JP2005033300A - Video information transmission method to train - Google Patents

Abstract

An object of the present invention is to provide a video transmission method to a train that can efficiently transmit video information from the ground side to the train by wireless communication.
An onboard station detection step (S1) for detecting an onboard station in a state in which wireless communication is possible by transmitting and receiving a predetermined signal between the ground station and the onboard station, A measurement station selection step S2 for selecting one on-board station as a measurement station for measuring the transmission quality of wireless communication with the ground station, and transmitting and receiving a predetermined data signal between the measurement station and the ground station. A transmission quality measurement step S3 for measuring the transmission quality of the wireless communication, a transmission permission determination step S4 for permitting the transmission of the video information when the measured transmission quality is equal to or higher than a predetermined value, and the transmission of the video information to the measuring station. Transmission end determination step S7 for determining the end is provided, and video information is transmitted from the ground station to the on-board station by wireless communication.
[Selection] Figure 3

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a video information transmission method to a train that mainly transmits video information having a large amount of data, among data transmission methods to a train that transmits data by radio communication to the train from the ground side. .
[0002]
[Prior art]
In the conventional data transmission method to trains, the position of the train that can transmit data in advance (hereinafter referred to as “communicable position”) is determined, and the position of the train is identified and specified from the ground side. When the train position matches the communicable position, data is transmitted from the ground side to the train. As a method of grasping and specifying the position of the train from the ground side, there were a method of detecting that the train arrived at the station, a method of judging based on the status of the train line and the route status assigned to the train, etc. (For example, refer to Patent Document 1).
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 10-203369 (page 3, FIG. 4 and FIG. 6)
[0004]
[Problems to be solved by the invention]
In the conventional data transmission method to trains, when data transmission is performed for a plurality of trains, first the first train is operated to a communicable position, and data transmission is performed from the ground side to the first train. Next, the first train is operated from the communicable position to another position, and then the second train is operated to the communicable position, and data transmission is performed from the ground side to the second train. The same applies to the third and subsequent trains. In this way, the train for which data transmission has been completed is operated from a communicable position to another position, and the next train is operated to a communicable position, that is, train replacement work frequently occurs. Since the data communication cannot be performed during the replacement work, there is a problem in that the efficiency of data transmission to a plurality of trains is lowered.
[0005]
Further, when the data to be transmitted is video information as in the present invention, the amount of data increases, and therefore the data transmission time becomes long. In the conventional data transmission method to trains, if one train occupies a communicable position for a long time, it will hinder the operation of other trains, for example, it will take longer time to wait for the next train to another position. If the time for one train to occupy a communicable position (hereinafter referred to as “communication occupancy time”) is restricted short, the amount of data that can be transmitted is limited, and the data There is a problem that transmission of video information with a large amount cannot be completed within a predetermined communication occupation time.
[0006]
Furthermore, when it is determined that the train is in a communicable position when the method of determining the position of the train from the ground side is adopted based on the status of the current train or the route status assigned to the train Even so, the actual data transmission performance may not reach the predetermined performance at the communicable position due to the influence of the deviation of the train position, the situation around the train, and the like. For this reason, for multiple trains, the communication occupation time of the train is longer than the scheduled time, or data transmission is not completed within the predetermined communication occupation time, and replacement work is required again. As a result, the efficiency of data transmission is reduced.
[0007]
The present invention has been made to solve the above-described problems, and video information that has a large amount of data and requires a long time for data transmission can be efficiently transmitted from the ground side to the train by radio communication. An object of the present invention is to obtain a video information transmission method to a train that can be transmitted.
[0008]
[Means for Solving the Problems]
In the video information transmission method to the train according to the present invention, the ground station installed on the ground side and the on-board station mounted on the train store transmission / reception means and video information capable of wireless communication between them. An onboard station detecting step for detecting an onboard station in a state in which wireless communication is possible by transmitting and receiving a predetermined signal between the ground station and the onboard station. A measuring station selection step of selecting one on-board station from among the detected on-board stations as a measuring station to be measured for transmission quality of wireless communication with the ground station, the measuring station and the ground station; A transmission quality measurement step for measuring the transmission quality of wireless communication by transmitting and receiving a predetermined data signal between, and whether or not to allow transmission of the video information when the measured transmission quality is equal to or higher than a predetermined value Judgment Step, includes a transmission end determining step of determining the end of transmission of the video information for the measuring station, in which so as to transmit the video information by wireless communication with respect to the vehicle upper station from the ground station.
[0009]
Moreover, in the video information transmission method to the train according to the present invention, the ground station installed on the ground side and the on-board station mounted on the train have transmission / reception means and video information capable of wireless communication between them. Vehicle station detection step for detecting an onboard station in a state in which wireless communication is possible by transmitting and receiving a predetermined signal between the ground station and the onboard station. A transmission quality measurement step of measuring transmission quality of wireless communication by transmitting and receiving a predetermined data signal between the detected on-board station and the ground station, and the measured transmission quality is a predetermined value or more A reference station selection step for selecting one on-board station from among a certain on-board station as a reference station to be determined for the end of transmission of the video information, transmission for determining the end of transmission of the video information to the reference station It includes a completion determination step, in which so as to transmit the video information by wireless communication with respect to the vehicle upper station from the ground station.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
FIG. 1 is an overall configuration diagram of a train stop used in a video information transmission method to a train according to Embodiment 1 of the present invention. On the ground, the railroad track 2 and railroad tracks 2a to 2c branching from the railroad track 2 are laid to constitute a train stop. A ground station 4 is installed on the ground side, and performs wireless communication via an antenna 6. A train 8 is stopped on the railroad track 2 and a train 10 is stopped on the railroad track 2b. The top station 12a and the antenna 14a, the onboard station 12b, and the antenna 14b are mounted on the leading vehicles of the train 8 and the train 10, respectively, and perform wireless communication with the ground station 4. For this wireless communication, a wireless communication line capable of data communication such as digital data is used. The onboard station 12a and the onboard station 12b have the same configuration, and the antenna 14a and the antenna 14b have the same configuration. In addition, FIG. 1 shows a case where two trains are stopped at a train stop, but a train with a similar onboard station and antenna of three trains or more may be stopped. Many more railway tracks may be laid.
[0011]
FIG. 2 is a block diagram of the ground station 4 and the onboard station 12a in the video information transmission method to the train according to the first embodiment. In addition, the onboard station mounted on other trains including the onboard station 10b of the train 10 has the same configuration as the onboard station 12a. The ground station 4 is connected to the ground station transmission / reception device 20 which is the first transmission / reception means for performing wireless communication with the onboard station 12a, the ground station video information storage device 22 which is the first video information storage means, and the ground station 4. On the other hand, to control the data input / output device 24 for inputting / outputting control information and other information such as advertisements in the train, still images such as station equipment, video information relating to moving images, train operation management data, and the like from the outside. The ground station controller 26 is provided. The antenna 6 shown in FIG. 1 is assumed to be included in the ground station transceiver 20.
[0012]
The onboard station 12a is an onboard station transmission / reception device 40 as second transmission / reception means for performing wireless communication with the ground station 4, an onboard station video information storage device 42 as second image information storage means, an onboard station. A video distribution device 44 for distributing the video information stored in the video information storage device 42 to a video display device or the like (not shown) in the train and an on-board station control device 46 for controlling them are provided. . It is assumed that the antenna 14a shown in FIG.
[0013]
The video information transmission method to the train according to the first embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. When the operation starts in FIG. 3, first, in the onboard station detection step S1, the onboard station on which the ground station 4 can wirelessly detect is detected. Here, the processing procedure in the onboard station detection step S1 will be described based on the sequence shown in FIGS. 4A to 4C, the same reference numerals as those in FIG. 2 denote the same or equivalent parts.
[0014]
(A) of FIG. 4 has shown the process sequence in the most basic onboard station detection step S1 in case only the train 8 can communicate in the train stop shown in FIG. At time interval T1, the ground station 4 transmits an opening request signal Q1 that is a first predetermined signal once, and the on-board station 12a of the train 8 receives the first opening request signal Q1 and receives the second opening request signal Q1. A station opening response signal A1, which is a predetermined signal, is transmitted.
[0015]
The operations of the ground station 4 and the onboard station 12a in this processing procedure will be described with reference to FIG. In the ground station 4, the ground station control device 26 transmits a station opening request signal Q 1 from the ground station transmitting / receiving device 20. When the onboard station 12a receives the opening request signal Q1 at the onboard station transmission / reception device 40, the onboard station control device 46 transmits an opening response signal A1 including an ID code identifying the train from the onboard station transmission / reception device 40. . When the ground station 4 receives the opening response signal A1 by the ground station transmission / reception device 20, the ground station control device 26 determines that the onboard station 12a is an onboard station capable of wireless communication, and determines the reception time on the vehicle. The time when the station 12a is detected. Further, the ground station control device 26 determines that the onboard station 12a is an onboard station of the train 8 by using the ID code. The ground station control device 26 stores that the onboard station 12a is detected, the detected time, and that the onboard station 12a is the onboard station of the train 8. The ground station control device 26 includes a memory unit for storing information necessary for control including these pieces of information.
[0016]
FIG. 4B is an example of the processing procedure in the onboard station detection step S1 when only the train 8 can communicate at the train stop shown in FIG. There is no response from the onboard station 12a to the first and second opening request signals Q1 transmitted from the station 4, and the onboard station 12a receives the third opening request signal Q1 in FIG. This is to transmit a station opening response signal A1 similar to a). The ground station 4 repeats transmission of the opening request signal Q1 and reception of the same opening response signal A1 from the on-board station at a constant time interval T1.
[0017]
FIG. 4C illustrates an example of a processing procedure in the onboard station detection step S1 when the train 8 and the train 10 can communicate at the train stop illustrated in FIG. For the first opening request signal Q1 transmitted from the ground station 4, there is no response from either the onboard station 12a of the train 8 or the onboard station 12b of the train 10, and the onboard station 12a receives the second opening request signal. Receives Q1 and transmits an opening response signal A1 similar to (a) in FIG. 4, and the onboard station 12b receives the third opening request signal Q1 and transmits a similar opening response signal A1 It is.
[0018]
For example, the on-board station 12a and the on-board station 12b may both receive the opening station request signal Q1 and transmit the opening station response signal A1, and these opening station response signals A1 reach the ground station 4. In order to prevent the timing from being overlapped, the on-board stations transmit the opening response signal A1 after a different delay time has elapsed after receiving the opening request signal Q1. Yes. Therefore, even when there are three or more trains that can be communicated, the timing at which the opening request signal Q1 from the onboard station mounted on these trains arrives at the ground station 4 is not overlapped, and the reception is impossible. The on-board station capable of communication can be detected by the procedure described above. In addition, the method for identifying a train on which a communicable on-board station is mounted using an ID code has been described above, but the train on which a communicable on-board station is mounted can be identified from the difference in the delay time. Is also possible.
[0019]
Returning to the description of FIG. The onboard station detection step S1 is continued until at least one onboard station capable of wireless communication is detected. When one or more onboard stations capable of wireless communication are detected, the measurement station selection step S2 is performed. Transition. In the following description, as in the example shown in FIG. 4C, the onboard station 12a is first detected, then the onboard station 12b is detected, and the process proceeds to the measuring station selection step S2. And
[0020]
In the measurement station selection step S2, the ground station control device 26 of the ground station 4 selects the vehicle station from one or more vehicle stations detected as the vehicle station capable of wireless communication in the vehicle station detection step S1. One onboard station that measures the transmission quality of wireless communication with the station 4 is selected (hereinafter, the selected onboard station is referred to as a “measuring station”). In the first embodiment, the selection condition for this measurement station is “the one that has not been selected as the measurement station, the one that has been detected at the onboard station detection step S1 is the earliest”, and is shown in FIG. As shown in (c), the onboard station 12a detected earlier is selected as the measuring station from the onboard station 12a and the onboard station 12b. Note that the measuring station selection step S2 terminates the entire operation shown in FIG. 3 when there is no on-board station that meets the above selection conditions (branch “No” in the figure).
[0021]
Next, the process proceeds to transmission quality measurement step S3, and the transmission quality between the ground station 4 and the measurement station is measured. Here, the processing procedure in the transmission quality measurement step S3 will be described based on the sequence shown in FIG. In FIG. 5A, the same reference numerals as those in FIG. 2 denote the same or corresponding parts.
[0022]
FIG. 5A shows a processing procedure in the transmission quality measurement step S3. A predetermined data signal Q2 is transmitted from the ground station 4 at a constant time interval T2, and the on-board station 12a serving as a measurement station When the predetermined data signal Q2 is received, the predetermined data signal A2 is transmitted.
[0023]
The operation of the ground station 4 and the on-board station 12a as the measurement station in this processing procedure will be described with reference to FIG. In the ground station 4, the ground station control device 26 transmits a predetermined data signal Q 2 from the ground station transmission / reception device 20. When the onboard station 12a receives the predetermined data signal Q2 at the onboard station transmitting / receiving device 40, the onboard station control device 46 transmits the predetermined data signal A2 from the onboard station transmitting / receiving device 40. An ID code of the onboard station 12a is added to the predetermined data signal A2. When the ground station 4 receives the predetermined data signal A2 at the ground station transmitting / receiving device 20, the ground station control device 26 uses the ID code to transmit the received predetermined data signal A2 from the onboard station 12a. Then, the transmission quality between the ground station 4 and the onboard station 12a is calculated, and the calculated transmission quality is stored in the ground station control device 26.
[0024]
As the predetermined data signal A2, the received signal including the error being transmitted in the predetermined data signal Q2 may be transmitted as it is as the predetermined data signal A2 without performing error correction or the like. In this way, when the predetermined data signal A2 is received by the ground station 4, there is an error received while the predetermined data signal Q2 is transmitted back and forth between the ground station 4 and the onboard station 12a. The transmission quality of the transmission path can be calculated by comparing this with the initial predetermined data signal Q2.
[0025]
Returning to the description of FIG. After performing the transmission quality measurement step S3, the process proceeds to the transmission availability determination step S4. In the transmission availability determination step S4, when the transmission quality of the measurement station measured in the transmission quality measurement step S3 is higher than a predetermined value by the ground station control device 26 of the ground station 4, the process proceeds to the data transmission / reception step S5 (in the figure). If “Yes” branch) is lower than the predetermined value, the process proceeds to the measurement station selection step S2 (“No” branch in the figure). When the transmission quality is lower than the predetermined value and the process proceeds to the measurement station selection step S2, the onboard station 12a selected as the measurement station does not meet the selection conditions of the measurement station and is selected as the next measurement station. The on-board station 12b is not selected as the next measuring station.
[0026]
When the transmission quality is higher than a predetermined value and the process proceeds to the data transmission / reception step S5, the video information is transmitted from the ground station 4, and the onboard station 12a and the onboard station 12b, which are measurement stations, receive the video information. . Next, in the reception response step S6, the onboard station 12a, which is the measurement station, transmits a reception response signal indicating whether or not the reception of the video information has been normally completed to the ground station 4. Here, the processing procedure in the data transmission / reception step S5 and the reception response step S6 will be described based on the sequences shown in FIG. 5B and FIG. 5C. In FIG. 5B and FIG. 5C, the same reference numerals as those in FIG. 2 denote the same or equivalent parts.
[0027]
FIG. 5B shows a processing procedure in the data transmission / reception step S5, in which the video information D3 is transmitted from the ground station 4, and is received and stored by the onboard station 12a. The operations of the ground station 4 and the onboard station 12a in this processing procedure will be described with reference to FIG. The ground station control device 26 reads the video information D3 (not shown in FIG. 2) from the ground station video information storage device 22, and transmits this video information D3 from the ground station transmission / reception device 20. The onboard station 12a receives the video information D3 by the onboard station transmitting / receiving device 40, and when receiving it normally, stores the received video information D3 in the onboard station video information storage device. Although not shown, this data transmission / reception step S5 is also executed in the onboard station 12b not selected as the measurement station.
[0028]
When an onboard station capable of two or more wireless communications is detected in the onboard station detection step S1, an onboard station that is not selected as a measurement station can receive video information transmitted by the ground station 4. The difference is that the video information is not retransmitted as in the measurement station when the reception of the video information at the on-board station not selected as the measurement station is not normally completed. is there.
[0029]
(C) of FIG. 5 shows the processing procedure of the reception response step S6, and the onboard station 12a, which is the measurement station that has received the video information D3 shown in (b) of FIG. 5, transmits the reception response signal A4. Is. The operation of the ground station 4 and the on-board station 12a as the measurement station in this processing procedure will be described with reference to FIG. When the onboard station transceiver 40 receives the video information D3, the onboard station 12a determines whether the onboard station control apparatus 46 has received the video information D3 normally, and the result is a reception response signal A4. Send as. The ID code of the onboard station 12a is added to the reception response signal A4. When the ground station 4 receives a predetermined reception response signal A4 at the ground station transmission / reception device 20, the ground station control device 26 uses the ID code to transmit the received reception response signal A4 from the onboard station 12a. Then, the ground station control device 26 stores whether or not the onboard station 12a has successfully received the video information D3 (hereinafter referred to as “reception determination result”).
[0030]
As described above, the onboard station detection step S1, the transmission quality measurement step S3, the data transmission / reception step S5, and the reception response step S6 shown in FIG. 3 are shown in FIGS. 4 and 5 (a) to (c). As described above, the on-board station is a processing procedure in which communication is performed with the ground station. Here, the operation of the on-board station in these processing procedures will be described in more detail with reference to the flowchart shown in FIG. The entire operation shown in FIG. 6 starts when the onboard station enters the train stop. When the onboard station 12a starts the entire operation shown in FIG. 6, the operation first proceeds to an operation continuation determination step S10 for determining whether to continue or stop the operation. The operation continuation determination step S10 terminates the entire operation shown in FIG. 6 of the onboard station 12a when an instruction to terminate the operation is given by a train driver or the like (“No” branch in the figure. The on-board station 12a normally shifts to a reception standby step S11 in which a signal transmitted from the ground station 4 by wireless communication is on standby (“Yes” in the figure). ”Branch). In the following description, it is assumed that the operation is not forcibly terminated in the operation continuation determination step S10, and the routine always shifts to the reception standby step S11 (branch “Yes” in the figure).
[0031]
When the onboard station 12a receives the signal transmitted from the ground station 4 in the reception standby step S11, the onboard station 12a proceeds to a reception signal determination step S12 for determining the content of the signal. Different patterns specific to the signal type are arranged at the head of the signal transmitted from the ground station 4, and the onboard station 12a determines the type of signal by the onboard station controller 46 based on this pattern. It is to be determined. In the reception signal determination step S12, the operation proceeds to the next corresponding step so that the operation corresponding to each signal is performed according to the type of the signal received by the onboard station 12a. When the received signal is the station opening request signal Q1, the process proceeds to the station opening response signal transmission step S13 (branch “B1” in the figure), and after transmitting the station opening response signal A1, the process proceeds to the operation continuation determining step S10. In the operation continuation determination step S10, the process is shifted to the reception standby step S11 (because the forced termination is not performed as described above) (the branch of “Yes” in the drawing), and enters the reception standby state.
[0032]
When the received signal is the predetermined data signal Q2, the process proceeds to the data signal transmission step S14 (branch “B2” in the figure), and after the predetermined data signal A2 is transmitted, the operation continuation determination step S10 and then the reception standby The process proceeds to step S11 to enter a reception standby state. When the received signal is video information D3, the process proceeds to video information storage step S15 (branch “B3” in the figure). When the video information D3 is normally received, the video information is stored in the on-board station video information. The data is stored in the device 42 and is not stored when it cannot be normally received. Next, the process proceeds to a reception response signal transmission step S16 to transmit a reception response signal A4. Thereafter, the process proceeds to the operation continuation determination step S10 and then to the reception standby step S11 to enter the reception standby state.
[0033]
Although not shown, when the received signal is not one of the opening request signal Q1, the predetermined data signal Q2, and the video information D3, the process proceeds to the operation continuation determination step S10, and then the reception standby step S11 is received. It will be in a standby state. When there is no signal to be received, the onboard station 12a is always in a reception standby state with respect to the signal transmitted from the ground station. Depending on the type of the signal transmitted from the onboard station 4, the subsequent processing procedure of the onboard station 12a Is to be decided. That is, when the ground station 4 executes the onboard station detection step S1, the transmission quality measurement step S3, the data transmission / reception step S5, and the reception response step S6, the onboard station 12a also follows the operation of the ground station 4 to perform these steps. This processing procedure is executed.
[0034]
Further, when there is an onboard station other than the onboard station 12a at the train stop, these onboard stations perform the same operation as the onboard station 12a independently. When a signal is transmitted from the ground station 4, each on-board station receives the transmitted signal all at once, and performs a processing procedure according to the type of the received signal. If the transmitted signals are the opening request signal Q1, the predetermined data signal Q2, and the video information D3, each on-board station transmits signals corresponding to these signals (opening response signal A1, predetermined data signal A2, The reception response signal A4) is transmitted independently, but as described above, each onboard station transmits after a different delay time has elapsed after reception, so it transmits from each onboard station. The timing at which the signals reach the ground station 4 does not overlap.
[0035]
The opening station response signal transmission step S13 is a procedure in which the onboard station transmits the opening station response signal A1 in the onboard station detecting step S1, and the onboard station transmits a predetermined data signal in the transmission quality measurement step S3. The video information storage step S15 stores the video information D3 normally received by the on-board station in the data transmission / reception step S5, and the reception response signal transmission step S16 receives the on-station station in the reception response step S6. Shows a procedure for transmitting the reception response signal A4. The operation continuation determination step S10, the reception standby step S11, and the reception signal determination step S12 are processing procedures executed by the onboard station control device 46.
[0036]
Returning to the description of FIG. In the transmission end determination step S7, the ground station control device 26 shifts to the measurement station selection step S2 based on the reception determination result when the reception of the video information is normally completed (branch “Yes” in the figure). When reception is not normally completed due to the occurrence of a burst-like transmission error during video information transmission, the process returns to the data transmission / reception step S5 ("No" branch in the figure), and the video information is retransmitted. When the process proceeds to the measurement station selection step S2, the on-board station 12a selected as the measurement station does not meet the selection conditions of the measurement station and is not selected as the next measurement station. Station 12b will be selected as the next measurement station.
[0037]
That is, the onboard station 12a and the onboard station 12b detected in the onboard station detection step S1 are selected as measurement stations in the order of the detected times to transmit video information, and the onboard station 12a and the onboard station After 12b is selected as the measurement station once, there is no on-board station to be selected in the measurement station selection step S2. Therefore, the whole operation shown in FIG. 3 is completed without selecting the measurement station in the measurement station selection step S2. (Branch “No” in the figure). According to the same procedure, even if there are three or more on-board stations detected in the on-board station detection step S1, the video stations are selected as measurement stations in the order of the detected times to transmit video information. After all the on-board stations detected in the detection step S1 are selected as measurement stations once, there is no on-board station to be selected in the measurement station selection step S2. Therefore, the measurement station is selected in the measurement station selection step S2. The entire operation shown in FIG. 3 is terminated (“No” branch in the figure). When the entire operation shown in FIG. 3 is completed, the ground station control device 26 controls to start the entire operation shown in FIG. 3 again. Therefore, while the video information transmission method to the train according to the first embodiment is being executed, the entire operation from the start to the end shown in FIG. 3 is repeatedly executed.
[0038]
If the transmission quality between the ground station 4 and the measurement station deteriorates after the transmission quality measurement step S3 or the measurement station breaks down, in the transmission end determination step S7, the video information is normally received. Since the reception response signal that has not been completed is repeatedly received, the video information is retransmitted repeatedly, or the reception response signal is not received, and thus the device waits for a long time. In order to prevent such a situation, the transmission end determination step S7 repeats the reception response signal that the reception of the video information is not normally completed a predetermined number of times, or the reception response signal is not received for a predetermined time. In some cases, it has a function of determining the end of transmission.
[0039]
In the video information transmission method to the train thus configured, when the ground station detects an on-board station capable of wireless communication, and there is an on-board station whose transmission quality between these is higher than a predetermined value. Since the video information is transmitted, it takes a long time to complete the transmission of the video information to the onboard station with low transmission quality, and other onboard stations can be prevented from waiting during that time. There is an effect that video information having a large amount of data and a long transmission time can be efficiently transmitted to a plurality of trains.
[0040]
Embodiment 2. FIG.
The video information transmission method to the train according to the second embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. 7 with the same reference numerals as those in FIG. 3 are the same or equivalent. Here, it is assumed that the train 8 and the train 10 are stopped at the train stop shown in FIG. 1, and the onboard station 12 a and the onboard station 12 b are in a state where they can communicate with the ground station 4.
[0041]
When the operation starts in FIG. 7, the on-board station 12a and the on-board station 12b are detected in the on-board station detection step S1 as on-board stations on which the ground station 4 can perform wireless communication, and the process proceeds to the transmission quality measurement end determination step S18. To do. In this case, it is assumed that the onboard station 12a is detected first and then the onboard station 12b is detected, as in FIG. 4C of the first embodiment. Using the ID code included in the opening response signal, the ground station 4 determines that the onboard station 12a is the onboard station of the train 8 and the onboard station 12b is the onboard station of the train 10, and stores it. This is the same as in the first embodiment.
[0042]
The transmission quality measurement end determination step S18 shifts to the reference station selection step 20 when the transmission quality measurement is completed for all the onboard stations detected at the onboard station detection step S1 (the branch of “Yes” in the figure). ) If there is an on-board station for which transmission quality measurement has not been completed, the on-board station to be measured is designated and the process proceeds to transmission quality measurement step S3 ("No" branch in the figure). The order of measurement is the order of the times detected in the onboard station detection step S1. Note that the order of measurement may be appropriately determined based on the train ID code or the like. The measured transmission quality of each on-board station is stored in the ground station controller 26.
[0043]
When the onboard station 12a and the onboard station 12b are detected in the onboard station detection step S1 and the process proceeds to the transmission quality measurement end determination step S18, the onboard station 12a with the earlier detected time is selected as the onboard station to be measured. Designate and move to transmission quality measurement step S3 ("No" branch in the figure), measure the transmission quality of the on-board station 12a, store the result in the ground station controller 26, and measure the transmission quality The process returns to the end determination step S18. Next, the onboard station 12b is designated as the onboard station to be measured, the process proceeds to the transmission quality measurement step S3 (the branch of “No” in the figure), the transmission quality of the onboard station 12b is measured, and the result Is stored in the ground station controller 26, and the process returns to the transmission quality measurement end determination step S18. The transmission quality measurement end determination step S18 designates all the onboard stations detected in the onboard station detection step S1 as onboard stations whose transmission quality is to be measured once, and proceeds to the transmission quality measurement step S3. Then, it is determined that the transmission quality measurement is completed. Therefore, at this stage, all the onboard stations detected in the onboard station detection step S1, that is, the onboard station 88a and the onboard station 88b are designated as onboard stations whose transmission quality is to be measured once. Therefore, it is determined that the measurement of the transmission quality is completed, and the process proceeds to the reference station selection step 20 (branch “Yes” in the figure).
[0044]
The reference station selection step 20 selects one on-board station to be determined as the end of transmission of video information (hereinafter, the selected on-board station is referred to as “reference station”). That is, in the transmission end determination step S7, the transmission end is determined based on the reception response signal from the reference station. In the second embodiment, the reference station selection condition is “has never been selected as a reference station and has the highest transmission quality among transmission quality higher than a predetermined value”. Here, the transmission quality of the onboard station 12a and the onboard station 12b are both higher than the predetermined value, and the transmission quality of the onboard station 12a is higher than the transmission quality of the onboard station 12b. Therefore, the reference station selection step 20 selects the onboard station 12a as the reference station, and shifts to the data transmission / reception step S5 (branch “Yes” in the figure). Note that the reference station selection step S20 terminates the entire operation shown in FIG. 7 (the “No” branch in the figure) when there is no on-board station that meets the above selection conditions.
[0045]
In the data transmission / reception step S5, video information is transmitted from the ground station 4, and the onboard station 12a and the onboard station 12b, which are reference stations, receive the video information. Next, in the reception response step S6, the onboard station 12a, which is a reference station, transmits a reception response signal indicating whether or not the reception of the video information has been normally completed to the ground station 4. In addition, the ID code of the onboard station 12a is added to the reception response signal, and the received reception response signal is transmitted from the onboard station 12a using the ID code by the ground station control device 26. In the same manner as in the first embodiment, the ground station control device 26 stores the reception determination result.
[0046]
In the transmission end determination step S7, based on the reception determination result, the ground station control device 26 shifts to the reference station selection step S20 when the reception of the video information is normally completed (branch “Yes” in the figure). When reception is not normally completed due to the occurrence of a burst-like transmission error during video information transmission, the process returns to the data transmission / reception step S5 ("No" branch in the figure), and the video information is retransmitted. When the process proceeds to the reference station selection step S20, the onboard station 12a that has been selected as the reference station does not meet the selection conditions of the reference station, and therefore is not selected as the next reference station. 12b will be selected as the next reference station.
[0047]
Since the transmission quality of the onboard station 12a and the onboard station 12b detected in the onboard station detection step S1 is higher than the predetermined transmission quality, the video information is selected and transmitted as the reference station in the order of higher transmission quality. It will be. When there are three or more on-board stations detected in the on-board station detection step S1 and whose transmission quality is higher than the predetermined transmission quality, after all of them are selected as reference stations once, the reference station selection step The entire operation shown in FIG. 7 is terminated without selecting a reference station in S20 ("No" branch in the figure). While the video information transmission method to the train according to the second embodiment is being executed, the whole operation from the start to the end shown in FIG. 7 is repeatedly executed as in the first embodiment.
[0048]
In the transmission end determination step S7, as in the first embodiment, when a reception response signal indicating that reception of video information has not ended normally is received a predetermined number of times, or a reception response signal is not received for a predetermined time. In some cases, it has a function of determining the end of transmission. The operation of the onboard station of the second embodiment is the same as the operation of the onboard station of the first embodiment shown in FIG.
[0049]
In the video information transmission method to the train configured as described above, the same effects as in the first embodiment can be obtained, and further, the completion of transmission of the video information can be confirmed in order from the onboard station with the higher transmission quality. Therefore, there is an effect that the transmission efficiency of video information for a plurality of trains can be further increased.
[0050]
Embodiment 3 FIG.
The video information transmission method to the train according to the third embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. 8, the same reference numerals as those in FIG. 3 denote the same or corresponding parts. The third embodiment is similar to the first embodiment shown in FIG. 3 in the update data confirmation step S30 for confirming the video information to be transmitted to the onboard station, and the data transmission / reception step S5 only when the video information to be updated exists. The update execution determination step S31 to be shifted to is added.
[0051]
The operation from the start of the operation to the transmission permission / inhibition determination step S4 is the same as that of the first embodiment. In the transmission feasibility determination step S4, when the transmission quality measured in the transmission quality measurement step S3 is lower than a predetermined value, the operation to shift to the measurement station selection step S2 (the branch of “No” in the figure) is also the same as that of the first embodiment. Similarly, when the value is higher than the predetermined value, a difference from the first embodiment is generated from the point of time when the process proceeds to the update data confirmation step S30 (the branch of “Yes” in the figure).
[0052]
Here, the processing procedure in the update data confirmation step S30 will be described based on the sequence shown in FIG. 9, the same reference numerals as those in FIG. 2 denote the same or corresponding parts. FIG. 9 shows the processing procedure in the update data confirmation step S30. The possession list request signal Q5 is transmitted from the ground station 4, and the onboard station 12a, which is the measurement station, receives the possession list request signal Q5. This is a processing procedure for transmitting the answer signal A5. The operation of the on-board station 12a will be described with reference to the flowchart shown in FIG.
[0053]
10, the same reference numerals as those in FIG. 6 denote the same or equivalent parts. The reception signal determination step S40 is the same as the reception signal determination step S12 of the first embodiment shown in FIG. 6, but in addition to this, when the possession list request signal Q5 is received, the possession list reply signal transmission step S42 is performed. Transition. The operation of the onboard station 12a shown in FIG. 10 is the same as the operation of the onboard station 12a of the first embodiment shown in FIG. 6 except that the signal received by the onboard station 12a is transmitted from the ground station 4. In Q5, the received signal determination step S40 shifts to the possession list response signal transmission step S42 ((B4 branch in the figure)), and after the possession list response signal is transmitted, the procedure proceeds to the operation continuation determination step S10. Is added. The possession list reply signal transmission step S42 shows a procedure in which the onboard station transmits the possession list reply signal A5 in the update data confirmation step S30. The possession list response signal transmission step S42 is executed by the onboard station control device 46.
[0054]
Further, the operations of the ground station 4 and the on-board station 12a as the measurement station in this processing procedure will be described with reference to FIG. When the onboard station 12a stores the video information in the onboard station video information storage device 42, the onboard station 12a stores the storage date and time together with the file name of the video information. In the ground station 4, the ground station control device 26 transmits from the ground station transmitting / receiving device 20 a possession list request signal Q5 requesting that the possession list of the video information stored in the onboard station 12a be created and returned. . When the onboard station 12a receives the possession list request signal Q5 at the onboard station transmitting / receiving device 40, the file name and the storage date and time of the video information stored in the onboard station video information storage device 42 by the onboard station control device 46 Is stored, and a holding list including these pieces of information is created, and the ID code of the onboard station 12a is added to the holding list and transmitted from the onboard station transmitting / receiving apparatus 40 as a holding list reply signal A5.
[0055]
When the ground station 4 receives the possession list reply signal A5 at the ground station transceiver 20, the ground station controller 26 uses the ID code to transmit the received possession list reply signal A5 from the onboard station 12a. Is determined. Next, the ground station control device 26 compares the file name of the video information between the possession list of the on-board station 12a and the management list of the video information stored in the ground station video information storage device 22, and Video information that is not stored in the upper video information storage device 42 is selected. Also, for the video information having the same file name in the possession list and the management list, the storage date and time are compared, and the video information that has been corrected or updated after being stored in the on-board station video information storage device 42 is stored. select. A transmission list is created with the selected video information as video information to be transmitted to the onboard station 12a, and this transmission list is stored in the ground station controller 26. At this time, the items of the transmission list are arranged in alphabetical order of the file name of the video information.
[0056]
FIG. 11 is an example of a management list for video information management created by the ground station control device 26, and attribute information such as a display period, a data type, and a display order is used for each of the file names A to I. The transmission list is a list obtained by extracting a portion corresponding to the file selected as the video information to be transmitted from the management list, and has the same attribute information as the management list. When the video information is stored in the ground station video information storage device 22, the attribute information as shown in FIG. 11 is also stored. The ground station control device 26 uses the attribute information to store the video information. Manage.
[0057]
Returning to the description of FIG. In the update data confirmation step S30, the transmission list of video information to be transmitted to the measurement station is stored in the ground station control device 26, and then the process proceeds to the update execution determination step S31. In the update execution determination step S31, when the transmission list stored in the ground station control device 26 is blank, that is, there is no video information to be transmitted, the process proceeds to the measurement station selection step S2 ("No" branch in the figure). At other times, that is, when there is video information to be transmitted, the process proceeds to the data transmission / reception step S5 (branch “Yes” in the figure). At this time, it instructs to transmit the video information located at the head of the transmission list.
[0058]
Data transmission / reception step S5 and reception response step S6 are the same as in the first embodiment. The transmission end determination step S32 is performed when the ground station control device 26 normally receives all video information in the transmission list stored in the ground station control device 26 based on the reception determination result at the measurement station. Then, it is determined that the transmission is completed, and the process proceeds to the measuring station selection step S2 (branch “Yes” in the figure). Otherwise, the process proceeds to the data transmission / reception step S5 (branch “No” in the figure). When the process proceeds to the data transmission / reception step S5 ("No" branch in the figure), if the reception is not normally terminated due to the occurrence of a burst-like transmission error during the transmission of the video information, the video information is retransmitted. Instructed to transmit video information of the next order in the transmission list when the reception ends normally. The transmission end determination step S32 is similar to the transmission end determination step S7 of the first embodiment when a reception response signal indicating that reception of video information has not ended normally is received a predetermined number of times, or for a predetermined time. When the reception response signal is not received, it has a function of determining the end of transmission.
[0059]
In the video information transmission method to the train thus configured, it goes without saying that the same effect as that of the first embodiment is obtained, and further, the video information stored in the ground station and the on-vehicle station are stored. Only the difference between the existing video information needs to be transmitted, and the transmission efficiency of the video information from the ground station to the on-board station can be improved. An update data check step and an update execution determination step may be added before the data transmission / reception step of the second embodiment shown in FIG. 7, and the transmission end determination step may be the same as in the third embodiment.
[0060]
Embodiment 4 FIG.
The video information transmission method to the train according to the fourth embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. In FIG. 12, the same reference numerals as those in FIG. 8 denote the same or corresponding parts. In the fourth embodiment, in order to set the transmission priority in the video information based on the transmission list stored in the ground station control device 26 in the third embodiment shown in FIG. The transmission order setting step S33 is added. As described above, the transmission list has the same attribute information as the management list.
[0061]
The processing procedure in the transmission order setting step S33 is to calculate and set the priority order for the ground station control device 26 to transmit according to a predetermined rule based on these attribute information. FIG. 13 is a flowchart showing an example of a rule for calculating the priority order. In FIG. 13, the priority order is determined based on whether the display period is the shortest, whether the data type is an advertisement, and whether the display order is the earliest.
[0062]
The transmission order setting step S33 instructs to transmit the video information having the highest priority when the process proceeds to the data transmission / reception step S5. Further, in the transmission end determination step S34, all the video information in the transmission list stored in the ground station control device 26 is normally received by the measurement station based on the reception determination result by the ground station control device 26. At this time, it is determined that the transmission is completed, and the process proceeds to the measurement station selection step S2 (branch “Yes” in the figure). Otherwise, the process proceeds to the data transmission / reception step S5 (branch “No” in the figure). When the process proceeds to the data transmission / reception step S5 ("No" branch in the figure), if the reception is not normally terminated due to the occurrence of a burst-like transmission error during the transmission of the video information, the video information is retransmitted. When the reception ends normally, the instruction is given to transmit the video information of the next order according to the priority determined in the transmission order setting step S33.
[0063]
Note that, in the same way as the transmission end determination step S7 of the first embodiment and the transmission end determination step S32 of the third embodiment, the transmission end determination step S34 sets a reception response signal indicating that reception of video information has not ended normally. When the signal is repeatedly received, or when the reception response signal is not received for a predetermined time, it has a function of determining the end of transmission. Further, in the transmission order setting step S33, the video information having a low priority is deleted from the transmission list, and in the transmission end determination step S34, it is determined that the transmission is completed even if the video information having a low priority is not transmitted. Can be set.
[0064]
In the video information transmission method to the train configured in this way, it goes without saying that the same effect as that of the third embodiment is obtained. There is an effect that a train that can be transmitted to a station and used for operation can be prepared early. That is, in order to transmit video information with low priority to one on-board station, it is not necessary to wait for the on-board station to transmit information with high urgency and high priority. In addition, what is necessary is just to perform video information etc. with low urgency, when there is room in train operation.
[0065]
In the fourth embodiment, the management list for video information management created by the ground station control device is created when necessary and stored in the ground station control device. A management area for storing the management list is secured in the storage device, and when the video information stored in the ground station video information storage device changes, the management list is also updated and stored in this management area. You may do it. Further, a data storage device for storing the management list in the ground station may be added separately.
[0066]
The attribute information is not limited to that shown in FIG. 11. For example, for each piece of video information, if the ID code of a train that has not been transmitted is stored in a data storage device or the like at the ground station, the measurement station In the selection step S2, if the selection condition is set so as to preferentially select the on-board station of the train with a lot of video information that has not been transmitted as the measurement station, the video information in order from the train having the video information that has not been transmitted. Therefore, it is possible to efficiently prepare a train that can be used for operation. Further, by combining the attribute information with the train operation management data, for example, it is possible to transmit only video information with high urgency from a train whose operation start time is close. An update data confirmation step, an update execution determination step, and a transmission order setting step are added before the data transmission / reception step of the second embodiment shown in FIG. 7, and the transmission end determination step is the same as that of the fourth embodiment. It may be.
[0067]
Embodiment 5 FIG.
The video information transmission method to the train according to the fifth embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. In FIG. 14, the same reference numerals as those in FIG. 8 denote the same or corresponding parts. The fifth embodiment is different from the third embodiment shown in FIG. 8 in that a reconfirmation determination step S52 for determining whether or not the update data confirmation step S30 is performed again after the transmission end determination step S50 is determined. It is added.
[0068]
The operation from the start of the operation to the transmission end determination step S50 is the same as that of the third embodiment. The transmission end determination step S50 of the fifth embodiment is substantially the same as the transmission end determination step S32 of the third embodiment, but the reception response that the reception of the video information is not normally ended by the reception response step S6. When the signal is received, transmission is not performed in that the same video information is not requested to be retransmitted, but the next rank video information is requested to be transmitted according to the transmission list stored in the ground station control device 26. Different from the end determination step S32. That is, since the transmission end determination step S50 does not request retransmission of the same video information, it is determined that the transmission ends when the transmission of the video information to be transmitted is performed once. If the reception response signal is not received for a predetermined time, it is determined that the transmission is finished.
[0069]
The reconfirmation determination step S52 is a processing procedure executed by the ground station control device 26. When it is determined that the transmission of video information to be transmitted is performed once in transmission end determination step S50 and the transmission is ended, When it is determined that the update data confirmation step S30 is to be performed again, the process proceeds to the update data confirmation step S30 (branch “Yes” in the figure), and when it is determined that the transmission ends without receiving the reception response signal for a predetermined time. Then, it is determined that the update data confirmation step S30 is not performed again, and the process proceeds to the measurement station selection step 2 (branch “No” in the figure).
[0070]
In the video information transmission method to the train configured as described above, it is needless to say that the same effect as in the third embodiment is obtained, and further, it is necessary to determine whether or not each video information is normally received. Therefore, the time can be shortened and the transmission efficiency of video information can be improved. Moreover, after transmitting the video information, it is possible to increase the reliability of updating the video information stored in the onboard station by confirming that there is no difference between the video information stored in the ground station and the onboard station. There is also an effect that can be done. Note that the update data confirmation step and update execution determination step of the third embodiment are added before the data transmission / reception step of the second embodiment shown in FIG. 7, and the transmission end determination step of the second embodiment is performed in the fifth embodiment. The reconfirmation determination step may be added after the transmission end determination step.
[0071]
Embodiment 6 FIG.
FIG. 15 is an overall configuration diagram of a train stop used in a video information transmission method to a train according to Embodiment 6 of the present invention. In FIG. 15, the same reference numerals as those in FIG. 1 denote the same or corresponding parts. Similar to FIG. 1, the railroad track 2 and railroad tracks 2a to 2c branched from the railroad track 2 are laid on the ground to constitute a train stop. A train 8 is stopped on the railroad track 2 and a train 10 is stopped on the railroad track 2b. A ground station 80 is installed on the ground side. Here, the configuration of the ground station 80 will be described with reference to a block diagram shown in FIG. In FIG. 16, the same reference numerals as those in FIG. 2 denote the same or corresponding parts.
[0072]
The ground station 80 has substantially the same configuration as the ground station 4 shown in FIG. 2, but the ground station control device 82 has a ground station transmission / reception device 84a similar to the ground station transmission / reception device 20 shown in FIG. In addition, a function of connecting the ground station transmission / reception device 84b and the ground station transmission / reception device 84c installed at remote locations to perform wireless communication is added. The ground station transceiver 84a performs wireless communication using the frequency F1, the ground station transceiver 84b uses the frequency F2, and the ground station transceiver 84c uses the frequency F3. When the ground station 80 transmits, the same content, for example, the opening request signal Q1 is transmitted simultaneously at the frequencies F1 to F3. On the other hand, when the ground station 80 receives, the ground station controller 82 adjusts so that signals received at the frequencies F1 to F3 do not overlap. For example, the ground station control device 82 may be provided with a buffer memory corresponding to each of the ground station transmission / reception devices 84a to 84c, and signals received at each frequency may be temporarily stored in each buffer memory and then sequentially read. With this configuration, complicated adjustment of the transmission / reception timing at the wireless communication level between the frequencies F1 to F3 is not necessary. The ground station transmission / reception device 84a is the same as the ground station transmission / reception device 20 shown in FIG. 2, and the ground station transmission / reception device 84b and the ground station transmission / reception device 84c have the same configuration as the ground station transmission / reception device 84a except for the frequencies used. .
[0073]
Returning to the description of FIG. A ground station transmission / reception device 84b and a ground station transmission / reception device 84c are installed at a location away from the ground station 80. The ground station transceiver 84a (not shown), the ground station transceiver 84b, and the ground station transceiver 84c of the ground station 80 include antennas 86a to 86c, respectively, as in the first embodiment. . The antennas 86a to 86c are obtained by combining the characteristics with the frequencies F1 to F3, respectively. The ground station transceiver 84 b and the ground station transceiver 84 c are connected to the ground station 80 by a cable 87.
[0074]
On-board station 88a and antenna 90a, on-board station 88b and antenna 90b are mounted on the leading vehicles of train 8 and train 10, respectively, and perform wireless communication with ground station 80. For this wireless communication, a wireless communication line capable of data communication such as digital data is used. The onboard station 88a and the onboard station 88b have the same configuration, and the antenna 90a and the antenna 90b have the same configuration.
[0075]
Here, the configuration of the onboard station 88a will be described with reference to a block diagram shown in FIG. In FIG. 17, the same reference numerals as those in FIG. 2 denote the same or corresponding parts. The onboard station 88a has substantially the same configuration as the onboard station 12a shown in FIG. 2, but the onboard station transmitting / receiving device 92 has an arbitrary frequency (hereinafter referred to as “provisional frequency”) of frequencies F1 to F3. The on-board station controller 94 has a function of setting the provisional frequency to any one of the frequencies F1 to F3 based on a predetermined condition.
[0076]
Further, the onboard station control device 94 stores the result of measuring the transmission quality sequentially for each of the frequencies F1 to F3 between the ground station 80 and the onboard station 88a, and the highest transmission quality among them is stored. It has a function of determining the frequency as a frequency for receiving video information (hereinafter referred to as “video reception frequency”). Further, the antenna 90a can be shared at the frequencies F1 to F3.
[0077]
The video information transmission method to the train according to the sixth embodiment is realized by repeatedly executing the entire operation from the start to the end of the flowchart shown in FIG. 18, the same reference numerals as those in FIG. 7 denote the same or corresponding parts. In the sixth embodiment, a signal obtained by adding a train ID code to the transmission quality calculated in the transmission quality measurement step S3 (hereinafter referred to as “transmission quality notification signal R”) in the second embodiment shown in FIG. .) Is added to the transmission quality transmission step S53 for transmitting to the on-board station. (Hereinafter, the parts composed of the onboard station detection step S1, the transmission quality measurement end determination step S18, the transmission quality measurement step S3, and the transmission quality transmission step S53 are collectively referred to as an onboard station frequency determination step S54.) Frequency determining station confirming step S56 for confirming whether there is an on-board station (hereinafter referred to as “frequency determining station”) for which the reception frequency has been determined, and a frequency for determining whether or not the on-board station frequency determining step S54 can be ended. A decision station determination step S58 is added.
[0078]
Here, the processing procedure in the onboard station detection step S1 will be described based on the sequence shown in FIG. 19, the same reference numerals as those in FIGS. 16 and 17 denote the same or corresponding parts. FIG. 19 shows the case where the on-board station 88a is the only on-board station capable of wireless communication, and corresponds to the case of FIG. 4 (a) or FIG. 4 (b). In the second embodiment, the ground station transmission / reception device 20 transmits the opening request signal Q1 with a single frequency, whereas the ground station transmission / reception devices 84a to 84c have the frequencies F1 to F3 and the opening request signal Q1 ( The frequency F2 and the frequency F3 are indicated by dotted lines In the figure, the arrows indicating the opening request signal Q1 at each frequency are shown at intervals in the time axis direction for the sake of drawing. Is transmitted at the same time). The ground station 80 repeats transmission of the opening request signal Q1 and reception of the opening response signal A1 from the on-board station at a constant time interval T1, and an ID code for identifying the train in the opening response signal A1. In the same manner as in the first to fifth embodiments, each on-board station transmits a station opening response signal A1 after a different delay time has elapsed after receiving the station opening request signal Q1. It is.
[0079]
The on-board station 88a has the provisional frequency set to the frequency F1, and does not receive radio waves of frequencies other than the frequency F1. Therefore, when viewed from the onboard station 88a, it can be seen that the ground station transmission / reception device 84b and the ground station transmission / reception device 84c are equivalent to the case where the ground station transmission / reception device 84c does not exist. That is, in FIG. 19, it can be seen that only the ground station transmission / reception device 84a and the arrow indicated by the solid line are described, which is the same as FIG. 4B. That is, the processing procedure shown in FIG. 19 has no response from the onboard station 88a to the first and second opening request signals Q1 transmitted from the ground station transmitting / receiving device 84a, as in FIG. 4B. The on-board station 88a receives the third opening request signal Q1 and transmits the opening response signal A1 at the frequency F1.
[0080]
The station response signal A1 is received by the ground station transceiver 84a. When viewed from the ground station transmitter / receiver 84b and the ground station transmitter / receiver 84c, it can be viewed as equivalent to the case where the onboard station 88a does not exist because the frequency used is different (from the onboard station 88a to the ground station transmitter / receiver 84b and the ground station). The station opening response signal A1 to the station transmitting / receiving device 84c cannot be received by these ground station transmitting / receiving devices, and is not shown in the figure.
[0081]
When the ground station transmitting / receiving device 84a receives the opening response signal A1, the ground station 80 determines that the onboard station 88a is an onboard station capable of wireless communication by the ground station control device 82, and determines this reception time on the vehicle. It is assumed that the time when the station 88a is detected. Further, the ground station controller 82 determines that the onboard station 88a is the onboard station of the train 8 by using the ID code. The ground station controller 82 stores that the onboard station 88a is detected, the time at which the onboard station 88a was detected, and that the onboard station 88a is the onboard station of the train 8. Even when the on-board station 88a sets the provisional frequency to the frequency F2 or the frequency F3, the processing procedure is the same as that for the frequency F1.
[0082]
Therefore, when there is one on-board station capable of wireless communication, the on-board station detection step S1 is the same as in the first to fifth embodiments. In addition, when the onboard stations 88a and 88b are wirelessly communicable on-board stations, and these provisional frequencies coincide with each other at the frequency F1, the same as on the case of a single on-board station, Since it can be regarded as equivalent to the case where the station transmission / reception device 84b and the ground station transmission / reception device 84c do not exist, the processing procedure is the same as, for example, (c) of FIG. Even when the provisional frequency is set to the frequency F2 or the frequency F3, the processing procedure is the same as that for the frequency F1. Furthermore, when there are three or more on-board stations capable of wireless communication and all of these provisional frequencies match, the ground station transmitting / receiving device 84b and Since it can be regarded as equivalent to the case where the ground station transmission / reception device 84c does not exist, the on-board station can be detected by the same processing procedure.
[0083]
Furthermore, even when there are a plurality of on-board stations capable of wireless communication and different provisional frequencies are set, all the above-mentioned provisional frequencies are all viewed from the on-board station where the provisional frequency is set to the frequency F1. Similar to the case where they match, it can be regarded as equivalent to the case where the ground station transceiver 84b and the ground station transceiver 84c do not exist. That is, when viewed from each on-board station, it is equivalent to the existence of only a ground station transmitting / receiving device corresponding to the provisional frequency.
[0084]
On the other hand, if attention is paid to only one frequency from the ground station 80 to the frequencies F1 to F3, this is equivalent to the case where all the provisional frequencies match. Since the ground station controller 82 adjusts the signals received at the frequencies F1 to F3 so as not to overlap as described above, each onboard station uses any one of the frequencies F1 to F3. Can be detected. Therefore, even when there are a plurality of on-board stations capable of wireless communication and different provisional frequencies are set, the same processing procedure as on-board station detection step S1 in the first to fifth embodiments is used. The station can be detected.
[0085]
Returning to the description of FIG. In the onboard station detection step S1, the onboard station 88a is first detected with the provisional frequency as the frequency F1, and then the onboard station 88b is detected with the provisional frequency as the frequency F2, and the process proceeds to the transmission quality measurement end determination step S18. It shall be. In the transmission quality measurement end determination step S18, the onboard station 88a detected earlier is designated as the onboard station to be measured, and the process proceeds to the transmission quality measurement step S3 ("No" branch in the figure). The transmission quality of the on-board station 88a is measured, the calculation result is stored in the ground station control device 82, and the process proceeds to the transmission quality transmission step S53. In the transmission quality transmission step S53, the calculation result of the transmission quality is transmitted, and the process returns to the transmission quality measurement end determination step S18.
[0086]
Since the provisional frequency is set to the frequency F1, the on-board station 88a measures the transmission quality using the frequency F1 with the ground station transmission / reception device 84a. During this measurement, it can be seen that the ground station transceiver 84b and the ground station transceiver 84c are equivalent to the case where there is no ground station. The same applies when the provisional frequency is the frequency F2 or the frequency F3. Therefore, transmission quality measurement step S3 is the same as in the first to fifth embodiments.
[0087]
In the transmission quality measurement end determination step S18, the onboard station 88b is designated as the next onboard station to be measured, the process proceeds to the transmission quality measurement step S3 ("No" branch in the figure), and the onboard station 88b The transmission quality is measured with the ground station transmission / reception device 84b at the frequency F2, which is the provisional frequency of the onboard station 88b, and the calculation result is stored in the ground station control device 82. Next, the process proceeds to the transmission quality transmission step S53, the calculation result of the transmission quality is transmitted, and the process returns to the transmission quality measurement end determination step S18. In the transmission quality measurement end determination step S18, the vehicle detected in the onboard station detection step S1 is the same as in the second embodiment regardless of whether the frequency at which the transmission quality measurement is performed is the frequency F1 to F3. When all of the upper stations are designated as on-board stations whose transmission quality is to be measured once and the process proceeds to the transmission quality measurement step S3, it is determined that the measurement of the transmission quality is completed. Therefore, at this stage, all the onboard stations detected in the onboard station detection step S1, that is, the onboard station 88a and the onboard station 88b are designated as onboard stations whose transmission quality is to be measured once. Thus, the process proceeds to the transmission quality measurement step S3, so that it is determined that the measurement of the transmission quality is completed, and the process proceeds to the frequency determination station confirmation step S56 (the branch of “Yes” in the figure).
[0088]
Thus, the on-board station frequency determination step S54 is executed once. In the onboard station frequency determination step S54, the transmission quality measurement step S3 and the transmission quality transmission step S53 are the number of times corresponding to the number of onboard stations detected in the onboard station detection step S1 (each onboard station is respectively This is repeatedly executed by the number of times of designating the on-board station whose transmission quality is to be measured once and shifting to the transmission quality measurement step S3). Next, the operation of the onboard station when this onboard station frequency determination step S54 is executed will be described with reference to the flowchart shown in FIG. In FIG. 20, the same reference numerals as those in FIG. 6 denote the same or corresponding parts.
[0089]
The onboard station in the sixth embodiment is the same as the number of frequencies used by the onboard station in the onboard station frequency determination step S54 in the operation of the onboard station of the first embodiment as shown in FIG. As described above, for example, when the frequencies F1 to F3 are used, an operation for determining the video reception frequency is added while being repeated three times or more. After the onboard station determines the video reception frequency, that is, after becoming the frequency determination station, the operation proceeds to the same operation as the onboard station of the first embodiment shown in FIG. The onboard station of the first embodiment starts the entire operation shown in FIG. 6 when entering the train stop. The onboard station of the sixth embodiment determines the video reception signal shown in FIG. When the operation is completed, the entire operation shown in FIG. 6 is started. In this case, the on-board station of the first embodiment operates at a single frequency, but the video reception frequency can be regarded as this single frequency.
[0090]
The flowchart shown in FIG. 20 represents an operation in which the on-board station determines the video reception frequency. This operation will be described below. When the onboard station starts the operation, the provisional frequency is set to the frequency F1 in provisional frequency setting step S70. In the provisional frequency setting step S70, when the value of the counter n is 1 to 3, the frequencies are frequencies F1 to F3, respectively, and the maximum number N of the counter n is 3. Next, the process proceeds to a time measurement start step S72, and measurement of an elapsed time (hereinafter referred to as “frequency maintenance time”) from the time when the provisional frequency is set is started. Next, the process proceeds to the reception standby step S74. Similarly to the reception standby step S11 of the first embodiment, the reception standby step S74 of the sixth embodiment shifts to a reception signal determination step S76 when the onboard station receives a signal transmitted from the ground station (" If the frequency maintenance time exceeds a predetermined time T4, the process proceeds to the recording end determination step S78 ("No" branch in the figure).
[0091]
In the sixth embodiment, similar to the first embodiment, different patterns specific to the type of signal are arranged at the head of the signal transmitted from the ground station 80. Based on this pattern, the on-board station control device determines the type of signal. Similarly to the reception signal determination step S12 of the first embodiment shown in FIG. 6, the reception signal determination step S76 corresponds to perform an operation corresponding to each signal depending on the type of signal received by the onboard station. Move to the next step.
[0092]
In the received signal determination step S76, when the received signal is the opening request signal Q1, the operation proceeds to the opening response signal transmission step S13 (branch “B1” in the figure), and the opening response signal A1 is transmitted. After shifting to the time measurement end step S80 for ending the measurement and ending the measurement of the frequency maintenance time, the process proceeds to the reception standby step S74. When the received signal is the predetermined data signal Q2, the process proceeds to the data signal transmission step S14 (branch “B2” in the figure), and after the predetermined data signal A2 is transmitted, the process proceeds to the reception standby step S74. When the received signal is the transmission quality notification signal R, the process proceeds to a transmission quality recording step S82 in which the calculation result of the received transmission quality is stored in the onboard station controller 46 (branch “B5” in the figure). After the quality calculation result is stored in the on-board station controller 46, the process proceeds to the recording end determination step S78.
[0093]
Although not shown, when the received signal is not any one of the station opening request signal Q1, the predetermined data signal Q2, and the transmission quality notification signal R, the process proceeds to the reception standby step S74. In other words, after setting the provisional frequency in the provisional frequency setting step S70, when receiving the station opening request signal Q1 and transmitting the station opening response signal A1 within a predetermined time T4, the measurement of the frequency maintenance time is terminated, In the standby step S74, the frequency maintenance time does not exceed the predetermined time T4, and the operation for shifting to the recording end determination step S78 ("No" branch in the figure) does not occur. On the other hand, if the opening request signal Q1 is received and the opening response signal A1 is not transmitted within the predetermined time T4, that is, if communication with the ground station is not possible, the process proceeds to the recording end determination step S78 (the branch of “Yes” in the figure) )
[0094]
In the recording end determination step S78, it is determined whether or not the counter n is the maximum value N. If the counter n is not the maximum value N, the process proceeds to the provisional frequency changing step S84 (branch “No” in the figure). If the maximum value N is reached, the process proceeds to reception frequency determination step S86 (branch “Yes” in the figure). In the provisional frequency changing step S84, the value of the counter n is incremented by 1, and the provisional frequency is set to the next frequency (for example, the frequency F2 next to the frequency F1), and the process proceeds to the time measurement start step S72.
[0095]
In the reception frequency determination step S86, the calculation result of the transmission quality is stored for each of the frequencies F1 to F3, or when the station opening request signal Q1 cannot be received within the predetermined time T4 and the process proceeds to the recording end determination step S78. That is, it is a step that determines whether or not communication with the ground station is possible for all of the frequencies F1 to F3 and, if possible, shifts when measurement of transmission quality at that frequency is completed. In the reception frequency determination step S86, the onboard station controller 46 calculates the transmission quality for each of the frequencies F1 to F3 (excluding frequencies that could not be communicated with the ground station) stored in the onboard station controller 46. By comparing the results, the frequency with the highest transmission quality is determined as the video reception frequency (note that an on-board station that cannot communicate with the ground station at all frequencies is not a frequency determination station).
[0096]
For example, when the on-board station completes the measurement of transmission quality with the frequency F1 as the provisional frequency, the frequency F2 is set as the provisional frequency and the process proceeds to the reception standby step S74, and the reception of the opening request signal at the frequency F2 is received. I will wait. At this time, since the onboard station detection step S1 of the onboard station frequency determining step S54 has already been completed, the onboard station frequency determining step S54 is executed next, and the onboard station detecting step S1 is executed therein. For the first time, it is possible to receive the opening request signal at the frequency F2 and measure the transmission quality in the subsequent procedure. That is, in order for the onboard station to complete the measurement of transmission quality for all frequencies F1 to F3, the onboard station frequency determination step S54 must be repeated at least three times.
[0097]
The provisional frequency setting step S70, the time measurement start step S72, the reception standby step S74, the reception signal determination step S76, the recording end determination step S78, the time measurement end step S80, and the provisional frequency change step S84 are the transmission quality recording step S82 and Similar to the reception frequency determination step S86, this is a processing procedure executed by the onboard station control device 46.
[0098]
Next, the operation for determining the video reception frequency will be described using the onboard station 88a and the onboard station 88b as examples. In the description of FIG. 18, in the onboard station detection step S1, the onboard station 88a is first detected with the provisional frequency as the frequency F1, and then the onboard station 88b is detected with the provisional frequency as the frequency F2. However, in the following description, only the onboard station 88b is stopped at the train stop, which is a stage before that, and the onboard station frequency determination step S54 is performed. This is an explanation from the time when the first operation starts.
[0099]
This will be described with reference to FIG. The onboard station 88b first sets the provisional frequency to the frequency F1 in the provisional frequency setting step S70, and starts measuring the frequency maintenance time in the time measurement start step S72. The on-board station 88b receives the opening request signal Q1 transmitted at the frequency F1 within the predetermined time T4, transmits the opening response signal A1 at the frequency F1, ends the measurement of the frequency maintenance time, and receives standby step S74. Migrate to Next, the predetermined data signal Q2 transmitted at the frequency F1 is received from the ground station transceiver 84a, the predetermined data signal A2 is transmitted at the frequency F1, and the process proceeds to the reception standby step S74. Furthermore, the transmission quality notification signal R transmitted from the ground station 80 is received, the calculation result of the received transmission quality is stored in the onboard station control device 46, and the process proceeds to the recording end determination step S78.
[0100]
In the recording end determination step S78, since the value of the counter n is 1, the process proceeds to the provisional frequency changing step S84, the value of the counter n is set to 2, and the provisional frequency is set to the frequency F2, and the process proceeds to the time measurement start step S72. In time measurement start step S72, measurement of the frequency maintenance time is started, and the process proceeds to reception standby step S74. Since the onboard station 88b has only completed measurement of transmission quality at the frequency F1, it is not a frequency determining station. Here, when viewed from the ground station 80, the onboard station detected in the onboard station detecting step S1 in the first onboard station frequency determining step S54 is only the onboard station 88b. Since the measurement of the transmission quality is completed, the process proceeds to the frequency determination station confirmation step S56 shown in FIG.
[0101]
A description will be given from the time point when the ground station 80 shifts to the frequency determination station confirmation step 38 with reference to FIG. The processing procedure in the frequency determination station confirmation step S56 will be described based on the sequence shown in FIG. In FIG. 21, the same reference numerals as those in FIG. 16 or 17 are the same or equivalent. Determination confirmation request signal Q6 from ground station 80 is transmitted at frequencies F1 to F3 by ground station transmission / reception devices 84a to 84c (in the figure, signals that can be received with the same frequency are indicated by solid arrows and different frequencies). Signals that cannot be received are indicated by dotted arrows.) Since the onboard station 88b uses the provisional frequency as the frequency F2, the onboard station 88b receives the determination confirmation request signal Q6 transmitted at the frequency F2 from the ground station transmission / reception device 84b, but is not a frequency determination station. Does not respond.
[0102]
Returning to the description of FIG. In frequency decision station confirmation step S56, it is confirmed that there is no frequency decision station because there is no response to the decision confirmation request signal, and then the process proceeds to frequency decision station decision step S58. The frequency determination station determination step S58 counts the number of executions of the onboard station frequency determination step S54 and determines the determination condition “the onboard station frequency determination step S54 is executed five or more times and there is at least one frequency determination station”. If it matches, the process proceeds to the reference station setting step S20 (branch “Yes” in the figure), and otherwise, the process proceeds to the onboard station frequency determination step S54 (branch “No” in the figure).
[0103]
The onboard station frequency determination step S54 is the first time and does not meet the above-described determination conditions, so the process proceeds to the onboard station frequency determination step S54 (branch “No” in the figure) and the second onboard station frequency determination. Step S54 is started. The onboard station 88a newly stops at the train stop and starts operation from the time when the second onboard station frequency determination step S54 is started. Therefore, the operation of the onboard station 88a is the same as the operation of the onboard station 88b in the first onboard station frequency determination step S54. Therefore, the on-board station 88a stores the calculation result of the transmission quality at the frequency F1, and moves to the reception standby step S74 with the provisional frequency as the frequency F2. The onboard station 88b performs the same operation as the operation at the first onboard station frequency determination step S54 using the frequency F2, stores the calculation result of the transmission quality at the frequency F2, and sets the provisional frequency. The process proceeds to reception standby step S74 as frequency F3.
[0104]
At this stage, the onboard station 88a is in the reception standby step S74 with the provisional frequency as the frequency F2, and the onboard station 88b is in the reception standby step S74 with the provisional frequency as the frequency F3, both of which are not frequency determination stations. The onboard station 88a receives the decision confirmation request signal Q6 transmitted from the ground station transceiver 84b at the frequency F2, and the onboard station 88b receives the decision confirmation request signal Q6 transmitted from the ground station transceiver 84c at the frequency F3. However, neither responds because they are not frequency decision stations.
[0105]
The onboard station frequency determination step S54 is the second time and does not meet the above-described determination condition, and therefore the process proceeds to the onboard station frequency determination step S54 ("No" branch in the figure). In the third onboard station frequency determination step S54, the onboard station 88a stores the calculation result of the transmission quality at the frequency F2, and proceeds to the reception standby step S74 with the provisional frequency as the frequency F3.
[0106]
On the other hand, the onboard station 88b stores the calculation result of the transmission quality at the frequency F3, and the measurement of the transmission quality at all the frequencies F1 to F3 is completed at this stage, so the process proceeds to the reception frequency determination step S86. . The onboard station 88b has the highest transmission quality at the frequency F2, and determines the video reception frequency to be the frequency F2 to become a frequency determination station. When the on-board station becomes the frequency determination station, as shown in FIG. 20, the on-board station proceeds to a confirmation request reception standby step S88 for waiting for reception of a determination confirmation request signal Q6 transmitted from the ground station 80. When the onboard station 88b receives the determination confirmation request signal Q6 transmitted at the frequency F2, the on-board station 88b proceeds to the determination confirmation response signal transmission step S90, and transmits the determination confirmation response signal A6 at the frequency F2 to determine the video reception frequency. The operation to be performed is terminated, and the operation proceeds to the same operation as that of the on-board station of the first embodiment shown in FIG. The decision confirmation response signal transmission step S90 shows a procedure in which the onboard station transmits the decision confirmation response signal A6 in the frequency decision station confirmation step S56. The confirmation request reception standby step S88 is a processing procedure executed by the onboard station control device 46.
[0107]
Returning to the description of FIG. The processing procedure in the frequency determination station confirmation step S56 in this case will be described based on the sequence shown in FIG. In FIG. 22, the same reference numerals as those in FIG. 21 denote the same or corresponding parts. The onboard station 88a is in the reception standby step S74 with the provisional frequency as the frequency F3, and the onboard station 88b is a frequency determining station with the video reception frequency as the frequency F2. Determination confirmation request signal Q6 from ground station 80 is transmitted at frequencies F1 to F3 by ground station transmission / reception devices 84a to 84c (in the figure, signals that can be received with the same frequency are indicated by solid arrows and different frequencies). Signals that cannot be received are indicated by dotted arrows.)
[0108]
The onboard station 88a receives the determination confirmation request signal Q6 transmitted at the frequency F3 from the ground station transceiver 84c, but does not respond because it is not a frequency determination station. The onboard station 88b, which is a frequency determination station, receives the determination confirmation request signal Q6 transmitted at the frequency F2 from the ground station transmission / reception device 84b, and transmits the determination confirmation response signal A6 at the frequency F2. The ground station 80 receives the decision confirmation response signal A6 from the on-board station 88b by the ground station transmitting / receiving device 84b. The ground station 80 stores in the ground station control device 82 that the on-board station 88b is a frequency determining station.
[0109]
When the onboard station receives the decision confirmation request signal Q6, the decision confirmation response signals A6 from a plurality of onboard stations can be transmitted if the decision confirmation response signal A6 is transmitted after a different delay time elapses. There is no overlap in reception timing. Therefore, even if there are a plurality of frequency determination stations using the same video reception frequency, the frequency determination station can be confirmed in the same manner. In addition, as described above, the ground station controller 82 adjusts so that signals received at the frequencies F1 to F3 do not overlap, so even if there are a plurality of frequency determination stations using different video reception frequencies, Similarly, the frequency determining station can be confirmed. A train ID code is added to the decision confirmation response signal A6 to identify which train the frequency decision station belongs to. A train can also be specified from the delay time of each on-board station.
[0110]
Returning to the description of FIG. In the frequency determination station confirmation step S56, after confirming that the onboard station 88b is a frequency determination station, the process proceeds to the frequency determination station determination step S58. The on-board station frequency determining step S54 is the third time, and does not match the determination condition, so the process proceeds to the on-board station frequency determining step S54 ("No" branch in the figure).
[0111]
Similarly, in the onboard station frequency determination step S54 for the fourth time, the onboard station 88a finishes measuring the transmission quality for the frequency F3 (assuming that the transmission quality at the frequency F1 is the highest) and receives the video. The frequency is determined as the frequency F1 to become a frequency determination station, and the process proceeds to the confirmation request reception standby step S88. In the frequency determination station confirmation step S56, the ground station 80 stores in the ground station controller 82 that the onboard station 88a is a frequency determination station. In the frequency determination station determination step S58, the onboard station frequency determination step S54 is the fourth time and does not meet the determination condition, so the process proceeds to the onboard station frequency determination step S54 (branch “No” in the figure).
[0112]
In the fifth onboard station frequency determination step S54, no newly communicable onboard station is detected, and when the process proceeds to the frequency determination station determination step S58, the determination condition “the onboard station frequency determination step S54 is five times. Since it is executed as described above and there is at least one frequency determination station, the process proceeds to the reference station setting step S20. The operations after the reference station setting step S20 are the same as those in the second embodiment.
[0113]
Next, an example in which there are four on-board stations will be described based on the state list shown in FIG. First, in the first onboard station frequency determination step S54, the onboard station A and the onboard station B are stopped at the train stop, and the provisional frequency is set to the frequency F1, respectively. The onboard station A and the onboard station B are detected in the onboard station detection step S1. Next, the process proceeds to the transmission quality measurement step S3, and the transmission quality of the onboard station A and the onboard station B is measured. The calculation result of the transmission quality is stored in the ground station controller 82 of the ground station 80 and transmitted to the onboard station, and the onboard station A and the onboard station B store this. Note that the order of measurement of transmission quality may be determined by the order of the detected times in the onboard station detection step S1. The onboard station A and the onboard station B change the provisional frequency to the frequency F2, respectively, and wait for reception of the next station opening request signal.
[0114]
Next, the process proceeds to frequency determination station confirmation step S56. The onboard station A and the onboard station B are not frequency determination stations because only the transmission quality accumulation step S52 at the frequency F1 has been executed. Therefore, in frequency determination station confirmation step S56, it is confirmed that there is no frequency determination station, and the process proceeds to frequency determination station determination step S58. In this case, since the number of executions of the onboard station frequency determination step S54 is one and there is no frequency determination station, the determination condition in the frequency determination station determination step S58 is “the onboard station frequency determination step S54 is 5”. It is executed more than once and there is at least one frequency determination station ”, so that the process proceeds to the onboard station frequency determination step S54.
[0115]
In the second onboard station frequency determination step S54, the onboard station A and the onboard station B complete the measurement of the transmission quality at the frequency F2, change the provisional frequency to the frequency F3, respectively, It will be in the reception waiting state of the opening request signal. In the frequency determination station confirmation step S56, the frequency determination station is not confirmed, and in the frequency determination station determination step S58, since it does not meet the determination condition, the process proceeds to the onboard station frequency determination step S54.
[0116]
In the onboard station frequency determination step S54 for the third time, the onboard station A and the onboard station B complete the measurement of the transmission quality at the frequency F3, so the measurement of the transmission quality at all the frequencies F1 to F3 is performed. Thus, the video reception frequency is determined in the reception frequency determination step S86 of FIG. 20 to become a frequency determination station and to wait for reception of a determination confirmation request signal. The onboard station C that has entered the train station and stopped has completed the measurement of the transmission quality at the frequency F1, changes the provisional frequency to the frequency F2, and waits for reception of the next station opening request signal. .
[0117]
In the frequency determination station confirmation step S56, the onboard station A and the onboard station B are confirmed as frequency determination stations. In the frequency determination station determination step S58, although there are two frequency determination stations, the number of executions of the onboard station frequency determination step S54 is three and does not meet the determination condition, so the process proceeds to the onboard station frequency determination step S54. To do.
[0118]
In the fourth onboard station frequency determination step S54, the onboard station C completes the measurement of the transmission quality at the frequency F2, changes the provisional frequency to the frequency F3, and waits for reception of the next station opening request signal. become. The onboard station D that has newly entered the train station and stopped has completed the measurement of the transmission quality at the frequency F1, changes the provisional frequency to the frequency F2, and waits to receive the next station opening request signal. . Since the onboard station A and the onboard station B are already frequency determination stations, the state in which the frequencies to be used are fixed to the respective video reception frequencies is maintained. In the frequency determination station confirmation step S56, a new frequency determination station is not confirmed, and in the frequency determination station determination step S58, the number of executions of the onboard station frequency determination step S54 is four and does not meet the determination condition. The process proceeds to frequency determination step S54.
[0119]
In the fifth onboard station frequency determination step S54, the onboard station C completes the measurement of the transmission quality at the frequency F3, so that the measurement of the transmission quality at all the frequencies F1 to F3 has been completed. Thus, the video reception frequency is determined to be the frequency F1 to become a frequency determination station, and a state of waiting for reception of the determination confirmation request signal is entered. The onboard station D completes the measurement of the transmission quality at the frequency F2, changes the provisional frequency to the frequency F3, and waits for reception of the next station opening request signal. The onboard station A and the onboard station B perform the same operation as in the fourth onboard station frequency determination step S54.
[0120]
In the frequency determination station confirmation step S56, the onboard station C is confirmed as a new frequency determination station. In the frequency determination station determination step S58, the frequency determination stations are three on-board stations A to C, and the number of executions of the on-board station frequency determination step S54 is five, which matches the determination condition, so the process proceeds to the reference station setting step S20. To do.
[0121]
The operations after the reference station setting step S20 are the same as those in the second embodiment. Here, it is assumed that the transmission quality is higher in the order of the onboard station A, the onboard station B, and the onboard station C, and all are higher than a predetermined value. The selection condition of the reference station is set as “the station that has not been selected as the reference station and has the highest transmission quality among transmission quality higher than a predetermined value”. Station B and onboard station C are selected as reference stations in this order, and the end of transmission of video information is confirmed.
[0122]
In the data transmission / reception step S5, video information is simultaneously transmitted from the ground station 80 at the frequencies F1 to F3, the onboard station A and the onboard station C receive at the frequency F1, and the onboard station B receives at the frequency F2. In the reception response step S6 and the transmission end determination step S7, the reference station is specified as one, the reception response signal from the reference station is received, and the transmission end is determined, so that there are three types of frequencies F1 to F3. However, the operation is the same as that of the second embodiment using one frequency. That is, one frequency in the second embodiment can be regarded as the frequency F1 when the onboard station A or the onboard station C is the reference station, and as the frequency F2 when the onboard station B is the reference station.
[0123]
In the transmission quality measurement step S3, the reception response step S6, and the frequency determination station confirmation step S56 including the processing procedure in which the ground station receives a signal from the onboard station, the same operation as the above-described onboard station detection step S1 is performed. Thus, even when there are a plurality of on-board stations capable of wireless communication and different provisional frequencies or video reception frequencies are set, signals from these on-board stations can be received without overlapping.
[0124]
In the video information transmission method to the train thus configured, it goes without saying that the same effect as that of the second embodiment is obtained, and further, the frequency with the highest transmission quality among the frequencies that can be used by each on-board station. Since the video information can be transmitted by selecting this, it is possible to improve the transmission efficiency of the video information. In addition, as described above, on-board station transceivers with different frequencies are installed at different locations, so that the most suitable on-board station transceiver can be selected according to the train position, and freedom regarding the position of the train can be selected. The degree can be increased. Therefore, there is an effect that arrangement of a plurality of trains at a train stop or the like is facilitated. In addition, in the said description, although the case where three types of frequencies F1-F3 were used was demonstrated, what is necessary is just two or more types of frequencies.
[0125]
In the first to sixth embodiments, the case where there is a train at the train stop has been described. However, the same effect can be obtained as long as it is a place that can accommodate a plurality of trains such as a train base and a large-scale station. Further, although the frequency transmitted from the ground station and the frequency transmitted from the on-board station have been described as being the same, a set of different frequencies may be used. At this time, as in the sixth embodiment, when a plurality of frequencies are used, a set of different frequencies is used.
[0126]
【The invention's effect】
As described above, according to the present invention, the video information to the train that can efficiently transmit the video information that requires a long time for the data transmission and the data transmission from the ground side to the train by wireless communication. There is an effect that a transmission method is obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a video information transmission method to a train according to Embodiment 1 of the present invention.
FIG. 2 is a block diagram of a ground station and an on-board station in the video information transmission method to a train according to the first embodiment of the present invention.
FIG. 3 is a flowchart showing a video information transmission method to a train according to Embodiment 1 of the present invention.
FIG. 4 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to Embodiment 1 of the present invention.
FIG. 5 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to Embodiment 1 of the present invention.
FIG. 6 is a flowchart showing a video information transmission method to a train according to the first embodiment of the present invention.
FIG. 7 is a flowchart showing a video information transmission method to a train according to Embodiment 2 of the present invention.
FIG. 8 is a flowchart showing a video information transmission method to a train according to Embodiment 3 of the present invention.
FIG. 9 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to Embodiment 3 of the present invention.
FIG. 10 is a flowchart showing a video information transmission method to a train according to Embodiment 3 of the present invention.
FIG. 11 is a list showing video information attributes in a video information transmission method to a train according to Embodiment 4 of the present invention;
FIG. 12 is a flowchart showing a video information transmission method to a train according to Embodiment 4 of the present invention.
FIG. 13 is a flowchart showing a video information transmission method to a train according to Embodiment 4 of the present invention.
FIG. 14 is a flowchart showing a video information transmission method to a train according to the fifth embodiment of the present invention.
FIG. 15 is a block diagram showing a video information transmission method to a train according to Embodiment 6 of the present invention.
FIG. 16 is a block diagram of a ground station showing a video information transmission method to a train according to Embodiment 6 of the present invention;
FIG. 17 is a block diagram of an on-board station in a video information transmission method to a train according to Embodiment 6 of the present invention.
FIG. 18 is a flowchart showing a video information transmission method to a train according to the sixth embodiment of the present invention.
FIG. 19 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to Embodiment 6 of the present invention.
FIG. 20 is a flowchart showing a video information transmission method to a train according to the sixth embodiment of the present invention.
FIG. 21 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to a sixth embodiment of the present invention.
FIG. 22 is a sequence diagram showing a processing procedure in a video information transmission method to a train according to a sixth embodiment of the present invention.
FIG. 23 is a status list showing a video information transmission method to a train according to the sixth embodiment of the present invention.
[Explanation of Symbols] S1 Onboard station detection step, S2 measuring station selection step, S3 transmission quality measurement step, S4 transmission availability determination step, S7 transmission end determination step, S20 reference station selection step, S32 transmission end determination step, S34 transmission End determination step, S52 Transmission end determination step.

Claims (5)

A second station that is mounted on the train and that performs wireless communication with the ground station from a ground station that is provided on the ground side and includes a first transmission / reception unit that performs wireless communication and a first video information storage unit that stores video information. The video information stored in the first video information storage means is transmitted by wireless communication to the on-board station provided with the transmission / reception means and the second video information storage means for storing the video information. In the video information transmission method to the train stored in the information storage means, when the onboard station receives the first predetermined signal transmitted from the ground station, the onboard station transmits the second predetermined signal. An on-board station detecting step for detecting an on-board station in a state in which wireless communication with the ground station is received by the ground station receiving the second predetermined signal; Between one onboard station and the above ground station A measurement station selection step for selecting a measurement station as a measurement target for transmission quality of wireless communication, transmission quality for measuring transmission quality of wireless communication by transmitting and receiving a predetermined data signal between the measurement station and the ground station A measurement step, a transmission permission determination step for permitting transmission of the video information when the measured transmission quality is equal to or higher than a predetermined value, and a transmission end determination step for determining the end of transmission of the video information to the measurement station. A video information transmission method to a train characterized by comprising. A second station that is mounted on the train and that performs wireless communication with the ground station from a ground station that is provided on the ground side and includes a first transmission / reception unit that performs wireless communication and a first video information storage unit that stores video information. The video information stored in the first video information storage means is transmitted by wireless communication to the on-board station provided with the transmission / reception means and the second video information storage means for storing the video information. In the video information transmission method to the train stored in the information storage means, when the onboard station receives the first predetermined signal transmitted from the ground station, the onboard station transmits the second predetermined signal. An on-board station detecting step of detecting an on-board station in a state in which wireless communication with the ground station is received by the ground station receiving the second predetermined signal; and the detected on-board station; Predetermined data signal with the above ground station A transmission quality measuring step for measuring the transmission quality of the wireless communication by receiving, the completion of the transmission of the video information from one onboard station among the onboard stations whose measured transmission quality is equal to or higher than a predetermined value. A video information transmission method to a train, comprising: a reference station selection step for selecting as a reference station to be determined; and a transmission end determination step for determining the end of transmission of the video information to the reference station. The first transmission / reception means performs wireless communication using two or more different frequencies, and the second transmission / reception means performs wireless communication by selecting any one frequency from the two or more frequencies. The transmission quality is measured by the transmission quality measurement step at at least one of two or more frequencies, and the onboard station sets a frequency for receiving the video information based on the measured transmission quality. The video information transmission method to a train according to claim 2, wherein the video information is transmitted to the train. The video information not stored in the measurement station is selected from the video information stored in the first video information storage means, and the selected video information is transmitted from the ground station to the on-board station. The method of transmitting video information to a train according to claim 1. The video information not stored in the reference station is selected from the video information stored in the first video information storage means, and the selected video information is transmitted from the ground station to the on-board station. The method for transmitting video information to a train according to claim 2 or claim 3, wherein:

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