A method may include receiving, via a processor, a frame of image data, such that the frame of image data may include an active portion and an idle portion. The active portion may include data for presenting one or more images via a first display of a first electronic device. The method may also include receiving a signal from a second electronic device during the idle portion of the frame of image data, such that the second electronic device is separate from the first display. The method may then involve initiating processing of the frame of image data in response to the signal being received from the second electronic device.

An inspection system for automotive components includes one or more cameras, a controller, a conveyor structure, and a row of platforms. The cameras are configured to collect images corresponding to a selected automotive component. The controller is communicably coupled to the cameras. The conveyor structure is operable to transport the selected automotive component. The cameras are synchronized and triggered to capture images of the selected automotive component with the controller. The controller is configured to generate a composite image based on the data set and generate, at a production speed, an output indicative of the selected automotive component with or without anomaly.

A control system includes a mirror controller generating horizontal and vertical mirror synchronization signals for a mirror based upon a mirror clock signal. Laser modulation circuitry generates horizontal and vertical laser synchronization signals as a function of first and second laser clock signals and generates control signals for a laser that emits a laser beam that impinges on the mirror. First synchronization circuitry receives the horizontal mirror synchronization signal and the horizontal laser synchronization signal, and modifies generation of the first laser clock signal to achieve alignment between the horizontal mirror synchronization signal and horizontal laser synchronization signal. Second synchronization circuitry receives the vertical mirror synchronization signal and the vertical laser synchronization signal, and modifies generation of the second laser clock signal to achieve alignment between the vertical mirror synchronization signal and vertical laser synchronization signal.

A control system includes a mirror controller generating horizontal and vertical mirror synchronization signals for a mirror based upon a mirror clock signal. Laser modulation circuitry generates horizontal and vertical laser synchronization signals as a function of first and second laser clock signals and generates control signals for a laser that emits a laser beam that impinges on the mirror. First synchronization circuitry receives the horizontal mirror synchronization signal and the horizontal laser synchronization signal, and modifies generation of the first laser clock signal to achieve alignment between the horizontal mirror synchronization signal and horizontal laser synchronization signal. Second synchronization circuitry receives the vertical mirror synchronization signal and the vertical laser synchronization signal, and modifies generation of the second laser clock signal to achieve alignment between the vertical mirror synchronization signal and vertical laser synchronization signal.

A system for generating real-time panoramic video is disclosed. The system comprises a plurality of micro panoramic cameras which are enabled on a processing unit and which are configured to simultaneously capture video frames from each of the plurality of micro panoramic cameras, wherein the video frames captured by two consecutive camera sensors from the plurality of camera sensors include an overlapping field of view, synchronize and feed the captured images to the processing unit with equal predefined delay, stitch the video frames captured by each of the plurality of micro panoramic cameras and output a real-time panoramic video on a display.

A system for generating real-time panoramic video is disclosed. The system comprises a plurality of micro panoramic cameras which are enabled on a processing unit and which are configured to simultaneously capture video frames from each of the plurality of micro panoramic cameras, wherein the video frames captured by two consecutive camera sensors from the plurality of camera sensors include an overlapping field of view, synchronize and feed the captured images to the processing unit with equal predefined delay, stitch the video frames captured by each of the plurality of micro panoramic cameras and output a real-time panoramic video on a display.

In some embodiments, an apparatus comprises a media module and a modification module included in an embedded appliance. The media module is configured to receive a first media signal associated with a first input port of the embedded appliance and a second media signal associated with a second input port of the embedded appliance. The media module is configured to identify a first set of media signal parameters based on the first media signal. The modification module is configured to receive a modification instruction associated with a session format having a second set of media signal parameters different from the first set of media signal parameters. The modification module is configured to modify the first media signal based on the first set of media signal parameters and the modification instruction to produce a first modified media signal in the session format and having the second set of media signal parameters.

The present invention provides a monitor system and a display control method thereof. The monitor system comprises: a control module, used for sending human-computer interaction interface information and background picture information to a processing module by means of a same channel; the processing module, used for receiving video image information, processing the video image information, the human-computer interaction interface information and the background picture information, and outputting target image information to a display; and the display, used for displaying the target image information. According to the system, background picture information is stored in the control module, and by means of information transmission and processing between the control module and the processing module, target image information can be displayed on the display, thus achieving display control over the monitor system, without the need to additionally arrange an external device to store background picture information. The problems in the prior art that costs are high, structural design is difficult, and control accuracy is low are solved.

The present invention provides a monitor system and a display control method thereof. The monitor system comprises: a control module, used for sending human-computer interaction interface information and background picture information to a processing module by means of a same channel; the processing module, used for receiving video image information, processing the video image information, the human-computer interaction interface information and the background picture information, and outputting target image information to a display; and the display, used for displaying the target image information. According to the system, background picture information is stored in the control module, and by means of information transmission and processing between the control module and the processing module, target image information can be displayed on the display, thus achieving display control over the monitor system, without the need to additionally arrange an external device to store background picture information. The problems in the prior art that costs are high, structural design is difficult, and control accuracy is low are solved.

An analog-to-digital conversion circuit includes a convertor configured to perform a first comparison operation for sensing a noise based on a reset signal and to perform a second comparison operation for sensing raw data to output data which is obtained by removing the noise from the raw data, and a ramp voltage generator configured to generate a ramp voltage used for the first comparison operation and the second comparison operation and to output the ramp voltage to the convertor. The ramp voltage generator includes a first current source for supplying a bias current for generating the ramp voltage in response to a first control signal, a second current source for supplying a boost current for generating the ramp voltage in response to a second control signal, and a generation circuit for generating the ramp voltage based on the bias current and the boost current.