Abstract:
Disclosed is a video processing method. The method comprises: splicing, according to pre-determined video sorting information, two or more original video images, to obtain a composite video image; encoding the composite video image; and sending out the encoded composite video image. Correspondingly, also disclosed are a video processing apparatus and system, which can ensure strict synchronization between multiple channels of videos in a telepresence meeting; moreover, the problem of how to determine a video image output position is solved, so that the telepresence meeting renders a vivid communication effect.

Description:
TECHNICAL FIELD 
       [0001]    An embodiment of the disclosure relates to video conference technology, and particularly to a video processing method, apparatus, and system. 
       BACKGROUND 
       [0002]    Telepresence enjoys great popularity among high-end users due to a true sense of on-scene presence thereof. Auditory positioning and life size imaging are key technical indicators in evaluating a telepresence system. 
         [0003]    To achieve life size imaging and auditory positioning in a telepresence conference system, each display of a terminal meeting room having multiple displays may display an image of conferees in a remote spatial area according to a direction in which an audio is output. Namely, in the meeting room, a display displaying the image of a speaker corresponds to the direction in which the audio of the speaker is output. For example, in a three-display meeting room, if a speaker seated on the left speaks, then sound should be heard from the left. Therefore, A position where a remote image is output has to be determined according to a negotiated strategy, and strict synchronization among multiple displays is required to achieve realistic communication effect. 
         [0004]    The inventors find that in a telepresence conference system, due to difficulty in strict synchronization among multiple video streams encoded and transmitted separately, it is hard to meet a strict real-time requirement of a video conference. In addition, there is no solution for determining a position where a video image is output. 
       SUMMARY 
       [0005]    In view of this, it is desired that embodiments of the disclosure provide a video processing method, apparatus, and system, capable of ensuring strict synchronization among multiple video streams in a telepresence conference. 
         [0006]    To this end, a technical solution according to an embodiment of the disclosure is implemented as follows. 
         [0007]    An embodiment of the disclosure provides a video processing method, including: 
         [0008]    obtaining a composite video image by stitching two or more original video images according to pre-determined video arranging information; 
         [0009]    encoding the composite video image; and 
         [0010]    sending the encoded composite video image. 
         [0011]    The video processing method may further include: before the stitching two or more original video images, collecting the two or more original video images respectively by two or more video collecting devices. 
         [0012]    The video arranging information may include a correspondence among an identity of a video collecting device collecting each of the two or more original video images, a position of each of the two or more original video images in the composite video image, and an identity of a video displaying device for displaying each of the two or more original video images. 
         [0013]    The video processing method may further include: before the stitching two or more original video images, determining the video arranging information by performing media capability negotiation with an endpoint configured for receiving the composite video image. 
         [0014]    According to an embodiment herein, a video processing apparatus may include a stitching module, an encoding module, and a sending module. 
         [0015]    The stitching module may be configured for obtaining a composite video image by stitching two or more original video images according to pre-determined video arranging information. 
         [0016]    The encoding module may be configured for encoding the composite video image obtained by the stitching module. 
         [0017]    The sending module may be configured for sending the composite video image encoded by the encoding module. 
         [0018]    The apparatus may be further connected to two or more video collecting devices respectively for collecting the two or more original video images. 
         [0019]    The video arranging information may include a correspondence among an identity of a video collecting device collecting each of the two or more original video images, a position of each of the two or more original video images in the composite video image, and an identity of a video displaying device for displaying each of the two or more original video images. 
         [0020]    The video processing apparatus may further include a first determining module configured for determining the video arranging information by performing media capability negotiation with an endpoint configured for receiving the composite video image. 
         [0021]    The stitching module may be configured for obtaining the composite video image by stitching the two or more original video images according to the video arranging information determined by the first determining module. 
         [0022]    According to an embodiment herein, a video processing method may include: 
         [0023]    receiving a composite video image, wherein the composite video image is obtained by stitching two or more original video images and is then encoded; 
         [0024]    decoding the composite video image; and 
         [0025]    dividing the decoded composite video image into the two or more original video images and respectively sending each of the two or more original video images to a video displaying device for displaying each of the two or more original video images according to pre-determined video arranging information. 
         [0026]    The video arranging information may include a correspondence among an identity of a video collecting device collecting each of the two or more original video images, a position of each of the two or more original video images in the composite video image, and an identity of the video displaying device for displaying each of the two or more original video images. 
         [0027]    The video processing method may further include: before the dividing the decoded composite video image, determining the video arranging information by performing media capability negotiation with an endpoint configured for sending the composite video image. 
         [0028]    According to an embodiment herein, a video processing apparatus may include a receiving module, a decoding module, and a dividing module. 
         [0029]    The receiving module may be configured for receiving a composite video image, the composite video image being obtained by stitching two or more original video images and then encoded. 
         [0030]    The decoding module may be configured for decoding the composite video image received by the receiving module. 
         [0031]    The dividing module may be configured for dividing the decoded composite video image into the two or more original video images and respectively sending each of the two or more original video images to a video displaying device for displaying each of the two or more original video images according to pre-determined video arranging information. 
         [0032]    The video arranging information may include a correspondence among an identity of a video collecting device collecting each of the two or more original video images, a position of each of the two or more original video images in the composite video image, and an identity of the video displaying device for displaying each of the two or more original video images. 
         [0033]    The video processing apparatus may further include a second determining module configured for determining the video arranging information by performing media capability negotiation with an endpoint configured for sending the composite video image. 
         [0034]    The dividing module may be configured for dividing the decoded composite video image into the two or more original video images according to the video arranging information determined by the second determining module. 
         [0035]    According to an embodiment herein, a video processing method may include: 
         [0036]    obtaining a composite video image by stitching two or more original video images according to pre-determined video arranging information; encoding the composite video image; and sending the encoded composite video image; 
         [0037]    receiving the composite video image; decoding the composite video image; and dividing the decoded composite video image into the two or more original video images and respectively sending each of the two or more original video images to a video displaying device for displaying each of the two or more original video images according to the pre-determined video arranging information. 
         [0038]    The video processing method may further include: before the stitching two or more original video images, collecting the two or more original video images respectively by two or more video collecting devices. 
         [0039]    The video arranging information may include a correspondence among an identity of a video collecting device collecting each of the two or more original video images, a position of each of the two or more original video images, and an identity of the video displaying device for displaying each of the two or more original video images. 
         [0040]    The video processing method may further include: determining the video arranging information by performing media capability negotiation. 
         [0041]    According to an embodiment herein, a video processing system may include a stitching module, a encoding module, a sending module, a receiving module, a decoding module, and a dividing module. 
         [0042]    The stitching module may be configured for obtaining a composite video image by stitching two or more original video images according to pre-determined video arranging information. 
         [0043]    The encoding module may be configured for encoding the composite video image obtained by the stitching module. 
         [0044]    The sending module may be configured for sending the composite video image encoded by the encoding module. 
         [0045]    The receiving module may be configured for receiving the composite video image sent by the sending module. 
         [0046]    The decoding module may be configured for decoding the composite video image received by the receiving module. 
         [0047]    The dividing module may be configured for dividing the decoded composite video image into the two or more original video images and respectively sending each of the two or more original video images to an external video displaying device for displaying each of the two or more original video images according to the pre-determined video arranging information. 
         [0048]    The stitching module may be further connected to two or more video collecting devices respectively for collecting the two or more original video images. 
         [0049]    The video processing system may further include a first determining module and a second determining module configured for determining the video arranging information by performing media capability negotiation. 
         [0050]    The stitching module may be configured for obtaining the composite video image by stitching the two or more original video images according to the video arranging information determined by the first determining module. 
         [0051]    The dividing module may be configured for dividing the decoded composite video image into the two or more original video images according to the video arranging information determined by the second determining module. 
         [0052]    The stitching module, the encoding module, the sending module and the first determining module may be provided in a local terminal. The local terminal may be externally connected to a video collecting device. The receiving module, the decoding module, the dividing module, and the second determining module may be provided in a remote terminal. The remote terminal may be externally connected to a video displaying device. 
         [0053]    The video processing system may further include a Multipoint Control Unit (MCU) configured for implementing interaction between a local terminal and one or more remote terminals. 
         [0054]    The video processing system may include a Multipoint Control Unit (MCU) and multiple terminals including a local terminal and a remote terminal interacting through the MCU. 
         [0055]    Each of the multiple terminals may be externally connected to a video collecting device and a video displaying device. Each of the multiple terminals may include the stitching module, the encoding module, the sending module, the receiving module, the decoding module, the dividing module, a first determining module, and a second determining module. 
         [0056]    The MCU may include the stitching module, the encoding module, the sending module, the receiving module, the decoding module, the dividing module, the first determining module, and the second determining module. 
         [0057]    With a video processing method, apparatus, and system according to an embodiment of the disclosure, multiple original video image streams may be stitched into a composite video image, which is then encoded and sent, thus ensuring strict synchronization among multiple video streams in a telepresence conference. Moreover, a received composite video image may first be divided into the multiple original video images, each of which then may be displayed by a proper video displaying device, providing a solution for determining a position where a video image is output, guaranteeing strict synchronization among multiple displays in a telepresence conference. A video image is output according to a pre-set position, thus achieving realistic communication effect. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0058]    Drawings herein are introduced briefly for clearer illustration of a technical solution. Note that drawings below refer merely to some embodiments of the disclosure. For those skilled in the art, other drawings may be obtained without creative work according to drawings herein. 
           [0059]      FIG. 1  is a schematic diagram of a structure of a video processing system according to Embodiment 1 of the disclosure; 
           [0060]      FIG. 2  is a specific flowchart of video processing according to Embodiment 1 of the disclosure; 
           [0061]      FIG. 3  is a schematic diagram of a structure of a video processing system according to Embodiment 2 of the disclosure; 
           [0062]      FIG. 4  is a specific flowchart of video processing according to Embodiment 2 of the disclosure; and 
           [0063]      FIG. 5  is a schematic diagram of a structure of a video processing system according to Embodiment 3 of the disclosure. 
       
    
    
     DETAILED DESCRIPTION 
       [0064]    In embodiments of the disclosure, a sending end obtains a composite image by stitching, according to video arranging information negotiated beforehand, multiple video images collected, encodes the composite image, and sends the encoded composite image. After receiving and decoding the composite image, a receiving end divides the decoded composite image into the multiple video images according to the video arranging information, and then sends the multiple video images respectively to display devices each for displaying one of the multiple video images. 
       Embodiment 1 
       [0065]    The embodiment provides a video processing system configured for telepresence. The system includes multiple video collecting devices (VC 1 , VC 2 , and VC 3 ), multiple video displaying devices (VD 1 , VD 2 , and VD 3 ), a local terminal, and a remote terminal. The multiple video collecting devices are connected to the local terminal. The multiple video displaying devices are connected to the remote terminal. A video collecting device is configured for collecting an original video image, and sends the collected original video image to the local terminal. The local terminal, as a video image sending end, obtains a composite video image by stitching original video images sent by the video collecting devices, and encodes and then sends the composite video image. The remote terminal, as a video image receiving end, receives the composite video image sent by the local terminal, divides the composite video image into the multiple original video images, and then sends the multiple original video images respectively to video displaying devices for displaying the multiple original video images respectively. 
         [0066]    As shown in  FIG. 1 , the local terminal and the remote terminal may be connected to each other via peer-to-peer networking. Three video collecting devices (VC 1 , VC 2 , and VC 3 ) connected to the local terminal respectively collect three original video image streams. Three video displaying devices (VD 1 , VD 2 , and VD 3 ) connected to the remote terminal respectively display the three original video image streams. 
         [0067]    As shown in  FIG. 2 , a flow of video processing based on the video processing system may specifically include steps as follows. 
         [0068]    In Step  201 , a local terminal determines, via beforehand media capability negotiation with a remote terminal, video arranging information configured for indicating to stitch original video images of VC 1 , VC 2 , and VC 3  from left to right. 
         [0069]    In this way, a left original video image stream (VC 1 ), a middle original video image stream (VC 2 ), and a right original video image stream (VC 3 ) respectively collected by three video collecting devices VC 1 , VC 2 , and VC 3  may be displayed respectively in video displaying devices located respectively on the left (VD 1 ), in the middle (VD 2 ), and on the right (VD 3 ). 
         [0070]    A position of a video image collected by a video collecting device may be provided in the video arranging information beforehand. Information such as sizes of video images collected by video collecting devices VC 1 , VC 2 , and VC 3  and coordinates of the video images in the composite video image may be provided in the video arranging information. For example, a width, a height, and coordinates of a starting point of a video image of the VC 1 ; a width, a height, and coordinates of a starting point of a video image of the VC 2 ; and a width, a height, and coordinates of a starting point of a video image of the VC 3  may be provided in the video arranging information. When video images of the VC 1 , the VC 2 , and the VC 3  are to be stitched together respectively as a left part, a middle part, and a right part of the composite image, it may be provided in the video arranging information an abscissa of the starting point of the video image of the VC 1  in the composite video image equal to zero, an abscissa of the starting point of the video image of the VC 2  in the composite video image equal to the width of the video image of the VC 1 , and an abscissa of the starting point of the video image of the VC 3  in the composite video image equal to a sum of the widths of the video images of the VC 1  and the VC 2 . Alternatively, information such as sizes of video image collected respectively by the video collecting devices (VC 1 , VC 2 , and VC 3 ) and relative positions of the video images in the composite video image may be provided in the video arranging information, such that the local terminal may obtain the composite video image by stitching the video images according to the sizes and the relative positions of the video images in the video arranging information. 
         [0071]    A video displaying device for displaying an original video image may also be provided in the video arranging information. With an application in the embodiment, it may be provided in the video arranging information that the VC 1  corresponds to the VD 1 , the VC 2  corresponds to the VD 2 , and the VC 3  corresponds to the VD 3 . The video displaying device VD 1  is located on the left. The video displaying device VD 2  is located in the middle. The video displaying device VD 3  is located on the right. 
         [0072]    In Step  202 , three video collecting devices (VC 1 , VC 2 , and VC 3 ) collect three original video image streams respectively. 
         [0073]    In Step  203 , the local terminal obtains a composite video image by stitching, according to the video arranging information, three original video image streams collected by the three video collecting devices (VC 1 , VC 2 , and VC 3 ), encodes the composite video image, and sends the encoded composite video image to the remote terminal through a media channel between the local terminal and the remote terminal. 
         [0074]    In Step  204 , the remote terminal receives and then decodes the composite video image, and divides the decoded composite video image into the three original video image streams according to the video arranging information. 
         [0075]    In Step  205 , the remote terminal sends the three original video image streams respectively to a video displaying device on the left, a video displaying device in the middle, and a video displaying device on the right for displaying the three original video image streams respectively. 
         [0076]    After receiving and then decoding the composite video image stream sent by the local terminal, the remote terminal divides the decoded composite video image into the three images VD 1 , VD 2 , and VD 3  according to the video arranging information as negotiated, and sends the three images respectively to the three video displaying devices for displaying the three images respectively. In this way, the remote terminal first divides the composite video image into multiple video images according to positions of video images collected respectively by the video collecting devices as provided in the video arranging information, and then displays the video images respectively on the video displaying devices accordingly. 
         [0077]    The local terminal may include a stitching module, an encoding module, and a sending module. The stitching module may be configured for obtaining a composite video image by stitching original video images sent respectively by video collecting devices according to pre-determined video arranging information. The encoding module may be configured for encoding the composite video image obtained by the stitching module. The sending module may be configured for sending the composite video image encoded by the encoding module to the remote terminal. 
         [0078]    The remote terminal may include a receiving module, a decoding module, and a dividing module. The receiving module may be configured for receiving a composite video image sent by the local terminal. The decoding module may be configured for decoding the composite video image received by the receiving module. The dividing module may be configured for dividing the composite video image decoded by the decoding module into original video images and sending the original video images respectively to video displaying devices for displaying the original video images respectively according to pre-determined video arranging information. 
         [0079]    The local terminal may further include a first determining module configured for determining the video arranging information by performing media capability negotiation with the remote terminal. The stitching module may be configured for obtaining the composite video image by stitching two or more original video images according to the video arranging information determined by the first determining module. 
         [0080]    The remote terminal may further include a second determining module configured for determining the video arranging information by performing media capability negotiation with a terminal configured for sending the composite video image. The dividing module may be configured for dividing the decoded composite video image into the two or more original video images according to the video arranging information determined by the second determining module. 
         [0081]    To sum up, in the embodiment, the video arranging information determined through negotiation between the local terminal and the remote terminal may include an identity of a video collecting device, a position of an original video image collected by a video collecting device, an identity of a video displaying device, and a correspondence among the three. The position of an original video image may further contain information such as the side of the original video image collected by a video collecting device. 
       Embodiment 2 
       [0082]    A structure of a telepresence video processing system according to the embodiment is as shown in  FIG. 3 , the structure being almost the same as that of the video processing system according to Embodiment 1, except that the video processing system according to Embodiment 2 may further include a Multipoint Control Unit MCU. The local terminal may be networked with the remote terminal through the MCU, that is, data exchange between the local terminal and the remote terminal is performed through the MCU. 
         [0083]    A video processing flow in the embodiment, as shown in  FIG. 4 , may include steps as follows. 
         [0084]    Step  401  is almost the same as Step  201 , except that the media capability negotiation between the local terminal and the remote terminal is performed in directly through the MCU. 
         [0085]    That is, in media capability negotiation, the local terminal may determine the video arranging information by performing media capability negotiation with an endpoint configured for receiving the composite video image. The endpoint may be the remote terminal or the MCU. 
         [0086]    Step  402  is identical with Step  202 . 
         [0087]    Step  403  is almost the same as Step  203 , except that after encoding the composite video image, the local terminal sends the encoded composite video image to the MCU through a media channel between the local terminal and the MCU. 
         [0088]    In Step  404 , the MCU sends the encoded composite video image to the remote terminal through a media channel between the MCU and the remote terminal. 
         [0089]    Step  405  is almost the same as Step  204 , except that the remote terminal receives the composite video image forwarded by the MCU. 
         [0090]    Step  406  is identical with Step  205 . 
         [0091]    The structure of the local terminal in Embodiment 2 is identical with that of the local terminal in Embodiment 1. The structure of the remote terminal in Embodiment 2 is identical with that of the remote terminal in Embodiment 1. The only difference is that in Embodiment 2, the sending module of the local terminal sends the composite video image to the MCU, and the receiving module of the remote terminal receives the composite video image forwarded by the MCU. 
       Embodiment 3 
       [0092]    Embodiment 3 provides a telepresence video processing system. As shown in  FIG. 5 , the system includes multiple video collecting devices, multiple video displaying devices, an MCU, a first terminal, a second terminal, and a third terminal. The first terminal is connected to three video collecting devices (VC 1 , VC 2 , and VC 3 ) and three video displaying devices (VD 4 , VD, and VD 6 ). The second terminal is connected to two video collecting devices (VC 4  and VC 5 ) and two video displaying devices (VD 1  and VD 2 ). The third terminal is connected to one video collecting device (VC 6 ) and one video displaying device (VD 3 ). Each of the first terminal, the second terminal and the third terminal may serve as a video image sending end and a video image receiving end at the same time. The first terminal, the second terminal, and the third terminal are networked through the MCU. When the first terminal serves as the local endpoint, both the second terminal and the third terminal serve as the opposite remote endpoints. When both the second terminal and the third terminal serve as the local endpoints, the first terminal serves as the opposite remote endpoint. 
         [0093]    In the embodiment, a video processing flow may include steps as follows. 
         [0094]    In Step  1 , video arranging information may be determined by beforehand media capability negotiation between an MCU and each of a first terminal, a second terminal, and a third terminal, and may be configured to the first terminal, the second terminal, the third terminal, and the MCU. 
         [0095]    Video arranging information negotiated by the first terminal and the MCU may include correspondence between VC 1  and VD 1 , correspondence between VC 2  and VD 2 , correspondence between VC 3  and VD 3 , and stitching original video images of VC 1 , VC 2 , and VC 3  from left to right to form a composite video image; and include correspondence between VC 4  and VD 4 , correspondence between VC 5  and VD 5 , correspondence between VC 6  and VD 6 , and stitching original video images of VC 4 , VC 5 , and VC 6  from left to right to form a composite video image. 
         [0096]    Video arranging information negotiated by the second terminal and the MCU may include correspondence between VC 1  and VD 1 , correspondence between VC 2  and VD 2 , and stitching original video images of VC 1  and VC 2  from left to right to form a composite video image; and include correspondence between VC 4  and VD 4 , correspondence between VC 5  and VD 5 , and stitching original video images of VC 4  and VC 5  from left to right to form a composite video image. 
         [0097]    In Step  2 , three video collecting devices (VC 1 , VC 2 , and VC 3 ) respectively collect original video images. 
         [0098]    In Step  3 , the first terminal obtains a first composite video image by stitching the original video images collected by the three video collecting devices (VC 1 , VC 2 , and VC 3 ) according to video arranging information negotiated by the first terminal and the MCU, encodes the first composite video image, and then sends the encoded first composite video image to the MCU through the media channel between the first terminal and the MCU. 
         [0099]    In Step  4 , the MCU receives and then decodes the first composite video image stream sent by the first terminal, divides the decoded first composite video image into the three original video images according to the video arranging information negotiated by the MCU and the first terminal, obtains a second composite video image by stitching the original video images of VC 1  and VC 2  according to video arranging information negotiated by the MCU and the second terminal, encodes the second composite video image, sends the encoded second composite video image to the second terminal connected to VD 1  and VD 2  through a channel between the MCU and the second termina, encodes the original video image of VC 3 , and sends the encoded original video image of VC 3  to the third terminal connected to VD 3 . 
         [0100]    In Step  5 , the second terminal receives and decodes the second composite video image sent by the MCU, divides the decoded second composite video image into the two original images of VC 1  and VC 2  according to the video arranging information negotiated by the MCU and the second terminal, and sends the two original images respectively to VD 1  and VD 2  which play the two original images respectively. The third terminal receives and decodes the video image of VC 3  sent by the MCU, and sends the decoded video image of VC 3  to VD 3  which plays the received video image of VC 3 . 
         [0101]    Additionally, the video processing flow may further include steps as follows. 
         [0102]    In Step  6 , two video collecting devices (VC 4  and VC 5 ) respectively collect original video images. The second terminal may obtain a third composite video image by stitching the two original video image streams collected by the two video collecting devices (VC 4  and VC 5 ) according to video arranging information negotiated by the second terminal and the MCU, encode the third composite video image, and sends the encoded third composite video image to the MCU through a media channel between the second terminal and the MCU. The third terminal may encode an original video image collected by the video collecting device VC 6  and then send the encoded original video image of VC 6  to the MCU. 
         [0103]    In Step  7 , the MCU may decode the third composite video image sent by the second terminal, divide the decoded third composite video image into the two original video images of VC 4  and VC 5  according to the video arranging information negotiated by the MCU and the second terminal. The MCU may decode the original video image stream sent by the third terminal. Then the MCU may obtain a forth composite video image by stitching the three original video image streams according to the video arranging information negotiated by the MCU and the first terminal, encode the forth composite video image, and send the encoded forth composite video image to the first terminal through a media channel between the MCU and the first terminal. 
         [0104]    In Step  8 , the first terminal may receive and decode the forth composite video image sent by the MCU, divides the decoded forth composite video image into the three original video image streams according to the video arranging information negotiated by the first terminal and the MCU, and send the three original video image streams respectively to VD 4 , VD 5 , and VD 6  which play the three original video image streams respectively. 
         [0105]    Note that the flow of Step  1  to Step  5  and the flow of Step  6  to Step  8  are independent of each other. 
         [0106]    Each of the first terminal, the second terminal, the third terminal, and the MCU may contain a stitching module, an encoding module, a sending module, and a first determining module, and may further contain a second determining module, a receiving module, a decoding module, and a dividing module. Each such module may serve basically the same function as a corresponding module in Embodiment 2. A stitching module may be configured for: sending, when there is only one original video image, the original video image directly (i.e. without stitching) to a local encoding module which may encode the received video image; and obtaining, when there are two or more original video images, a composite video image by stitching the two or more original video images according to pre-determined video arranging information, and sending the composite video image to the local encoding module for encoding. A sending module may be configured for sending an original video image or a composite image video encoded by an encoding module to the receiving module of the first terminal, the second terminal, the third terminal, or the MCU. A receiving module may be further configured for receiving an original video image or a composite image video sent by the first terminal, the second terminal, the third terminal, or the MCU. A decoding module may be configured for decoding an original video image or a composite image video received by a receiving module. A dividing module may be configured for dividing a composite video image (instead of an original video image) decoded by a decoding module into original video images according to pre-determined video arranging information, and sending, according to the video arranging information, the original video images respectively to video displaying devices each for playing the received original video image. 
         [0107]    In an actual application, a terminal in an aforementioned embodiment may be a hardware device capable of video communication, such as a video conference terminal, a mobile terminal, a set-top box, or the like. 
         [0108]    What described are only embodiments of the disclosure, and shall not be used to limit protection scope of the disclosure. 
       INDUSTRIAL APPLICABILITY 
       [0109]    With a video processing method, apparatus, and system according to an embodiment of the disclosure, a sending end obtains a composite image by stitching multiple video images collected according to pre-negotiated video arranging information, encodes the composite image, and then sends the encoded composite image. A receiving end receives and decodes the composite image, divides the decoded composite image into the multiple video images according to the video arranging information, and sends the multiple video images respectively to devices each for displaying a received video image. 
         [0110]    With embodiments of the disclosure, multiple original video image streams may be stitched into a composite video image, which is then encoded and sent, thus ensuring strict synchronization among multiple video streams in a telepresence conference. Moreover, a received composite video image may first be divided into the multiple original video images, each of which then may be displayed by a proper video displaying device, providing a solution for determining a position where a video image is output, guaranteeing strict synchronization among multiple displays in a telepresence conference. A video image is output according to a pre-set position, thus achieving realistic communication effect.