server, second media content to a streaming broadcast chain. The streaming server transitions from the synchronized mode to an independent mode, during which it delivers the second media content to the streaming broadcast chain independent of control by over-air media server. While operating in the independent mode the streaming media server obtains the second media content, including obtaining external content, from the same location from which over-air media server obtains its external content. The second media content is delivered to the streaming broadcast chain independent of control by the over-air media server.