A synchronous modulation method based on an embedded player. The method comprises the steps of: Step S1, acquiring a current timestamp adopted by a current synchronous audio signal and a current synchronous video signal; Step S2, acquiring a jump difference value of the current timestamp; Step S3, determining whether the jump difference value is less than a first preset time, if yes, synchronously playing, by the player, the audio signal and the video signal through a first timestamp, and exiting; and Step S4, determining whether the jump difference value is greater than a second preset time, if yes, synchronously playing, by the player, the audio signal and the video signal through a second timestamp, and exiting.

A synchronous modulation method based on an embedded player. The method comprises the steps of: Step S1, acquiring a current timestamp adopted by a current synchronous audio signal and a current synchronous video signal; Step S2, acquiring a jump difference value of the current timestamp; Step S3, determining whether the jump difference value is less than a first preset time, if yes, synchronously playing, by the player, the audio signal and the video signal through a first timestamp, and exiting; and Step S4, determining whether the jump difference value is greater than a second preset time, if yes, synchronously playing, by the player, the audio signal and the video signal through a second timestamp, and exiting.

An electronic device is provided. The electronic device includes a first image sensor, a second image sensor electrically connected to the first image sensor, and a processor operatively connected to the first image sensor and the second image sensor. The processor may be configured to generate first image data using the first image sensor and generate second image data using the second image sensor based on a synchronizing signal, transmit the second image data generated by the second image sensor to the first image sensor, and control the first image sensor to generate and output image data by processing the first image data and the second image data based on the synchronizing signal.

An electronic device is provided. The electronic device includes a first image sensor, a second image sensor electrically connected to the first image sensor, and a processor operatively connected to the first image sensor and the second image sensor. The processor may be configured to generate first image data using the first image sensor and generate second image data using the second image sensor based on a synchronizing signal, transmit the second image data generated by the second image sensor to the first image sensor, and control the first image sensor to generate and output image data by processing the first image data and the second image data based on the synchronizing signal.

The present disclosure relates to a system and method. The system includes: a storage device storing a set of instructions; and one or more processors in communication with the storage device. When executing the set of instructions, the one or more video processors: synchronize a signal with a first PN sequence, wherein the signal includes a plurality of second PN sequences, marked as 0 PN sequence, 1 PN sequence, . . . , (k−1) PN sequence, k sequence, wherein k is a positive integer number; determine that the signal is synchronized with the first PN sequence; determine a first target distance between the (k−1) PN sequence and the k sequence; and determine a formality standard of the signal based on the first target distance.

The present disclosure relates to a system and method. The system includes: a storage device storing a set of instructions; and one or more processors in communication with the storage device. When executing the set of instructions, the one or more video processors: synchronize a signal with a first PN sequence, wherein the signal includes a plurality of second PN sequences, marked as 0 PN sequence, 1 PN sequence, . . . , (k−1) PN sequence, k sequence, wherein k is a positive integer number; determine that the signal is synchronized with the first PN sequence; determine a first target distance between the (k−1) PN sequence and the k sequence; and determine a formality standard of the signal based on the first target distance.

An imaging system may include two or more pipeline processing circuits that receive image data streams from two or more corresponding image sensors and process the received image data in parallel in an image signal processing mode of operation. The imaging system may include fault detection circuitry coupled to the two or more pipeline processing circuits. The fault detection circuitry may configure the two or more pipeline processing circuits with fault detection configuration states and generate injection data for processing by the two or more pipeline processing circuits in a fault detection mode of operation. Fault detection may be enabled dynamically based on a horizontal and vertical sync circuit and during an image processing pause period between image frames. The imaging system having the fault detection circuitry may be configured to efficiently perform fault detection without interrupting image signal processing.

An imaging system may include two or more pipeline processing circuits that receive image data streams from two or more corresponding image sensors and process the received image data in parallel in an image signal processing mode of operation. The imaging system may include fault detection circuitry coupled to the two or more pipeline processing circuits. The fault detection circuitry may configure the two or more pipeline processing circuits with fault detection configuration states and generate injection data for processing by the two or more pipeline processing circuits in a fault detection mode of operation. Fault detection may be enabled dynamically based on a horizontal and vertical sync circuit and during an image processing pause period between image frames. The imaging system having the fault detection circuitry may be configured to efficiently perform fault detection without interrupting image signal processing.

Introduced here are synchronization modules designed to integrate streams of data acquired from multiple sources in a precise, repeatable manner. To improve the usability of data acquired from multiple sources, a synchronization module can tightly couple streams of data received from these sources so that the data is temporally aligned. For example, a synchronization module may tightly couple motion data generated by a motion sensor with location data generated by a location sensor and image data generated by an image sensor in a manner that lessens the incurrence of software overhead.

Introduced here are synchronization modules designed to integrate streams of data acquired from multiple sources in a precise, repeatable manner. To improve the usability of data acquired from multiple sources, a synchronization module can tightly couple streams of data received from these sources so that the data is temporally aligned. For example, a synchronization module may tightly couple motion data generated by a motion sensor with location data generated by a location sensor and image data generated by an image sensor in a manner that lessens the incurrence of software overhead.