The present invention provides an apparatus and a method for switching and converting video signals, wherein the method majorly includes the steps of: receiving N number of DisplayPort video signals and N number of USB video signals by N number of USB Type-C connection interfaces which are in compliance with a DisplayPort Alternate Mode specification, and N is a natural number greater than or equal to 2; and selecting one out of the DisplayPort video signals and one out of the USB video signals; converting the selected DisplayPort video signal and the selected USB video signal into a DisplayPort video signal or a HDMI video signal; transmitting the converted DisplayPort video signal or HDMI video signal to Q number of display devices, and Q is a natural number greater than or equal to 2.

The disclosure is related to a method and a system for detecting a video scan type. In the method, a first frame and a second frame are firstly extracted from a video. The scan lines of each frame can be divided into a top field and a bottom field. A first zipper index of the combination of the top field of the first frame and the bottom field of the second frame is obtained. Further, a second zipper index of the combination of the bottom field of the first frame and the top field of the second frame is also obtained. A zipper index difference between the first zipper index and the second zipper index is calculated and is provided to determine the video scan type as an interlaced-scan video or a progressive-scan video.

A data processing system includes a scaler 18 operable to scale a received input data array to provide a scaled output version of the input data array. When it is desired to produce a de-interlaced and scaled output version of an input data array 21, 22, the input data array 21, 22 is provided to the scaler 18, and the scaler 18 scales the input data array 21, 22 so as to simultaneously de-interlace and scale the input data array and to produce a de-interlaced and scaled output version of the input data array.

The image processing system receives first field information, second field information, and third field information. The first and the third field information correspond to first pixels, and the second field information corresponds to second pixels. The first pixels and the second pixels are disposed in interlaced rows. Generate the motion adaptive deinterlacing parameter of a first pixel by performing the motion detection and interpolation according to the first and the third field information. Calculate the horizontal and the vertical compensating display parameters of the first pixel according to the horizontal and vertical motion estimation values and the first and the third field information. Generate the mixed display parameter of the first pixel by using a weighted average of the horizontal or the vertical compensating display parameter of the first pixel and the motion adaptive deinterlacing parameters of the first pixel.

Efficient editing is enabled when a video material encoded as an interlaced signal is mixed during editing. A first video signal in a progressive mode is obtained. This first video signal is encoded. The first video signal or a second video signal obtained by reducing resolution and/or a frame rate of the first video signal is converted to an interlaced signal from a progressive signal such that a third video signal is obtained. The third video signal is encoded. Encoded data of the first video signal and encoded data of the third video signal are recorded to a recording medium.

The present invention provides an apparatus and a method for switching and converting video signals, wherein the method majorly includes the steps of: receiving N number of DisplayPort video signals and N number of USB video signals by N number of USB Type-C connection interfaces which are in compliance with a DisplayPort Alternate Mode specification, and N is a natural number greater than or equal to 2; and selecting one out of the DisplayPort video signals and one out of the USB video signals; converting the selected DisplayPort video signal and the selected USB video signal into a DisplayPort video signal or a HDMI video signal; transmitting the converted DisplayPort video signal or HDMI video signal to Q number of display devices, and Q is a natural number greater than or equal to 2.

A system and method are provided for capturing a high resolution, high frame rate video using a Universal Serial Bus (USB) port. Generally, the method involves transmitting a High-Definition Multimedia Interface (HDMI) video including a number of video frames from a HDMI-source. Receiving the HDMI video and buffering and splitting each one of the video frames into a plurality of split video frames. Each of the split video frames is converted into a number of USB data packets. USB data packets from each of the split video frames are then interleaved to form a stream of USB data packets. The stream of USB data packets is coupled to a host system, which executes a program to stitch the USB data packets back together to reassemble each of the video frames, and order the video frames to restore or recreate the HDMI video.

Provided is a video processing device that generates a display video signal to be supplied to a liquid crystal display having a liquid crystal that is driven by a frame inversion scheme and includes a control microcomputer and a video signal processor. The control microcomputer controls a data enable signal such that a display invalid section having a predetermined number of fields is set for an interlace video signal at a predetermined period based on a vertical synchronization signal included in the interlace video signal input from outside. The video signal processor generates the display video signal by setting the display invalid section for the interlace video signal based on the data enable signal and outputs the display video signal to the liquid crystal display.

A system including a motion adaptive de-interlacer, a film mode detector, and a combiner. The motion adaptive de-interlacer is configured to determine a first output by de-interlacing a plurality of interlaced frames based on at least a first motion indicator indicating motion between fields of the plurality of interlaced frames. The film mode detector is configured to determine a second output based on a film mode detected based on at least a second motion indicator indicating motion between fields of the plurality of interlaced frames. The film mode detector is further configured to output a control signal based on the second motion indicator and the film mode. The combiner is configured to combine the first output and the second output based on the control signal.

A video processing device generates a display video signal to be supplied to a liquid crystal display unit that is driven by a frame inversion scheme. The video processing device includes a controller and a video signal processor. The controller controls a vertical synchronizing signal included in an interlace video signal input from outside the video processing device so that a display invalid section having a predetermined number of fields is set for the interlace video signal at a predetermined period. The video signal processor i) generates the display video signal based on the interlace video signal in which the display invalid section has been set by control of the vertical synchronizing signal and ii) outputs the display video signal to the liquid crystal display unit.