A measurement recording system is configured to measure timing information for correcting out-of-synchronization of a time axis between a first captured video and a second captured video and correct the out-of-synchronization to align the start timing between the first captured video and the second captured video based on the measured timing information.

A measurement recording system is configured to measure timing information for correcting out-of-synchronization of a time axis between a first captured video and a second captured video and correct the out-of-synchronization to align the start timing between the first captured video and the second captured video based on the measured timing information.

Disclosed is a system (100) comprising server(s) (102) communicably coupled to devices (104a, 104b, 202a-202c). Server(s) is/are configured to: receive depth information generated by said device using active illuminator and active sensor; detect when at least two devices are in same surroundings, based on at least partial matching of depth information received from at least two devices; and send instructions to at least two devices to generate new depth information by: controlling active illuminator (106a) of one of at least two devices (104a, 202a) to project sequence of light patterns on same surroundings, whilst switching off active illuminator (106b) of another of at least two devices (104b, 202b), and controlling first active sensor (108a) of one of at least two devices and second active sensor (108b) of another of at least two devices to sense simultaneously reflections of sequence of light patterns.

Disclosed is a system (100) comprising server(s) (102) communicably coupled to devices (104a, 104b, 202a-202c). Server(s) is/are configured to: receive depth information generated by said device using active illuminator and active sensor; detect when at least two devices are in same surroundings, based on at least partial matching of depth information received from at least two devices; and send instructions to at least two devices to generate new depth information by: controlling active illuminator (106a) of one of at least two devices (104a, 202a) to project sequence of light patterns on same surroundings, whilst switching off active illuminator (106b) of another of at least two devices (104b, 202b), and controlling first active sensor (108a) of one of at least two devices and second active sensor (108b) of another of at least two devices to sense simultaneously reflections of sequence of light patterns.

A control device includes: generation circuitry configured to output a field signal to a medical imaging device; first detection circuitry configured to detect a horizontal synchronization signal from video data output from the medical imaging device, the video data including at least the horizontal synchronization signal; and a monitoring circuitry configured to monitor whether or not an abnormality occurs in one frame period of the video data based on a period of the horizontal synchronization signal detected by the first detection circuitry for a predetermined n-th time after polarity of the field signal is switched.

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.

A receiving device for reducing video latency includes a display render unit, a communication interface, a memory, and a processor. The display render unit performs a video transmission to output a video to a display apparatus. The video generated by a video capture unit of the sending device is transmitted through the communication interface to the receiving device. The memory stores at least one computer readable instruction. The processor accesses and executes the at least one computer readable instruction to: determine whether a video latency is necessary to be reduced; determine a target reduced latency based on a target line count and a current line count; and determine a first period based on the target reduced latency and an accelerating scheme at the display render unit. The display render unit performs the video transmission to the display apparatus based on the accelerating scheme for the first period.

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.