A media output device operates to receive audio and/or video data for a content item. The audio and/or video data can be communicated from another device over a network. The output device generates an audio or video output for the content item based on the audio or video data. While receiving the audio or video data, the output device determines an instance of time that is synchronized to an external clock reference. The output device also determines an output correction to perform based at least in part on the synchronized instance of time. The output device adjusts the output to include the output correction.

Controlling or limiting visibility into particular metadata associated with the transfer of media content from a source device or system to a receiving device or system.

The present invention is intended to permit both real-time display of a picture represented by a non-compressed video signal on a television and display of a picture represented by a compressed video signal at any desired time by simultaneously transmitting the compressed video signal and non-compressed video signal via one interface. An STB packetizes a compressed video signal, and multiplexes the compressed video signal and a blanking signal combined with a non-compressed video signal. Thus, both the video signals are transmitted simultaneously. A picture represented by the non-compressed video signal is displayed on a television in real time. The compressed video signal is stored in a storage medium incorporated in the television, read at any user's desired time, and decoded so that a picture represented by the compressed video signal can be viewed at the user's desired time.

An Internet Layer end-to-end security connection (an Internet protocol (IP) encrypted tunnel) is established between a television receiving device and each player device on a home local area network (LAN) as part of the initial pairing process between each player device and the television receiving device. Traffic between the television receiving device and the player device is communicated via IP on the LAN, such that data between the two devices is securely encrypted at the Internet Layer, thus reducing potential security issues related to managing security and encryption at the application layer. This results in a secure virtual private network (VPN) between each player device and the television receiving device.

Devices, systems, and processes are described for seamless use of timers across multiple user devices on a LAN. A system may include a first user device, communicatively coupled to the LAN, having at least one first tuner and a first hardware processor configured for facilitating a first timer manager. A second user device communicatively coupled to the LAN may include at least one second tuner and a second hardware processor configured for facilitating a second timer manager. Each of the first timer manager and the second timer manager may be configured to populate a universal timer schedule that identifies at least one of a future availability and a future use for each of the at least one first tuner and the at least one second tuner. The universal timer schedule is populated based upon a request type, such as an auto-tune, PPV, original content, re-run, and a Joey request type.

An electronic device according to the disclosure includes an infrared signal receiver, an infrared signal transmitter, a memory that stores computer instruction code, which, when executed by a processor, causes the processor to: receive a first infrared signal output from a remote control device according to a user input for controlling an external device connected with the electronic device through the infrared signal receiver, identify a second infrared signal corresponding to one of control commands for controlling the operation of the external device based on control information included in the received first infrared signal, identify the output timing of the second infrared signal based on the type of the first infrared signal, and control the infrared signal transmitter to output the determined second infrared signal based on the identified output timing.

Devices, systems, and processes are described for seamless use of timers across multiple user devices on a LAN. A system may include a first user device, communicatively coupled to the LAN, having at least one first tuner and a first hardware processor configured for facilitating a first timer manager. A second user device communicatively coupled to the LAN may include at least one second tuner and a second hardware processor configured for facilitating a second timer manager. Each of the first timer manager and the second timer manager may be configured to populate a universal timer schedule that identifies at least one of a future availability and a future use for each of the at least one first tuner and the at least one second tuner. The universal timer schedule is populated based upon a request type, such as an auto-tune, PPV, original content, rerun, and a Joey request type.

Disclosed are a transmitting method, a receiving method, a transmitting device, and a receiving device for audio and video data in a long-distance transmission. The receiving method comprises the follows. A first protocol data stream is obtained by the receiving device via a second transmission medium interface. The first protocol data stream is processed by the receiving device to obtain a second preset protocol data stream and second preset audio and video data. The second preset protocol data stream is outputted by the receiving device via a third transmission medium interface. The second preset audio and video data is outputted by the receiving device via a second high definition multimedia interface (HDMI). By adopting the disclosure, the extended transmission of audio and video data can be realized, which can reduce the transmission cost and construction time. This shall result in higher user experience.

The present invention is intended to permit both real-time display of a picture represented by a non-compressed video signal on a television and display of a picture represented by a compressed video signal at any desired time by simultaneously transmitting the compressed video signal and non-compressed video signal via one interface. An STB packetizes a compressed video signal, and multiplexes the compressed video signal and a blanking signal combined with a non-compressed video signal. Thus, both the video signals are transmitted simultaneously. A picture represented by the non-compressed video signal is displayed on a television in real time. The compressed video signal is stored in a storage medium incorporated in the television, read at any user's desired time, and decoded so that a picture represented by the compressed video signal can be viewed at the user's desired time.

An electronic device according to an embodiment of the disclosure includes: a memory, and a processor electrically connected to the memory, wherein the memory stores a high dynamic range image and dynamic metadata including dynamic tone mapping information corresponding to a plurality of frames included in the high dynamic range image, and wherein the memory stores instructions that, when executed, cause the processor to: control the electronic device to transmit a packet including data obtained by combining one frame among the plurality of frames and a part of the dynamic metadata corresponding to the one frame among the dynamic metadata to an external electronic device in response to an image request from the external electronic device.