JP2024035958A - Broadcasting station maintenance work support system, AR display device, performance hall and broadcasting station - Google Patents

Abstract

The present invention provides a broadcasting station maintenance work support system that can utilize existing terrestrial digital broadcasting equipment. A performance hall 10 includes an AC area multiplexing device 13 that multiplexes monitoring information into an ISDB-T AC area, and an STL device 14 that transmits a broadcast signal multiplexed with monitoring information to a broadcasting station 20. , the broadcast station 20 includes an STL device 21 that receives a broadcast signal multiplexed with monitoring information from the performance hall 10, and a broadcaster 22 that broadcasts the broadcast signal via a transmission antenna 30, and an AR display device 40. uses the monitoring information of the AC area to display maintenance work support information of the broadcasting station 20 in AR. [Selection diagram] Figure 1

Description

The present invention relates to a broadcasting station maintenance work support system.

In recent years, systems and technology applications related to augmented reality (AR) have been developed. For example, Patent Documents 1 and 2 propose a maintenance work support system that uses an AR display device to support maintenance work on equipment in a factory or the like.

Furthermore, the ISDB-T (Integrated Services Digital Broadcasting for Terrestrial Television Broadcasting) system is adopted as a terrestrial digital broadcasting system in Japan (Non-Patent Document 1). In the ISDB-T system, in addition to carriers that transmit video and audio, there is an auxiliary information channel (AC) carrier that can transmit data such as emergency earthquake information. Patent Document 3 proposes a conventional technique that utilizes an AC carrier to measure delay time between broadcasting stations. The AC carrier is DBPSK (Differential Binary Phase Shift Keying) modulated, and can be demodulated even in a low C/N reception environment compared to a 64QAM (Quadrature Amplitude Modulation) modulated carrier for video and audio transmission.

Japanese Patent Application Publication No. 2020-170249 Japanese Patent Application Publication No. 2018-181232 Japanese Patent Application Publication No. 2006-14140

“Terrestrial digital television broadcasting transmission method standard” ARIB STD-B31

Conventional maintenance work support systems use IP lines to transmit the monitoring information of the monitored target from the server where the monitoring information is stored to the AR display device. is transmitted over an IP line such as a LAN (Local Area Network).

When this configuration is applied to maintenance work at a broadcasting station, there are problems as described below. When installing a new dedicated IP line such as a VPN (Virtual Private Network) from a performance venue to a broadcasting station, the line installation and operation costs are high. Furthermore, if an existing IP line is used, monitoring information of broadcasting equipment will be transmitted over a public IP line such as the Internet, which poses a security risk. In order to realize a low-cost, high-security maintenance work support system, it is considered important to utilize existing terrestrial digital broadcasting equipment.

Therefore, an object of the present invention is to provide a broadcasting station maintenance work support system, an AR display device, a performance hall, and a broadcasting station that can utilize existing terrestrial digital broadcasting equipment.

In order to solve the above problems, a broadcasting station maintenance work support system according to the present invention is configured to support maintenance work at a broadcasting station with an AR display device using monitoring information transmitted from a performance hall.

According to this configuration, the performance hall transmits broadcast signals containing video and audio through an AC area multiplexing device that multiplexes monitoring information of the broadcasting station into an ISDB-T AC area, and a dedicated wireless line. A transmitting device that transmits a broadcast signal multiplexed with monitoring information to a broadcasting station.
In addition, the broadcasting station has a receiving device that receives broadcast signals multiplexed with monitoring information from the performance hall via a dedicated wireless line, and a transmitting antenna that modulates the broadcast signal received by the receiving device using the ISDB-T method. and a broadcaster that broadcasts a modulated broadcast signal through the transmitter.
Further, the AR display device demodulates the broadcast signal broadcast by the broadcaster and uses the monitoring information multiplexed in the AC area to display maintenance work support information of the broadcasting station in AR.

Additionally, the broadcasting station is equipped with an AC demodulator that receives and demodulates the broadcast signal broadcast by the broadcaster via the receiving antenna, and outputs the monitoring information multiplexed in the AC area to the AR display device via the communication line. may be provided. In this case, the AR display device receives monitoring information from the AC demodulator via the communication line, and uses the received monitoring information to display maintenance work support information of the broadcasting station in AR.

In this way, in the broadcasting station maintenance work support system, existing terrestrial digital broadcasting equipment can be used in addition to the AC area multiplexing device in the performance hall and the AC demodulation device in the broadcasting station, so line installation costs and operating costs can be suppressed. Furthermore, in the broadcasting station maintenance work support system, since monitoring information is not transmitted over public IP lines from the performance venue to the broadcasting venue, security risks can also be suppressed.

According to the present invention, by utilizing existing terrestrial digital broadcasting equipment, it is possible to adopt a transmission method for realizing a low-cost, high-security broadcasting station maintenance work support system.

FIG. 1 is a block diagram showing the configuration of a broadcasting station maintenance work support system according to a first embodiment. FIG. 2 is an explanatory diagram illustrating a redundant configuration of a broadcasting station in the first embodiment. FIG. 2 is an explanatory diagram illustrating an example of a data structure of monitoring information in the first embodiment. FIG. 2 is an explanatory diagram illustrating an example of a broadcasting station ID in the first embodiment. FIG. 2 is an explanatory diagram illustrating an example of monitoring target ON/OFF information in the first embodiment. FIG. 2 is an explanatory diagram illustrating AR virtual care in the first embodiment. FIG. 3 is an explanatory diagram illustrating AR device information display in the first embodiment. FIG. 2 is an explanatory diagram illustrating AR operation support in the first embodiment. 2 is a sequence diagram showing the operation of the broadcast station maintenance work support system of FIG. 1. FIG. FIG. 2 is a block diagram showing the configuration of a broadcasting station maintenance work support system according to a second embodiment. 11 is a sequence diagram showing the operation of the broadcasting station maintenance work support system of FIG. 10. FIG. 3 is a block diagram showing the configuration of a broadcasting station maintenance work support system according to Modification 1. FIG.

Hereinafter, each embodiment of the present invention will be described with reference to the drawings. However, each embodiment described below is for embodying the technical idea of the present invention, and unless there is a specific description, the present invention is not limited to the following. Further, the same means may be denoted by the same reference numerals, and the description thereof may be omitted.

(First embodiment)
[Overview of broadcasting station maintenance work support system]
Referring to FIG. 1, an overview of a broadcasting station maintenance work support system 1 according to a first embodiment will be described.
As shown in FIG. 1, a broadcasting station maintenance work support system 1 supports maintenance work of a broadcasting station 20 using an AR display device 40 using monitoring information transmitted from a performance hall 10. It includes equipment 2 and an AR display device 40.

<Terrestrial digital broadcasting equipment>
The terrestrial digital broadcasting equipment 2 is general broadcasting equipment used in terrestrial digital broadcasting, and includes, for example, a performance hall 10, a broadcasting station 20, and a transmission antenna 30.
The performance hall 10 is a general performance hall that transmits a broadcast signal containing video and audio to a broadcasting hall 20. Furthermore, the performance hall 10 multiplexes monitoring information, which will be described later, onto the broadcast signal in order to support maintenance work of the broadcasting hall 20.
The broadcast station 20 is a general broadcast station that broadcasts the broadcast signal from the performance hall 10 using terrestrial digital broadcast waves. Although one broadcasting station 20 is illustrated in FIG. 1, there may be a plurality of broadcasting stations 20.
The transmitting antenna 30 is a general antenna (for example, a UHF antenna) for broadcasting digital terrestrial broadcast waves.

Here, the performance hall 10 and the broadcasting station 20 are connected via a dedicated wireless line owned by the broadcasting station. Examples of this dedicated wireless line include an STL (Studio to Transmitter Link) 50 and a TSL (Transmitter to Studio Link) 51.

<AR display device>
The AR display device 40 supports maintenance work at the broadcasting station 20 through AR display using monitoring information multiplexed with broadcast signals. For example, the AR display device 40 may include AR glasses worn on the head of a worker who performs maintenance work on the broadcasting station 20. Then, the AR display device 40 uses the monitoring information to perform maintenance work support such as AR virtual care, AR device information display, and AR operation support. The details of these maintenance work supports will be described later.

[Configuration of broadcasting station maintenance work support system]
<Performance hall>
The configuration of the broadcasting station maintenance work support system 1 will be specifically explained below.
As shown in FIG. 1, the performance hall 10 includes an operation device 11, a monitoring and control device 12, an AC area multiplexing device 13, an STL device (transmission device) 14, and a TSL device 15. It goes without saying that each means other than the AC area multiplexing device 13 is common and is not limited to the following.

The operation device 11 sends out a broadcast signal of a program consisting of video and audio in a broadcast TS (Transport Stream) format to the AC area multiplexing device 13 based on the time of a preset program schedule.

The monitoring control device 12 monitors and controls a monitoring target of the broadcasting station 20, which will be described later. In this embodiment, the monitoring control device 12 outputs monitoring information of the broadcasting station 20 to the AC area multiplexing device 13. Here, the monitoring and controlling device 12 of the performance hall 10 and the monitoring and controlling device 23 of the broadcasting place 20 are configured to form a pair. Further, the monitoring control device 12 can remotely control the monitoring target of the broadcasting station 20. For example, the supervisory control device 12 can remotely control switching between an active system and a standby system, and turn on/off the power.

Note that the monitoring target of the broadcasting station 20 refers to a device that is placed in the broadcasting station 20 and is a target of monitoring and control by the monitoring and control device 12. For example, the targets to be monitored by the broadcasting station 20 include the STL device 21 and the broadcasting machine 22 of the broadcasting station 20.
Further, details of the monitoring information of the broadcasting station 20 will be described later.

The AC area multiplexing device 13 multiplexes the monitoring information of the broadcasting station 20 into the AC area of the ISDB-T system with respect to the broadcast signal including video and audio. In this embodiment, the AC area multiplexing device 13 multiplexes the monitoring information input from the monitoring control device 12 onto the AC area of the broadcast signal input from the operation device 11. Then, the monitoring control device 12 outputs a broadcast signal multiplexed with monitoring information to the STL device 14.

The STL device 14 transmits a broadcast signal multiplexed with monitoring information to the broadcast station 20 via a dedicated wireless line (STL 50). Here, the STL device 14 has a redundant configuration of an active system and a standby system. Further, the STL device 14 of the performance hall 10 and the STL device 21 of the broadcasting place 20 are configured to form a pair.

The TSL device 15 receives sent back monitoring information from the broadcasting station 20 via a dedicated wireless line (TSL 51). The TSL device 15 then outputs the sent back monitoring information to the monitoring control device 12. For example, the sent back monitoring information is used by the monitoring and control device 12 to remotely monitor and control the broadcasting station 20 when the broadcasting station 20 is unmanned. Here, the TSL device 15 of the performance hall 10 and the TSL device 24 of the broadcasting place 20 are configured to form a pair. Note that, like the STL device 14, the TSL device 15 may have a redundant configuration of an active system and a standby system (not shown).

<Broadcast station>
As shown in FIG. 1, the broadcast station 20 includes an STL device (receiving device) 21, a broadcaster 22, a monitoring control device 23, and a TSL device 24. Note that the broadcasting station 20 is a general one, and it goes without saying that it is not limited to the following.

The STL device 21 receives a broadcast signal multiplexed with monitoring information from the performance hall 10 via a dedicated wireless line (STL 50). Then, the STL device 21 outputs the received broadcast signal to the broadcaster 22.

The broadcaster 22 modulates the broadcast signal received by the STL device 21 using the ISDB-T method, and broadcasts the modulated broadcast signal via the transmitting antenna 30. That is, the broadcaster 22 broadcasts a broadcast signal multiplexed with monitoring information to the AR display device 40 in addition to a general broadcast receiver (not shown). Further, the broadcaster 22 separates the monitoring information multiplexed into the broadcast signal and outputs the separated monitoring information to the monitoring control device 23.

The monitoring control device 23 monitors and controls monitoring targets such as the STL device 21 and the broadcasting device 22.
In addition, the monitoring control device 23 receives a message from _each monitoring target _of the broadcasting station _{20 (} in the example of FIG. A state such as "0" representing "0" is input. Then, the monitoring control device 23 generates monitoring information representing the state of each monitored object, and transmits the generated monitoring information to the monitoring control device 12 via the dedicated wireless line (TSL 51).

The TSL device 24 transmits monitoring information from the monitoring and control device 23 to the performance hall 10 via a dedicated wireless line (TSL 51). Note that, like the STL device 21, the TSL device 24 may have a redundant configuration of an active system and a standby system (not shown).

As described above, the broadcasting station 20 has a redundant configuration in which the STL device 21 and the broadcasting machine 22 are configured. As shown in FIG. 2, the broadcasting station 20 includes two STL devices 21 ₁ and 21 ₂ and two broadcasting machines 22 ₁ and 22 ₂ . Then, one of the two STL devices 21 ₁ and 21 ₂ operates as an active system, and the other stands by as a standby system. Further, one of the two broadcasting machines 22 ₁ and 22 ₂ operates as an active system, and the other stands by as a standby system. For example, the STL device 21 ₁ and the broadcaster 22 ₁ become the active system, and the STL device 21 ₂ and the broadcaster 22 ₂ become the backup system.

<AR display device>
The AR display device 40 demodulates the broadcast signal broadcast by the broadcaster 22 and displays maintenance work support information of the broadcasting station 20 in AR using the monitoring information multiplexed in the AC area. This maintenance work support information is information related to support for maintenance work of the broadcasting station 20. For example, the AR display device 40 may be an AR glass that has a tuner function for digital terrestrial broadcasting, and is equipped with a function to separate monitoring information of broadcast signals and a function to support maintenance work of the broadcasting station 20. .

As described above, the broadcasting station maintenance work support system 1 can transmit monitoring information to the AR display device 40 using existing digital terrestrial broadcasting equipment without using a public IP line.

<<Monitoring information>>
The monitoring information will be specifically explained below assuming that the transmission method complies with ARIB STD-B31 (ISDB-T).

First, a method of multiplexing monitoring information into an AC area (AC channel) will be described.
Of the 13 segments (0 to 12 segments) of OFDM (Orthogonal Frequency Division Multiplexing), the AC region of segment 11 is used to measure the delay time between each broadcasting station. Furthermore, the use of the AC area of segment 0 for transmission of earthquake early warnings is being considered. Currently, AC areas other than segments 0 and 11 are not used and can be used for transmitting monitoring information. An example of multiplexing monitoring information into the AC area of segment 12 will be shown below.

There are two types of segments: synchronous segments and differential segments. Furthermore, there are two types of AC: AC1 and AC2. AC1 is a carrier common to both the synchronous segment configuration and the differential segment configuration. AC2 is a carrier having only a differential segment configuration. For example, in the case of mode 3, there are eight AC1s in the synchronous segment, eight ACls, and 19 AC2s in the differential segment. There are eight AC carriers in segment 12, which is a synchronous segment. Further, one AC carrier has 204 bits. Therefore, when using the AC carrier of segment 12, data transmission of 204×8=1624 bits per frame is possible.

3 to 5 illustrate examples of data structures of the monitoring information 100.
As shown in FIG. 3, the monitoring information 100 includes a broadcast station ID and monitoring target ON/OFF information (monitoring target information). Furthermore, the monitoring information 100 includes standards for differential demodulation and configuration identification.

The standard for differential demodulation is 1-bit length data, which is treated as a parity bit (located at the 0th bit). For example, the differential demodulation standard is set to "0" or "1" in accordance with the ISDB-T (ARIB STD-B31) standard.

The configuration identification is 3-bit data (located at bits 1-3). For example, in accordance with the ISDB-T (ARIB STD-B31) standard, the configuration identification is set to "000" for highly reliable data transmission, and to "111" for data transmission with little delay time.

The broadcasting station ID represents identification information of the broadcasting station 20. The monitoring target ON/OFF information indicates whether each monitoring target, which is preset for each broadcasting station 20, is in use or not. Here, in the monitoring information 100, 8-bit length broadcasting station IDs and 32-bit length monitoring target ON/OFF information are repeatedly set for a total of five stations, "Broadcasting Station 1" to "Broadcasting Station 5." .

As the broadcasting station ID, a unique ID is set for each broadcasting station. FIG. 4 illustrates an example of a broadcasting station ID. In the example of FIG. 4, the broadcasting station ID "00000001" represents "broadcasting station 1 (Seto Broadcasting Station)", the broadcasting station ID "00000010" represents "broadcasting station 2 (Higashiyama Broadcasting Station)", and the broadcasting station ID " 00000011” represents broadcasting station 3 “(Nabeta Broadcasting Station)”. Since the broadcasting station ID is 8 bits, a total of 256 broadcasting station IDs can be registered.

FIG. 5 illustrates an example of monitoring target ON/OFF information. In the example of FIG. 5, a monitoring target is assigned to each bit of the monitoring target ON/OFF information. Each bit of the monitoring target ON/OFF information is "1" when the monitoring target is in use, and is "0" when the monitoring target is not in use.

For example, the 0th bit of the monitoring target ON/OFF information is assigned to the first STL device _21-1 , and the 1st bit is assigned to the second STL device _21-2 . Further, the second bit of the monitoring target ON/OFF information is assigned to the first broadcasting device ₂₂₁ , and the third bit is assigned to the second broadcasting device ₂₂₂ . Here, consider a case where the STL device 21 ₁ and the broadcaster 22 ₁ are the active system, and the STL device 21 ₂ and the broadcaster 22 ₂ are the backup system. In this case, the 0th bit of the monitoring target ON/OFF information corresponds to the active STL device _21-1 , so it is "1" when it is in use, and the 1st bit corresponds to the backup STL device _21-2 , so it is "1" when it is not in use. 0". In addition, the second bit of the monitoring target ON/OFF information corresponds to the active broadcaster _22-1 , so it is "1" when it is in use, and the third bit corresponds to the backup-system broadcaster _22-2 , so it is "0" when it is not in use. ”. Since the monitoring target ON/OFF information is 32 bits, a maximum of 32 monitoring targets can be registered per one broadcasting station 20.

Since the AC area is 204 bits, monitoring information for five broadcasting stations 20 can be stored in one AC area. Moreover, monitoring information for 40 broadcasting stations 20 can be stored in one OFDM frame. Since the same monitoring information is repeatedly transmitted in each OFDM frame, the AR display device 40 that receives this monitoring signal can always use the monitoring information of the broadcasting station 20. Furthermore, since the monitoring information is multiplexed onto unused segments of the broadcast signal, no problems will occur in existing broadcast receivers that receive this broadcast signal.

Note that the data structure of the monitoring information shown in FIGS. 3 to 5 is an example, and it goes without saying that the data structure is not limited thereto. In other words, the data structure of the monitoring information can be changed arbitrarily depending on the operation mode of each business operator.

<<Maintenance work support function>>
An example of the maintenance work support function will be described below.
As described above, this maintenance work support function includes AR virtual care, AR device information display, and AR operation support, which will be explained in order.

AR virtual curing is a function of virtually masking (curing) the monitoring target being used by the AR display device 40 worn by the worker. In this case, virtual masking corresponds to maintenance work support information. That is, the AR display device 40 refers to the monitoring target information and virtually masks the monitoring target in use as an AR display of maintenance work support information. Specifically, the AR display device 40 refers to the monitoring target ON/OFF information of the broadcasting station 20 where the worker is performing maintenance work, and displays the QR code ( Virtual curing is performed using markers such as (registered trademark) as a reference. As shown in FIG. 6, the AR display device 40 displays the operation panels of the active STL device 21 ₁ and the broadcaster 22 ₁ in red semi-transparent AR, while the backup STL device 21 ₂ and the broadcaster 22 ₂ display the operation panel as is. Thereby, in the broadcasting station maintenance work support system 1, it is possible to suppress the situation in which the operator mistakenly operates the monitoring target of the usage collection.

The AR device information display is a function that allows an operator to check an explanatory document to be monitored using the AR display device 40 worn by the worker. Specifically, the AR display device 40 displays the explanatory document to be monitored in AR based on the result of the AR virtual care. As shown in FIG. 7, when the operator specifies the STL device 21 ₁ on the operation interface (not shown) of the AR display device 40, the AR display device 40 displays an explanation next to the operation panel of the STL device 21 ₁ . A document 200 (for example, an instruction manual, a completed drawing) is displayed in AR. As a result, the broadcasting station maintenance work support system 1 can reduce the effort required by the operator to search for paper explanatory documents. Note that this AR device information display does not refer to monitoring information.

AR operation support is a function that allows the operator to check the operation procedure of the monitored object using the AR display device 40 worn by the operator. At this time, since operating the active system may affect broadcasting, only the backup system may be maintained and inspected. Therefore, monitoring information is used to specify the monitoring target for which operating procedures should be presented. That is, the AR display device 40 refers to the monitoring target information and displays the operating procedure only for unused monitoring targets. In this case, the operation procedure to be monitored corresponds to maintenance work support information. As shown in FIG. 8, the AR display device 40 refers to the monitoring target ON/OFF information of the broadcasting station 20 where the operator is performing maintenance work, and selects only the monitoring target that is unused as "0" for maintenance work. Display operating procedures and confirmation procedures for work in AR. For example, when a worker specifies the broadcaster 22 ₂ on the operation interface of the AR display device 40 , the AR display device 40 displays operating procedures and confirmation procedures for maintenance work in AR because the broadcaster 22 ₂ is a backup system. do. In the example of FIG. 8, the AR display device 40 displays in AR a confirmation procedure 300 "Check ○○ of QPSK modulator" above the operation panel of the broadcaster ₂₂₂ . Thereby, in the broadcasting station maintenance work support system 1, the operator can efficiently perform maintenance work.

Note that the maintenance work support functions described in FIGS. 6 to 8 are merely examples, and it goes without saying that the present invention is not limited thereto.

[Operation of broadcasting station maintenance work support system]
Referring to FIG. 9, the operation of the broadcasting station maintenance work support system 1 will be explained.
As shown in FIG. 9, in step S1, the operation device 11 of the performance hall 10 sends a broadcast signal in the broadcast TS format to the AC area multiplexing device 13 based on the time of a preset program schedule.
In step S2, the monitoring control device 12 outputs the monitoring information of the broadcasting station 20 to the AC area multiplexing device 13.
In step S3, the AC area multiplexing device 13 multiplexes the monitoring information into the ISDB-T AC area with respect to the broadcast signal including video and audio.

In step S4, the STL device 14 transmits a broadcast signal multiplexed with monitoring information to the broadcasting station 20 via a dedicated wireless line. Then, the STL device 21 of the broadcasting station 20 receives the broadcast signal multiplexed with monitoring information from the performance hall 10 via the dedicated wireless line.

In step S5, the broadcaster 22 modulates the broadcast signal received in step S4 using the ISDB-T method.
In step S6, the broadcaster 22 broadcasts the broadcast signal modulated in step S5 via the transmitting antenna 30.

In step S7, the AR display device 40 demodulates the broadcast signal broadcast by the broadcaster 22.
In step S8, the AR display device 40 acquires the monitoring information multiplexed in the AC region of the broadcast signal demodulated in step S7.
In step S9, the AR display device 40 uses the monitoring information acquired in step S9 to display maintenance work support information for the broadcasting station 20B in AR.

[Action/Effect]
As described above, by utilizing the existing digital terrestrial broadcasting equipment 2, it is possible to adopt a transmission method for realizing a low-cost, high-security broadcasting station maintenance work support system 1.
That is, since the broadcasting station maintenance work support system 1 can transmit the monitoring information necessary for maintenance work support using the existing digital terrestrial broadcasting equipment 2, the cost is lower than when a new dedicated IP line is installed. Furthermore, since the broadcasting station maintenance work support system 1 can transmit monitoring information over a dedicated wireless line (for example, STL50) that requires a license, it has higher security than when using a public IP line such as the Internet. Furthermore, the broadcasting station maintenance work support system 1 does not require any changes to the broadcasting main line equipment of the broadcasting station 20, so it is easy to introduce.

(Second embodiment)
[Configuration of broadcasting station maintenance work support system]
With reference to FIG. 10, the configuration of a broadcasting station maintenance work support system 1B according to the second embodiment will be mainly described with respect to the differences from the first embodiment.

In the broadcasting station maintenance work support system 1 shown in FIG. 1, monitoring information is transmitted from the broadcasting station 20 to the AR display device 40 using terrestrial digital broadcast waves. On the other hand, the broadcasting station maintenance work support system 1B shown in FIG. 10 differs from the first embodiment in that monitoring information is transmitted from the broadcasting station 20 to the AR display device 40 using the communication line 52.

As shown in FIG. 10, the broadcasting station maintenance work support system 1B supports maintenance work at the broadcasting station 20B with an AR display device 40B using monitoring information transmitted from the performance hall 10. It includes equipment 2B and an AR display device 40B.

<Terrestrial digital broadcasting equipment>
The terrestrial digital broadcasting equipment 2B is general broadcasting equipment used in terrestrial digital broadcasting, and includes, for example, a performance hall 10, a broadcasting station 20B, a transmitting antenna 30, and a receiving antenna 60. Note that the performance hall 10 and the transmitting antenna 30 are the same as those in the first embodiment, so a description thereof will be omitted.

The broadcasting station 20B is a general performance venue that broadcasts the broadcast signal from the performance venue 10 using terrestrial digital broadcast waves. Although one broadcasting station 20B is illustrated in FIG. 10, there may be a plurality of broadcasting stations 20B.

As shown in FIG. 10, the broadcast station 20B includes an STL device (receiving device) 21, a broadcaster 22, a supervisory control device 23, a TSL device 24, and an AC demodulator 25. Note that each means other than the AC demodulator 25 is the same as in the first embodiment, and therefore a description thereof will be omitted.

The AC demodulator 25 receives and demodulates the broadcast signal broadcast by the broadcaster 22 via the receiving antenna 60, and outputs the monitoring information multiplexed in the AC area to the AR display device 40 via the communication line 52. It is something to do. That is, the AC demodulator 25 separates the monitoring information multiplexed into the broadcast signal and outputs the separated monitoring information to the AR display device 40.

The receiving antenna 60 is a general antenna (for example, a UHF antenna) for receiving terrestrial digital broadcast waves. For example, as the receiving antenna 60, one installed at each broadcasting station 20B as an antenna for air monitoring can be used. In this embodiment, the receiving antenna 60 receives the broadcast signal from the transmitting antenna 30 and outputs the received broadcast signal to the AC demodulator 25.

<AR display device>
The AR display device 40B receives monitoring information from the AC demodulator 25 via the communication line 52, and uses the received monitoring information to display maintenance work support information for the broadcasting station 20B in AR. For example, the AR display device 40B may be a general AR glass equipped with a maintenance work support function for the broadcasting station 20B. That is, unlike the first embodiment, the AR display device 40B does not need to have a tuner function for digital terrestrial broadcasting. Note that the maintenance work support function itself of the AR display device 40B is the same as that in the first embodiment, so further explanation will be omitted.

<Communication line>
The communication line 52 is a general communication line that connects the AC demodulator 25 and the AR display device 40B. For example, the communication line 52 may be a wireless communication line such as Wi-Fi (registered trademark) or Bluetooth (registered trademark).

[Operation of broadcasting station maintenance work support system]
With reference to FIG. 11, differences in the operation of the broadcasting station maintenance work support system 1B from the first embodiment will be described.
The processing in steps S1 to S4 is the same as in the first embodiment, so the description thereof will be omitted.

In step S10, the broadcaster 22 modulates the broadcast signal received in step S4 using the ISDB-T method. Then, the broadcaster 22 broadcasts the modulated broadcast signal via the transmitting antenna 30.

In step S11, the AC demodulator 25 receives and demodulates the broadcast signal broadcast by the broadcaster 22 via the receiving antenna 60.
In step S12, the AC demodulator 25 acquires the monitoring information multiplexed in the AC region of the broadcast signal demodulated in step S11.
In step S13, the AC demodulator 25 outputs the monitoring information acquired in step S12 to the AR display device 40B via the communication line 52.
In step S14, the AR display device 40B uses the monitoring information received from the AC demodulator 25 to display maintenance work support information for the broadcasting station 20B in AR.

[Action/Effect]
As described above, similarly to the first embodiment, by utilizing the existing digital terrestrial broadcasting equipment 2B, it is possible to adopt a transmission method for realizing a low-cost, high-security broadcasting station maintenance work support system 1B.

Here, the differences between the broadcasting station maintenance work support systems 1 and 1B will be summarized. Taking these differences into consideration, the broadcast station maintenance work support systems 1 and 1B may be introduced.
The broadcasting station maintenance work support system 1 (FIG. 1) according to the first embodiment is easy to introduce because there is no need to change the broadcasting station 20. On the other hand, in the broadcasting station maintenance work support system 1 according to the first embodiment, it is necessary to use an AR display device 40 that can demodulate terrestrial digital broadcasting and acquire monitoring information multiplexed in the AC area.

In the broadcast station maintenance work support system 1B (FIG. 10) according to the second embodiment, a general AR display device 40B that can receive IP packets can be used. Furthermore, since the broadcasting station maintenance work support system 1B according to the second embodiment uses the receiving antenna 60 for air monitoring, it can be introduced even in places with low electric fields. On the other hand, in the broadcasting station maintenance work support system 1B according to the second embodiment, the broadcasting station 20B needs to be equipped with the AC demodulation device 25.

(Modification 1)
Although the embodiments have been described in detail above, the present invention is not limited to each of the above-described embodiments, and may include design changes within the scope of the invention.

With reference to FIG. 12, differences from the first embodiment regarding the broadcasting station maintenance work support system 1C according to Modification Example 1 will be described.
As shown in FIG. 12, the broadcasting station maintenance work support system 1C differs from the first embodiment in that it includes a core broadcasting station 20 and a relay broadcasting station 20C as broadcasting stations. That is, the broadcasting station maintenance work support system 1C includes terrestrial digital broadcasting equipment 2C and an AR display device 40C.

<Terrestrial digital broadcasting equipment>
The digital terrestrial broadcasting equipment 2C includes a performance hall 10, a broadcasting station (main broadcasting station) 20, a broadcasting station (relay broadcasting station) 20C, transmitting antennas 30, 30C, and a receiving antenna 60C. In this modification, it is assumed that the performance hall 10 and the relay broadcasting station 20C are connected through a communication line. Note that the performance hall 10 and the transmitting antenna 30 are the same as those in the first embodiment, so a description thereof will be omitted.

The basic broadcasting station 20 broadcasts the broadcast signal from the performance hall 10 using terrestrial digital broadcast waves to the relay broadcasting station 20C. Note that the configuration of the basic broadcasting station 20 itself is the same as that in the first embodiment, so further explanation will be omitted.

The relay broadcast station 20C relays the broadcast signal from the basic broadcast station 20 to a general broadcast receiver (not shown). As shown in FIG. 12, the relay broadcasting station 20C includes a broadcasting machine 22C and a monitoring control device 23C.

The broadcaster 22C receives terrestrial digital broadcast waves from the basic broadcasting station 20 via a receiving antenna 60C. Then, the broadcaster 22C decodes and encodes the received terrestrial digital broadcast wave, and broadcasts it again as a terrestrial digital broadcast wave via the transmitting antenna 30C. Here, like the broadcaster 22, the broadcaster 22C has a redundant configuration.

The monitoring control device 23C generates monitoring information of the monitoring target (for example, the broadcasting machine 22C) of the relay broadcasting station 20C. Then, the monitoring and control device 23C transmits the generated monitoring information to the performance hall 10 (the monitoring and control device 12) via the communication line.

Note that, as described above, monitoring information of a plurality of broadcasting stations can be included (see FIG. 3). Therefore, the monitoring control device 12 multiplexes the monitoring information of the basic broadcasting station 20 and the relay broadcasting station 20C into the AC area.

<AR display device>
The AR display device 40C demodulates the broadcast signal broadcast by the broadcaster 22C, and uses the monitoring information multiplexed in the AC area to display maintenance work support information of the broadcasting station 20C in AR. Note that the configuration of the AR display device 40C itself is similar to that of the first embodiment, so further explanation will be omitted. Further, in FIG. 12, the illustration of the AR display device 40 (FIG. 1) is omitted in order to make the drawing easier to see, but the broadcasting station maintenance work support system 1C may include the AR display device 40.

(Other variations)
In each of the embodiments described above, the AR display device is described as being an AR glass, but the present invention is not limited to this. The AR display device may be any mobile terminal that can perform AR display, such as a smartphone or a tablet.

1, 1B, 1C Broadcasting station maintenance work support system 2, 2B, 2C Digital terrestrial broadcasting equipment 10 Performance hall 11 Operation equipment 12 Monitoring control equipment 13 AC area multiplexing equipment 14 STL equipment (transmission equipment)
15 TSL device 20, 20B, 20C Broadcasting station 21 STL device (receiving device)
22, 22C Broadcasting machine 23, 23C Monitoring control device 24 TSL device 25 AC demodulator 30, 30C Transmission antenna 40, 40B AR display device 50 STL
51 TSL
52 Communication line 60, 60C receiving antenna

Claims (8)

A broadcasting station maintenance work support system that supports maintenance work at a broadcasting station with an AR display device using monitoring information transmitted from a performance venue,
The said performance hall is
an AC area multiplexing device that multiplexes monitoring information of the broadcasting station into an ISDB-T AC area for broadcast signals containing video and audio;
a transmitting device that transmits a broadcast signal multiplexed with the monitoring information to the broadcasting station via a dedicated wireless line,
The said broadcasting station is
a receiving device that receives a broadcast signal multiplexed with the monitoring information from the performance hall via the dedicated wireless line;
a broadcaster that modulates the broadcast signal received by the receiving device using the ISDB-T method and broadcasts the modulated broadcast signal via a transmitting antenna,
The AR display device includes:
A broadcasting station maintenance work support system, characterized in that the broadcasting station maintenance work support information is displayed in AR by demodulating the broadcast signal broadcast by the broadcasting machine and using monitoring information multiplexed in the AC area. A broadcasting station maintenance work support system that supports maintenance work at a broadcasting station with an AR display device using monitoring information transmitted from a performance venue,
The said performance hall is
an AC area multiplexing device that multiplexes monitoring information of the broadcasting station into an ISDB-T AC area for broadcast signals containing video and audio;
a transmitting device that transmits a broadcast signal multiplexed with the monitoring information to the broadcasting station via a dedicated wireless line,
The said broadcasting station is
a receiving device that receives a broadcast signal multiplexed with the monitoring information from the performance hall via the dedicated wireless line;
a broadcaster that modulates the broadcast signal received by the receiving device according to the ISDB-T method and broadcasts the modulated broadcast signal via a transmitting antenna;
an AC demodulator that receives and demodulates a broadcast signal broadcast by the broadcaster via a receiving antenna, and outputs monitoring information multiplexed in the AC area to the AR display device via a communication line; Prepare,
The AR display device includes:
Broadcasting station maintenance work support, characterized in that the monitoring information is received from the AC demodulator via the communication line, and maintenance work support information of the broadcasting station is displayed in AR using the received monitoring information. system. The monitoring information includes identification information of the broadcasting station, and monitoring target information preset for each broadcasting station indicating whether each monitoring target is in use or not,
3. The AR display device refers to the monitoring target information and virtually masks the monitoring target in use as an AR display of the maintenance work support information. broadcasting station maintenance work support system. An AR display device of a broadcasting station maintenance work support system that supports maintenance work of a broadcasting station using an AR display device using monitoring information transmitted from a performance venue,
An AR display device that demodulates a broadcast signal broadcast by a broadcaster and displays maintenance work support information of the broadcasting station in AR using monitoring information multiplexed in an ISDB-T AC area. An AR display device of a broadcasting station maintenance work support system that supports maintenance work of a broadcasting station using an AR display device using monitoring information transmitted from a performance venue,
An AR display device that receives the monitoring information from an AC demodulator of the broadcasting station via a communication line, and uses the received monitoring information to display maintenance work support information of the broadcasting station in AR. . A performance venue of a broadcasting station maintenance work support system that supports maintenance work of a broadcasting station with an AR display device using monitoring information transmitted from the performance venue,
an AC area multiplexing device that multiplexes monitoring information of the broadcasting station into an ISDB-T AC area for broadcast signals containing video and audio;
A performance hall comprising: a transmitting device that transmits a broadcast signal multiplexed with the monitoring information to the broadcasting station via a dedicated wireless line. A broadcasting station of a broadcasting station maintenance work support system that supports maintenance work of a broadcasting station with an AR display device using monitoring information transmitted from a performance venue,
a receiving device that receives a broadcast signal multiplexed with the monitoring information from the performance hall via a dedicated wireless line;
A broadcasting station characterized by comprising: a broadcaster that modulates the broadcast signal received by the receiving device using an ISDB-T method and broadcasts the modulated broadcast signal via a transmitting antenna. A broadcasting station of a broadcasting station maintenance work support system that supports maintenance work of a broadcasting station with an AR display device using monitoring information transmitted from a performance venue,
a receiving device that receives a broadcast signal multiplexed with the monitoring information from the performance hall via a dedicated wireless line;
a broadcaster that modulates the broadcast signal received by the receiving device according to the ISDB-T method and broadcasts the modulated broadcast signal via a transmitting antenna;
AC demodulation that receives and demodulates the broadcast signal broadcast by the broadcaster via the receiving antenna, and outputs the monitoring information multiplexed in the ISDB-T AC area to the AR display device via the communication line. A broadcasting station characterized by comprising a device.

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