JP2011044974A - Ancillary information display monitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem of a conventional ancillary information monitoring device that cannot extract and monitor only required items in a plurality of ancillary information items, and cannot grasp temporal changes and sequence thereof. <P>SOLUTION: An ancillary information display monitor includes a function for selecting a plurality of ancillary information items to be multiplexed with a video signal, converting the information items into waveforms, disposing the waveforms on the same time base, and simultaneously displaying them on one screen. Therefore, the plurality of ancillary information items are selected, converted into waveforms, disposed on the same time base and simultaneously displayed on one screen, thereby showing visual and real-time temporal changes and sequence thereof for the plurality of ancillary information items selected by a user. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a monitor having a function of converting a plurality of ancillary (auxiliary) information multiplexed on a video signal into a waveform, arranging them on a time axis and displaying them simultaneously on one screen.

  A conventional ancillary information monitoring device has a dedicated screen for each ancillary information, and it is possible to simultaneously monitor multiple ancillary information by the multi-screen display function of the device, but the dedicated screen for each ancillary information is a property In addition, information more than the items that the user wants to monitor is often displayed, and from the viewpoint of ease of viewing, there is an increasing demand for users to extract and monitor only a part of the plurality of ancillary information. Also, for TV stations, switching between the main part and CM is controlled by inter-station control, subtitles, audio, and multiple ancillary information, and each ancillary information did not change correctly or did not change in the correct order. If this happens, problems such as broadcast accidents may occur. When a problem occurs, the user needs to investigate the cause by going back to the time when the problem occurred using the log function of the ancillary information monitoring device.

Japanese Patent No. 3884016 JP 2002-314953 A

  However, it is difficult for a conventional ancillary information monitoring device to extract and monitor only necessary items for a plurality of ancillary information that a user wants to monitor, and to grasp each temporal change and its order. There was a problem.

  An object of the present invention is to solve the above-mentioned problem and to provide a monitor capable of visually grasping a change in time and the order of items necessary for a plurality of ancillary information in real time.

  In order to solve the above problems, the ancillary information display monitor of the present invention selects a plurality of ancillary information multiplexed on a video signal, converts it into a waveform, arranges it on the same time axis, and displays it simultaneously on one screen. It is characterized by having a function.

  According to the present invention, a plurality of ancillary information is selected, converted into a waveform, arranged on the same time axis, and simultaneously displayed on one screen. It is possible to grasp the order visually in real time.

  According to the present invention, it is possible to visually grasp a change in time and the order of a plurality of ancillary information in real time. It becomes possible to capture the moment when it happened, and it is not necessary to follow the history for investigating the cause, thereby reducing the burden on the user.

  The conventional technique will be described below with reference to FIG.

  The SDI signal 101 is input to the monitor 160 and converted into video data 105 by the converter circuit 103.

  The ancillary decoder circuit 107 extracts a plurality of ancillary data of the ancillary A data 120, the ancillary B data 122, the ancillary C data 124, and the ancillary D data 126 from the video data 105. These selections are performed by switch operation mounted on the monitor or ancillary information selection 175 from the PC control 170.

  Ancillary converter circuit 130 creates ancillary screen A data 135 from ancillary A data 120, creates ancillary screen B data 136 from ancillary B data 122, and creates ancillary screen C data 137 from ancillary C data 124, Ancillary screen D data 138 is created from the ancillary D data 126, and a plurality of screen display data are created.

  In the selector & scaler circuit 140, the ancillary screen A data 135, the ancillary screen B data 136, the ancillary screen C data 137, and the ancillary screen D data 138 are reduced and arranged to create screen data 145 and display it on the display 150.

  As described above, a plurality of ancillary information can be displayed on one screen. However, not all the plurality of ancillary information displayed on one screen is necessary information for the user.

  Next, a monitor display when the conventional technique is applied to a monitor will be described with reference to FIG.

  On the display 150, an ancillary screen A210, an ancillary screen B212, an ancillary screen C214, and an ancillary screen D216 are displayed at the same time, so that the user can obtain a plurality of ancillary information on one screen.

  However, not all of these are necessary information for the user. In some cases, the user needs to extract information necessary for the user from each ancillary screen and then comprehensively determine the information.

  Next, a case where the function of converting a plurality of ancillary information into a waveform and arranging it on the same time axis and displaying it on the screen according to the present invention is applied to a monitor will be described with reference to FIG.

  The SDI signal 101 is input to the monitor 160 and converted into video data 105 by the converter circuit 103.

  The ancillary decoder circuit 107 extracts a plurality of ancillary data of the ancillary A data 120, the ancillary B data 122, the ancillary C data 124, and the ancillary D data 126 from the video data 105. These selections are performed by switch operation on the monitor or ancillary information & item selection 330 from the PC control 170. Here, in addition to the selection of ancillary information, the necessary items are also selected.

  Ancillary waveform converter circuit 300 creates ancillary waveform A data 310 from ancillary A data 120, creates ancillary waveform B data 312 from ancillary B data 122, and creates ancillary waveform C data 314 from ancillary C data 124, Ancillary waveform D data 316 is created from the ancillary D data 126, and a plurality of waveform data is created.

  The waveform synthesis circuit 320 synthesizes the ancillary waveform A data 310, the ancillary waveform B data 312, the ancillary waveform C data 314, and the ancillary waveform D data 316 to create screen data 145 and display it on the display 150.

  As described above, necessary items of a plurality of ancillary information can be converted into waveform data and displayed on one screen.

  Next, screen display when a function of converting a plurality of ancillary information into a waveform and arranging it on the same time axis and displaying the screen is applied to a monitor will be described with reference to FIG.

  On the display 150, an ancillary waveform A400 that represents the trigger signal specified by the inter-broadcasting station control signal (ARIB STD-B39) and a CS that is specified by the digital subtitle data (ARIB STD-B37) are represented by waveforms. The ancillary waveform B410, the ancillary waveform C420 that represents the CM catch code (ARIB TR-B23), and the ancillary waveform D430 that represents the digital voice (BTA S-006B) are displayed on the same time axis 440. The

  An ancillary waveform A400 expresses “1” or “0” of the trigger signals (Q1 to Q25) in the packet of the inter-broadcast station control signal (ARIB STD-B39) as a waveform, and the trigger signal ( When Q1 to Q25) is “1”, the trigger flag 402 is set, and when it is “0”, the flag is not set. The rise of the trigger flag 402 is the same as the time when the trigger signal (Q1 to Q25) in the inter-broadcast station control signal (ARIB STD-B39) is detected, and visibility is improved by giving a certain range to the rise period. . The user can catch the moment when the selected trigger signal (Q1 to Q25) becomes ‘1’ by monitoring the trigger flag 402.

  An ancillary waveform B410 represents the presence / absence of control code CS (screen erase) in the packet of digital caption data (ARIB STD-B37) as a waveform, and when there is a control code CS (screen erase), a CS flag If 412 stands and does not, the flag does not stand. The rising edge of the CS flag 412 is the same as the time when the control code CS (screen erasure) in the packet of the digital subtitle data (ARIB STD-B37) is detected, and visibility is improved by giving a certain range to the rising period. . By monitoring the CS flag 412, the user can grasp the presence / absence of the control code CS (screen erase) and the moment when the control code CS (screen erase) is multiplexed.

  The ancillary waveform C420 expresses the presence / absence of packet multiplexing of the CM catch code (ARIB TR-B23) as a waveform. When the CM catch code is packet-multiplexed, the CM catch flag 422 is set and the packet is not multiplexed. In this case, no flag is set. The rise of the CM catch flag 422 is the same as the time when the packet multiplexing of the CM catch code (ARIB TR-B23) is detected, and visibility is improved by giving a certain range to the rise period. By monitoring the CM catch flag 422, the user can capture the moment when the CM catch code (ARIB TR-B23) is multiplexed.

  The ancillary waveform D430 represents the voice data (CH1 to CH16) in the packet of the digital voice (BTA S-006B) as a waveform, and the voice level obtained by sequentially level-converting the voice data (CH1 to CH16) selected by the user. Waveform 432 is plotted within audio level scale 434. The user can confirm the temporal change of the voice level of the selected voice data (CH1 to CH16) by monitoring the voice level waveform 432, and the voice level is appropriate by comparing with the voice level scale 434. Can be confirmed.

  The ancillary waveform displayed on the display 150 represents that it is past as it is plotted to the right of the time axis 440, and that it is closer to the present as it is plotted to the left of the time axis 440. Flows from left to right over time.

  As described above, the items selected by the user for a plurality of ancillary information are converted into waveform data that can be easily viewed and displayed on one screen with the same time axis. Changes and their order can be visually grasped in real time.

  Next, a case where a plurality of ancillary information in the present invention is converted into a waveform, arranged on the same time axis and displayed on the screen, and the function of adjusting the screen display time is applied to the monitor will be described with reference to FIG. .

  The SDI signal 101 is input to the monitor 160 and converted into video data 105 by the converter circuit 103.

  The ancillary decoder circuit 107 extracts a plurality of ancillary data of the ancillary A data 120, the ancillary B data 122, the ancillary C data 124, and the ancillary D data 126 from the video data 105. These selections are performed by switch operation on the monitor or ancillary information & item selection 330 from the PC control 170. Here, in addition to the selection of ancillary information, the necessary items are also selected.

  An ancillary waveform converter 300 sets a display time 500 as a waveform display time on one screen from a switch operation on the monitor or the PC control 170. Specifically, the display time 500 is a parameter for adjusting the number of samples of input ancillary data and the number of samples referred to for generating output waveform data. Compared to the case where the display time 500 is set to a waveform display time on an arbitrary screen, if the display time 500 is set to be shorter than this, the number of input ancillary data samples per unit time On the other hand, the number of samples referred to for generating the output waveform data takes a small value, so that the waveform data for one screen has a high resolution but the time that can be expressed is shortened. On the other hand, when the display time 500 is set to be longer than this, the number of samples referred to for output waveform data creation is larger than the number of samples of input ancillary data per unit time. The waveform data for one screen has a low resolution, but the time that can be expressed becomes long.

  After an ancillary waveform converter 300 sets the display time 500 from the switch operation on the monitor or the PC control 170, the ancillary waveform A data 310 is created from the ancillary A data 120, and the ancillary waveform B data 312 is created from the ancillary B data 122. Then, the ancillary waveform C data 314 is created from the ancillary C data 124, the ancillary waveform D data 316 is created from the ancillary D data 126, and a plurality of waveform data is created.

  The waveform synthesis circuit 320 synthesizes the ancillary waveform A data 310, the ancillary waveform B data 312, the ancillary waveform C data 314, and the ancillary waveform D data 316 to create screen data 145 and display it on the display 150.

  As described above, necessary items of a plurality of ancillary information are converted into waveform data and displayed on one screen, and the ancillary waveform display time on one screen can be adjusted.

  Next, the screen display when the function of adjusting the screen display time is applied will be described with reference to FIG. 6 by converting a plurality of ancillary information in the present invention into a waveform and arranging it on the same time axis for screen display. To do.

  The enlarged screen display 610 when the display time length is halved with respect to the screen display 600 when the display time is set to an arbitrary display time is obtained by expanding the enlarged portion 602 of the screen display 600 to one screen. It can be seen that the ancillary waveform for one screen has high resolution, but the time that can be expressed is short. As a result, the user can monitor in detail the order of changes in a plurality of ancillary waveforms and the change in waveform level.

  The reduced screen display 620 when the display time length is doubled with respect to the screen display 600 when the display time is set to an arbitrary display time, the entire screen display 600 is integrated into the reduction unit 622 of the screen display 620. It can be seen that the waveform data for one screen has a low resolution, but the time that can be expressed is long. As a result, the user can monitor changes in a plurality of ancillary waveforms over a long period of time.

  As described above, since the display time can be set and the shape of the ancillary waveform displayed on one screen can be adjusted, it is possible to display the screen according to the user's monitoring application.

  Next, FIG. 7 is used for a case where a plurality of ancillary information according to the present invention is converted into a waveform, arranged on the same time axis, displayed on the screen, and a flag is set when the time set by the user is applied to the monitor. Explain

  The SDI signal 101 is input to the monitor 160 and converted into video data 105 by the converter circuit 103.

  The ancillary decoder circuit 107 extracts a plurality of ancillary data of the ancillary A data 120, the ancillary B data 122, the ancillary C data 124, and the ancillary D data 126 from the video data 105. These selections are performed by switch operation on the monitor or ancillary information & item selection 330 from the PC control 170. Here, in addition to the selection of ancillary information, the necessary items are also selected.

  An ancillary & time waveform converter 704 sets a display time 500 from the switch operation on the monitor or the PC control 170, creates an ancillary waveform A data 310 from the ancillary A data 120, and creates an ancillary waveform B data 312 from the ancillary B data 122. Are created, ancillary waveform C data 314 is created from the ancillary C data 124, ancillary waveform D data 316 is created from the ancillary D data 126, and a plurality of waveform data is created.

  Clock information 701 from the internal clock 700 is converted into clock data 703 by the clock information converter 702 and input to the ancillary & time waveform converter circuit 704. An ancillary & time waveform converter circuit 704 sets a time setting 710 from a switch operation or PC control 170 mounted on a monitor, and converts a time period in which the time setting 710 and the clock data 703 coincide with each other into time waveform data 705.

  In the waveform synthesis circuit 320, the ancillary waveform A data 310, the ancillary waveform B data 312, the ancillary waveform C data 314, the ancillary waveform D data 316, and the time waveform data 705 are synthesized to generate screen data 145 and display it on the display 150. .

  As described above, the necessary items of the plurality of ancillary information and the period that the user wants to monitor can be converted into waveform data and displayed on one screen. Further, by replacing the time information 701 from the internal clock 700 with a time code multiplexed on the SDI signal 101, or acquiring it from the outside, more general monitoring is possible.

  Next, a screen display when a plurality of ancillary information according to the present invention is converted into a waveform, arranged on the same time axis and displayed on the screen, and a function for setting a flag when the time set by the user comes, is applied to the monitor. 8 will be used for explanation.

  The display 150 includes a monitor waveform 800 that represents the time that the user wants to monitor, an ancillary waveform A400 that represents the trigger signal defined by the inter-broadcast station control signal (ARIB STD-B39), and digital subtitle data ( Ancillary waveform B410 expressing CS defined by ARIB STD-B37), ancillary waveform C420 expressing CM catch code (ARIB TR-B23), and digital speech (BTA S-006B) An ancillary waveform D430 is displayed with the same time axis 440.

  The monitoring waveform 800 expresses whether or not it is the time that the user wants to monitor. The monitoring flag 801 is set when the time set by the user is reached, and the flag is not set otherwise.

  The user can arbitrarily set the time to be monitored, and the set time is displayed as a start time 802 at the rising edge of the flag. The user can also set the time to be monitored with a range, in which case the start time 802 is displayed at the rising point of the flag and the end time 803 is displayed at the falling point.

  The monitored waveform and ancillary waveform displayed on the display 150 are expressed as being past as they are plotted to the right of the time axis 440, and are expressed as being closer to the present as they are plotted to the left of the time axis 440. The monitoring waveform and the ancillary waveform flow from left to right as time passes.

  As described above, the time that the user wants to monitor and a plurality of ancillary information are converted into waveform data and displayed on one screen with the same time axis, so the temporal changes in the plurality of ancillary information at the time that the user wants to monitor It is possible to visually grasp the order in real time.

  Next, a case where a plurality of ancillary information according to the present invention is converted into a waveform, arranged on the same time axis, displayed on the screen, and the function of capturing the display screen when the time set by the user comes, is applied to the monitor. Will be described.

  The SDI signal 101 is input to the monitor 160 and converted into video data 105 by the converter circuit 103.

  The ancillary decoder circuit 107 extracts a plurality of ancillary data of the ancillary A data 120, the ancillary B data 122, the ancillary C data 124, and the ancillary D data 126 from the video data 105. These selections are performed by switch operation on the monitor or ancillary information & item selection 330 from the PC control 170. Here, in addition to the selection of ancillary information, the necessary items are also selected.

  An ancillary & time waveform converter 704 sets a display time 500 from the switch operation on the monitor or the PC control 170, creates an ancillary waveform A data 310 from the ancillary A data 120, and creates an ancillary waveform B data 312 from the ancillary B data 122. Are created, ancillary waveform C data 314 is created from the ancillary C data 124, ancillary waveform D data 316 is created from the ancillary D data 126, and a plurality of waveform data is created.

  Clock information 701 from the internal clock 700 is converted into clock data 703 by the clock information converter 702 and input to the ancillary & time waveform converter circuit 704. An ancillary & time waveform converter circuit 704 sets a time setting 710 from a monitor switch operation or PC control 170, and converts a time period in which the time setting 710 and the clock data 703 coincide with each other into time waveform data 705.

  The waveform synthesis circuit 320 synthesizes the ancillary waveform A data 310, the ancillary waveform B data 312, the ancillary waveform C data 314, the ancillary waveform D data 316, and the time waveform data 705 to create screen data 145.

  Clock information 701 from the internal clock 700 is input to the memory controller 901, and when the time set by the user (including the current time) comes, the screen data 145 is converted into internal memory data 902 and stored in the internal memory 903. The user can select data stored in the internal memory 903 and screen data 145 that changes in real time, and displays the selected screen display data 904 on the display 150. In addition, the memory controller 901 can convert data stored in the internal memory 903 into external memory data 905 and store it in the external memory 906. These controls are performed by switch operation on the monitor or by memory control & video switching 900 from the PC control 170.

  As described above, it is possible to convert the necessary items of multiple ancillary information and the period that the user wants to monitor into waveform data and display it on one screen, and save the display screen data of the time that the user wants to monitor in the internal memory. It can be used for later confirmation work, and it can be saved in an external memory to carry the display screen data. Data sharing between monitors proposed in the present invention and report editing by PC editing can be performed. It can also be used for creation and the like.

It is a block diagram of the monitor by a prior art. It is a screen display figure of the monitor by a prior art. It is a block diagram for displaying the ancillary waveform by this invention. It is a screen display figure at the time of applying the function to display an ancillary waveform by the present invention. It is a block diagram for adjusting the screen display time of the ancillary waveform according to the present invention. It is a screen display figure at the time of applying the function which adjusts the screen display time of the ancillary waveform by this invention. FIG. 5 is a block diagram for setting a flag at a time that a user wants to monitor according to the present invention. It is a screen display figure at the time of applying the function which sets a flag at the time which the user wants to monitor by the present invention. FIG. 6 is a block diagram for capturing a display screen at a time that a user wants to monitor according to the present invention.

101 SDI signal 103 converter 105 video data 107 ancillary decoder 120, 122, 124, 126 ancillary data 145 image data 150 display 170 switch scan or PC control 210, 212, 214, 216 ancillary screen 300 ancillary waveform converter 310, 312 314,316 Ancillary waveform data 320 Waveform synthesis 330 Ancillary information & item selection 400 Ancillary waveform A
402 Trigger flag 410 Ancillary waveform B
412 CS flag 420 Ancillary waveform C
422 CM catch flag 430 Ancillary waveform D
432 Audio level waveform 434 Audio level scale 440 Time axis 500 Display time 600 Screen display 602 Expansion unit 610 Expansion screen display 620 Reduction screen display 622 Reduction unit 700 Internal clock 701 Time information 702 Clock information converter 703 Clock data 704 Ancillary & time waveform converter 705 Time waveform data 710 Time setting 800 Monitoring waveform 801 Monitoring flag 802 Start time 803 End time 900 Memory control & video switching 901 Memory controller 902 Internal memory data 903 Internal memory 904 Screen display data 905 External memory data 906 External memory

Claims (5)

  In a video signal display monitor, a means for selecting a plurality of ancillary information multiplexed on a video signal, a means for converting ancillary data into an ancillary waveform, and a selection waveform arranged on the same time axis as one screen as image data A monitor characterized by having an ancillary information display function including means for displaying inside.   2. The monitor according to claim 1, wherein in the ancillary information display function, the ancillary information selection means is a switch mounted on the monitor or an external PC.   The monitor according to claim 1, wherein the ancillary information display function can arbitrarily change a display time range.   4. The monitor according to claim 1, wherein the ancillary information display function allows a user to set a monitoring time and sets a confirmation flag on the screen when the set time comes.   The monitor according to claim 1, 2, 3, or 4, wherein the ancillary information display function can capture a display screen when a set time comes.