JP2010074497A - Video signal receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video signal receiver which includes a plurality of signal processing sections for decoding and outputting the encoded video signals supplied via a network and makes the phases of output signals for output synchronize. <P>SOLUTION: The video signal receiver includes a plurality of signal processing sections which receive the encoded video signal and time information supplied via a network, generate synchronous signals based on the time information, and make it synchronize with the synchronous signal to decode the video signal, which is outputted as output video signal. The receiver further includes a synchronous signal distributing section that extracts a synchronous signal from one of the output video signals outputted from the plurality of signal processing sections, and distributes it as a first synchronous signal, to each of the signal processing sections. Each of the plurality of signal processing sections includes a second synchronous signal generating section for generating a second synchronous signal, based on the time information; a synchronous signal selecting section for selecting the first synchronous signal or the second synchronous signal; and a decoding section decoding the video signal, at a timing that corresponds to one synchronous signal selected by the synchronous signal selecting section to generate an output video signal. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a video signal receiving apparatus, and more particularly to a technique for synchronously reproducing a video signal supplied via a network among a plurality of receiving apparatuses.

  With the expansion of the broadband network, it has become possible to implement a system for video communication using an IP network. FIG. 1 shows the overall configuration of a video signal transmission system that transmits and receives video signals using a plurality of transmission devices and reception devices via a network.

  The plurality of video signal sources 10 are video devices such as a camera that captures moving images and a DVD player that reproduces and outputs storage media. The synchronization signal source 12 supplies a synchronization signal to each video signal source 10. Each video signal source 10 generates a transmission video signal in synchronization with the supplied synchronization signal, and supplies this to a subsequent transmission apparatus 11.

  The transmission device 11 extracts a synchronization signal from the received transmission video signal, performs signal processing such as encoding and format conversion at a timing according to the synchronization signal, and includes a video packet including the encoded video signal. Is generated. Further, the transmission device 11 generates a time information packet including time information necessary for synchronization between the transmission device 11 and the reception device 12. The time information includes at least frequency information of a video synchronization signal used when decoding the encoded video signal received by the receiving device 12. The transmission device 11 transmits the generated video packet and time information packet to the reception device 12 via the network 30.

  Each of the plurality of reception devices 12 connected to the network 30 generates a system clock signal and a video synchronization signal based on the time information supplied from the transmission device 11. Then, after the received encoded video signal is decoded in synchronization with the system clock signal and the video synchronization signal, signal processing such as format conversion is performed, and an output video signal is generated. It is supplied to the external device 20.

The external device 20 receives a video receiving terminal having a display monitor, a recording medium for recording an output video signal, or an output video signal output from the plurality of receiving devices 12, and any one of these is further connected to a subsequent device. A change-over switch that outputs to
JP 2007-201797 A

  The conventional system and receiving apparatus described above have the following problems. FIG. 2 is a timing chart of a video synchronization signal and a video signal generated in the transmission device 11 and the reception device 12 in the conventional video signal transmission system. The transmission device 11 extracts a synchronization signal from the transmission video signal supplied from the video signal source 10, and encodes the transmission video signal at a timing synchronized with this to generate an encoded video signal. That is, the transmission device 11 generates a video frame that is a constituent unit of the encoded video signal at a timing according to the synchronization signal. In FIG. 2, the number given to the encoded video signal indicates the frame number. The transmission device 11 transmits a video packet including the encoded video signal to the plurality of reception devices 12 via the network 30 together with the time information packet. Each receiving device 12 that has received the video packet and the time information packet generates a video synchronization signal based on the received time information, decodes the encoded video signal that is sequentially supplied in synchronization with this, and decodes the decoded video signal. Generate a signal. The receiving device 12 further performs signal processing such as format conversion on the decoded video signal, and outputs this as an output video signal. Here, due to variations in packet arrival intervals on the network, the time at which packets are received differs among the plurality of receiving apparatuses 12, and as a result, a phase difference occurs in the output video signal between the receiving apparatuses 12. As a result, when the output video signal to be received is switched (channel switching) between the external devices 20 in the subsequent stage, the video synchronization signal is disturbed, and the output video signal processing (for example, format conversion) in the subsequent apparatus is appropriate. It was not possible to do so, and there was a restriction on the operation of the latter apparatus.

  The present invention has been made in view of the above points, and in a video signal receiving apparatus including a plurality of signal processing units that decode and output an encoded video signal supplied via a network, It is an object of the present invention to provide a video signal receiving apparatus that outputs an output signal with the phase thereof synchronized.

  The video signal receiving apparatus of the present invention receives time information and an encoded video signal each supplied via a network, generates a synchronization signal based on the time information, and synchronizes with the synchronization signal. A video signal receiving device comprising a plurality of signal processing units for decoding the video signal and outputting the decoded video signal as an output video signal, wherein the output video signal is output from each of the plurality of signal processing units. A synchronization signal distribution unit that extracts a synchronization signal from one of the signal processing units and distributes the synchronization signal as a first synchronization signal to each of the signal processing units, wherein each of the plurality of signal processing units is based on the time information According to a second synchronization signal generation unit that generates a second synchronization signal, a synchronization signal selection unit that selects one of the first and second synchronization signals, and one synchronization signal selected by the synchronization signal selection unit The Decodes the video signal in timing is characterized by including a decoding unit configured to generate the output video signal.

  According to the video signal receiving apparatus of the present invention, it is possible to obtain output video signals that are phase-synchronized with each other from each of a plurality of signal processing units that decode and output an encoded video signal supplied via a network. Therefore, it is possible to perform switching (channel switching) of the output video signal in the subsequent apparatus without any restrictions.

BEST MODE FOR CARRYING OUT THE INVENTION

  Embodiments of the present invention will be described below with reference to the drawings. In the following drawings, substantially the same or equivalent components or parts are denoted by the same reference numerals.

  FIG. 3 is a block diagram illustrating a configuration example of a video signal transmission system to which the video signal receiving apparatus 100 according to the embodiment of the present invention is applied. The configuration of this system will be described below.

  The video signal source 10 is a video device having a video signal output function, such as a camera that captures moving images, a DVD player that reproduces and outputs storage media, a Blu-ray disc player, a TV tuner, and the like. In this embodiment, a plurality of video signal sources 10 are introduced into the system, but it is sufficient that at least one video signal source 10 is provided.

  The synchronization signal source 12 supplies a synchronization signal to each video signal source 10. Each video signal source 10 generates a transmission video signal in phase synchronization with the supplied synchronization signal, and supplies this to a corresponding transmission device 11.

  The transmission device 11 is provided in the subsequent stage of each video signal source 10 and is connected to the network 30. The transmission device 11 extracts a video synchronization signal from a transmission video signal supplied from each video signal source, and receives a video packet including an encoded video signal obtained by encoding the transmission video signal in synchronization with the extracted video synchronization signal. Generate. In addition, the transmission device 11 generates a time information packet including time information necessary for synchronization with the video signal reception device 100 that is a video signal supply destination. The time information includes at least frequency information of a video synchronization signal used when the encoded video signal received by the video signal receiving apparatus 100 is decoded. The transmission device 11 transmits the generated video packet and time information packet to the video signal reception device 100 via the network 30.

  The network 30 is a communication network such as an IP network or a dedicated line network for transmitting video packets and time information packets sent from the transmission device 11 to the video signal reception device 100.

  The video signal receiving device 100 decodes the encoded video signal from the transmitting device 11 to generate an output video signal. At this time, the video signal receiving apparatus 100 generates a system clock signal Vck and a video synchronization signal Vb based on the time information supplied from the transmission apparatus 11, and generates and outputs an output video signal in synchronization with these. The video signal receiving apparatus 100 includes N signal processing units 110, a synchronization signal distribution unit 130, and a control unit 140 connected to the network 30.

  FIG. 4 is a block diagram showing a more detailed configuration of the video signal receiving apparatus 100. Each of the signal processing units 110 generates a system clock signal Vck and a video synchronization signal Vb synchronized with the video synchronization signal used for the encoding process of the transmission device 11 based on the time information supplied from the transmission device 11. The functional block includes a synchronization signal generation unit 115, a synchronization signal selection unit 116, a phase comparator 117, a loop filter 118, a voltage controlled oscillator (VCXO) 119, and a frequency divider 120.

  The synchronization signal generation unit 115 generates a video synchronization signal Va having the same frequency as the video synchronization signal used for the encoding process of the transmission device 11 based on the time information supplied from the transmission device 11. Note that the video synchronization signal Va generated at this stage has a phase difference between the signal processing units 110 due to variations in packet arrival intervals on the network.

  The synchronization signal selection unit 116 selects either the video synchronization signal Va supplied from the synchronization signal generation unit 115 or the selection synchronization signal Vs supplied from the synchronization signal distribution unit 130 described later as a selection command S1 supplied from the control unit. Select based on and output.

  The phase comparison 117, the loop filter 118, the voltage controlled oscillator (VCXO) 119, and the frequency divider 120 constitute a PLL (phase synchronization circuit), and the video synchronization signal Va or the selection synchronization signal selected by the synchronization signal selection unit 116. A new video synchronization signal Vb having the same phase and the same frequency as Vs and a system clock signal Vck obtained by multiplying the video synchronization signal Vb are output.

Each of the signal processing units 110 performs signal processing such as decoding and format conversion in synchronization with the video synchronization signal Vb and the system clock signal Vck generated internally from the encoded video signal supplied from the transmission device 11. As a functional block for outputting these as output video signals V _{O1 to} V _ON , a video decoder 112, a video buffer 113, and a video format generation unit 114 are provided.

  The packet distribution unit 111 receives the video packet and the time information packet transmitted from the transmission device 11 and distributes the video packet to the video decoder 112 and the time information packet to the synchronization signal generation unit 115.

The synchronization signal distribution unit 130 receives the output video signals V _{O1 to} V _ON and the external signal V _OX generated by each of the plurality of signal processing units 110, and is input based on the selection command S2 from the control unit 140. The output video signal selection unit 131 for selecting one of the output video signals V _{O1 to} V _ON and the external signal V _OX , and the video synchronization signal is extracted from the one output video signal selected by the output video signal selection unit 131 Synchronization signal extraction unit 132, and a selection synchronization signal Vs having the same phase and the same frequency as the video synchronization signal extracted by the synchronization signal extraction unit 132 are generated and distributed to the synchronization signal selection unit 116 of each signal processing unit 110. PLL unit 133. The PLL circuit 133 includes a phase comparator 134, a loop filter 135, a voltage controlled oscillator (VCXO) 136, and a frequency divider 137.

  The control unit 140 transmits the selection command S1 to each of the signal processing units 110 and transmits the selection command S2 to the synchronization signal distribution unit 130.

  Next, the operation of each component constituting the video signal transmission system will be described. The synchronization signal source 12 continuously supplies a synchronization signal to each video signal source 10. Each of the video signal sources 10 generates a transmission video signal in phase synchronization with the supplied synchronization signal. Transmission video signals transmitted from the video signal sources 10 are output in phase with each other by this synchronization signal. The transmission video signal from each video signal source 10 is supplied to the subsequent transmission device 11.

  The transmission device 11 extracts a video synchronization signal included in the received transmission video signal, encodes the transmission video signal in synchronization with this, and generates an encoded video signal. The transmission device 11 generates a video packet including an encoded video signal corresponding to one video frame. In addition, the transmission device 11 generates a time information packet including time information for synchronizing with the video signal receiving device 100 that is a video signal supply destination. The video signal receiving apparatus 100 can generate a video synchronization signal having the same frequency as the video synchronization signal used for the encoding process of the transmission apparatus 11 by referring to the time information. Thus, by matching the frequency of the video synchronization signal between the transmission side and the reception side, it is possible to match the timing of the encoding process on the transmission side and the decoding process on the reception side. In other words, if the decoding process on the receiving side is too early compared to the encoding process on the transmitting side, the receiving side tries to proceed faster than receiving data, and the buffer memory on the receiving side becomes empty. The video will be interrupted. On the other hand, if the decoding process on the receiving side is too late compared with the encoding process on the transmitting side, the buffer memory on the receiving side will overflow. Therefore, it is possible to avoid such a problem by performing signal processing using the video synchronization signal having the same frequency on the reception side and the transmission side. The time information supplied from the transmission device 11 includes at least frequency information of a video synchronization signal to be generated on the reception side. The transmission device 11 transmits the generated video packet and time information packet to the video signal reception device 100 via the network 30.

  The video packet and the time information packet transmitted from the transmission device 11 are received by each of the signal processing units 110 of the video signal reception device 100. The packet distributor 111 distributes the received video packet to the video decoder 112 and the time information packet to the synchronization signal generator 115.

  The synchronization signal generation unit 115 generates a video synchronization signal Va having the same frequency as the video synchronization signal used for the encoding process of the transmission device 11 based on the received time information, and supplies this to the synchronization signal selection unit 116. .

In addition to the video synchronization signal Va, the synchronization signal selection unit 116 is supplied with the selection synchronization signal Vs from the synchronization signal distribution unit 130, and is also supplied with the selection command S 1 from the control unit 140. As will be described later, the selection synchronization signal Vs is a video synchronization signal extracted from one of the output video signals V _{O1 to} V _ON or the external signal V _OX generated in each signal processing unit 110, and all signals This is supplied to the processing unit 110. The synchronization signal selection unit 116 selects and outputs either the video synchronization signal Va or the selection synchronization signal Vs based on the selection command S1. Here, the control unit 140 issues a selection command S1 to the signal processing unit 110 to select the selection synchronization signal Vs, but the signal corresponds to the source of the output video signal used to generate the selection synchronization signal Vs. Only the processing unit issues a selection command to select the video synchronization signal Va generated in the signal processing unit 110. By such a selection command, the same frequency of the video synchronization signal on the transmission side and the reception side is ensured.

  The synchronization signal selection unit 116 supplies the selected video synchronization signal Va or selection synchronization signal Vs to the phase comparator 117. The phase comparator 117 generates a phase difference detection signal having a voltage level corresponding to the phase difference between the video synchronization signal (Va or Vs) supplied from the synchronization signal selection unit 116 and the output signal of the frequency divider 120. The loop filter 118 is constituted by a low-pass filter, and smoothes the phase difference detection signal including ripples, and generates a DC voltage having no AC component. The voltage controlled oscillator (VCXO) 119 generates a pulse signal having a frequency corresponding to the DC voltage supplied from the loop filter 118. The pulse signal from the voltage controlled oscillator (VCXO) 119 is frequency-divided by 1 / N times by the frequency divider 120. The pulse signal divided by the frequency divider 120 is returned to the phase comparator 117. Thus, the phase comparator 117, the loop filter 118, the voltage controlled oscillator (VCXO) 119, and the frequency divider 120 constitute a PLL (phase synchronization circuit), and the input signal (Va or Vs) and the frequency divider 120 are The passed output signals are controlled to have the same phase and the same frequency. The output signal of the frequency divider 120 is supplied to the video decoder 112 and the video format generator 114 as a new video synchronization signal Vb having the same phase and the same frequency as the video synchronization signal Va or the selection synchronization signal Vs. On the other hand, the output signal of the voltage controlled oscillator (VCXO) 119 before passing through the frequency divider 120 is a pulse signal whose phase is synchronized with the video synchronization signal Vb and whose frequency is N times. The output signal of the voltage controlled oscillator (VCXO) 119 is supplied to the video decoder 112 and the video format generator 114 as a system clock signal Vck.

  The video decoder 112 decodes the encoded video signal included in the video packet supplied from the packet distribution unit 111 at a timing according to the video synchronization signal Vb generated by the PLL in the signal processing unit 110 and the system clock signal Vck. . The video decoder 112 performs a decoding process at a timing corresponding to the video synchronization signal Vb, thereby achieving a harmony with the encoding process in the transmission device 11. The video signals decoded by the video decoder 112 are sequentially supplied to the video buffer 113 and temporarily stored therein.

The video format generation unit 114 reads the decoded video signal from the video buffer 113 at a timing based on the video synchronization signal Vb and the system clock signal Vck, and generates a format such as NTSC, SDTV-SDI, HDTV-SDI, This is output as output video signals V _{O1 to} V _ON . The output video signals V _{O1 to} V _ON output from each signal processing unit 110 are supplied to the external device 20 at the subsequent stage and to the synchronization signal distribution unit 130, respectively.

The output video signals V _{O1 to} V _ON output from each of the signal processing units 110 are supplied to the output video signal selection unit 131 of the synchronization signal distribution unit 130, respectively. In addition to this, an external signal V _OX is supplied to the output video signal selection unit 131. The external signal V _OX is a signal including an arbitrary video synchronization signal supplied from the outside. The output video signal selection unit 131 selects one of the input output video signals V _{O1 to} V _ON or the external signal V _OX based on the selection command S2 supplied from the control unit 140, and Is supplied to the synchronization signal extraction unit 132.

The synchronization signal extraction unit 132 extracts a video synchronization signal from the selected one output video signal V _{O1 to} V _ON or the external signal V _OX . The output video signals V _{O1 to} V _ON are composed of a data frame including a header part and a data part, and the synchronization signal extraction part 132 extracts a video synchronization signal from the description of the header part. The extracted video synchronization signal is supplied to a PLL (phase synchronization circuit) 133.

The phase comparator 134 generates a phase difference detection signal having a voltage level corresponding to the phase difference between the video synchronization signal supplied from the synchronization signal extraction unit 132 and the output signal of the frequency divider 137. The loop filter 135 is configured by a low-pass filter, smoothes the phase difference detection signal including ripples, and generates a DC voltage having no AC component. The voltage controlled oscillator (VCXO) 136 generates a pulse signal having a frequency corresponding to the DC voltage supplied from the loop filter 135. The pulse signal from the voltage controlled oscillator (VCXO) 136 is frequency-divided by 1 / N times by the frequency divider 137. The pulse signal divided by the frequency divider 120 is returned to the phase comparator 134. In this manner, the phase comparator 134, the loop filter 135, the voltage controlled oscillator (VCXO) 136, and the frequency divider 137 constitute a PLL (phase synchronization circuit), and the video synchronization signal that is an input signal and the frequency divider 137 are input. The passed output signals are controlled to have the same phase and the same frequency. The output signal of the frequency divider 137 is output as a selection synchronization signal Vs having the same phase and the same frequency as the video synchronization signal extracted from the output video signals V _{o1 to} V _oN or the external signal V _oX. Distributed to. As described above, each of the signal processing units 110 outputs the output video signal V in synchronization with the video synchronization signal Vb and the system clock signal Vck generated based on the common selection synchronization signal Vs generated by the synchronization signal distribution unit 130. _{Since O1 to} V _ON are generated, the phase difference generated between the output video signals V _{O1 to} V _ON output from each signal processing unit 110 can be eliminated.

The control unit 140 determines which one of the output videos V _{O1 to} V _ON or the external signal V _OX output from each signal processing unit 110 in the synchronization signal distribution unit 130 is selected. In this case, it is possible to eliminate the phase difference between the output video signals regardless of which signal is selected, but the control unit 140 selects a signal other than the output video signal in which an abnormality has occurred, for example. A selection command S2 is issued as much as possible. For example, when the control unit 140 issues a selection command S2 to select the output video signal V _O1 output from the first signal processing unit 110, the signal processing unit 110 receives the signal. A selection command S1 is issued to the synchronization signal selection unit 116 to select the video synchronization signal Va generated in the processing unit 110. In this case, a selection command S1 is issued to the 2nd to Nth signal processing units 110 in order to select the selection synchronization signal Vs generated in the synchronization signal distribution unit 130. By performing such control, the control unit 140 eliminates the phase difference generated between the output video signals V _{O1 to} V _ON and ensures the same frequency of the video synchronization signals on the transmission side and the reception side.

FIG. 5 is a timing chart of each signal generated by each of the transmission device 11 and the signal processing unit 110. The transmission device 11 extracts a video synchronization signal from the transmission video signal supplied from the video signal source 10, and generates an encoded video signal at a timing synchronized with this. That is, the transmission device 11 generates a video frame that is a constituent unit of the encoded video signal at a timing according to the synchronization signal. The transmission device 11 transmits a video packet including the encoded video signal to the plurality of reception devices 12 via the network 30 together with the time information packet. Each signal processing unit 110 that has received the video packet and the time information packet generates a video synchronization signal Va based on the received time information. The video synchronization signal Va generated by each signal processing unit 110 is output at a different phase for each signal processing unit 110 due to variations in packet arrival intervals on the network. However, each signal processing unit 110 generates the video synchronization signal Vb having the same phase and the same frequency as the same based on the common selection video signal Vs supplied from the synchronization signal distribution unit 130. Therefore, the video synchronization signals Vb generated in each signal processing unit 110 have the same phase and the same frequency, and the frequency matches the frequency of the video synchronization signal in the transmission device 11. The output video signals V _{O1 to} V _ON generated at the timing according to the video synchronization signal Vb in each signal processing unit 110 are output in the same phase. As a result, the phase difference between the output video signals is eliminated, and it is possible to prevent problems associated with switching of the output video signals.

Further, in this embodiment, by providing a PLL (phase synchronization circuit) 133 in the synchronization signal distribution unit 130, noise components are mixed in the output video signals V _{O1 to} V _ON selected by the output video signal selection unit 131. Even in this case, it is possible to maintain a stable supply of the selected video signal Vs to each signal processing unit 110. That is, the frequency change of the voltage controlled oscillator (VCXO) 136 constituting the PLL 133 is determined by the time constant of the loop filter 135. If the time constant is long, the input signal is slowly followed and synchronized. Therefore, even when a noise component is mixed in the output video signals V _{O1 to} V _ON and a video synchronization signal generated based on the noise components is input to the PLL 133, the voltage controlled oscillator (VCXO) 136 immediately follows. Therefore, transmission is continued in synchronization with the average frequency of the input video synchronization signal without being affected by noise. As a result, the stability of the selection synchronization signal Vs is also ensured.

  In the video signal receiving apparatus 100 according to the present invention, the signal processing unit 110, the synchronization signal distribution unit 130, and the control unit 140 may be provided separately or may be configured integrally. When these components are integrally configured as a single device, it is easy to realize with a chassis and a board based on the ATCA regulations. For example, each signal processing unit 110, the synchronization signal distribution unit 130, and the control unit 140 are realized by an ATCA board, and the signal line of the selection synchronization signal Vs from the synchronization signal distribution unit 130 is a clock wiring that is wired on the back board of the chassis. The signal lines of the selection commands S1 and S2 from the control unit can be realized by LAN wiring wired to the chassis back board. As described above, since it can be realized by hardware conforming to the ATCA standard, it is possible to simplify the construction from the existing system.

It is a figure which shows the structure of the conventional video signal transmission system. It is a timing chart which shows operation | movement of the transmission apparatus and receiving apparatus of the conventional video signal. It is a figure which shows the structure of the video signal transmission system to which the video signal receiver which is an Example of this invention is applied. It is a block diagram which shows the structure of the video signal receiver which is an Example of this invention. It is a timing chart which shows operation | movement of the video signal receiver which is an Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Video signal source 11 Transmission apparatus 12 Synchronization signal source 20 External apparatus 30 Network 100 Video signal reception apparatus 110 Signal processing part 112 Video decoder 115 Synchronization signal generation part 116 Synchronization signal extraction part 130 Synchronization signal distribution part 131 Output video signal selection part 133 PLL
140 Control unit

Claims (4)

Each receives time information and an encoded video signal supplied via a network, generates a synchronization signal based on the time information, and decodes the video signal in synchronization with the synchronization signal. A video signal receiving device comprising a plurality of signal processing units for outputting as an output video signal,
A synchronization signal distribution unit that extracts a synchronization signal from one of the output video signals output from each of the plurality of signal processing units and distributes the synchronization signal as a first synchronization signal to each of the signal processing units; Including
Each of the plurality of signal processing units includes:
A second synchronization signal generator for generating a second synchronization signal based on the time information;
A synchronization signal selector for selecting one of the first and second synchronization signals;
A video signal receiving apparatus comprising: a decoding unit that decodes the video signal at a timing corresponding to one synchronization signal selected by the synchronization signal selection unit to generate the output video signal. Each of the output video signals output from each of the plurality of signal processing units is input to the synchronization signal distribution unit, and an output video signal selection unit that selects one of them,
A synchronization signal extraction unit that extracts a synchronization signal from the selected one output video signal;
2. The video according to claim 1, further comprising: a PLL (phase synchronization circuit) that receives the extracted synchronization signal and outputs a synchronization signal having the same phase and the same frequency as the first synchronization signal. Signal receiving device. A control unit for supplying a selection command indicating which signal should be selected to each of the synchronization signal selection unit and the output video signal selection unit of each of the signal processing units;
The control unit supplies a selection command to select the second synchronization signal to the synchronization signal selection unit of the signal processing unit corresponding to the supply source of the output video signal selected by the output video signal selection unit. The video signal receiving apparatus according to claim 1, wherein a selection command for selecting the first synchronization signal is supplied to the synchronization signal selection unit of the other signal processing unit. Each of the plurality of signal processing units receives the first or second synchronization signal selected by the synchronization signal selection unit, the third synchronization signal having the same phase and the same frequency, and the third synchronization signal. A phase-locked loop (PLL) that outputs a clock signal that is phase-synchronized with each other and multiplied by the third synchronization signal,
4. The video according to claim 1, wherein the decoding unit generates the output video signal by decoding the video signal in synchronization with the third synchronization signal and the clock signal. 5. Signal receiving device.

Images