KR100579942B1 - Train broadcast system with optical lines - Google Patents

Abstract

The present invention relates to a train broadcasting system capable of displaying a high-quality image without losing a signal without harming the aesthetics of a train by connecting a server inside a train and a display device of each passenger car using an optical line.

According to an aspect of the present invention, there is provided a train broadcasting system comprising: at least one server storing multimedia data, transmitting multimedia data according to a broadcast schedule, and checking a failure state of each device; A first optical transmission device for converting and transmitting multimedia data transmitted from the server into an optical signal; A first distribution for receiving the optical signal transmitted from the first optical transmission device through an optical line, transmitting the multimedia data to at least one display device in its vehicle, and transmitting the multimedia data to another neighboring vehicle Device; At least one display device for displaying multimedia data transmitted from the first distribution device; And a second optical transmission device positioned in another neighboring vehicle and converting the multimedia data transmitted from the first distribution apparatus into an optical signal and transmitting the optical data to a second distribution apparatus existing in the same vehicle through an optical line.

Train, broadcasting, optical fiber, optical cable, image, distribution, transmission

Description

Train broadcast system with optical lines             

1 is an overall block diagram of a train broadcasting system according to the present invention;

Figure 2 is a detailed block diagram of an optical transmission device according to the present invention.

Figure 3 is a detailed block diagram of a distribution device according to the present invention.

4 is another detailed block diagram of the optical transmission device according to the present invention;

5 is a detailed block diagram of a display device main board according to the present invention;

* Explanation of symbols for the main parts of the drawings

10: train server

11, 14: optical transmission device

12, 15: distribution device

13: display device

The present invention relates to a train broadcasting system using an optical line, and more particularly, to a train broadcasting system for distributing multimedia data transmitted from a multimedia server via wireless to a display device of each passenger vehicle through an optical line in a moving train. will be.

For passengers traveling on trains, the company also provides multimedia broadcasting services on the train. Currently, the multimedia broadcasting service provided is simply at the level of distributing and displaying video and audio signals output from the server to each display device through a distributor.

Korean Patent Publication No. 0399077 discloses a train broadcasting control system and method thereof. The conventional patent is a GPS terminal for receiving the position information from the GPS satellites to determine the current position of the train, a wireless communication terminal for receiving control signals for broadcast control and text data for subtitle broadcasting, and satellite broadcast reception A satellite broadcast receiver for the device. In addition, the conventional patent includes a moving picture storage unit for storing moving picture data, and a schedule memory for storing broadcast and train operation schedule information. Furthermore, the conventional patent includes a video processing unit for converting and outputting text data into a caption video signal, a video playback unit for reproducing and outputting video data stored in the video storage unit according to the broadcasting schedule, and included in the train schedule information. A sound processor for outputting a guide broadcast, a switching unit for selecting and outputting one of the signals output from the sound processor of the satellite broadcast receiver video playback unit, and a signal installed in each vehicle and selected and output from the switching unit It includes a plurality of output means for outputting.

In addition, the conventional patent includes a control device, wherein the control device includes a plurality of broadcast devices, the video playback unit, the satellite broadcast receiver, the video processor, and the outputs of the sound processor to a broadcast schedule set in the schedule memory. The broadcasting schedule is changed according to a control signal input through the wireless communication terminal while processing the station guide before the preset station arrival time by using the location information of the train received through the GPS terminal while broadcasting through the broadcasting system. do. The remote control apparatus is correspondingly connected to the wireless communication terminal through a wireless communication network, transmits text data, and remotely controls a broadcast through the control apparatus.

In the prior art having the configuration described above, after setting a broadcast schedule including a stop station guide broadcast according to a train running schedule, the station is processed according to the set schedule before and after the start of the train while processing the stop station guide before the station arrival time, During the broadcast according to the broadcast schedule, the control signal is periodically monitored through the wireless communication terminal to check whether the broadcast schedule has been changed. If the broadcast schedule is not changed, the broadcast schedule is broadcast according to the original broadcast schedule. Follow the broadcast.

The prior art as described above uses a coaxial cable to connect the monitor and the digital distribution device, which may harm the beauty of the interior of the train. Moreover, in the prior art, when the transmission distance is long, the loss of the transmission signal is high and an amplifier must be installed in the middle.

Accordingly, the present invention is to solve the problems of the prior art as described above, by connecting the server inside the train and the display device of each passenger car by using an optical line, without losing the aesthetics of the train without loss of signal An object of the present invention is to provide a train broadcasting system capable of displaying an image.

According to an aspect of the present invention, there is provided a train broadcasting system, comprising: at least one server configured to store multimedia data, transmit multimedia data according to a broadcast schedule, and check a failure state of each device; A first optical transmission device for converting and transmitting multimedia data transmitted from the server into an optical signal; A first distribution for receiving the optical signal transmitted from the first optical transmission device through an optical line, transmitting the multimedia data to at least one display device in its vehicle, and transmitting the multimedia data to another neighboring vehicle Device; At least one display device for displaying multimedia data transmitted from the first distribution device; And a second optical transmission device positioned in another neighboring vehicle and converting the multimedia data transmitted from the first distribution apparatus into an optical signal and transmitting the optical data to a second distribution apparatus existing in the same vehicle through an optical line.

Preferably, the first distribution device and the second optical transmission device are connected by a coaxial cable.

Preferably, the first distribution device and the second optical transmission device are connected by a wireless LAN.

Preferably, the first distribution device and the display device are connected by an optical line.

Preferably, the distribution device is connected with one display device through an optical line, and the display devices are connected with a neighboring display device.

Preferably, the display devices are connected by using an optical line.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an entire train broadcasting system according to the present invention.

The train broadcasting system according to the present invention includes a train server 10. The train server is a conventional server computer, and the train server includes a GPS receiver for checking a current position, a mobile communication module for receiving living information such as real-time news information, control information, multimedia information, and the like through a mobile communication network; Wireless LAN modules for providing multimedia data and Internet services can be connected via a wireless LAN network.

The train server 10 stores train operation information, multimedia data, advertisement information, and broadcast schedule information as in the related art, and transmits the stored data according to the broadcast schedule information to each display device. In addition, the train server 10 collects the operation state of each device, and transmits the contents to the manager when a failure such as a failure occurs in a specific device. At this time, if the administrator is located at a remote site, the mobile communication module is used to notify the remote site of the failure. In addition, the train server 10 may download and store multimedia data from a multimedia center of a remote place through a wireless communication network (for example, a wireless LAN, a mobile communication network, etc.). In this case, the train server 10 manages the download history information of the multimedia data, and downloads only the multimedia data not downloaded. Of course, you can also manage your download history at a remote multimedia center. In this case, the download history is managed for each identifier of each train server, and only the multimedia data not downloaded is transmitted.

The optical transmission device 11 converts the video and audio data transmitted from the train server 10 into an optical signal and transmits the optical signal to the distribution device 12 through the optical path. In addition, the optical transmission device 11 periodically collects by requesting the operation state of the display device, and then converts the operation state measurement information transmitted from each device to the train server, and converts it to an electric signal. The optical transmission device 11 stores unique information of each display device, and may request operation state information of each display device at the request of a train server, and periodically requests operation state information of each display device. For example, after storing the transmitted operation state information, the train server may transmit the stored operating state information to the train server at the request of the train server.

The distribution device 12 converts the optical signal transmitted through the optical line into an electrical signal and transmits the optical signal to the optical transmission device 14 installed in another passenger vehicle through a coaxial cable. In addition, the distribution apparatus 12 converts the optical signal into an electrical signal and then converts the optical signal into an optical signal and transmits the same to the display apparatus 13 existing in the same vehicle. The distribution device 12 also includes a digital to analog converter for audio output to output the transmitted audio through the speaker.

The display device 13 includes a main board and an LCD panel. The display device 13 converts the optical signal transmitted from the distribution device 12 into an electrical signal and then displays the video signal through the LCD panel. On the other hand, the train broadcasting system according to the present invention includes a plurality of display devices per vehicle, the signal transmission between the display devices in the form of a chain. That is, as shown in FIG. 1, the main board of the display apparatus converts an optical signal transmitted from the distribution apparatus 12 into an electrical signal, and then converts the converted electrical signal into an optical signal and transfers the signal to a nearby display apparatus. do.

On the other hand, the train broadcasting system according to the present invention transmits a signal using a coaxial cable without using an optical line between the carriage and the carriage.

2 is a block diagram of an optical transmission device 11 according to the present invention.

One optical transmission device is provided for each vehicle, and FIG. 2 shows an optical transmission device installed in a carriage where a train server is located.

In FIG. 2, reference numeral 20 denotes a connector, to which a train server 10 is connected. The video signal input through the connector 20 is a low voltage differential signal (LVDS) level signal. Accordingly, the video signal converter 21 converts the LVDS level signal into a TTL (Transistor Transistor Logic) level signal. In the present invention, the video signal type has been described as an LVDS signal, but this is also possible in the case of other types of video signals. In this case, the video signal converter 21 converts the input video signal into a TTL level signal.

The audio signal converter 22 converts the analog audio signal into a digital audio signal, and then converts the digital audio signal into a Sonny / Philips Digital Interface (SPDIF) signal format. The digital audio signal in the SPDIF form is converted into a TTL level signal.

The sync processor 23 serves to match frame synchronization of a video signal. The LAN module 24 is provided to form a LAN network with a train server or other devices. The LAN module 24 converts LAN data into TTL level signals or converts TTL level signals into LAN data.

The EEPROM 26 stores programs for controlling the operation of the optical transmission device, unique identifier information of the device, and unique information of the display device. The processor 25 operates by loading a program from the EEPROM 26. The processor 25 controls usage rights of a bus, periodically requests and receives operation status information from display devices, and then trains the server. Upon request, the operation state information of each display device is transmitted to the train server. That is, the processor 25 requests the current operation state from each display device using the unique identification information of each display device stored in the EEPROM, and receives the operation state information from each display device. Then, at the request of the train server 10, the operation state information of each display device is transmitted to the train server. To this end, the processor 25 converts a control message into a signal converter 27 to transmit each display device as a destination, and receives operation state information reported from each display device through the signal converter 27. Save temporarily. Then, if required by the train server, the operation state information of each display device is transmitted to the train server through a signal line separately connected to the connector 20.

The signal converter 27 serializes the TTL level video data, audio data, and LAN data transmitted through the bus, and then converts the TTL level into an ECL level signal. At this time, the signal converter 27 operates under the control of the processor 25. In addition, the signal converter 27 converts a control signal for confirming an operation state of each device transmitted from the processor 25 into an ECL level signal and transmits the signal to the optical transmitter 28, and transmits it through the optical transmitter 28. The operation state signal of each device is converted into a TTL level signal and transmitted to the processor 25.

The optical transceiver 28 converts the ECL level signal converted by the signal converter 27 into an optical signal and transmits it through the optical line. 2, 29 shows an optical connector.

Meanwhile, the optical transmission device 11 may further include a connector for receiving an external audio signal. The external audio input connector may include an A / D converter (not shown) for converting an analog audio signal into a digital audio signal. Is connected).

In addition, the optical transmission device 11 may be further provided with a LAN connector for network connection with other devices. In order to network with other external devices, the optical transmission device 11 should include a LAN hub module (not shown).

3 is a block diagram of a distribution device according to the present invention.

The distribution device receives an optical signal and transmits it to a display device or to an optical transmission device of another vehicle. An optical connector is provided at one side to receive a signal from the optical transmission device through an optical line. An optical transceiver 30 is provided at the rear end of the optical connector. The optical transceiver 30 receives an optical signal transmitted from the optical transmission device and converts the optical signal into an ECL level signal, and operation of each device transmitted to the train server. It converts status information into optical signals and transmits them.

The signal converter 31 converts the ECL level signal converted by the optical transceiver 30 into a TTL signal. In addition, the signal converter 31 converts the operation state signal of the TTL level signal transmitted from each device into an ECL level signal and transmits the signal to the optical transceiver 30.

The TTL signal converted by the signal converter 31 is transmitted through the bus. The processor 35 is operated by a program stored in the EEPROM 36, which controls the usage rights of the bus. The EEPROM 36 stores a unique identifier of the distribution device. The unique identifier is used to confirm whether or not the control signal transmitted from the server is intended to be its destination, and is used to indicate the sender when transmitting its operation state information to the train server. The synchronization processor 34 performs a function of synchronizing the frame synchronization of the video signal among the TTL level signals converted by the signal converter 31.

The TTL level signal converted by the signal converter 31 is transferred to the signal converter 32 and the signal converter 37 via the bus. The signal converter 32 serializes the TTL level signal, converts the TTL level signal into an ECL level signal, and transmits the TTL level signal to the optical transceiver 33 for transmission to the display device. The optical receiver 33 converts the ECL level signal transmitted from the signal converter 32 into an optical signal and transmits the optical signal to the display device 13 through the optical connector.

On the other hand, the signal converter 37 serializes the TTL level signal transmitted from the signal converter 31, converts the TTL level signal into an ECL level signal, and transmits the same to the optical transmission device of the next passenger vehicle using a coaxial cable. That is, the signal changer 37 converts the video, audio, and LAN data converted into TTL level signals into ECL level signals and transmits them to the next passenger vehicle. In addition, the signal converter 37 converts the operation state information of each device transmitted from another passenger vehicle into a TTL level signal, and transmits the signal to the signal converter 31.

The audio signal converter 38 converts the audio signal of the TTL level transmitted from the signal converter 31 into a digital audio signal of SPDIF format and outputs it. Of course, the audio signal converter may convert the TTL level audio signal into an analog signal and output the analog signal to the speaker.

The LAN module 39 converts LAN data of the TTL level transmitted from the signal converter 31 into LAN data packets and transfers them to other network equipment through the connector.

On the other hand, the distribution device may be provided with a LAN hub (not shown) for connecting the LAN with the external network equipment.

4 is a detailed block diagram of an optical transmission apparatus for a passenger car in which a train server is not located.

The signal converter 40 receives the ECL level signal from the signal converter 37 of FIG. 3 and converts the ECL level signal into a TTL level signal. In addition, the signal converter 40 converts the operation state signal transmitted from each device into an ECL level signal and transmits the signal to the signal converter 37 of FIG.

The TTL level signal converted by the signal converter 40 is transferred to the signal converter 44 via a bus. Processor 42 is operated by a program stored in EEPROM 43, which controls the usage rights of the bus. The EEPROM 43 stores its own unique identifier. The unique identifier is used to confirm whether or not the control signal transmitted from the train server is intended for itself, and is used to indicate the sender when transmitting its operation state information to the train server. The synchronization processor 41 performs a function of synchronizing the frame synchronization of the video signal among the TTL level signals converted by the signal converter 40.

The signal converter 44 serializes the TTL level signal converted by the signal converter 40, converts the TTL level signal into an ECL level signal, and transmits the signal to the optical transceiver 45. In addition, the signal converter 44 converts the operation state information of the device transmitted from another passenger vehicle into a TTL level signal and transmits the signal to the signal converter 40 through the bus. The optical transmitter 45 converts the ECL level signal transmitted from the signal converter 44 into an optical signal and transmits the optical signal to a distribution apparatus in the same passenger vehicle through the optical connector.

In FIG. 4, the optical transmitter converts an ECL level signal into a TTL level signal, converts the TTL level signal into an ECL level signal, and then transmits the optical signal. However, this can be modified as follows. If the transmission distance is short, there is no signal attenuation. Therefore, the ECL level signal transmitted from the neighboring passenger vehicle is directly converted into an optical signal through the optical transmitter and transmitted to the distribution device in the same passenger car. The optical signal transmitted from the device may be converted into an ECL level signal through an optical transmitter and transmitted to a distribution device of a neighboring passenger vehicle. Therefore, in FIG. 4, the optical transmission device may include only the optical transmitter and receiver.

5 is a block diagram of a main board of the display device according to the present invention.

The display device converts the optical signal transmitted from the distribution device into an electrical signal and outputs it through the LCD panel, and converts the converted electrical signal into an optical signal and transfers it to another display device. It looks at the specific configuration for this with reference to the drawings.

The optical signal transmitted from the distribution device is converted into an ECL level signal by the optical transceiver 51 connected to the connector 50. The ECL level signal converted by the optical transceiver 51 is converted into a TTL level signal by the signal converter 52 and transferred to the bus. The synchronization processor 53 performs a function of synchronizing the video frame of the TTL level signal converted by the signal converter 52.

The EEPROM 58 stores a program for performing an operation and its own unique identifier. The processor 57 controls each component and the use of the bus according to a program stored in the EEPROM 58. The TTL level signal converted by the signal converter 52 is converted into an ECL level signal by the signal converter 54 again for delivery to another display device. The ECL level signal converted by the signal converter 54 is converted into an optical signal by the optical transceiver 55 and transmitted to another display device through the optical connector 56.

On the other hand, the TTL level signal converted by the signal converter 52 is transmitted to the signal converter 59 via the bus. The signal converter 59 converts the TTL level signal into an LVDS level signal and transmits it to the LCD panel connected to the connector 61. As a result, video is displayed on the LCD panel.

Meanwhile, the current meter 60 measures the current of the board under the control of the processor 57. The processor checks the board for failure from the result of the current meter 60, and transmits the TTL level signal to the signal converter 52 to transmit the result to the train server.

The present invention as described above can be modified in the following form.

In an exemplary embodiment of the present invention, the display devices are connected in a chain form, but it may be possible to connect them in a star form through a digital divider. In this case, a digital cable is used to connect the digital splitter and the display devices without using an optical cable.

According to the present invention as described above, in broadcasting the multimedia data stored in the train server to each display device in the carriage, it is possible to transmit the multimedia data at high speed without damaging the aesthetics in the carriage.

Claims (15)

In the train broadcasting system, At least one server for storing multimedia data, transmitting the multimedia data according to a broadcast schedule, and checking a failure state of each device; A first optical transmission device for converting and transmitting multimedia data transmitted from the server into an optical signal; A first distribution receiving the optical signal transmitted from the first optical transmission device through optical preference, transmitting the multimedia data to at least one display device in its own object, and transmitting the multimedia data to another neighboring vehicle Device; At least one display device for displaying multimedia data transmitted from the first distribution device; And Located in a neighboring passenger car, connected to the first distribution device via a coaxial cable, the multimedia data transmitted from the first distribution device is converted into an optical signal and transmitted to a second distribution device existing in the same vehicle through an optical line. A second optical transmission device, The first optical transmission device, A video signal converter for converting a video signal into a TTL level signal, An audio signal converter that converts analog audio signals into digital audio signals, A first sync processor for frame synchronization of the video signal, A first memory for storing an operating program and a device unique identifier, A first processor which loads and operates an operating program stored in the first memory and controls each component; A first signal converter for converting the TTL level signal converted by the video signal converter into a level signal for optical transmission; A first optical transceiver for converting the output of the first signal converter into an optical signal and converting the received optical signal; The second optical transmission device, A second optical transceiver for converting an electrical signal transmitted from the first distribution device into an optical signal and transmitting the optical signal to the second distribution device; A second signal converter for converting the ECL level signal transmitted from the first distribution device into a TTL level signal; A second synchronization processor for synchronizing the video frame of the signal converted by the second signal converter; A second memory for storing an operating program and a device unique identifier; A second processor configured to load and operate an operation program stored in the second memory, and to control each component; And a third signal converter converting the TTL level signal converted by the second signal converter into a level signal for optical transmission and transmitting the converted TTL level signal to the second optical transceiver. delete delete delete delete delete delete delete The method of claim 1, The first and second optical transmission device, And a LAN module for converting a LAN packet into a TTL level signal and converting the TTL level signal into a LAN packet for a network connection between the devices. The method of claim 9, The first and second optical transmission device, The train broadcasting system further comprises a LAN hub for network connection with an external device. The method of claim 1, The distribution device, A third optical transceiver for transmitting / receiving an optical signal with the optical transmitter; A fourth signal converter for converting a signal input from the third optical transceiver into a TTL level signal; A fifth signal converter converting the TTL level signal transmitted from the fourth signal converter into a signal for optical transmission; A fourth optical transceiver connected to the fifth signal converter to transmit and receive an optical signal with the display device; A third memory for storing an operation program and its own unique identifier; A third processor which loads an operation program stored in the third memory and controls each component; A third synchronization processor for synchronizing the video frame of the TTL level signal converted by the fourth signal converter; A sixth signal converter for converting the TTL level signal converted by the fourth signal converter into an ECL level signal; And And an audio signal converter for converting the TTL level audio signal converted by the fourth signal converter into a signal for audio reproduction. The method of claim 11, The distribution device, And a LAN module for converting a LAN packet into a TTL level signal and converting the TTL level signal into a LAN packet for a network connection between the devices. The method of claim 12, The distribution device, The train broadcasting system further comprises a LAN hub for network connection with an external device. The method of claim 1, The display device, A fifth optical transceiver for transmitting and receiving an optical signal with the distribution device; A seventh signal converter connected to the fifth optical transceiver to perform signal conversion; An eighth signal converter configured to signal convert the output of the seventh signal converter to another neighboring display device; A fourth synchronization processor for synchronizing the video frame of the signal converted by the seventh signal converter; A fourth memory for storing the operation program and its unique identifier; A fourth processor for controlling each component by loading an operation program stored in the fourth memory; A ninth signal converter for converting the signal converted by the seventh signal converter to the LCD panel; And And a sixth optical transceiver connected to the eighth signal converter to transmit and receive an optical signal with another neighboring display device. The method of claim 14, The display apparatus further includes a current meter for measuring the current to check the fault state of the device under the control of the fourth processor.

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