JP2009170989A - Distributed computer system, method and device for setting configuration information - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a distributed computer system which can reduce the burden on a worker by automating the setup of configuration information of a computer having a function which is different for each installation place, and can efficiently perform maintenance and management. <P>SOLUTION: A terminal (PC#1-PC#24) connected with a management apparatus 30 via a communication line (LAN cable 40a, 40b) includes a configuration information setup preprocessing means for setting a virtual IP address based on an apparatus address inherent to an apparatus when power is turned on and transmitting a configuration information setup request to the management apparatus 30, and a configuration information setup processing means for specifying the installation place of an apparatus according to a signal designating a chance for acquiring a terminal installation place which is transmitted from the management apparatus 30 based on the configuration information setup request and setting up an actual address reflecting a specified installation place. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a distributed computer system suitable for use in a railway information service providing system for displaying information on a plurality of display terminals provided in the vicinity of a door of a railway vehicle, a configuration information setting method, and a configuration information setting apparatus. .

  As a railroad information service, information such as vehicle video advertisements is circulated on display terminals in vehicles, and more information is expected to be provided. When a display terminal with a built-in PC (Personal Computer) is used as a display terminal in a vehicle, it is necessary to set an IP (Internet Protocol) address, a subnet mask, a host name, and the like initially. First, a conventional setting method will be described.

  FIG. 12 is a diagram schematically showing a procedure from setting configuration information to installation in the vicinity of a door for a display terminal with a built-in PC used in the railway information service providing system. As shown in FIG. 12A, when a plurality of computers of PC # 1 to PC # N are mounted on a vehicle, first, in which office each PC # 1 to PC # N is installed in which office Whether the vehicle is to be installed, which vehicle is to be installed, and which door is to be installed is determined based on the judgment by the staff, and configuration information such as data for each IP address and function is set. In some cases, the setting computer 100 is used to set data for each function in each PC # 1 to PC # N. In this case, since the number of installed devices is large, there is a possibility of setting errors and duplication of configuration information by workers. Therefore, the worker needs time and effort to manage PC # 1 to PC # N.

  After the configuration information is set, as shown in FIG. 12 (b), the operator brings PC # 1 to PC #N into the vehicle where he / she wants to install, but there are a plurality of vehicles, vehicle # 1 to vehicle #N. For this reason, the vehicle is selected by artificial judgment.

  Also, as shown in FIG. 12 (c), there are also each vehicle (No. 1 to No. 10) for vehicles, and there are a plurality of doors (door # 1 to door # 8) in the vehicle. Which door to install has become an artificial decision, and installation errors may occur.

  If a setting mistake is found, the worker returns to the office and resets the configuration. In the example of FIG. 12D, the IP address is changed so that the PC # 2 is installed in the door # 7 of the second car of the vehicle # 1, and the setting of the function used in the door # 7 is set by the setting computer 100. As described above, there are four places in FIG. 12 (a), FIG. 12 (b), FIG. 12 (c), and FIG. The probability of error occurrence is high and cannot be ignored.

  FIG. 13 is a schematic diagram when an IP address is automatically assigned to PC # 1 to PC # N using DHCP (Dynamic Host Configuration Protocol). If the DHCP server 200 is used, it is possible to automatically assign IP addresses without manually setting IP addresses for PC # 3 to PC # 10.

  Specifically, as shown in FIGS. 13 (a) and 13 (b), PC # 3 is installed in the vicinity of the door # 1 of the vehicle. An IP address is automatically assigned. Similarly, PC # 4 is installed in door # 2, IP address of 192.168.0.2, PC # 5 is installed in door # 3, and IP address of 192.168.0.3 is It is assumed that each is automatically set.

  On the other hand, when each PC # 3 to PC # 10 is restarted, the IP address is set as shown in FIGS. 14 (a) and 14 (b). The IP address of 192.168.0.4 is set in PC # 3, and the IP address of 192.168.0.8 is set in PC # 4 installed in door # 2. The IP address assigned by the DHCP server 200 is different before and after the restart. On the other hand, an IP address of 192.168.0.3 is set for PC # 5 installed in door # 3, and the addresses assigned by the DHCP server 200 before and after the restart are the same.

  In other words, the IP address set by DHCP may be the same or different depending on the timing of allocation, and therefore it is not possible to specify an IP address that is to be allocated to a PC installed at a predetermined location. For this reason, the installation location of the PC cannot be specified from the assigned IP address.

In order to solve the above-described problems, conventionally, in a distributed system configured by connecting a plurality of devices to a network, a device connected to the network is automatically detected, and information held by the device is detected from the detected devices. Automate communication settings between devices by reading and generating system configuration information necessary for communication based on this read information and setting the generated configuration information for each device A distributed system setting method is known (for example, see Patent Document 1).
JP 2000-269998 A (paragraphs “0035” to “0037”, FIG. 13)

  According to the above-described prior art, in a distributed computer system such as a railway information service providing system, an IP address, a subnet mask, a host name, application definition data, etc., which are unique items for each PC built in the display terminal, etc. It was necessary to manually set the configuration information. For this reason, when the number of PCs increases, it is necessary to manage the correct time and configuration so that the PC where the configuration information is set should not be mistaken. Met. Moreover, a certain level of skill was required for PC.

  DHCP is conventionally known as a method for automatically assigning an IP address which is one of the unique items. As described above, according to DHCP (DHCP server 200), an IP address is automatically assigned to a PC. Although it is possible to assign, it is not possible to arbitrarily set which IP address is assigned to the PC where it is installed. Therefore, data can be transferred from a PC installed in one location to a PC installed in another location. There was a problem that communication by PC designation such as transmission could not be performed.

  On the other hand, according to the technique disclosed in Patent Document 1, the installation position of the device connected to the network is automatically acquired for each device, and construction information such as an IP address can be automatically set in each node. Although communication by device designation is possible, the installation location of the device can be determined only after the device is installed, and each device is fixed at the time of shipment to identify the installation location of the device. It is necessary to incorporate a wireless communication device such as an infrared ray that periodically transmits and receives the assigned position identifier.

  The present invention has been made to solve the above-described problems, and reduces the burden on workers and increases the efficiency of maintenance management by automating the setting of configuration information of computers such as PCs having different functions for each installation location. It is an object of the present invention to provide a distributed computer system, a configuration information setting method, and a configuration information setting device.

  In order to solve the above-described problem, a configuration information setting device according to the present invention includes, for example, a plurality of terminal devices distributed in the vicinity of a door in a vehicle and a management device that manages the plurality of terminal devices. In a railway information providing system connected via a communication line such as an area network), it is possible to identify a place where each of a plurality of terminal devices is installed if the car information and door position information are grasped in one vehicle. Since it can do, it was set as the structure which gives a terminal device the function which acquires this car information and door position information.

  In addition, it is assumed that an opportunity for automatically acquiring configuration information including information specifying the above-mentioned location is transmitted from a management device that manages the number of connected terminal devices, and each terminal device that has received this information transmits its own device It is configured to identify which door position is installed, and specify the car address information and set the IP address to be used in actual work. This makes it possible to set configuration information, which is a unique item necessary for work, and process the work.

  According to the present invention, it is possible to reduce the burden on the worker and increase the efficiency of maintenance management by automating the setting of the configuration information of a computer such as a PC having different functions for each installation location.

Embodiments of the present invention will be described below with reference to the drawings.
(Configuration of distributed computer system)
FIG. 1 is a diagram showing a system configuration of a distributed computer system according to an embodiment of the present invention. As an application example, a railway information providing system is shown. In FIG. 1, a maximum of six doors (door # 1 to door # 6 and door # 7 to door # 12, respectively) are installed on the left and right of each car 10 of the railway vehicle, and in the vicinity of door # 1. PC # 1 and PC # 2 as terminal devices, PC # 3 and PC # 4 in the vicinity of door # 2, PC # 5 and PC # 6 in the vicinity of door # 3, door # PC # 7 and PC # 8 are connected in the vicinity of PC4, PC # 9 and PC # 10 are connected in the vicinity of door # 5, and PC # 11 and PC # 12 are connected in the vicinity of door # 6, respectively. Yes. Also, PC # 13 and PC # 14 are near door # 7, PC # 15 and PC # 16 are near door # 8, PC # 17 and PC # 18 are near door # 9, PC # 19 and PC # 20 are connected near door # 10, PC # 21 and PC # 22 are connected near door # 11, and PC # 23 and PC # 24 are connected near door # 12, respectively. Has been.

  As shown in FIG. 1A, each PC # 1 to PC # 24 is connected to a management device 30 installed for each car 10 of a railway vehicle via a LAN cable 40 as a communication line. And Further, as shown in FIG. 1B, in order to grasp the connection positions of the PCs # 1 to # 24, in addition to the normal LAN cable 40, DI / DO (Digital Input / Digital Output) Contact information by 50 serial lines is required.

  For this reason, according to the distributed computer system according to the embodiment of the present invention, as shown in FIG. 1C, a line for obtaining contact information by the DI / DO 50 is also allocated to the normal LAN cable 40, Two LAN cables 40a and 40b that use both LAN transmission / reception and DI / DO contact input / output information are used. That is, the normal LAN cable 40 has an eight-core cable structure, but only four-core (Tx +, Tx-, Rx +, Rx- bidirectional transmission / reception line) is actually used as a LAN. Yes, the remaining 4 cores are unused. For this reason, the unused four cores are assigned and used as DI / DO contact input / output information, whereby two types of functions are realized by one LAN cable 40a, 40b.

  As a result, the number of cable cables is reduced, so that the labor of laying can be saved and the maintenance efficiency is improved. Note that the LAN cable 40 normally has an eight-core structure, but if a cable having a large number of cores is used, the number of DI / DO contacts can be increased. The reason why the two LAN cables 40a and 40b are used is that the installation positions of PC # 1 to PC # 24 installed at arbitrary locations are specified with reference to the contact input / output information. Details will be described later.

(Configuration of terminal device (configuration information setting device))
FIG. 2 is a diagram showing an example of a mounting structure of PC # 1 to PC # 24 as the terminal device shown in FIG. 1, and only PC # 1 is illustrated here. As shown in FIG. 2, a PC (Central Processing Unit) 51 is connected to the PC # 1 and a liquid crystal display device (LCD) module (not shown) is connected as a display device via a bus 52. The hub 53 and a DIO (Digital Input Output) 54 are connected. The hub 53 is a LAN concentrator circuit, and is connected to the management apparatus 30 via a normal RJ45 connector 55 (bidirectional transmission / reception terminals Tx +, Tx−, Rx +, Rx− are assigned). PC # 2 is a dedicated DI / DO terminal that can generate 0 to 3 contact input / output information to be described later, in addition to bidirectional transmission / reception lines Tx +, Tx-, Rx +, Rx- The connector 56 is connected. In FIG. 2, Tx +, Tx−, Rx +, and Rx− are represented as Tx (+), Tx (−), Rx (+), and Rx (−).

  FIG. 3 is a block diagram showing an expanded function of the internal configuration of a terminal device (PC) as a configuration information setting device. As shown in FIG. 3, the configuration information setting device functionally includes a power-on detection unit 501, a temporary IP address generation unit 502, an autoconfiguration (automatic configuration) instruction request transmission unit 503, and an autoconfiguration instruction. The receiving unit 504, the installation position specifying unit 505, and the real IP address generating unit 506 are divided and configured.

  The power-on detection unit 501 has a function of detecting a power-on of the PC and starting a temporary IP address generation process by the temporary IP address generation unit 502. The temporary IP address generation unit 502 generates a MAC (Media Access Control) address that does not overlap with other terminal devices when the power is turned on as a temporary IP address, and sets configuration information by the autoconfiguration instruction request transmission unit 503. It has a function of starting the start request transmission process. The autoconfiguration instruction request transmission unit 503 has a function of transmitting a configuration information setting start request generated by setting a temporary IP address to the management apparatus 30 via the LAN cable 40.

  For this reason, the power-on detection unit 501, the temporary IP address generation unit 502, and the auto-configuration instruction request transmission unit 503 cooperate with each other as “one of the constituent elements of the present invention when triggered by power-on. A temporary IP address based on a unique device address is set, and a configuration information setting preprocessing means for transmitting a configuration information setting start request to the management apparatus ”is operated.

  The auto-configuration instruction receiving unit 504 is transmitted from the management apparatus 30 when the management apparatus 30 receives the configuration information setting start request from all the PCs # 1 to PC # 24 that are managed and managed in number (units). And a function for starting the installation position specifying process of the own apparatus by the installation position specifying unit 505.

  In addition, the installation position specifying unit 505 refers to or updates the contact input / output information by DI / DO assigned to the LAN cable 40 and outputs it to another PC connected adjacently via the LAN cable 40. Thus, the installation position (door position, car position) of the own apparatus is specified and supplied to the real IP address generation unit 506, and the real IP address generation process by the real IP address generation unit 506 is activated.

  Based on the installation position information of the own device specified by the installation position specifying unit 505, the real IP address generation unit 506 re-creates the IP address that reflects the installation position of the PCs from the temporary IP address set with the MAC address. It has a function to perform allocation.

  For this reason, the auto-configuration instruction receiving unit 504, the installation position specifying unit 505, and the real IP address generating unit 506 cooperate with each other based on the “configuration information setting start request” which is one of the configuration requirements of the present invention. In accordance with an instruction signal for instructing an opportunity to acquire the installation position of the terminal device transmitted from the management apparatus, the installation position of the own apparatus is specified, and a real address setting in which the specified installation position is reflected is set. It operates as “configuration information setting processing means”.

  The configuration information setting preprocessing means (power-on detection unit 501, temporary IP address generation unit 502, autoconfiguration instruction request transmission unit 503) and configuration information setting processing means (autoconfiguration instruction reception unit 504, installation position) described above. The functions of the specifying unit 505 and the real IP address generation unit 506) are that the CPU 51 sequentially reads and executes each program stored in the memory (not shown) of the terminal device (PC # 1) shown in FIG. It is realized by the above, and does not indicate only what is actually divided into other blocks in the CPU 51, but is expressed separately for the sake of simplification of description. is there.

(Distributed computer system operation)
FIG. 4 is an operation sequence diagram shown for explaining the operation of the distributed computer system. Here, the respective processing on the terminal device side (PC # 1 to PC # 24) and the management device 30 side, and the flow of processing between the devices are shown. The operation of the distributed computer system according to the embodiment of the present invention will be described in detail below with reference to the operation sequence diagram of FIG.

  First, on the terminal device side, when the power is turned on and the own device is started, the power-on detection unit 501 detects that the own device has been started by turning on the power (S401: device power-on detection). Subsequently, the PC # 1 receives a LAN packet indicating this in order to receive a trigger (trigger) of the auto-configuration instruction from the management apparatus 30, but it is necessary to set a temporary IP address for this purpose.

  In order to set the temporary IP, it is necessary to arbitrarily assign an IP address as in DHCP, or to set it automatically inside the apparatus. However, when a DHCP server is prepared, it is necessary to prepare a management apparatus corresponding to the DHCP, and therefore, a method of automatically setting inside the apparatus is adopted here.

  Note that if each of the PC # 1 to PC # 24 automatically sets an IP address inside the apparatus, there is a possibility of duplication, so it is necessary to use an arbitrary value that does not overlap. For this reason, the MAC address of its own device that does not overlap (for example, the lower first byte (XX) and lower second byte (YY) of 00-00-87-59-YY-XX) is adopted as the IP address. 192.168.YY.XX is set as a temporary IP address (S402: generation of temporary IP address).

  By using the MAC address, it becomes possible to execute configuration processing in a batch for each PC # 1 to PC # 24 by creating a trigger (trigger timing) for configuration information setting. An auto configuration instruction request signal is transmitted to the management apparatus 30 via the LAN cable 40 (S403: auto configuration instruction request transmission).

  On the other hand, the management apparatus 30 receives an autoconfiguration instruction request (S404: reception of an autoconfiguration instruction request), and turns on the flag of the corresponding PC (computer) (S405: ON of the flag of the corresponding PC). However, the PC is not specified here, and only the number connected is managed by the flag. Then, the management device 30 determines whether or not an auto-configuration instruction request has been received from the PC that wants to execute the configuration information setting process. That is, the management device 30 manages the number of connected devices by using a flag assigned to each of the PC # 1 to PC # 24, and if there are responses from all PCs of a predetermined number (connected number), that is, the number of connected devices is aligned. For example, it is determined whether all the flags are turned on (S406: are all the flags turned on?). When all the flags are turned on (S406, Yes), a timing signal is generated for all the PC # 1 to PC # 24 as a trigger for executing the process of acquiring the installation position (S407: Auto). Config instruction transmission). If there is no response from all the PCs, that is, if the number of connected devices is not prepared (S406, No), the process waits for reception of an autoconfiguration instruction request and returns to step S404.

  When the management apparatus 30 transmits a trigger (auto configuration instruction transmission) for obtaining the installation position to all the PC # 1 to PC # 24, the auto configuration instruction request transmitted from each PC # 1 to PC # 24. The information (flag) related to is cleared (S408: all flags OFF). Note that the management device 30 executes a process of turning off all the flags before receiving the autoconfiguration instruction request (S400: all flags off).

  When each PC # 1 to PC # 24 receives an auto-configuration instruction from the management apparatus 30 (S409: auto-configuration instruction reception), the PC # 1 to PC # 24 perform an acquisition process of the installation position of the own apparatus (S410: acquisition of in-vehicle position information). Thereafter, the car number is specified (S411: acquisition of the car number), and a real IP address used for business is generated (S412: real IP address is generated). Then, an interface is set up so that communication with the management apparatus 30 can be performed (S413: start up of the interface), and thereby, a task using a real IP address can be started (S414: Business start). Details of the installation position acquisition process (S410) and the real address generation process (S412) will be described later.

(Operation of configuration information setting device)
Next, the operation of the configuration information setting apparatus will be described in detail with reference to FIG. Each of the PCs # 1 to PC # 24 starts up its own device when the power is turned on. At this time, the power-on detection unit 501 detects the power-on and activates the temporary IP address generation unit 502.

  The temporary IP address generation unit 502 adopts the lower first byte (XX) and the lower second byte (YY) of the MAC address (for example, 00-00-87-59-YY-XX) of its own device as the IP address, 192.168. YY. XX is set as a temporary IP address, and autoconfiguration instruction request transmission processing addressed to the management apparatus 30 by the autoconfiguration instruction request transmission unit 503 is started. The management apparatus 30 waits for reception of auto-configuration instruction requests from all connected PC # 1 to PC # 24, and auto-configuration that is an opportunity for setting auto-configuration for all connected PC # 1 to PC # 24. Generate and send a config instruction (timing signal).

  When each of the PC # 1 to PC # 24 receives the autoconfiguration instruction from the management apparatus 30 by the autoconfiguration instruction receiving unit 504, the PC # 1 to PC # 24 activates the installation position specifying unit 505, and the installation position specifying unit 505 determines the installation position of the own apparatus. Perform the acquisition process. As will be described later, the installation position specifying unit 505 specifies the installation positions of the PC # 1 to PC # 24 from a matrix (row number and column number) logically assigned to rows and columns.

  5 and 6 are explanatory diagrams showing a method for specifying the installation position of each PC by the installation position specifying unit. FIG. 5 is a diagram in which PC # 1 to PC # 24 are developed on the vehicle layout diagram, and FIG. 6 is a table format for the method of specifying the position by the DI / DO read value for each row I and row II. It is the figure shown by. 5 and 6 are diagrams illustrating details of the installation position acquisition process (S410) shown in the flowchart of FIG.

  As shown in FIG. 5, a configuration in which 24 PCs (PC # 1 to PC # 24) are connected to the management apparatus 30 is illustrated as in FIG. When it is assumed that two systems of LAN cables 40a and 40b are connected from the management apparatus 30 to the lines I and II, each PC # connected to each line of the lines I and II 1 to PC # 24, whether it is PC # 1 or PC # 24, if the row number and the column number can be specified without particular awareness, PC # 1 to PC # 24 correspond to which door It can be determined whether it is installed. For example, even if two PCs are installed in the vicinity of door # 1, it is possible to specify the installation position, such as the left of door 1 if it falls under row A, and the right of door 1 if it falls under row B become.

  The method for determining the row number and column number is as follows. That is, first, the management device 30 specifies the connected LAN cable 40a or 40b, outputs DO for row I with “0”, and outputs DO with row “1” for row II. As described above, unique values such as “0”, “1”, “2”, “3”, “4”,... Are output to the LAN cables 40a and 40b. At that time, the output value is limited by the number of DI / DO contacts. That is, if the DO is 1 point (using 2 cores), only “0” and “1”, and if the DO is 2 points (using 4 cores), “0”, “1”, “2”, “3” 4 types. Here, description will be made on the assumption that DO is two points.

  The management apparatus 30 always outputs DO to the specified line I of the LAN cable 40a, and each PC # 1 to PC # 24 reads the DI when receiving the autoconfiguration instruction and is located downstream. DO output is performed three times for PCs (PC # 1 to PC # 12), and the installation location is specified.

  In the case of row I, the management apparatus 30 continues to output “0” for DO to DO. PC # 1 reads DI, and outputs it to DO with the same value “0” for the first time. PC # 2 reads “0” in the same way with DI, and outputs “0” with DO. Thereafter, PC # 3 and PC # 4 to PC # 12 can recognize that PC # 1 to PC # 12 are connected to row I by reading “0”.

  After the first reading is completed as described above, the second reading is started. Similarly, the management apparatus 30 continues to output “0” by DO, and PC # 1 similarly reads “0” by DI. When PC # 1 performs the second reading, it updates +1 and outputs it to DO. When PC # 2 performs the second reading, it reads “1” output from PC # 1 with DI, similarly updates +1 and outputs it to DO. Thereafter, +1 is updated to PC # 12 in the order of PC # 3 and PC # 4. However, since the DO output is two points here, only values up to “0”, “1”, “2”, and “3” can be set. Therefore, the +1 update at the time of the second reading is performed in the quaternary system, and the value overlaps as a repetition of “0”, “1”, “2”, “3”, “0”, “1”. To avoid. Note that this corresponds to the first column (row, column, column) in FIG.

After the second reading is completed, the third reading is started. Similarly, the management apparatus 30 continues to output “0” by DO, and PC # 1 similarly reads “0” by DI. PC # 1 also updates +1 and outputs DO when the third reading is performed. When the PC # 2 also performs the third reading, it reads “1” output from the PC # 1 with DI, similarly updates +1 and outputs it to DO. Thereafter, +1 is updated to PC # 12 in the order of PC # 3 and PC # 4.
However, since the value is duplicated if +1 update is performed as in the case of reading the second time, +1 update is performed in ternary notation for the third time, and “0”, “1”, “2”, “0”, “1” By repeating “,” “2”, it is possible to make a difference in the contents of the second reading and the third reading and to make a difference in specifying the column. It corresponds to the last column of (row, column, column) in FIG.

  The method for specifying the position based on the read value of DI / DO is shown in a table format in FIGS. 6 (a) and 6 (b). Here, the cases of row I and row II are shown separately. Since 12 columns can be identified per row by reading three times, the installation position specifying unit 505 can define DI / DO by defining the installation positions of PC # 1 to PC # 24 so that they do not overlap. (1) PC # 1 is set to row 0, column 0-0, row I column A, (2) PC # 2 is set to row 0, column 1-1, row I column B, (3 Similarly, it is possible to determine that PC # 3 is installed in the row I column C, and (4) PC # 12 is installed in the row I column L. Further, it is possible to determine that the row II column A and the PC # 14 are installed at the location of the row II column B even in the PC # 13 located closest to the management apparatus 30 in the same manner as the PC # 1 described above. .

  In addition, since the above-mentioned example illustrated the case where 24 PCs (PC # 1 to PC # 24) are connected to the management apparatus 30, the installation position is specified by three readings. The number varies depending on the number of connected PCs and the number (n) of unused lines of the LAN cables 40a and 40b.

  That is, the management device 30 specifies two communication lines and outputs n unique contact information for each of the communication lines. Each PC (PC # 1 to # 24) (a) reads the contact information in accordance with an instruction signal instructing an opportunity to acquire the installation position of the own device output by the management device (where m is (B) the first time, the fixed contact information output from the management device is read and sequentially output to n × m terminal devices per row located downstream, Among the 2 × m × n terminal devices connected to the communication line, the row number of the own device assigned to the own device is specified. (C) From the second time onward, for each m−1 readings. 2 × m × n terminals connected to the communication line by sequentially updating and outputting the contact information output to n × m terminal devices per row located downstream with a non-overlapping value Among the devices, the column number assigned to the own device is specified. Specifically, in FIGS. 5 and 6, n is 4 and m is 3, and 2 × m × n = 24 is specified.

  By the way, not only in the second time and the third time, but when DO is updated by +1, the value is changed, so the timing of taking in becomes important. In other words, DI / DO value capture, +1 update processing, and output are performed immediately, but there is a difference in the timing at which the value is updated between the PC located near the management device 30 and the PC located farthest away. End up. For this reason, the timing of data capture will be described with reference to FIG.

  FIG. 7 is a diagram showing the data fetch timing of the configuration information setting device. In FIG. 7, the update data fetch timing of the PCs # 1 to # 24 by the management apparatus 30 is shown on the time axis. A is the PC farthest from the management apparatus 30 (latest timing), B is the PC closest to the management apparatus 30 (fastest timing), C is the inter-PC common update timing (50 seconds), and D is PC The common reference timing (10 seconds) is shown. The management device 30 updates the update data at an arbitrary timing (30 seconds) within a common update processing period (50 seconds) between the PC located closest to the management device 30 and the PC located farthest away. By taking in, the variation of the value is suppressed.

  Here, as shown in FIG. 7, the first, second, and third readings are performed at 60-second intervals, and the timing at which the management apparatus 30 finally captures the status information of the PC is the DI / DO reading. The processed 30 seconds. This makes it possible to suppress variations in value changes.

  Note that the reason for determining whether or not the management apparatus 30 has received the autoconfiguration instruction request from all the PCs (PC # 1 to PC # 24) in step S406 in the operation sequence diagram shown in FIG. Since the value will be different if it is shifted, the interlock is applied so that all the PCs are aligned, and this is a consideration for eliminating the failure of the update data fetching process.

  The installation position specifying unit 505 activates the real IP address generation unit 506 after executing the installation position acquisition process of the own device, and activates the real address generation process by the real IP address generation unit 506. 8 to 11 are diagrams schematically showing real address generation processing of the configuration information setting device. Each figure is an explanatory diagram of the processing contents of the real address generation processing by the real IP address generation unit 506, and (a) of each figure (FIGS. 8 to 11) shows the arrangement configuration of the PCs in the vehicle. In (b) of each figure (FIGS. 8 to 11), a relationship diagram between the arrangement location, the PC number (PC No.), and the IP address is shown. Here, for comparison with the conventional example, a case where eight PCs PC # 3 to PC # 10 are connected to the management apparatus 30 will be described as an example.

  FIG. 8 shows an IP address setting state that is set up by a temporary IP address, that is, before autoconfiguration is performed. Since the temporary IP address is arbitrarily set from the MAC address, PC # 3 is 192.168.99.10 and PC # 4 is 192.168.14.2, and 192.168 .. Subsequent addresses are disjoint.

  In this state, even if only the IP address is viewed, it cannot be determined to which door the PC is positioned. When auto-confing is executed by the real IP address generation unit 506 in the state shown in FIG. 8, the state changes to the state shown in FIG. 9, the installation positional relationship between the PCs # 3 to # 10 becomes clear, and the LAN cable 40a is connected. The IP address 192.168.0.1 is assigned to the door # 1 connected via the IP address. Further, an IP address of 192.168.0.5 is assigned to door # 5 connected via another LAN cable 40b. This means that the IP address is automatically assigned to each of the PCs # 3 to # 10, reflecting the installation location of the door.

  FIG. 10 assumes a case where the PC # 3 to PC # 10 are arbitrarily rearranged. That is, in the state shown in FIG. 9, the PC # 3 is installed on the door # 1, but here it is assumed that the PC # 10 is installed on the door # 1 and replaced.

  In this case, since the IP address of 192.168.0.8 is already assigned to the PC # 10, it is determined that the PC # 10 is installed at the door # 8 when only the IP address is seen. In order to execute the application defined for use, the function for the door # 8 is operated. Even in such a case, according to the configuration information setting device according to the embodiment of the present invention, the actual IP address generation unit 506 reflects the installation positions of PC # 3 to PC # 10 by the installation position specifying unit 505. In order to execute the auto-confing, it is possible to grasp the installation positions of PC # 3 to PC # 10 shown in FIG. 11 and change the IP address for door # 1.

  The distributed computer system according to the embodiment of the present invention manages, for example, a plurality of terminal devices (PC # 1 to PC # 24 in FIG. 1) distributed near the doors in the vehicle and the plurality of terminal devices. In the railway information providing system in which the management device 30 to be connected is connected via a communication line (LAN cable 40), if the car information and door position information in the vehicle are grasped, the location where each of the plurality of terminal devices is installed Therefore, the terminal device has a function of acquiring the car information and the door position information, and the management device 30 transmits an opportunity for acquiring the car information and the door position information. Is. For this reason, the terminal devices (PC # 1 to PC # 24) specify the door position where the device is installed after obtaining the opportunity to acquire the installation position information, specify the car information, The IP address used for business is set.

  In addition, according to the distributed computer system according to the embodiment of the present invention, the setting of configuration information of computers such as PCs having different functions for each installation location is automated, thereby reducing the burden on workers and improving the efficiency of maintenance management. Therefore, communication between computers by specifying the installation location can be realized without requiring a wireless communication device. In addition, since an independent information providing service is possible for each terminal device, it is possible to contribute to improvement of user service.

  Further, according to the configuration information setting device according to the embodiment of the present invention, configuration information that needs to be set for each terminal device can be automatically set, and the installation position of each identified terminal device is reflected. By automatically generating an IP address, it is possible to reduce the burden on the worker, reduce work errors, and improve the efficiency of maintenance management.

  Note that the functions of the constituent blocks included in the configuration information setting apparatus shown in FIG. 3 may be realized entirely by software, or at least a part thereof may be realized by hardware. That is, the power-on detection unit 501, the temporary IP address generation unit 502, the autoconfiguration instruction request transmission unit 503, the autoconfiguration instruction reception unit 504, the installation position specifying unit 505, and the actual IP address generation unit 506 have one or more data processes. These programs may be realized on a computer, or at least a part thereof may be realized by hardware.

  The configuration information setting method in the distributed computer system according to the embodiment of the present invention is, for example, as shown in FIG. 1, a plurality of terminal devices (PC # 1 to PC # 24) arranged in a distributed manner. And a configuration information setting method in a distributed computer system in which a management device 30 that manages the plurality of terminal devices is connected via a communication line (LAN cable 40). For example, as shown in FIG. First steps (S401 to S403) in which each terminal device sets a temporary IP address based on a device address unique to itself when power is turned on, and transmits a configuration information setting start request to the management device. ), And the management device generates an instruction signal instructing an opportunity to acquire an installation position of the terminal device after waiting for arrival of a configuration information setting request from a predetermined number of the terminal devices, In the second step (S404 to S408) to be transmitted to the terminal device, each terminal device specifies its own installation position according to the instruction signal instructing the trigger, and the real address reflecting the installation position And a third step (S409 to S412) for setting.

  Further, in the second step (S404 to S408), the management device refers to a flag assigned to each of the connected terminal devices and instructs the terminal devices to acquire an opportunity to acquire an installation position A signal is transmitted. Further, in the third step (S409 to S412), each terminal device refers to contact information that propagates contact input / output assigned to an unused line of the communication line, and is logically arranged in a matrix. The installation position of the terminal device is specified by the row number and the column number.

  According to the configuration information setting method in the distributed computer system according to the embodiment of the present invention, the setting of configuration information of a computer such as a PC having a different function for each installation location is automated, thereby reducing the burden on the worker and maintenance. Management efficiency can be improved, and communication between computers by specifying an installation location can be realized without requiring a wireless communication device.

It is a figure which shows an example of the system configuration | structure of the distributed computer system which concerns on embodiment of this invention. It is a figure which shows an example of the mounting structure of the terminal device which a distributed computer system has. It is the block diagram which expanded the function and showed the internal structure of the structure information setting apparatus. It is the operation | movement sequence diagram shown in order to demonstrate operation | movement of a distributed computer system. It is the figure which showed typically about the specific process of the installation position of a configuration information setting apparatus. It is the figure which showed typically about the specific process of the installation position of a configuration information setting apparatus. It is the figure which showed the timing of the data acquisition of a configuration information setting apparatus. It is the figure which showed typically about the production | generation process of the real address of a structure information setting apparatus. It is the figure which showed typically about the production | generation process of the real address of a structure information setting apparatus. It is the figure which showed typically about the production | generation process of the real address of a structure information setting apparatus. It is the figure which showed typically about the production | generation process of the real address of a structure information setting apparatus. In the conventional railway information service provision system, it is the figure which showed typically the procedure from setting configuration information to installation. It is the figure which showed typically the operation | movement at the time of assigning an IP address to a terminal device using DHCP in the conventional railway information service provision system. It is the figure which showed typically the operation | movement at the time of assigning an IP address to a terminal device using DHCP in the conventional railway information service provision system.

Explanation of symbols

30 Management device 40, 40a, 40b LAN cable 51 CPU
51 System Bus 52 Bus 53 Hub 54 DIO
501 Power-on detection unit 502 Temporary IP address generation unit 503 Autoconfiguration instruction request transmission unit 504 Autoconfiguration instruction reception unit 505 Installation position specification unit 506 Real IP address generation unit # 1 to # 24 Terminal device (PC, configuration information setting device)

Claims (8)

A plurality of terminal devices that are arranged in a distributed manner, set a temporary address based on a device address unique to the own device upon power-on, and transmit configuration information setting information to the management device via a communication line;
Managing the plurality of terminal devices, generating an instruction signal instructing an opportunity to acquire an installation position of the terminal device after waiting for arrival of the configuration information setting request from a predetermined number of the plurality of terminal devices, Via the management device that transmits the generated instruction signal to each terminal device,
Each of the terminal devices specifies an installation position of its own device according to an instruction signal for acquiring an installation position transmitted from the management device, and sets a real address reflecting the installation position. Type computer system. A configuration information setting method in a distributed computer system in which a plurality of terminal devices distributed and a management device that manages the plurality of terminal devices are connected via a communication line,
A first step in which each terminal device sets a temporary address based on a device address unique to the device itself upon power-on, and transmits a configuration information setting start request to the management device;
The management device generates an instruction signal indicating an opportunity to acquire the installation position of the terminal device after waiting for the arrival of a configuration information setting request from a predetermined number of the terminal devices, and transmits the instruction signal to each terminal device Steps,
A distributed computer system comprising: a third step in which each terminal device specifies an installation position of the terminal device in accordance with the instruction signal and sets a real address reflecting the installation position. Configuration information setting method. In the second step,
The said management apparatus transmits the instruction | indication signal which instruct | indicates the opportunity which acquires a setting position with respect to each said terminal device with reference to the flag allocated for every said connected terminal device. Method for setting configuration information in a distributed computer system. In the third step,
Each terminal device refers to contact input / output information assigned to n unused lines (where n is an arbitrary integer) of the communication line, and determines the installation position of the own device logically assigned to the matrix. The configuration information setting method in the distributed computer system according to claim 2, wherein the configuration information is specified. The management device
Identify the communication lines provided in two systems, and output n unique contact information for each of the communication lines,
Each terminal device is
The contact information is read m times (where m is an arbitrary integer) in accordance with an instruction signal for instructing an opportunity to acquire the installation position of the own device output from the management device,
The first time, the fixed contact information output from the management device is read, and sequentially output to n × m terminal devices per row located downstream, and 2 × m × connected to the communication line. Of the n terminal devices, specify the row number of the own device assigned to the own device,
From the second time onward, for each of the m-1 readings, the contact information output to n × m terminal devices per row located downstream is sequentially updated with a non-overlapping value and output, 5. The method for setting configuration information in a distributed computer system according to claim 4, wherein a column number assigned to the own device among 2 × m × n terminal devices connected to the communication line is specified. In the third step,
The management device may update the output data at an arbitrary timing within a common update processing period between a terminal device located closest to the management device and a terminal device located farthest from the management device. The configuration information setting method in the distributed computer system according to claim 2, wherein the setting information is captured. A management device is a configuration information setting device connected via a communication line,
Configuration information setting pre-processing means for setting a temporary address based on a device address unique to the own device upon power-on, and transmitting a configuration information setting start request to the management device;
Based on the instruction signal for instructing the opportunity to acquire the installation position of the terminal device transmitted from the management device based on the configuration information setting start request, the installation position of the own device is specified, and the specified installation position is reflected. A configuration information setting processing unit configured to set a real address. The configuration information setting processing means includes:
The transmission / reception information assigned to the communication line and the contact information assigned to the unused line are branched, supplied to each of the hub and the contact input / output unit, and referred to the contact information taken in via the contact input / output unit. The configuration information setting device according to claim 7, wherein an installation position of the terminal device logically arranged in a matrix is specified by a row number and a column number.

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