JP2008124614A - Image transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image transmission system in which a display device, installed on a platform or concourse of a station to broadcast television images, commercial images, etc., with high image quality nearly in real time. <P>SOLUTION: The video image transmission system is equipped with a central control system, a base station control system, and one or more general station control systems. The central control system converts the fetched optical signals of high-definition images into electric signals, encodes them, and sends the encoded electric signals to the base station control system. The base station control system applies the prescribed signal conversion processing to, the encoded electric signals then decodes the electric signals, broadcasts the decoded electric signals through a large display device, and sends the optical signals of video images to the general station control systems. The general station control system broadcasts the video images through a large display device and sends the optical signals of video images to the other general station control systems, in relay. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

The present invention relates to a video transmission system capable of broadcasting television images and commercial videos with high image quality and almost real time on a display device installed on a platform or concourse of a station.

  2. Description of the Related Art Conventionally, some station platforms and concourses have advertising billboards that are used to post desired information to station users by displaying large advertising posters or the like. In addition, since advertising billboards are still images, there is an apparatus that installs a small display to broadcast information such as television images and commercial images in order to increase information to be provided (Patent Document 1).

  For example, the apparatus described in Patent Document 1 has a mechanism in which a television video or a commercial video is acquired and distributed to each station via the Internet.

  In addition, the invention disclosed in Patent Document 2 can broadcast a television image or the like by installing a home server. However, since the image is stored once, almost no real-time broadcasting can be performed. In addition, when broadcasting high-quality video, the amount of information becomes enormous, so the image quality must be substantially reduced.

JP 2001-354138 A JP 2002-142208 A

  In recent years, a large display device (for example, a 103-inch plasma display panel (PDP)) has been developed. By installing the large display device on a platform or a concourse, more powerful images can be provided. . However, when a video is played back on a large display device, the image quality becomes conspicuous, and thus it is inevitably necessary to deliver a high-quality video. For example, it is desired to distribute high definition video (high definition video).

  However, when distributing high-quality video, the amount of information of the video to be distributed becomes enormous. And it cannot respond with the apparatus of the above-mentioned patent documents 1 and patent documents 2, or the broadcasting system in the conventional station and vehicles. One factor is that, for example, in the device disclosed in Patent Document 1, a control device that distributes video simultaneously distributes to all stations, station buildings, and the like, so that a very large load is placed on the control device and the network of the distribution route. This is because there is a high possibility that a part of the video signal loses data or a processing delay occurs.

  For this reason, even if a large display device is installed on the platform or concourse of a station, it is impossible to broadcast high-quality video in real time. On the contrary, the installation of a large display device will increase the level of attention from passengers, but the loss of video signal data and processing delay will be conspicuous, and stress will be accumulated from the users of the station watching the display device. The advertising effect will also be reduced.

  Therefore, a video transmission system for making it possible to broadcast high-quality video broadcast on a large display device in almost real time is desired. Also, when installing such a system at a station, the safety of station users and the operation of railway vehicles must not be compromised. Therefore, there is a need for a video transmission system that realizes the above points and that does not impair the safety of station users and railway vehicle operations.

  In view of the above problems, the present inventor has invented a video transmission system for enabling high-quality video broadcast on a large display device to be broadcast almost in real time.

  The invention of claim 1 is a video transmission system for broadcasting high-definition video on a display device installed in a station, the video transmission system comprising a central control system, a base station control system, one or more A general station control system, and the central control system encodes the electrical signal by converting the optical signal into an electrical signal, and a video capturing device that captures the optical signal of the high-definition video. A high-definition encoder that transmits to the base station control system via an IP network, and the base station control system is installed at a predetermined location of the base station. A first media converter that receives the transmitted electrical signal, converts it to an optical signal, and transmits the optical signal via an optical fiber; A second media converter that receives an optical signal from the first media converter and converts the optical signal into an electrical signal, and the electrical signal. A high-definition decoder that decodes the optical signal, and a photoelectric transmission device that converts the decoded electrical signal into an optical signal and sends the optical signal to the general station control system via an optical fiber, The video of the decoded electrical signal is broadcast on a display device provided in the video display device, and the general station control system receives an optical signal transmitted from the base station control system or another general station control system. A general station control system that receives and transmits the optical signal connected by an optical fiber. A general-purpose station control system having a photoelectric transmission device that transmits the received optical signal and converts the received optical signal into an electrical signal, and a display device that broadcasts the video of the electrical signal. It is a video transmission system.

  By configuring as in the present invention, it is possible to broadcast high-definition high-definition video on a display device installed at each station in almost real time. In other words, the video signal is not sent directly from the central control system to the control systems of all stations as in the past, but the video signal is sent from the central control system to the base station control system of the base station. The base station sends a video signal to the general station control system of the general station connected to the general station by an optical fiber, and the general station transmits to the general station control system of another general station connected to the general station by the optical fiber. On the other hand, a video signal is transmitted and broadcast is performed on the display device at each station. As a result, since the video signal is transmitted in a so-called relay system, the load on the central control system is greatly reduced unlike the conventional case. By broadcasting high-definition video in real time, not just video, the amount of information of the video signal becomes enormous. However, with the conventional configuration, the central control system cannot substantially process the high-definition video. The video signal could not be sent out, but the processing can be performed by the configuration of the present invention. In addition, since the high definition video can be transmitted, the display device can be enlarged and more powerful video can be broadcast in real time.

  In the invention of claim 2, the video display device is a video transmission system installed in any one or more of a platform, a concourse, and a wall surface of a station.

  Such a video display device is preferably installed on the platform, concourse, wall surface, etc. of the station. This is because it tends to attract the attention of users of the station.

  In the invention of claim 3, in the base station control system or the general station control system, sound corresponding to the video broadcast on the display device is reproduced from a speaker installed at a predetermined location, and the speaker is a directional speaker. A video transmission system.

  It is preferable to play audio together with the video broadcast on the display device, but the station is a public facility, and for example, business broadcasts such as arrival of trains are erased by the audio of the broadcast from the display device It is a problem. Therefore, it is preferable that only the user who wants to hear the sound can hear the sound by reproducing the sound from the directional speaker.

  5. The video transmission system according to claim 4, wherein the video display device is provided with a display unit in which a warning message for the presence of a directional speaker is written in or near the video display device.

  The directional speaker is a speaker that operates so that sound can be heard only in a specific range. Therefore, when a user who normally passes enters the range where the sound of the directional speaker can be heard, the sound is suddenly heard. Therefore, in order to prevent such a situation, it is preferable to give a user's attention by providing a display indicating that sound is being reproduced from the directional speaker.

  In the invention of claim 5, the directional speaker is provided above the video display device, and the color of the floor surface in the range that matches or substantially matches the range in which the sound from the directional speaker can be heard. The video transmission system has a color different from the color of the other floor surface.

  The directional speaker is a speaker that operates so that sound can be heard only in a specific range. Therefore, when a user who normally passes enters the range where the sound of the directional speaker can be heard, the sound is suddenly heard. Therefore, in order to prevent such a situation, it is preferable that the color of the floor surface in the range where the sound from the directional speaker can be heard is different from the colors of the other floor surfaces, thereby prompting the user's attention. .

  7. The video transmission system according to claim 6, wherein a sensor is provided in or near the video display device, and when the sensor reacts, a message about the presence of the directional speaker is reproduced from a speaker different from the directional speaker. It is.

  The directional speaker is a speaker that operates so that sound can be heard only in a specific range. Therefore, when a user who normally passes enters the range where the sound of the directional speaker can be heard, the sound is suddenly heard. Therefore, in order to prevent such a situation, install a sensor in the vicinity of the video display device, and if the sensor reacts due to the user passing through the sensor, the speaker other than the directional speaker is used. It is preferable to alert the user by configuring the user to play a message that tells the presence of the directional speaker.

  In the invention of claim 7, the video transmission system further includes a sensor for detecting a railway vehicle installed on a track on which the railway vehicle travels, in the vicinity thereof, or in a tunnel, and the base station control system or The general station control system is a video transmission system that turns off the display of the display device when the sensor detects a railway vehicle.

  When the display device is provided near the railway vehicle, for example, when the display device is embedded in the wall surface in the tunnel, from the radio wave emitted from the display device and the railroad radio antenna provided in the railroad It has been found by the inventor's research that there may be cases where noise is generated due to interference with transmitted radio waves. If this is left unattended, it may interfere with the safe operation of the railway. Therefore, when it is detected that the railway is approaching, it is preferable to eliminate the interference by turning off the display on the display device. Therefore, by adopting the configuration of the present invention, the above problem can be solved.

  In the invention of claim 8, in the video transmission system, a first sensor is provided at a predetermined distance from the video display device in the traveling direction of the railcar, and further than the first sensor. A second sensor is provided at a distant predetermined distance. When the railroad vehicle is detected by the first sensor, the video display device is turned off, and when the railcar is detected by the second sensor, the video display device displays the railcar. Is a video transmission system that is resumed.

  According to the configuration of the present invention, after the display device is turned off by detection by the first sensor, display on the display device can be restarted by detection by the second sensor.

  In a ninth aspect of the present invention, the predetermined distance of the first sensor is equal to or less than the distance from the head portion of the vehicle to the antenna located at the headmost in the traveling direction of the railcar, and the second sensor The predetermined distance of the sensor is not less than the distance from the head of the vehicle to the antenna located at the rearmost in the traveling direction of the railway vehicle, and when the first sensor detects the railway vehicle, By sending a signal to the display device, the display on the display device is turned off. When the second sensor detects a railcar, the display device is sent by sending a signal to the video display device. Is a video transmission system.

  The first sensor and the second sensor are preferably installed at positions as in the present invention. By installing in such a position, it is possible to prevent the antenna installed on the railway causing interference from approaching the display device in a state where display is performed.

By using the video transmission system of the present invention, even if a large display device is installed on a station platform or a concourse, a high-definition video with high image quality can be broadcast almost in real time. As a result, the attention of the large-sized display device from the users of the station is increased, and the advertising effect of the commercial video broadcast there is inevitably increased.

  An example of the system configuration of the video transmission system 1 of the present invention is shown in FIG. The video transmission system 1 is installed at a central control system 2 installed at a predetermined location, a base station control system 3 installed at one predetermined station (base station), and a station (general station) other than the base station. And a general station control system 4. The video transmission system 1 shown in FIG. 1 has one central control system 2, one base station control system 3, and a plurality of general station control systems 4, but the base station control system 3 Is preferably provided for each route or each railway company. Therefore, when broadcasting a video captured by the central control system 2 in a plurality of routes or railway companies, between the central control system 2 and the base station control system 3 provided for each route or each railway company. You can send and receive information. This case is schematically shown in FIG. In addition, although the railway at the station is preferably a subway, it may be a railway that travels on the ground.

  Information is transmitted and received between the central control system 2 and the base station control system 3 via the IP network. Information is transmitted and received between the base station control system 3 and the general station control system 4 or between the general station control systems 4 via optical fibers. It should be noted that the processing of video signals exchanged between systems (in this specification, “video” includes “sound”) is realized using both optical signals and electrical signals. .

  The central control system 2 includes a video capturing device 5 and a high definition encoder. The video capturing device 5 receives an optical signal of a video broadcast by a broadcasting station (as described above, this also includes an optical optical signal. The same applies in this specification) from the broadcasting station system. Alternatively, it is an apparatus for reading out an optical signal of a commercial video recorded in advance on a recording medium. The optical signals of these images are sent to the high definition encoder 6. Note that these images are preferably high-quality images (such as high-definition images), such as images conforming to the HD-SDI standard.

  When broadcasting a video signal received from a public broadcast station system, before and after that, a video other than the commercial video, for example, an environmental video signal such as a landscape, is read from the recording medium, and the commercial signal is received for a predetermined time. After broadcasting a video other than the video, it is preferable to broadcast the video received from the system of a public broadcast station. This makes it possible to more clearly identify that the video is a public broadcast video.

  The high definition encoder 6 converts the optical signal of the video received from the video capture device 5 into an electrical signal, encodes it, and sends it to a predetermined base station control system 3 via the IP network. It is. Therefore, this encoder not only simply converts an optical signal into an electric signal but also has a network function. For example, when the video signal is in the HD-SDI standard, it is encoded in the MPEG2-TS standard. The encoding here corresponds to a known encoding such as packetization in order to transmit an electric signal via the IP network.

  The base station control system 3 is provided at a place where a large-scale display device 11 such as a media converter (first media converter 7) installed in a predetermined station location, for example, a distribution room, and a station platform or concourse is installed. A video display device 20. The video display device 20 includes a second media converter 8, a high definition decoder 9, a large display device 11, a distributor 10, and a photoelectric transmission device 12.

  The first media converter 7 is a device that receives an electrical signal of video sent from the central control system 2 via the IP network and converts the electrical signal into an optical signal. Since the electric signal of the image is received through the IP network, it is preferable to be provided in the distribution room of the station. Further, the optical signal is transmitted from the distribution room to the video display device 20 installed in the platform or concourse of the station using an optical fiber.

  The second media converter 8 provided in the video display device 20 is a device that converts an optical signal into an electric signal. Both the first media converter 7 and the second media converter 8 are devices that support high-definition video processing.

  The high definition decoder 9 is a device that decodes the video converted into the electrical signal by the second media converter 8. The decoding here may be a normal decoding process, and corresponds to a known decoding for returning the electric signal packetized by the high-definition encoder 6 to the electric signal of the original video.

  The distributor 10 is an apparatus that distributes an electric video signal to the large display device 11 and the photoelectric transmission device 12. The distributor 10 has a function capable of processing an electric signal of a high definition video. The distributor 10 is also provided with a D / A converter, an audio processor, a modulator, an amplifier, and the like. A plurality of (preferably two) D / A converters are provided, and one is connected to the large display device 11. That is, the distributed electric signal is displayed on the large display device 11. The other is connected to the large display device 11 and the audio processor. In other words, the electrical signal is sent to the large display device 11 to be displayed on the large display device 11, and the audio electrical signal is sent to the audio processor to perform output processing related to the sound. The output processing related to sound may be a method that is normally used. An electric signal of sound is sent from the D / A converter to the audio processor and further sent to the modulator. Then, after the modulation process is performed by the modulator, the electric signal is amplified by the amplifier and output from each speaker. The speaker will be described later. Note that the above processing is processing when audio output is not performed from the large display device 11, but when audio output is performed from the large display device 11, the distributor 10 also transmits an audio electrical signal to the large display device 11. Send it out.

  The large display device 11 is a large display device installed on the base 21 of the video display device 20, and corresponds to, for example, a 103-inch PDP (plasma display panel). The large display device 11 is preferably installed on both the front side and the back side of the video display device 20 with the back surface of the PDP facing each other, but is not limited thereto. In consideration of the force of the image, the large display device 11 is preferably 50 inches or more, but may be a PDP of 103 inches or more, for example. Various display devices such as a liquid crystal display, a surface-conduction electron display (SED), and a display device using an organic EL can be used without being limited to the PDP. The large display device 11 has a function capable of broadcasting (reproducing) an electric signal of a high definition video.

  In addition, about the electrical signal of an audio | voice, audio | voices may be directly reproducible from the large sized display apparatus 11, and a speaker may be installed in a ceiling etc. and audio | voices may be reproducible. Further, by using this speaker as the directional speaker 30, it may be configured such that sound can be reproduced only in a specific region. There is a problem that when the sound is played back with a normal speaker at a station platform or a concourse, the sound is diffused and business broadcasts cannot be heard. Therefore, by using the directional speaker 30, broadcast sound is not reproduced outside the area, so that the above problem can be solved.

  When the directional speaker 30 is used, a user who is about to pass through the vicinity of the video display device 20 suddenly hears a voice, and the user is surprised. Therefore, when the video display device 20 is provided with a display section (such as displaying on the side of the video display device 20 or installing a display board) such as “sound is being reproduced”, or when the directional speaker 30 is installed on the ceiling. It is advisable to provide considerations such as setting the color of the floor surface where the sound can be heard to be different from the color of the floor surface where the sound cannot be heard. Such a state is schematically shown in FIG. FIG. 5 is a diagram when the home is viewed from above, and a video display device 20 is installed in the center of the home in parallel to the home. The directivity is set on the ceiling in the vicinity of the video display device 20 (preferably above the video display device 20 and the directional speaker 30 is installed so that sound is reproduced with respect to the floor surface direction). A speaker 30 is installed, and a range where the sound can be heard is indicated by a shaded portion. It is preferable that the floor surface corresponding to the shaded portion has a color different from the floor surface of the other portion (a range where sound cannot be heard). Note that the range in which the color of the floor surface is changed includes the range in which the sound from the directional speaker 30 can be heard, and the range may not completely match as long as the range substantially matches (substantially match range). .

  Further, when a sensor 40 (for example, an optical sensor) or the like is attached to the video display device 20 itself or in the vicinity of the video display device 20 and the user crosses the sensor 40, a predetermined speaker 41 (a speaker different from the directional speaker 30). (The video display device 20 is installed in or near the video display device 20). An announcement such as “Television broadcast audio is being played back, please be careful” may be made. The sensor 40 is provided in front of the video display device 20 as viewed from the user, and is installed so that the sensor 40 reacts before the user reaches the audible range of the directional speaker 30. . When the sensor 40 reacts, a warning message is reproduced from a predetermined speaker 41 different from the directional speaker 30, and after the user listens to the warning message, the user passes through the audible range of the directional speaker 30. It is better to configure as follows. FIG. 6 shows a view when the home is viewed from above. In the center of the home, the video display device 20 is installed in parallel to the home, and sensors 40a to 40d are installed on the left and right. For example, in the case of the optical sensor 40, when the user passes between the sensor 40a and the sensor 40b from the left side to the right side in the figure, the user passes the right side in the figure between the sensor 40c and the sensor 40d. The sensor 40 reacts, for example, when it passes to the left, and a warning message is reproduced from a predetermined speaker 41. The predetermined speaker 41 is installed on a ceiling, a home, a concourse, etc., and is located on the front side of the range in which the sound of the directional speaker 30 can be heard with respect to the traveling direction of the user. It is installed so that sound from a predetermined speaker 41 can be heard before passing through a range where 30 sounds can be heard.

  The photoelectric transmission device 12 is a device that converts the electrical signal of the video distributed from the distributor 10 into an optical signal, and then transmits the optical signal of the video to the general station control system 4 via an optical fiber. The photoelectric transmission device 12 has a function capable of processing an optical signal of high definition video.

  In FIG. 3, the image figure of the state in which the video display apparatus 20 provided with the large sized display apparatus 11 was installed in the platform center part of the station is shown. In this video display device 20, two large display devices 11 are installed on the front side and the back side, and the second media converter 8 is placed inside the base 21 of the video display device 20 located below the large display device 11. , A high-definition decoder 9, a distributor 10, a photoelectric transmission device 12, and the like. FIG. 4 shows a front view of the video display device 20. The video display device 20 shown in FIG. 4 is installed in a home, and a large display device 11 is provided on a base 21. Such a video display device 20 may be installed in a concourse or the like in addition to being installed in a home. Moreover, it may be embedded in the wall surface.

  The general station control system 4 receives an optical signal of an image from the base station control system 3 or another general station control system 4 through an optical fiber, and broadcasts the image received by the large display device 11 installed in the station. The received video signal is sent to another general station control system 4 through an optical fiber.

  The photoelectric transmission device 13 receives the optical signal of the image from the photoelectric transmission device 12 in the base station control system 3 or the photoelectric transmission device 13 in the other general station control system 4, converts the optical signal into an electric signal, and sends it to the distributor 10. It is a device to send out. In addition, this photoelectric transmission device 13 transmits the optical signal of the video received from the base station control system 3 or another general station control system 4 to another general station control system 4 connected by the optical fiber via the optical fiber. It is also a device for sending out.

  The distributor 10 is a device that distributes the electric signal of the video received from the photoelectric transmission device 13 to each large display device 11. The distributor 10 may be the same device as the distributor 10 of the base station control system 3.

  The general station control system 4 also includes a video display device 20 having a base 21 as shown in FIG. 4 and a large display device 11 positioned above the base station control system 3 as in the base station control system 3. The base 21 may not include the media converter (second media converter 8) or the high definition decoder 9. Further, when a plurality of large display devices 11 are provided in the video display device 20, the distributor 10 is required. However, in the case of one large display device 11, the distributor 10 is not necessary and is directly from the photoelectric transmission device 12. A video electrical signal may be received.

  Next, an example of the processing process of the video transmission system 1 of the present invention will be described with reference to the flowchart of FIG. 2 and the conceptual diagram of FIG.

  If there is an image to be broadcast on the large display device 11 at the base station or general station, the image capturing device 5 of the central control system 2 captures the image (S100). This capturing can be performed by receiving an optical signal of the video from each broadcasting station, or capturing an optical signal of a video recorded on a recording medium for a commercial video or the like.

  Then, after converting the optical signal of the video captured by the video capture device 5 into an electrical signal, the high definition encoder 6 encodes the electrical signal (S110). For example, an HD-SDI standard video signal is encoded into an MPEG2-TS standard electrical signal.

  Then, the high-definition encoder 6 sends the electrical signal to the base station control system 3 via the IP network (S120).

  The first media converter 7 provided in the power distribution room of the base station control system 3 converts the electrical signal of the video sent from the central control system 2 via the IP network into an optical signal. Then, the optical signal is transmitted to the second media converter 8 provided in the video display device 20 via the optical fiber.

  The second media converter 8 converts the optical signal into an electric signal and then sends the electric signal to the high definition decoder 9. Then, the high definition decoder 9 decodes the video electric signal (such as MPEG2-TS standard) sent from the second media converter 8 (S130), and sends it to the distributor 10.

  The distributor 10 distributes the decoded electrical signal to the large display device 11 and the photoelectric transmission device 12 (S140). In the large display device 11, the video captured by the central control system 2 is broadcast by reproducing the video of the electric signal (S150). On the other hand, in parallel with this, the photoelectric transmission device 12 converts the electrical signal of the video received from the distributor 10 into an optical signal, and then transmits the optical signal to the general station control system 4 through the optical fiber (S160). .

  When the optical signal of the image is received by the photoelectric transmission device 13 of the general station control system 4, the optical signal is transmitted to the other general station control system 4 connected to the general station control system 4 through the optical fiber via the optical fiber. To do. The optical transmission unit 13 converts the received optical signal of the video into an electrical signal and sends it to the distributor 10.

  The distributor 10 of the general station control system 4 distributes the electric signal to each large display device 11 (S170), and the large display device 11 takes in the central control system 2 by reproducing the electric signal of the video. The video is broadcast (S180).

  Further, in the general station control system 4 that has received the video signal from the other general station control system 4, by performing the same processing as described above, broadcasting is performed on the large display device 11 of the station, and another general station control system. The video signal is transmitted to 4.

  In this way, the central control system 2 does not send an optical signal or electric signal of the image to all stations, but the central control system 2, the base station control system 3, the general station control system 4, and other general station control systems. 4 is transmitted in order, that is, in a so-called relay manner, the system load related to the central control system 2 is greatly reduced. As a result, even a high-quality video having a large amount of information can be broadcast on the large display device 11 at each station in almost real time without degrading the image quality. Further, since the video is high quality, the deterioration of the image quality is not conspicuous even in the large display device 11, which attracts the attention of the user of the station, and the degree of attention to the commercial video is improved. In addition, it is preferable that the video transmission system 1 is used to broadcast a television video such as news and a commercial video in the meantime. In general, news videos have a high level of attention from station users, and by broadcasting commercial videos with high-definition video with high image quality between news videos, attention to commercial videos is higher than that of conventional advertising signs. Will increase. As a result, the value of the commercial video is increased.

  In addition to improving the value of commercial video as described above, emergency information such as disaster information at the time of disaster can also be broadcast. When you are at a station, it may be difficult to obtain information. By providing the large display device 11 on the platform or concourse of the station in this way, for users of stations in a situation where information is scarce. It is possible to provide various information promptly.

  In the above-described embodiment, when the video display device 20 is installed on the wall surface of a platform or a subway tunnel (particularly when installed on the wall surface) and the railway approaches the video display device 20, the video display device The radio wave generated by the large display device 11 at 20 and the radio wave transmitted from the antenna for railway radio installed in the railway may interfere with each other, and noise may be generated in the video display apparatus 20 and the railway radio. . In this case, the image displayed on the large display device 11 is disturbed, or noise enters the railroad radio.

  Therefore, a sensor is installed in front of a predetermined distance from the video display device 20, the vehicle is detected by the sensor, and when it is detected, the large display device 11 is muted (the display is turned off), and the vehicle is provided. The video display device 20 may have a function of canceling mute (resuming display) after the antenna passes through the large display device 11. This is schematically shown in FIG.

  In the case of FIG. 8, there are railway radio antennas at the second, third and fourth and fifth cars, and the right end position of the video display device 20 (large display device 11) (shown as PDP in FIG. 8). The first sensor is provided at a predetermined distance with respect to the traveling direction of the vehicle, and further, the second sensor is provided at a predetermined distance farther than the first sensor with respect to the traveling direction of the vehicle. . The predetermined distance between the video display device 20 and the first sensor is shorter than the distance from the head of the vehicle to the first antenna in the traveling direction of the vehicle, and the short distance is It is preferable that there is a distance traveled by the railway until the large display device 11 is muted when the first sensor detects the head of the vehicle. Similarly, the predetermined distance between the video display device 20 and the second sensor is preferably longer than the distance from the top of the vehicle to the second antenna.

  That is, when the first sensor detects that the head of the railway vehicle passes, the signal is sent to the video display device 20, and the video display device 20 mutes the large display device 11 (turns off the display). Become. When the second sensor detects that the head of the railway vehicle passes, the signal is sent to the video display device 20, and the video display device 20 cancels the mute of the large display device 11 (resumes display). )

  For example, when the distance from the head of the vehicle to the first antenna is 38 meters when viewed from the traveling direction, and the moving distance from detection to mute is 10 meters, the first sensor It is preferable that the display device 20 is installed in a place 28 meters or less from the end (most end in the traveling direction). If the distance from the top of the vehicle to the second antenna is 80 meters, the second sensor is installed at a location 80 meters or more from the end of the video display device 20 (most end with respect to the traveling direction). Preferably it is.

  That is, when the first sensor detects the vehicle, a signal for muting the large display device 11 is sent to the video display device 20, and when the second sensor detects the vehicle, a signal for canceling the mute of the large display device 11 is sent. The image is sent to the video display device 20.

  Although FIG. 8 illustrates the case where the railway has only two antennas, when there are a plurality of antennas, the first antenna corresponds to the antenna provided closest to the traveling direction, and the first antenna The second antenna corresponds to the antenna provided on the most opposite side to the traveling direction (the rearmost with respect to the traveling direction).

  By providing such a function, the radio wave generated from the large display device 11 and the radio wave transmitted from the railway antenna do not interfere with each other.

  In the above description, the case of using the first sensor and the second sensor has been described. However, only one sensor may be used. In this case, the function of the sensor has a function corresponding to the first sensor. After the display of the large display device is turned off by this sensor, the time is measured by a timer (not shown) provided in the video display device 20, and after the preset time has elapsed, the display on the large display device 11 is performed. Can be configured to resume.

By using the video transmission system 1 of the present invention, even if a large display device 11 is installed on a station platform or a concourse, a high-definition video with high image quality can be broadcast almost in real time. As a result, the attention of the station user to the large display device 11 is increased, and the advertising effect of the commercial video broadcast there is inevitably increased.

It is a conceptual diagram which shows an example of the system configuration | structure of this invention. It is a flowchart which shows an example of the processing process of this invention. It is an image figure at the time of installing the video display apparatus provided with the large sized display apparatus in the platform of a station. It is a front view of a video display device. FIG. 6 is a diagram schematically showing changing the color of the floor surface in the audible range when sound is reproduced by a directional speaker. It is a figure which shows typically displaying a message from a predetermined speaker different from a directional speaker by installing a sensor around the video display device. It is another conceptual diagram of the video transmission system of the present invention. It is a figure which shows typically the structure which prevents interference with a display apparatus and the antenna of a rail vehicle.

Explanation of symbols

1: Video transmission system 2: Central control system 3: Base station control system 4: General station control system 5: Video capture device 6: High definition encoder 7: First media converter 8: Second media converter 9: High definition decoder 10: Distributor 11: Large display device 12: Photoelectric transmitter 20: Video display device 21: Base 30: Directional speaker 40: Sensor 41: Predetermined speaker

Claims (9)

A video transmission system for broadcasting high-definition video on a display device installed in a station, the video transmission system having a central control system, a base station control system, and one or more general station control systems. And
The central control system
An image capturing device for capturing an optical signal of the high definition image;
A high-definition encoder that converts the optical signal into an electrical signal, encodes the electrical signal, and sends the electrical signal to the base station control system via an IP network,
The base station control system is
A first media converter that is installed at a predetermined location of a base station, receives an electrical signal sent from the central control system, converts it into an optical signal, and sends the optical signal through an optical fiber;
A video display device comprising the display device,
The video display device includes a second media converter that receives an optical signal from the first media converter and converts the optical signal into an electrical signal;
A high definition decoder for decoding the electrical signal;
A photoelectric transmission device that converts the decoded electrical signal into an optical signal and sends the optical signal to the general station control system via an optical fiber is further provided, and an image of the decoded electrical signal Is broadcast on a display device provided in the video display device,
The general station control system is
The optical signal transmitted from the base station control system or other general station control system is received, and is received for a general station control system other than the general station control system that transmits the optical signal, which is connected by an optical fiber. A photoelectric transmission device for transmitting an optical signal and converting the received optical signal into an electrical signal;
A display device that broadcasts the video of the electrical signal,
A video transmission system characterized by that. The video display device is installed on any one or more of a station platform, a concourse, a wall surface,
The video transmission system according to claim 1. In the base station control system or the general station control system,
The audio corresponding to the video broadcast on the display device is reproduced from a speaker installed at a predetermined location, and the speaker is a directional speaker.
The video transmission system according to claim 1, wherein the video transmission system is a video transmission system. In the video display device or in the vicinity thereof, a display unit in which a warning message for the presence of a directional speaker is described is provided.
The video transmission system according to claim 3. The directional speaker is provided above the video display device, and the color of the floor surface in a range that matches or substantially matches the range where the sound from the directional speaker can be heard, A color different from the color,
The video transmission system according to claim 3. When the image display device is provided with a sensor in the vicinity thereof, and the sensor reacts, a message regarding the presence of the directional speaker is reproduced from a speaker different from the directional speaker.
The video transmission system according to claim 3. The video transmission system further includes:
A sensor for detecting a railway vehicle is installed on the track on which the railway vehicle runs or in the vicinity thereof, in the tunnel,
The base station control system or the general station control system is
When the sensor detects a railway vehicle, the display on the display device is turned off.
The video transmission system according to claim 1, wherein the video transmission system is a video transmission system. In the video transmission system,
A first sensor is provided at a predetermined distance with respect to the traveling direction of the railway vehicle from the video display device, and further, a second sensor is provided at a predetermined distance farther than the first sensor. ,
When the railroad vehicle is detected by the first sensor, the video display device is turned off, and when the railroad vehicle is detected by the second sensor, display is resumed by the video display device.
The video transmission system according to claim 1, wherein the video transmission system is a video transmission system. The predetermined distance of the first sensor is
Less than or equal to the distance from the top of the vehicle to the antenna located at the top of the traveling direction of the railway vehicle,
The predetermined distance of the second sensor is
More than the distance from the head of the vehicle to the antenna located most rearward with respect to the traveling direction of the railway vehicle,
When the first sensor detects a railway vehicle, the display on the display device is turned off by sending a signal to the video display device,
When the second sensor detects a railway vehicle, the display device is displayed by sending a signal to the video display device.
The video transmission system according to claim 8.

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