WO2024053359A1 - Dispositif de traitement de signal, système d'aiguilleur et programme associé - Google Patents

Dispositif de traitement de signal, système d'aiguilleur et programme associé Download PDF

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Publication number
WO2024053359A1
WO2024053359A1 PCT/JP2023/029770 JP2023029770W WO2024053359A1 WO 2024053359 A1 WO2024053359 A1 WO 2024053359A1 JP 2023029770 W JP2023029770 W JP 2023029770W WO 2024053359 A1 WO2024053359 A1 WO 2024053359A1
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Prior art keywords
box
switcher
signal
boxes
logical
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PCT/JP2023/029770
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English (en)
Japanese (ja)
Inventor
響平 秋岡
俊太 越後谷
孝啓 平林
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ソニーグループ株式会社
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Publication of WO2024053359A1 publication Critical patent/WO2024053359A1/fr

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N5/00Details of television systems
    • H04N5/222Studio circuitry; Studio devices; Studio equipment
    • H04N5/262Studio circuits, e.g. for mixing, switching-over, change of character of image, other special effects ; Cameras specially adapted for the electronic generation of special effects
    • H04N5/268Signal distribution or switching

Definitions

  • the present technology relates to a signal processing device, a switcher system, and a program that can be used, for example, as a component of a video production system.
  • Patent Document 1 describes a vision mixer (video switcher). Conventionally, there has been a lineup of multiple vision mixers depending on the scale of video production. After the video production system is constructed, it is conceivable that a larger vision mixer will be required due to changes in the content of video production.
  • the purpose of this technology is to make it possible to easily expand the scale of a vision mixer (video switcher) after constructing a video production system.
  • the concept of this technology is a signal receiving unit that receives video signals from a plurality of devices having switcher signal processing functions; a cross-point processing unit that aggregates and redistributes video signals received by the signal receiving unit to obtain video signals to the plurality of devices;
  • the signal processing device further includes a signal transmitter that transmits a video signal obtained by the cross-point processor to the plurality of devices.
  • the signal processing device corresponds to a crosspoint box.
  • a signal receiving unit receives video signals from a plurality of devices having a switcher signal processing function.
  • the plurality of devices includes devices owned by the device itself as well as external devices.
  • the cross-point processing section aggregates and redistributes the video signals received by the signal receiving section to obtain video signals for multiple devices. Then, the signal transmitter transmits the video signal obtained by the cross-point processor to a plurality of devices.
  • the signal receiving section receives a multiplexed signal in which a plurality of video signals are multiplexed on at least one transmission line from an external device
  • the signal transmitting section receives a multiplexed signal in which a plurality of video signals are multiplexed from an external device on at least one transmission line.
  • a multiplex signal in which a plurality of video signals are multiplexed may be transmitted.
  • the transmission line may be compatible with 100G QSFP.
  • the switcher system has a minimum configuration including one first box having a switcher signal processing function, and can be expanded in scale by physically connecting a predetermined number of other boxes.
  • a minimum configuration includes one first box having a switcher signal processing function.
  • the scale can be expanded by physically connecting a predetermined number of other boxes.
  • the other predetermined number of boxes may include at least a first box that aggregates and redistributes video signals from a plurality of devices having the signal processing function of the switcher to obtain video signals to the plurality of devices.
  • 2 box may be included.
  • the first box may be an ME box and the second box may be a crosspoint box.
  • a predetermined number of logical switchers configured to include one or more first boxes may be provided.
  • a system manager may be provided that controls the construction of the logical switcher.
  • a plurality of first boxes it is also possible to have a plurality of small-scale logical switchers.
  • a system manager may build a logical system for a physically configured system, or a system manager may build multiple logical systems within a physically configured system. It may be configured such that a system can be constructed. child
  • the first box and the second box may be connected by a predetermined number of transmission lines, and at least one transmission line may transmit a multiplexed signal in which a plurality of video signals are multiplexed.
  • the transmission line may be compatible with 100G QSFP.
  • the second box has a signal receiving section that receives the multiplexed signal on the signal input side from the first box and performs a process of extracting individual video signals from the multiplexed signal, and A signal transmitter may be provided on the signal output side to one box for multiplexing a plurality of video signals to generate a multiplexed signal and transmitting the multiplexed signal.
  • the number of transmission lines between the first box and the second box can be reduced, the appearance of the vision mixer (video switcher) can be simplified, and the number of transmission lines between the first box and the second box can be reduced.
  • the box and the second box can be easily connected.
  • this technology has a minimum configuration that includes one first box with the switcher signal processing function, and can be expanded in scale by physically connecting a predetermined number of other boxes. This makes it easy to expand the scale of the vision mixer (video switcher).
  • a procedure for detecting a predetermined number of boxes that should constitute a switcher configuring a predetermined number of logical switchers based on the predetermined number of boxes;
  • the predetermined number of boxes includes one first box having a switcher signal processing function, or a second box that aggregates and redistributes video signals from a plurality of devices having a signal processing function of a switcher including the first box and obtains video signals to the plurality of devices;
  • the logical switcher is configured to include one or more of the first boxes, and is included in a program for causing a computer to execute a system construction method.
  • This technology is a program that causes a computer to execute a system construction method.
  • This system construction method includes a procedure for detecting a predetermined number of boxes that should constitute a switcher, and a procedure for configuring a predetermined number of logical switchers based on the predetermined number of boxes.
  • the predetermined number of boxes includes one first box with switcher signal processing functionality, or aggregates video signals from multiple devices with switcher signal processing functionality, including this first box. and one or more first boxes and one second box that redistributes video signals to the plurality of devices.
  • the logical switcher is configured to include one or more first boxes.
  • the predetermined number of boxes may exist as one group or as multiple groups.
  • at least one of the plurality of groups may exist via a network.
  • it becomes possible to configure a logical switcher by effectively utilizing a predetermined number of boxes (resources) not only as one group but as multiple groups.
  • a system construction method that includes a procedure for detecting a predetermined number of boxes that should constitute a switcher, and a procedure for configuring a predetermined number of logical switchers based on the predetermined number of boxes is implemented in a computer.
  • This is a program to be executed, and by using this program, it is possible to easily expand the scale of the vision mixer (video switcher) by increasing the number of first boxes having the signal processing function of the switcher.
  • FIG. 1 is a block diagram showing an example of the configuration of a switcher system.
  • FIG. 2 is a diagram schematically showing that the scale of the vision mixer can be mechanically expanded by increasing the number of boxes.
  • FIG. 2 is a block diagram illustrating a configuration example where the vision mixer is composed of one ME box (ME BOX), or one ME box (ME BOX) and one cross point box (XPT BOX).
  • FIG. 2 is a block diagram showing a configuration example in which a vision mixer is composed of two ME boxes (ME BOX) and one cross point box (XPT BOX).
  • FIG. 2 is a block diagram showing an example of a configuration in which a vision mixer is composed of four ME boxes (ME BOX) and one cross point box (XPT BOX).
  • FIG. 1 is a block diagram showing an example of the configuration of a switcher system.
  • FIG. 2 is a diagram schematically showing that the scale of the vision mixer can be mechanically expanded by increasing the number of boxes.
  • FIG. 2 is a block
  • FIG. 3 is a diagram for more specifically explaining the connection between the ME box and the crosspoint box.
  • FIG. 3 is a block diagram showing another example of the configuration of the switcher system.
  • FIG. 4 is a block diagram showing an example of a case where four ME boxes and one crosspoint box exist in one island, and two logical vision mixers are configured using them.
  • FIG. 3 is a block diagram showing another example of the configuration of the switcher system.
  • FIG. 3 is a block diagram showing another example of the configuration of the switcher system.
  • FIG. 3 is a block diagram showing another example of the configuration of the switcher system.
  • 1 is a diagram showing an example of a system configuration in which a vision mixer according to the present technology is configured and used.
  • FIG. 1 is a diagram showing an example of a system configuration in which a vision mixer according to the present technology is configured and used.
  • 1 is a diagram showing an example of a system configuration in which a vision mixer according to the present technology is configured and used.
  • 3 is a flowchart illustrating an example of a processing procedure for initial system construction.
  • FIG. 3 is a diagram illustrating an example of a list display (UI display) of information on devices detected in device detection processing.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to box registration processing.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to cross-point box setting processing.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to logical switcher setting processing.
  • FIG. 7 is a diagram showing an example of a UI display corresponding to network setting processing (when network settings for a control system network are performed for up to five ME boxes or crosspoint boxes belonging to an island);
  • FIG. 7 is a diagram showing an example of a UI display corresponding to network setting processing (when network settings for a video transmission network are performed for up to five ME boxes or crosspoint boxes belonging to an island);
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to network setting processing (a case where network settings for a control system network are performed for a control panel assigned to a logical switcher (vision mixer));
  • FIG. 3 is a diagram illustrating an example of a UI display corresponding to license setting processing.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to system configuration execution processing.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to format setting processing (when the logical switcher (vision mixer) has a one-box configuration).
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to format setting processing (when the logical switcher (vision mixer) has a multiple box configuration).
  • 3 is a flowchart illustrating an example of a system change processing procedure.
  • FIG. 7 is a diagram illustrating an example of a UI display corresponding to package initial load processing.
  • FIG. 1 shows a configuration example of a switcher system 100. In this example, one island 101 is used.
  • an island means a unit (group) of a predetermined number of boxes including cross point boxes, ME (Mix Effect) boxes, and the like.
  • a predetermined number of boxes (ME box, crosspoint box) exist as one group.
  • the ME box is a box that has the signal processing functions of a switcher, such as synthesis and effect functions.
  • a crosspoint box is a box that aggregates and redistributes video signals from a plurality of devices having a switcher signal processing function such as an ME box, and obtains video signals to the plurality of devices.
  • the switcher system 100 includes a vision mixer 102 and a system manager 103 on one island 101.
  • the system manager 103 is management software that defines the roles of the crosspoint boxes and ME boxes included in the island 101, and defines them as logical vision mixers (logical switchers).
  • the system manager 100 constructs a logical system for the physically configured system.
  • the system manager 100 is configured to be able to construct a plurality of logical systems within a physically configured system.
  • the vision mixer 102 is constructed by the system manager 103 described above using a predetermined number of boxes included in the island 101. In this case, based on the predetermined number of boxes included in the island 101, it is possible to configure a predetermined number of logical vision mixers that each operate independently.
  • the illustrated example shows an example in which one logical vision mixer is configured.
  • the switcher system 100 also includes a control panel 104, a user interface section 105, a user interface section 106, and an IP switch 107.
  • the control panel 104 is a switcher console for the user to operate the vision mixer 102.
  • the user interface unit 105 is a user interface for a user to operate the system manager 103, and is configured of, for example, a PC (Personal Computer).
  • the user interface unit 106 is a user interface for a user to operate the vision mixer 102, and is configured of, for example, a PC.
  • the IP switch 107 transmits video/audio/metadata, etc., and performs information transmission with the outside of the switcher system. Note that in the illustrated example, audio/metadata is omitted.
  • the vision mixer 102 has a minimum hardware configuration including one ME box, and can be expanded in scale by physically connecting a predetermined number of other boxes.
  • this vision mixer 102 has a stackable structure and can be mechanically expanded in size.
  • the other predetermined number of boxes aggregates and redistributes video signals from multiple devices having switcher signal processing functions, including at least the ME box, to obtain video signals for the multiple devices. Includes 1 cross point box
  • FIG. 2 schematically shows that the scale of the vision mixer 102 can be mechanically expanded by increasing the number of individually configured hardware boxes.
  • the vision mixer 102 can be configured with one ME box (MR BOX).
  • the vision mixer 102 can be configured with one ME box and one cross point box (XPT BOX).
  • a crosspoint box is a box that aggregates and redistributes video signals from multiple devices with a switcher signal processing function such as an ME box, and obtains video signals to the multiple devices.
  • the crosspoint box in this case includes a device with the signal processing function of the switcher, and this device (internal device) and one ME box (external device) perform the switcher.
  • a plurality of devices with signal processing functions are configured.
  • the vision mixer 102 can be configured with one crosspoint box and two to four ME boxes.
  • the crosspoint box in this case may or may not include a device having a switcher signal processing function.
  • the maximum number of ME boxes is four, but the maximum number of ME boxes is not limited to four, and may be greater than that. In that case, it goes without saying that the crosspoint box is configured to be able to connect the maximum number of ME boxes.
  • FIG. 3(a) shows a configuration example where the vision mixer 102 is composed of one ME box (ME BOX).
  • ME BOX ME box
  • an input signal is sent from the IP switch 107 to one ME box, and an output signal is sent from the ME box to the IP switch 107.
  • FIG. 3(b) shows a configuration example where the vision mixer 102 is composed of one ME box (ME BOX) and one cross point box (XPT BOX).
  • ME BOX ME box
  • XPT BOX cross point box
  • the display of "ME function unit included" in the crosspoint box indicates that the crosspoint box includes a device having the same function as the ME box, that is, a device having the signal processing function of a switcher.
  • an input signal (Input Signal) is sent from the IP switch (IP Switch) 107 to the ME box and the crosspoint box, and an output signal (Output Signal) is sent from the ME box and the crosspoint box to the IP switch 107.
  • IP switch IP Switch
  • the ME box and the crosspoint box are connected using a local line that constitutes a transmission line, and signals are transmitted (transmitted and received) between them.
  • the transmission lines existing between the ME box and the crosspoint box include a predetermined number, usually multiple transmission lines, for transmitting signals from the ME box to the crosspoint, and a transmission line for transmitting signals from the crosspoint box to the ME box. It consists of a predetermined number of transmission lines, usually a plurality of transmission lines.
  • At least one transmission line transmits a multiplexed signal in which a plurality of video signals are multiplexed.
  • a transmission line compatible with 100G QSFP quad small form factor pluggable
  • this transmission line is one that can support transmission of 4K or HD video signals.
  • the crosspoint box receives a multiplexed signal of a plurality of video signals for each transmission line from the ME block, and transmits a multiplexed signal of a plurality of video signals for each transmission line to the ME block.
  • the crosspoint box has a signal receiving section that receives the multiplexed signal on the signal input side from the ME box and performs processing to extract individual video signals from the multiplexed signal, and has a signal receiving section on the signal output side to the ME box.
  • a signal transmitter that multiplexes a plurality of video signals to generate a multiplexed signal and transmits the multiplexed signal.
  • FIG. 4 shows a configuration example where the vision mixer 102 is composed of two ME boxes (ME BOX) and one cross point box (XPT BOX).
  • the display of "ME function unit included" in the crosspoint box indicates that the crosspoint box includes a device having the same function as the ME box, that is, a device having the signal processing function of a switcher. Note that when the vision mixer 102 is configured with two ME boxes and one crosspoint box in this way, the crosspoint box may have a configuration that does not include a device with a switcher signal processing function. .
  • an input signal (Input Signal) is sent from the IP switch (IP Switch) 107 to the ME box and the crosspoint box, and an output signal (Output Signal) is sent from the ME box and the crosspoint box to the IP switch 107.
  • IP switch IP Switch
  • the ME box and the crosspoint box are connected using a local line that constitutes a transmission line, similar to the configuration example in FIG. 3(b) described above, and signals are transmitted between them. (transmission and reception) is performed.
  • FIG. 5 shows a configuration example where the vision mixer 102 is composed of four ME boxes (ME BOX) and one cross point box (XPT BOX).
  • the display of "ME function unit included" in the crosspoint box indicates that the crosspoint box includes a device having the same function as the ME box, that is, a device having the signal processing function of a switcher. Note that when the vision mixer 102 is configured with four ME boxes and one crosspoint box in this way, the crosspoint box may have a configuration that does not include a device with a switcher signal processing function. .
  • an input signal (Input Signal) is sent from the IP switch (IP Switch) 107 to the ME box and the crosspoint box, and an output signal (Output Signal) is sent from the ME box and the crosspoint box to the IP switch 107.
  • IP switch IP Switch
  • the ME box and the crosspoint box are connected using a local line that constitutes a transmission line, similar to the configuration example in FIG. 3(b) described above, and signals are transmitted between them. (transmission and reception) is performed.
  • FIG. 6 shows the input signal (Input Signal) from the IP switch 107 to each box, the output signal (Output Signal) from each box to the IP switch, and the communication between the ME box and the crosspoint box in the configuration example of FIG. 5. This shows more specifically local lines as transmission lines between the two.
  • the crosspoint block has a signal receiving section that receives a multiplexed signal on the signal input side from the ME box and performs processing to extract individual video signals from this multiplexed signal.
  • the crosspoint block aggregates and redistributes video signals from the ME box (external device) and the ME function section (internal device) of this crosspoint block, and distributes the video signals to multiple devices. It has a cross point section (XPT section) that obtains the following.
  • this crosspoint block has a signal processing section that multiplexes a plurality of video signals to generate a multiplexed signal and transmits the multiplexed signal to the ME box.
  • the vision mixer (video switcher) 102 has a minimum configuration including one ME box and physically connects a predetermined number of other boxes.
  • the scale of the vision mixer (video switcher) can be easily expanded.
  • one logical vision mixer 102 is configured based on a predetermined number of boxes included in one island 101.
  • FIG. 7 shows a configuration example of another switcher system 100A.
  • a plurality of (in this case, two) logical vision mixers 102A and 102B are configured based on a predetermined number of boxes included in one island 101.
  • parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and detailed explanation thereof will be omitted as appropriate.
  • the switcher system 100A includes vision mixers 102A and 102B and a system manager 103 on one island 101.
  • the switcher system 100A also includes control panels 104A and 104B, a user interface section 105, user interface sections 106A and 106B, and an IP switch 107.
  • Control panels 104A and 104B are switcher consoles for users to operate vision mixers 102A and 102B, respectively.
  • the user interface units 106A and 106B are user interfaces for users to operate the vision mixers 102A and 102B, respectively, and are composed of, for example, a PC.
  • FIG. 8 shows an example where four ME boxes and one crosspoint box exist in one island 101, and logical vision mixers 102A and 102B are configured using them.
  • the vision mixer 102A is configured to include two ME boxes
  • the vision mixer 102B is configured to include the remaining two ME boxes.
  • the vision mixers 102A and 102B may include different numbers of ME boxes to configure two vision mixers with different production scales.
  • the vision mixer 102A may be configured to include three ME boxes, and the vision mixer 102B may be configured to include the remaining one ME box.
  • the vision mixer 102A may be configured to include three ME boxes, and the vision mixer 102B may be configured to include the remaining one ME box.
  • four ME boxes and one crosspoint box exist in one island 101, a configuration with one to four vision mixers is possible.
  • switcher systems 100 and 100A are examples that focus on one island 101, it is also possible to perform processing by linking vision mixers each configured on a plurality of islands, or to perform processing across a plurality of islands. It is also conceivable to configure a vision mixer to perform processing.
  • FIG. 9 shows a configuration example of another switcher system 100B.
  • This example is an example in which vision mixers 102-1 and 102-2 configured in two islands 101-1 and 101-2 are linked to perform processing.
  • parts corresponding to those in FIG. 1 are designated by the same reference numerals, and detailed explanation thereof will be omitted as appropriate.
  • a predetermined number of boxes (ME boxes, crosspoint boxes) exist as a plurality of boxes, in this case two groups.
  • the switcher system 100B includes a vision mixer 102-1 on an island 101-1. This vision mixer 102-1 is similar to the vision switcher 102 configured in the island 101 of the switcher system 100 in FIG.
  • the switcher system 100B also includes a control panel 104-1, a user interface section 106-1, and an IP switch 107-1 on the island 101-1 side.
  • the control panel 104-1 is a switcher console for the user to operate the vision mixer 102-1.
  • the user interface unit 106-1 is a user interface for a user to operate the vision mixer 102-1, and is configured of, for example, a PC.
  • the IP switch 107-1 transmits video/audio/metadata, etc., and performs information transmission with the outside of the switcher system. Note that in the illustrated example, audio/metadata is omitted.
  • the switcher system 100B includes a vision mixer 102-2 on the island 101-2.
  • This vision mixer 102-2 is similar to the vision switcher 102 configured in the island 101 of the switcher system 100 in FIG.
  • the switcher system 100B also includes a control panel 104-2, a user interface section 106-2, and an IP switch 107-2 on the island 101-2 side.
  • the control panel 104-2 is a switcher console for the user to operate the vision mixer 102-2.
  • the user interface unit 106-2 is a user interface for a user to operate the vision mixer 102-2, and is configured of, for example, a PC.
  • the IP switch 107-2 transmits video/audio/metadata, etc., and performs information transmission with the outside of the switcher system. Note that in the illustrated example, audio/metadata is omitted.
  • the IP switch 107-1 on the island 101-1 side and the IP switch 107-2 on the island 101-2 side cooperate with the vision mixers 102-1 and 102-2 configured on the islands 101-1 and 101-2, respectively. They are connected by a transmission line to perform the processing.
  • the switcher system 100B includes a system manager 108 and a user interface unit 109 outside the islands 101-1 and 101-2.
  • the system manager 108 is management software that defines the roles of the crosspoint boxes and ME boxes included in the islands 101-1 and 101-2, and defines them as logical vision mixers 102-1 and 102-2.
  • the user interface unit 109 is a user interface for a user to operate the system manager 108, and is configured of, for example, a PC (Personal Computer).
  • FIG. 10 shows a configuration example of another switcher system 100C.
  • the vision mixer 102 is configured to straddle two islands 101-1 and 101-2 to perform processing.
  • parts corresponding to those in FIGS. 1 and 9 are designated by the same reference numerals, and detailed explanation thereof will be omitted as appropriate.
  • the switcher system 100C has a vision mixer 102 configured to straddle islands 101-1 and 101-2.
  • This vision mixer 102-1 is similar to the vision switcher 102 configured in the island 101 of the switcher system 100 in FIG.
  • the system manager 108 defines the roles of the crosspoint boxes and ME boxes included in the islands 101-1 and 101-2, and defines them as the logical vision mixer 102.
  • the other parts of this switcher system 100C are configured similarly to the switcher system 100B shown in FIG. 9.
  • the vision mixer 102 configured across the islands 101-1 and 101-2 may be operated only by the control panel 104-1 and user interface unit 106-1 on the island 101-1 side, or The control panel 104-2 and the user interface unit 106-2 on the 101-2 side may be used alone, or both may be used.
  • FIG. 11 shows a configuration example of another switcher system 100D.
  • a vision mixer 102B is configured to perform processing across two islands 101-1 and 101-2, and another vision mixer 102A is configured on island 101-1. be.
  • parts corresponding to those in FIGS. 7 and 10 are designated by the same reference numerals, and detailed explanation thereof will be omitted as appropriate.
  • control panel 104-1B and a user interface section 106-1B that operate the vision mixer 102B, as well as a control panel 104-1A and a user interface section 106-1A that operate the vision mixer 102A.
  • system manager 108 defines the roles of the crosspoint boxes and ME boxes included in the islands 101-1 and 101-2, and defines them as logical vision mixers 102A and 102B.
  • the other parts of this switcher system 100D are configured similarly to the switcher system 100C shown in FIG. 10.
  • FIG. 12(a) is an example in which one island exists on the imaging venue side or the home side.
  • the home is, for example, a broadcasting station
  • the shooting venue is, for example, a stadium.
  • the video signal from the camera is fed directly to the island.
  • a vision mixer is configured on the island.
  • the control panel that operates the vision mixer is connected directly to the island.
  • a vision mixer performs processing such as synthesis and effects on the video signal from the camera to generate and output a video signal for on-air use.
  • FIG. 12(b) is an example where the shooting venue and the platform are separated, and there is one island on the platform side.
  • the shooting venue and the platform are separate when, for example, there are cameras at the stadium and a switcher at the broadcasting station.
  • the video signal from the camera is fed to the island via the network.
  • a vision mixer is configured on the island.
  • the control panel that operates the vision mixer is connected directly to the island.
  • a vision mixer performs processing such as synthesis and effects on the video signal from the camera to generate and output a video signal for on-air use.
  • FIG. 12(c) is an example in which the shooting venue and the platform are separated, and there is one island on the imaging venue side.
  • the video signal from the camera is fed directly to the island.
  • a vision mixer is configured on the island.
  • a control panel that operates the vision mixer is connected to the island via a network.
  • a vision mixer performs processing such as synthesis and effects on the video signal from the camera to generate an on-air video signal, and this on-air video signal is sent to the home side via the network.
  • FIG. 13(a) is an example in which two islands are located close to each other on the imaging venue side or the home side, that is, one base, and processing is performed in which they are linked.
  • the video signal from the camera is fed to the first island.
  • a vision mixer is configured on this first island.
  • a control panel for operating the vision mixer is connected directly to the first island.
  • the vision mixer on the first island performs processing such as synthesis and effects on the video signal from the camera.
  • the second island is supplied with the video signal processed by the vision mixer of the first island.
  • a vision mixer is configured on this second island, and a control panel for operating the vision mixer is directly connected to the second island.
  • the video signal processed by the vision mixer of the first island is subjected to processing such as synthesis and effects by the vision mixer of the second island, and a video signal for on-air is generated and output.
  • FIG. 13(b) is an example in which two islands are located close to each other on the imaging venue side or the home side, that is, one base, and processing is performed in which they are linked.
  • a vision mixer is configured across the first island and the second island, and the control panel that operates the vision mixer is directly connected to the first island, the second island, or both islands. has been done.
  • a video signal from the camera is provided to the first island.
  • a vision mixer configured across the first island and the second island performs processing such as synthesis and effects on the video signal from this camera to generate a video signal for on-air, and the second island output from the island.
  • the shooting venue and the platform are separated, with the first island existing on the imaging venue side (base 1) and the second island existing on the home side (base 2) via the network.
  • the video signal from the camera on the first island side is provided to the first island.
  • a vision mixer is configured on this first island.
  • a control panel for operating the vision mixer is connected directly to the first island. The vision mixer on the first island performs processing such as synthesis and effects on the video signal from the camera.
  • the video signal processed by the vision mixer of the first island is supplied to the second island via the network. Also, a video signal from a camera on the second island side is supplied to the second island. A vision mixer is configured on this second island, and a control panel for operating the vision mixer is directly connected to the second island.
  • the video signal processed by the vision mixer of the first island and the video signal from the camera are processed by the vision mixer of the second island, such as synthesis and effects, to generate a video signal for on-air and output. be done.
  • the shooting venue and the platform are separated, with the first island existing on the imaging venue side (base 1) and the second island existing on the home side (base 2) via the network.
  • base 1 the imaging venue side
  • base 2 the second island existing on the home side
  • a vision mixer is configured via a network spanning the first island and the second island, and the control panel for operating the vision mixer is located on the first island, the second island, or both. Connected directly to the island.
  • the video signal from the camera on the first island side is supplied to the first island.
  • a video signal from a camera on the second island is provided to the second island.
  • These video signals are processed by a vision mixer that spans the first island and the second island to perform processing such as synthesis and effects to generate on-air video signals, which are then sent to the second island. is output from.
  • FIG. 15 shows an example of a processing procedure for initial system construction.
  • This initial system construction processing procedure includes a System Manager Menu and a Vision Mixer Menu that follows.
  • the system manager menu is a process performed by accessing the system manager from the first user interface unit (PC).
  • the first user interface section corresponds to the user interface section 105 for operating the system manager 103.
  • the first user interface section corresponds to the user interface section 109 for operating the system manager 108.
  • the vision mixer menu is a process performed by the second user interface unit (PC) accessing each logical vision mixer set by the system manager.
  • the user interface unit 106 for operating the vision mixer 102 corresponds to the second user interface unit.
  • the user interface units 106-1 and 106-2 for operating the vision mixers 102-1 and 102-2 correspond to the second user interface unit.
  • step ST1 devices within the island (ME boxes, crosspoint boxes, control panels) are detected via a network such as a LAN (Local Area Network), and information on the detected devices (previously set ID, hostname, IP address, etc.) are displayed in a list on the first user interface section.
  • a network such as a LAN (Local Area Network)
  • information on the detected devices previously set ID, hostname, IP address, etc.
  • the control panel is shown as being outside the island, but here, the control panel is also treated as a device within the island.
  • FIG. 16 shows an example of a list display of information on devices detected in the device detection process of step ST1 described above.
  • the "PBID (Physical Box ID)” item is an ID indicating the physical arrangement of up to five ME boxes or crosspoint boxes within the island.
  • GID is an ID that indicates logical switchers 1 to 4 (vision mixers)
  • LBID is an ID that indicates the ME box or cross point in one logical switcher. This is the logical box ID of the box.
  • the "PRI/SEC (Primary/Secondary)" item indicates whether each box in one logical switcher operates as a primary or a secondary.
  • the box with LBID: 1 always operates as the primary and plays the role of UI (User Interface) and management. Boxes with LBID: 2 to 5 operate as secondary, and operate under control from the primary.
  • the "System Manager” item indicates in which box the system manager is running. “Main” indicates the box that is currently running, “Backup” indicates the box that the system manager will run in place of when the “Main” box fails. “Type” indicates the device type. , indicates whether it is an ME box (M/E Box) or a crosspoint box (XPT Box).
  • the "Hostname” item indicates the host name given by the user to each device (ME box, crosspoint box, control panel).
  • the "IPv4 Address / Prefix Length” item indicates the network settings of each device.
  • the "Status” item indicates the error status and connection status of each device.
  • a “R” mark indicates a normal state.
  • a “R” mark indicates an abnormal state.
  • GID is an ID that indicates 1 to 4 logical switchers (vision mixers), and Panel ID belongs to one logical switcher (vision mixer). Logical ID of up to two control panels to be used.
  • the "Panel Name” item indicates the name given to the control panel by the user.
  • the "Line ID” item is a physical ID assigned to each column of the control panel, which is composed of multiple columns.
  • the box registration that is, the PBID (Physical Box ID) in the island
  • the box registration is performed for the ME box and crosspoint box among the detected devices.
  • This PBID needs to be set to be the same as the physical connection of the local line between the ME box and the crosspoint box. In this case, it is also possible to check whether the local line connection is correct in test mode and confirm the result. It is also possible to visually identify the device by blinking the LED of each device using the "Send" button of each device.
  • FIG. 17 shows an example of a UI display corresponding to the box registration process in step ST2 described above.
  • the "PBID (Physical Box ID)” item is an ID indicating the physical arrangement of up to five ME boxes or crosspoint boxes within the island.
  • the "Type” item indicates the device type, and indicates whether it is an ME Box or a Cross Point Box (XPT Box).
  • the "Hostname” item indicates the host name given by the user to each device (ME box, crosspoint box, control panel).
  • the snow peak mark "*" is placed at the location where there has been a change from the previous setting.
  • the "Send Beacon” item button when this button is pressed, the front LED of the target ME box or crosspoint box will blink for, for example, 5 seconds, making it visually identifiable.
  • the "Check Local I/F” button when you press this button, you can check whether the connection locations of the local lines between the crosspoint box and the four ME boxes are correct, and whether there are any problems with the signal quality of the local lines. You can check if
  • step ST3 the frame rate, reference, and crosspoint box format in the video signal format, which are common settings within the island, are set.
  • FIG. 18 shows an example of a UI display corresponding to the cross-point box setting process in step ST3 described above.
  • the frame rate in the video signal format which is a common setting within the island
  • the reference signal in the video signal format which is a common setting within the island
  • the format (resolution) of the crosspoint box in the video signal format which is a common setting within the island.
  • the snow peak mark "*" is placed at the location where there has been a change from the previous setting.
  • step ST4 up to five ME boxes and crosspoint boxes belonging to the island constructed in step ST2 are connected to one to four logical switchers (vision mixer). Further, in this step ST4, the control panel detected in step ST1 is assigned to one to four logical switchers (vision mixers).
  • FIG. 19 shows an example of a UI display corresponding to the logical switcher setting process in step ST4 described above.
  • the "LBID” item is the logical box ID of the ME box or crosspoint box in one logical switcher.
  • the "Type” item indicates the device type, and indicates whether it is an ME Box or a Cross Point Box (XPT Box).
  • the "Hostname” item indicates the host name given by the user to each device (ME box, crosspoint box, control panel).
  • the snow peak mark “*” is placed at the location where there has been a change from the previous setting.
  • PBID Physical Box ID
  • the "Panel ID” item is the logical ID of up to two control panels that belong to one logical switcher (vision mixer).
  • the "Panel Name” item indicates the name given to the control panel by the user.
  • the "Send Beacon” item button when this button is pressed, the front LED of the target ME box or crosspoint box flashes for, for example, 5 seconds, making it visually identifiable.
  • the "Group ID” item is an ID indicating logical switchers (vision mixers) 1 to 4.
  • the snow peak mark "*" is placed at the location where there has been a change from the previous setting.
  • step ST5 the control network and video transmission network are Settings are made. Further, in this step ST5, network settings of a control system network are performed for the control panel assigned to the logical switcher (vision mixer) in step ST4.
  • FIGS. 20 to 22 show examples of UI displays corresponding to the network setting process in step ST5 described above.
  • FIG. 20 is an example of a UI display when network settings for a control network are performed for up to five ME boxes and crosspoint boxes belonging to an island.
  • FIG. 21 is an example of a UI display when network settings for a video transmission network are performed for up to five ME boxes and crosspoint boxes belonging to an island.
  • FIG. 22 is an example of a UI display when network settings for a control system network are performed on a control panel assigned to a logical switcher (vision mixer).
  • vision mixer logical switcher
  • license assignment for each function is performed for up to five ME boxes and crosspoint boxes belonging to the island constructed in step ST2. For example, when trying to set the signal format to 4K using a logical switcher (Vision Miki), if the 4K format license is not assigned, the signal format cannot be set to 4K.
  • FIG. 23 shows an example of a UI display corresponding to the license setting process in step ST6 described above.
  • the "Logical Switcher X” item indicates the license assigned to each logical switcher (vision mixer).
  • the "Logical Box X” item indicates a license assigned to each box in the logical switcher (vision mixer).
  • the “Option” item indicates the license model number.
  • the “Description” item indicates the function name of the license.
  • the snow peak mark "*" is placed at the location where there has been a change from the previous setting.
  • step ST7 in the process of executing the system configuration in step ST7, the contents set in steps ST2 to ST6 are reflected in each device (ME box, crosspoint box, control panel), and a reboot is performed. , a new system is built.
  • FIG. 24 shows an example of a UI display corresponding to the process of executing the system configuration in step ST7 described above.
  • the "PBID (Physical Box ID)” item is an ID indicating the physical arrangement of up to five ME boxes or crosspoint boxes within the island.
  • GID is an ID that indicates logical switchers 1 to 4 (vision mixers)
  • LBID is an ID that indicates the ME box or cross point in one logical switcher. This is the logical box ID of the box.
  • the "PRI/SEC (Primary/Secondary)" item indicates whether each box in one logical switcher operates as a primary or a secondary.
  • the box with LBID: 1 always operates as the primary and plays the role of UI (User Interface) and management. Boxes with LBID: 2 to 5 operate as secondary, and operate under control from the primary.
  • the "System Manager” item indicates in which box the system manager is running. “Main” indicates the box that is currently running, and “Backup” indicates the box that the system manager will run in place of when the “Main” box fails.
  • the “Type” item indicates the device type. , and indicates whether it is an ME Box (ME Box) or a Cross Point Box (XPT Box).
  • the "Hostname” item indicates the host name given by the user to each device (ME box, crosspoint box, control panel).
  • the "IPv4 Address / Prefix Length” item indicates the network settings of each device.
  • the snow peak mark “*” is placed at the location where there has been a change from the previous setting.
  • the "Status” item indicates the error status and connection status of each device.
  • the “R” mark indicates a normal state.
  • a “R” mark indicates an abnormal state.
  • GID is an ID that indicates 1 to 4 logical switchers (vision mixers), and Panel ID belongs to one logical switcher (vision mixer). Logical ID of up to two control panels to be used.
  • the "Panel Name” item indicates the name given to the control panel by the user.
  • the "Line ID” item is a physical ID assigned to each column of the control panel, which is composed of multiple columns.
  • step ST11 the video signal format (resolution) of the logical switcher (vision mixer) set in step ST4 in the system manager menu described above is set.
  • FIGS. 25 and 26 show examples of UI displays corresponding to the format setting process in step ST11 described above.
  • FIG. 25 is an example of a UI display when the logical switcher (vision mixer) has a one-box configuration. In this case, since there are no restrictions on the format of the crosspoint box, the resolution, frame rate, reference, etc. of the video signal format of the logical switcher (vision mixer) can be freely set.
  • FIG. 26 is an example of a UI display when the logical switcher (vision mixer) has a multiple box configuration.
  • the resolution of the video signal format of the logical switcher (vision mixer) can be set.
  • the contents set in the cross point box setting process of step ST3 in the system manager menu described above are displayed.
  • step ST12 setup and preparation for program production of the logical switcher (vision mixer) are performed.
  • steps ST11 and ST12 of the vision mixer menu described above is repeated for the number of logical switchers (vision mixers) set in the logical switcher setting processing of step ST4 in the system manager menu described above.
  • FIG. 27 shows an example of a system change processing procedure. Similar to the initial system construction flow described above, this system change processing procedure also includes a system manager menu and a vision mixer menu following it.
  • step ST21 the frame rate, reference, and crosspoint box format in the video signal format, which are common settings within the island, are set.
  • the process in step ST21 is similar to the process in step ST3 in the flowchart of FIG. 15 (initial system construction flow).
  • step ST22 a maximum of five ME boxes and crosspoint boxes belonging to the island are assigned to one to four logical switchers (vision mixers). Further, in this step ST22, the control panel is assigned to one to four logical switchers (vision mixers).
  • the process in step ST22 is similar to the process in step ST4 in the flowchart of FIG. 15 (initial system construction flow).
  • step ST23 network settings for the control system network are performed for the control panel assigned to the logical switcher (vision mixer) in step ST22.
  • This process is performed when there is an increase in the number of logical switchers (vision mixers) in the process of step ST22.
  • the process in step ST23 is similar to the process in step ST5 in the flowchart of FIG. 15 (initial system construction flow) to configure the control system network for the control panel assigned to the logical switcher (vision mixer). .
  • the archive file includes a setup file and a content file.
  • the logical switcher (vision mixer) set in step ST22 will be constructed after executing the process in step ST26, which will be described later, and each logical switcher (vision mixer) will be constructed.
  • the specified package file (Package File) is automatically loaded into each logical switcher (vision mixer) at the first startup. This allows program production and operation to begin immediately after constructing each logical switcher (vision mixer).
  • FIG. 28 shows an example of a UI display corresponding to the package initial load process in step ST24 described above.
  • the "GID” item is an ID indicating logical switchers (vision mixers) 1 to 4.
  • the item "Init Setup Archive Filename” indicates the file name of the archive file of the logical switcher (vision mixer) that is stored in advance in the SSD of the system manager. When an archive file is specified, the setup file in the archive file is always imported into the primary ME box of the logical switcher (vision mixer).
  • the "Select” button by pressing this button, an archive file is selected from the SSD of the system manager.
  • the "Load Setup” item not only imports the setup file in the specified archive file to the primary ME box of the logical switcher (vision mixer), but also loads the setup to reflect the settings. This shows the operation panel for selecting on/off.
  • the "Import Content” item indicates the operation unit for selecting ON/OFF whether to import the content file in the specified archive file to the primary ME box of the logical switcher (vision mixer).
  • the "Load Content” item not only imports the content file in the specified archive file to the primary ME box of the logical switcher (vision mixer), but also loads the setup to reflect the settings. This shows the operation panel for selecting on/off.
  • the snow peak mark "*" is placed where there has been a change from the previous setting. Further, the mark “X in the circle” indicates an abnormal state in which the ME box, which is the file load destination, cannot be connected due to power off or the like.
  • step ST25 license assignment for each function is performed for up to five ME boxes and crosspoint boxes belonging to the island.
  • the process in step ST25 is similar to the process in step ST6 in the flowchart of FIG. 15 (initial system construction flow).
  • step ST26 the contents set in steps ST21 to ST25 are reflected in each device (ME box, crosspoint box, control panel), reboot is performed, and a new system is constructed.
  • the process in step ST26 is similar to the process in step ST7 in the flowchart of FIG. 15 (initial system construction flow).
  • step ST31 the video signal format (resolution) of the logical switcher (vision mixer) set in the logical switcher setting process of step ST22 in the system manager menu described above is set.
  • the process in step ST31 is similar to the process in step ST11 in the flowchart of FIG. 15 (initial system construction flow).
  • step ST32 setup and preparation for program production of the logical switcher (vision mixer) are performed.
  • the process in step ST32 is similar to the process in step ST12 in the flowchart of FIG. 15 (initial system construction flow).
  • steps ST31 and ST32 of the vision mixer menu described above is repeated for the number of logical switchers (vision mixers) set in the logical switcher setting processing of step ST22 in the system manager menu described above.
  • the present technology can also have the following configuration.
  • a signal receiving unit that receives video signals from multiple devices having a switcher signal processing function; a cross-point processing unit that aggregates and redistributes video signals received by the signal receiving unit to obtain video signals to the plurality of devices;
  • a signal processing device comprising: a signal transmitting section that transmits a video signal obtained by the cross-point processing section to the plurality of devices.
  • the signal receiving unit receives a multiplexed signal in which a plurality of video signals are multiplexed on at least one transmission line from the external device;
  • the signal processing device is compatible with 100G QSFP.
  • the transmission line is compatible with 100G QSFP.
  • a switcher system that has a minimum configuration that includes one first box that has a switcher signal processing function, and that can be expanded in scale by physically connecting a predetermined number of other boxes.
  • the other predetermined number of boxes aggregate and redistribute video signals from a plurality of devices having a switcher signal processing function, including at least the first box, and transmit the video signals to the plurality of devices.
  • the switcher system includes one second box that obtains the following.
  • a predetermined number of transmission lines are connected between the first box and the second box,
  • the switcher system according to any one of (6) to (10), wherein the transmission line transmits a multiplexed signal in which a plurality of video signals are multiplexed.
  • the second box has a signal receiving section that receives the multiplexed signal on the signal input side from the first box and performs a process of extracting individual video signals from the multiplexed signal, and
  • the switcher system according to any one of (6) to (13), wherein the first box is an ME box and the second box is a crosspoint box.
  • the predetermined number of boxes includes one first box having a switcher signal processing function, or a second box that aggregates and redistributes video signals from a plurality of devices having a signal processing function of a switcher including the first box and obtains video signals to the plurality of devices;
  • the logical switcher is configured to include one or more of the first boxes.
  • (16) The program according to (15), wherein the predetermined number of boxes exist as one group or as multiple groups.

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  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Signal Processing (AREA)
  • Studio Circuits (AREA)

Abstract

La présente invention facilite l'extension de l'échelle d'un mélangeur d'images (aiguilleur vidéo) après la construction d'un système de production vidéo. Une structure comprenant une instance d'un premier boîtier (boîtier ME) ayant une fonction de traitement de signal d'un aiguilleur est considérée comme étant une structure minimale. L'extension d'échelle est rendue possible par la connexion physique d'un nombre déterminé d'autres boîtiers. Le nombre déterminé d'autres boîtiers comprend, par exemple, une instance d'un deuxième boîtier (boîtier de point de convergence) qui agrège et redistribue des signaux vidéo provenant d'une pluralité de dispositifs, y compris au moins du premier boîtier, qui ont la fonction de traitement de signal de l'aiguilleur, afin d'obtenir des signaux vidéo pour la pluralité de dispositifs.
PCT/JP2023/029770 2022-09-05 2023-08-17 Dispositif de traitement de signal, système d'aiguilleur et programme associé WO2024053359A1 (fr)

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Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH01292976A (ja) * 1988-04-04 1989-11-27 Grass Valley Group Inc:The 映像スイッチャ装置
JPH07312723A (ja) * 1994-03-19 1995-11-28 Sony Corp 入出力切換装置及びマトリクススイツチヤ制御装置
JP2009206988A (ja) * 2008-02-28 2009-09-10 Sony Corp 放送用システムおよび放送用システムの表示制御方法
JP2009302893A (ja) * 2008-06-13 2009-12-24 Onkyo Corp 信号入出力装置及び信号伝送システム
WO2018021112A1 (fr) * 2016-07-27 2018-02-01 ソニー株式会社 Système de commande de dispositif de studio, procédé de commande pour système de commande de dispositif de studio et programme
JP2018082276A (ja) * 2016-11-15 2018-05-24 株式会社東芝 プレビューシステム、端末装置およびプレビュー方法
WO2022070249A1 (fr) * 2020-09-29 2022-04-07 日本電信電話株式会社 Système de traitement d'informations, dispositif de contrôle de retard, procédé de traitement d'informations et programme

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH01292976A (ja) * 1988-04-04 1989-11-27 Grass Valley Group Inc:The 映像スイッチャ装置
JPH07312723A (ja) * 1994-03-19 1995-11-28 Sony Corp 入出力切換装置及びマトリクススイツチヤ制御装置
JP2009206988A (ja) * 2008-02-28 2009-09-10 Sony Corp 放送用システムおよび放送用システムの表示制御方法
JP2009302893A (ja) * 2008-06-13 2009-12-24 Onkyo Corp 信号入出力装置及び信号伝送システム
WO2018021112A1 (fr) * 2016-07-27 2018-02-01 ソニー株式会社 Système de commande de dispositif de studio, procédé de commande pour système de commande de dispositif de studio et programme
JP2018082276A (ja) * 2016-11-15 2018-05-24 株式会社東芝 プレビューシステム、端末装置およびプレビュー方法
WO2022070249A1 (fr) * 2020-09-29 2022-04-07 日本電信電話株式会社 Système de traitement d'informations, dispositif de contrôle de retard, procédé de traitement d'informations et programme

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