According to examples, a system for using to processing of audio data using a plurality of distributed computer manner is described. The system may include a processor and a memory storing instructions. The processor may cause the system to receive audio data associated with a content item in an initial format, process the audio data to generate one or more audio segments for distributed processing, and decode the one or more audio segments from the audio data in the initial format to generate decoded audio data in a decoding format. The processor may then encode the decoded audio data in a decoding format to encoded audio data in an encoding format and trim a segment of the encoded audio data in the encoded format to generate a trimmed segment of audio data that may be utilized to enable continuous playback by a receiving device.

According to examples, a system for using to processing of audio data using a plurality of distributed computer manner is described. The system may include a processor and a memory storing instructions. The processor may cause the system to receive audio data associated with a content item in an initial format, process the audio data to generate one or more audio segments for distributed processing, and decode the one or more audio segments from the audio data in the initial format to generate decoded audio data in a decoding format. The processor may then encode the decoded audio data in a decoding format to encoded audio data in an encoding format and trim a segment of the encoded audio data in the encoded format to generate a trimmed segment of audio data that may be utilized to enable continuous playback by a receiving device.

The technology relates to an encoding device, an encoding method, a decoding device, a decoding method, and a program enabling encoding with favorable transmission efficiency with a controlled running disparity.

There are provided: a calculation section dividing inputted data into N bits to calculate a first running disparity of a data string of the N bits; a determination section determining whether the data string of the N bits is inverted based on the first running disparity calculated by the calculation section and a second running disparity calculated at a time point before the first running disparity; and an addition section inverting or non-inverting the data string of the N bits based on a result of the determination by the determination section to add a flag indicating the result of the determination by the determination section for outputting. The technology is applicable to a device communicating in an SLVS-EC specification.

The technology relates to an encoding device, an encoding method, a decoding device, a decoding method, and a program enabling encoding with favorable transmission efficiency with a controlled running disparity.

There are provided: a calculation section dividing inputted data into N bits to calculate a first running disparity of a data string of the N bits; a determination section determining whether the data string of the N bits is inverted based on the first running disparity calculated by the calculation section and a second running disparity calculated at a time point before the first running disparity; and an addition section inverting or non-inverting the data string of the N bits based on a result of the determination by the determination section to add a flag indicating the result of the determination by the determination section for outputting. The technology is applicable to a device communicating in an SLVS-EC specification.

A data distribution method, a data aggregation method, and related apparatuses are disclosed. The data distribution method may include: receiving a first packet stream; dividing the first packet stream to obtain a first data block stream; sending the first data block stream to a first circuit; processing, by the first circuit, the first data block stream to obtain a first data stream; distributing, by the first circuit, the first data stream to N1 second circuits of M second circuits in a PT-W, where M is greater than N1, N1 is a positive integer, and M is a positive integer; and processing, by the N1 second circuits, the received first data stream to obtain N1 first code streams. The technical solutions provided by the embodiments of the present application help to meet a requirement for complex bandwidth configuration and extend an application scenario.

Methods, systems, and apparatuses for a single edge nibble transmission (SENT) multi-transmission mode are described. In an example, a system can include a transmitter and a receiver connected to one another. The transmitter may encode an identifier of a device in a synchronization nibble of a SENT signal. The transmitter may transmit the SENT signal with the encoded identifier to the receiver. The receiver may receive the SENT signal from the transmitter. The receiver may decode the identifier of the device from the synchronization nibble of the SENT signal to identify the device.

A transmission device of the disclosure includes: a generator unit that generates, on the basis of a control signal, a transmission symbol signal that indicates a sequence of transmission symbols; an output control unit that generates an output control signal on the basis of the transmission symbol signal; and a driver unit that generates, on the basis of the output control signal, a first output signal, a second output signal, and a third output signal. The generator unit generates the transmission symbol signal on the basis of the control signal, to allow the first output signal, the second output signal, and the third output signal to exchange signal patterns with one another.

A transmission device of the disclosure includes: a generator unit that generates, on the basis of a control signal, a transmission symbol signal that indicates a sequence of transmission symbols; an output control unit that generates an output control signal on the basis of the transmission symbol signal; and a driver unit that generates, on the basis of the output control signal, a first output signal, a second output signal, and a third output signal. The generator unit generates the transmission symbol signal on the basis of the control signal, to allow the first output signal, the second output signal, and the third output signal to exchange signal patterns with one another.

A test and measurement instrument including a digital down converter configured to receive a bus signal and output in-phase and quadrature-phase baseband component waveform data, a trace generator configured to receive the in-phase and quadrature-phase baseband component waveform data and generate at least one radio frequency versus time trace, a decoder configured to receive the at least one radio frequency versus time trace and decode the bus signal based on the at least one radio frequency versus time trace and a wireless modulation scheme, and a trigger configured to capture at least a portion of the bus signal based on the decoded bus signal.

The application discloses a polar system and a delay difference calibration method. The polar system includes: a calibration signal generation unit, a CORDIC, a delay difference generation unit, a transmission unit, a receiving unit, a Fourier transformer and a calibration unit. The receiving unit is configured to receive a transmission signal from the transmission unit. The Fourier transformer is configured to compute a power of a receiving signal at a specific frequency. The calibration unit is configured to control the delay difference generation unit and determine a delay difference calibration value in a calibration mode.