JP2009157852A - Spatial data conversion device, spatial data conversion program and spatial data conversion method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve a method of retrieving/displaying spatial data, to promote circulation of the spatial data. <P>SOLUTION: This intermediary device 1 converts metadata of the spatial data provided in advance by each spatial data provider server 3 into a predetermined format and stores them. The intermediary device 1 retrieves the metadata satisfying retrieval conditions designated by a user terminal 2 from the stored metadata, and transmits the retrieval result to the user terminal 2. At this time, not only the metadata satisfying the input retrieval conditions but also the metadata satisfying only a position condition included in the input retrieval conditions are transmitted as the retrieval result. The spatial data corresponding to the metadata designated by the user terminal 2 are transmitted to the spatial data provider server 3 according to the transmitted retrieval result, and the spatial data provider server 3 transmits the spatial data to the user terminal 2. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a technique for retrieving and displaying spatial data such as satellite images and aerial photographs.

In the field of geographic information systems (GIS), there is an idea of a clearing house that refers to the entire distribution mechanism of geographic information utilizing a communication network. The mechanism of the clearinghouse is that an organization or organization that holds geographical information such as an electronic map connects the server to the Internet and publishes information (metadata) necessary for using spatial data through the server. To do. A data user can obtain spatial data by accessing a clearinghouse server connected to the network. This mechanism makes it easy for users to obtain necessary information, promotes mutual use of data, and avoids unnecessary redundant investment.
JP 2002-117245 A

However, in the clearinghouse, each spatial data provider provides only the products provided by itself, so to obtain the products provided by each spatial data provider, access the server of each spatial data provider and perform a search. There is a need to do. On the other hand, the user has a request to obtain image data of an area of interest (an area where he wants to purchase spatial data) acquired by various sensors. For this reason, the user accesses the server of each provider, individually searches and orders, and acquires spatial data individually from each provider, which places a burden on the user.
In particular, the search / order method for spatial data is very complicated, and the search / order method differs for each provider. For this reason, the user cannot easily acquire the desired data, which is a factor that hinders the promotion of the distribution of spatial data.
It is an object of the present invention to improve a spatial data search / display method and promote the distribution of spatial data.

The spatial data conversion device according to the present invention is, for example, a spatial data conversion device that converts metadata of spatial data into a predetermined format and registers it in a database.
A character string storage unit that stores a predetermined character string in the storage device for each metadata format of the spatial data;
A metadata input unit for inputting spatial data metadata via an input device;
The processing device searches for a predetermined character string stored in the character string storage unit from the character string included in the metadata input by the metadata input unit, and the format of the metadata by the character string included in the metadata A format determination unit for determining
A correspondence information storage unit that stores correspondence information indicating a correspondence relationship between metadata items and database items in a storage device for each metadata format of the spatial data;
A format conversion unit that acquires correspondence information of the format determined by the format determination unit from the correspondence information storage unit, and converts the metadata into a predetermined format by a processing device based on the acquired correspondence information;
And a metadata registration unit that registers the metadata converted by the format conversion unit into the predetermined format in a database.

The character string storage unit stores a character string included in a certain type of metadata and not included in another type of metadata for each spatial data metadata format. Features.

The spatial data conversion program according to the present invention is, for example, a spatial data conversion program that converts metadata of spatial data into a predetermined format and registers it in a database.
Metadata input processing to input spatial data metadata;
A predetermined character string stored in a storage device in advance for each metadata format of the spatial data is searched from the metadata input in the metadata input process, and the metadata format is determined by the character string included in the metadata. A format determination process for determining
Acquire the correspondence information of the format determined in the format determination process from a storage device that stores the correspondence information indicating the correspondence between the metadata item and the database item for each metadata format of the spatial data. Format conversion processing for converting the metadata into a predetermined format based on the corresponding information,
It is characterized in that the computer executes a metadata registration process for registering the metadata converted into the predetermined format by the format conversion process in a database.

In the format determination processing, for each metadata format of spatial data, a storage device that stores in advance a character string that is included in metadata in a certain format and that is not included in metadata in other formats Then, each character string is acquired, and the acquired character string is searched from the metadata.

The spatial data conversion method according to the present invention is, for example, a spatial data conversion method in which metadata of spatial data is converted into a predetermined format and registered in a database.
A metadata input step in which the input device inputs spatial data metadata;
The processing device searches for a predetermined character string stored in the storage device in advance for each metadata format of the spatial data from the metadata input in the metadata input step, and the character string included in the metadata A format determination step for determining the format of the metadata;
The processing device obtains the correspondence information of the format determined in the format determination step from the storage device that stores in advance the correspondence information indicating the correspondence relationship between the metadata item and the database item for each metadata format of the spatial data. A format conversion step of converting the metadata into a predetermined format based on the acquired correspondence information;
The processing apparatus includes a metadata registration step of registering the metadata converted into the predetermined format in the format conversion step in a database.

  The spatial data conversion device, the spatial data conversion program, and the spatial data conversion method according to the present invention arrange the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format, and the spatial data of each spatial data provider server 3 To be able to search in a unified way. Therefore, according to the mediation apparatus according to the present invention, the user does not need to create a search condition for each spatial data provider server and perform a search, and can perform a search efficiently.

Embodiment 1 FIG.
In this embodiment, an intermediary device 1 (spatial data display device, spatial data conversion device) that mediates between a user and a spatial data provider will be described.

FIG. 1 is a diagram illustrating a flow of spatial data acquisition processing when the mediation device 1 is not interposed.
When a user acquires spatial data, the user terminal 2 accesses the spatial data provider server 3 (an example of a data providing server) that is a server of the spatial data provider from an Internet browser or the like, and searches for desired spatial data. And get. Here, there are a plurality of spatial data providers that provide spatial data. That is, there are a plurality of spatial data provider servers 3 that are servers of the spatial data provider. In FIG. 1, the spatial data provider server 3 exists from the spatial data provider server 3a to the spatial data provider server 3n.

A process between the user terminal 2 and the spatial data provider server 3a will be described as an example.
(1) The user terminal 2 registers as a user in the spatial data provider server 3a. That is, the user terminal 2 inputs predetermined information to the spatial data provider server 3a, and the spatial data provider server 3a issues a user ID and the like to the user terminal 2.
(2) The spatial data provider server 3 a transmits catalog information of spatial data to the user terminal 2. The catalog information is item information of metadata of searchable spatial data. That is, the catalog information is an item that the user terminal 2 can specify as a search condition. Note that the metadata of the spatial data is information such as the platform used when the spatial data is acquired and the observation date and time of the spatial data. The catalog information and metadata will be described later.
(3) The user terminal 2 issues a search instruction for spatial data of an area (interested area) that the user terminal 2 desires to purchase. For example, the user terminal 2 transmits information indicating the area of interest together with other search conditions to the spatial data provider server 3a. At this time, the user terminal 2 designates a search condition based on the catalog information acquired in (2). That is, for example, the user terminal 2 searches for an item indicating the position from the catalog information, specifies a condition indicating the area of interest in a format that matches the format of the item indicating the position, and sends the search condition to the spatial data provider server 3a. Send.
(4) The spatial data provider server 3a transmits a part of the spatial data metadata corresponding to the search condition to the user terminal 2 as a search result. For example, the spatial data provider server 3a transmits the identification information of the spatial data corresponding to the search condition, the thumbnail image of the spatial data, and the position information to the user terminal 2.
(5) The user terminal 2 determines whether or not to download the spatial data based on the metadata (here, the thumbnail image and the position information) of the spatial data received from the spatial data provider server 3a. When downloading the spatial data, the user terminal 2 transmits order information including the identification information of the spatial data to the spatial data provider server 3a.
(6) When the user terminal 2 needs to pay the price, the user terminal 2 pays the price together with the order information. For example, the user terminal 2 may make payment with electronic money, and the payment information may be sent to the spatial data provider server 3a.
(7) The spatial data provider server 3a receives the confirmation information of the transmitted order information, information necessary for downloading the spatial data (for example, link information to the download screen, and transition permission information to the download screen) Is transmitted to the user terminal 2.
(8) The spatial data provider server 3a transmits the spatial data to the user terminal 2 (the user terminal 2 downloads the spatial data).

The user terminal 2 performs the processing performed with the spatial data provider server 3a also with other spatial data provider servers 3, and acquires necessary spatial data. That is, the user terminal 2 acquires the satellite image of the area of interest from the spatial data provider server 3a, and acquires the aerial photograph of the area of interest from the spatial data provider server 3b.
Here, the catalog information acquired by the user terminal 2 in (2) differs for each spatial data provider server 3 and is specialized information. Therefore, in general, it is difficult for the user to perform the search shown in (3) from the user terminal 2. Performing this difficult process for each spatial data provider server 3 is a very heavy burden on the user. In addition, the user cannot obtain desired spatial data because appropriate search of the spatial data cannot be performed.

FIG. 2 is a diagram illustrating a flow of spatial data acquisition processing when the mediation device 1 is used.
When acquiring the spatial data, the user accesses the intermediary device 1 from the user terminal 2 and searches for and acquires the desired spatial data. Here, as described with reference to FIG. 1, there are a plurality of spatial data provider servers 3. In FIG. 2, the spatial information providing server 4 is described, but the spatial information providing server 4 will be described later. That is, first, only the processes among the mediation device 1, the user terminal 2, and the spatial data provider server 3 will be described.

(1 ′) Each spatial data provider server 3 registers the metadata of the spatial data in the intermediary device 1 in advance. Here, the intermediary device 1 arranges the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format and registers it in the database. That is, the metadata of the spatial data acquired from each spatial data provider server 3 is in the format of the catalog information of each spatial data provider server 3, so that catalog information in a unified format is generated and registered in the database. To do.
(2 ′) The user terminal 2 registers as a user in the mediation device 1. That is, the user terminal 2 inputs predetermined information to the mediation device 1, and the mediation device 1 issues a user ID and the like to the user terminal 2.
(3 ′) The intermediary device 1 transmits spatial data catalog information to the user terminal 2.
(4 ′) The mediation device 1 transmits spatial data search and order guide information to the user terminal 2. The order guide information is, for example, information that explains each item of the catalog information and the flow of processing.
(5 ′) The user terminal 2 searches for spatial data of an area (interested area) to be purchased based on catalog information. For example, the user terminal 2 transmits information indicating the area of interest to the intermediary device 1 together with other search conditions.
(6 ′) The mediation device 1 transmits the metadata of the spatial data corresponding to the search condition to the user terminal 2 as a search result.
(7 ′) The user terminal 2 determines whether or not to download the spatial data based on the information received from the intermediary device 1 (here, the metadata of the spatial data). When downloading the spatial data, the user terminal 2 transmits the order information to the mediation device 1.
(8 ') The user terminal 2 pays the price together with the order information when the price needs to be paid. For example, the user terminal 2 may make payment with electronic money, and the payment information may be sent to the user terminal 2.
(9 ′) The intermediary device 1 receives the confirmation information of the transmitted order information and information necessary for downloading the spatial data (for example, link information to the download screen and transition permission information to the download screen). It transmits to the user terminal 2. When spatial data is downloaded from a plurality of spatial data provider servers 3, for example, link information to the download screen and transition permission information to the download screen for each spatial data provider server 3 are transmitted.
(10 ′) The mediation device 1 transmits the order information received from the user terminal 2 to the spatial data provider server 3 (here, referred to as the spatial data provider server 3a) that provides the spatial data specified from the order information. To do. At this time, the intermediary device 1 converts the order data format for each spatial data provider server 3 and transmits it. If there is a plurality of order information, the order information is sorted and transmitted to each spatial data provider server 3.
(11 ′) When payment is required, the mediation device 1 transmits the payment information received from the user terminal 2 in (8 ′) to the spatial data provider server 3a. The transfer at (8 ′) may be directly credited to the spatial data provider server 3a, or it may be credited to the intermediary device 1, and the settlement data from the intermediary device 1 as the settlement information at (10 ′). It may be transmitted to 3a.
(12 ′) After confirming the payment information, the spatial data provider server 3a transmits the spatial data to the user terminal 2 (the user terminal 2 downloads the spatial data).
(13 ′) The spatial data provider server 3 a transfers the brokerage fee / advertisement fee to the brokerage device 1.

As described above, the intermediary device 1 arranges the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format and registers it in the database. When the user terminal 2 searches for spatial data, the spatial data can be searched from each spatial data provider server 3 by a unified method. A method of arranging the metadata in a predetermined format so that the spatial data can be retrieved from each spatial data provider server 3 by a unified method will be described later.
The feature of the mediation apparatus 1 according to this embodiment is that it does not hold spatial data. That is, the intermediary device 1 holds only the spatial data metadata in the database, and does not hold the spatial data itself (image data of the spatial data). Then, when there is an order from the user terminal 2, the intermediary device 1 instructs the spatial data provider server 3 to transmit the spatial data directly from the spatial data provider server 3 to the user terminal 2.

Next, the spatial information providing server 4 (an example of a data providing server) shown in FIG. 2 will be described.
The spatial information providing server 4 is a server of a spatial information provider that provides information obtained by adding additional information to spatial data (here, spatial information is used to distinguish it from the spatial data described above, but is a type of spatial data). It is. The spatial information is, for example, a forest pest damage map obtained by adding forest pest damage information to map data. That is, map data or the like that makes it possible to identify in which area the forest pests are damaged.
Similarly to the spatial data provider server 3, the spatial information providing server 4 registers the metadata of the spatial information in the mediation device 1 in advance. Then, the spatial information is provided to the user terminal 2 in the same flow as the spatial data provider server 3. However, in the example illustrated in FIG. 2, the spatial information providing server 4 does not directly transmit the spatial information to the user terminal 2, unlike the spatial data provider server 3. In the example illustrated in FIG. 2, the spatial information providing server 4 transmits the ordered spatial information to the mediation device 1, and the mediation device 1 transmits the spatial information to the user terminal 2. This is because the spatial information provider may not have a function of transmitting data to the user terminal 2 unlike the spatial data provider. Further, the intermediary device 1 may store not only the spatial information metadata but also the spatial information itself in advance.
The spatial information providing server 4 may transmit the spatial information directly to the user terminal 2 as with the spatial data provider server 3, and the spatial data provider server 3 may mediate as with the spatial information providing server 4. The intermediary device 1 may transmit the spatial data to the user terminal 2 by transmitting the spatial data to the device 1.

Next, metadata and catalog information will be described. FIG. 3 is a diagram illustrating an example of metadata.
The metadata includes a directory data part 81, an inventory data part 82, and an image part 83.
The directory data unit 81 includes a provider name 84, a sensor platform name 85, and a data type 86. The provider name 84 is the name of the spatial data provider, and is information that can uniquely identify the spatial data provider. The sensor platform name 85 is the name of the sensor platform used for obtaining the spatial data. The data type 86 is type information indicating what kind of data the spatial data is, for example, satellite engineering image, satellite radar image, aerial optical photograph, aerial radar image, three-dimensional elevation data, map data, etc. Information.
The inventory data unit 82 includes an observation date and time 87, an observation range 88, and the like. The observation date and time 87 is date and time information indicating the date and time when the spatial data is observed (acquired). The observation range 88 is range information indicating a range in which spatial data is observed.
The image unit 83 includes a thumbnail image 89. The thumbnail image 89 is an image obtained by reducing the image data of spatial data or spatial information.

Here, the metadata is information included in each item shown in FIG. In other words, the metadata is information such as “XX company” included in the provider name 84 and “xx radar” included in the sensor platform name 85.
Further, the catalog information is the name of each item shown in FIG. That is, the catalog information is an item name such as the provider name 84 and the sensor platform name 85.
As described above, the format of metadata, that is, catalog information differs depending on the spatial data provider and the spatial information provider. That is, item names different from the item names shown in FIG. 3 are used by the spatial data provider and the spatial information provider, and the order of the items is also different. Also, information other than the items shown in FIG. 3 is included.

Next, the configuration and function of a spatial data mediation system that performs spatial data acquisition processing via the mediation device 1 will be described.
FIG. 4 is an overall view of the spatial data mediation system. FIG. 5 is a functional block diagram of the intermediary device 1 showing the functions of the intermediary device 1 in more detail than FIG. FIG. 6 is a diagram illustrating an example of a hardware configuration of the intermediary device 1.
As shown in FIG. 4, the spatial data mediation system includes a plurality of user terminals 2 used by a user, a plurality of spatial data provider servers 3 serving as spatial data provider servers, and a plurality of spatial information serving as servers of spatial information providers. The mediation apparatus 1 is provided as a mediator server that mediates between the providing server 4, the user terminal 2, the spatial data provider server 3, and the spatial information providing server 4. Further, the intermediary device 1, the user terminal 2, the spatial data provider server 3, and the spatial information providing server 4 are connected via a network such as the Internet network 9.

The mediation device 1 is a device that mediates transmission of spatial data from a data providing server that stores spatial data to a user terminal. As shown in FIG. 4, the intermediary device 1 includes a metadata storage unit 10 (spatial data storage unit), a spatial information storage unit 11, a provider management unit 12, a user management unit 13, a search unit 14, a search result output unit 15, An order receiving unit 16, a data relay unit 17 (data receiving unit, data transmitting unit), a metadata database 18, and a spatial information database 19 are provided.
Further, as shown in FIG. 5, the functions shown in FIG. 4 have the following functions, respectively.
The metadata storage unit 10 includes a metadata input unit 31, a format determination unit 32, a format conversion unit 33, a metadata registration unit 34, a character string database 35 (character string storage unit), and a correspondence information database 36 (corresponding information storage unit). Is provided.
The spatial information storage unit 11 includes a spatial information input unit 37 and a spatial information registration unit 38.
The provider management unit 12 includes a provider registration information input unit 39 and a provider management database 40.
The user management unit 13 includes a user registration information input unit 41 and a user management database 42.
The search unit 14 includes a search screen display unit 43, a search information receiving unit 44 (search information input unit), a search condition interpretation unit 45, a search condition search unit 46 (data search unit), and a position condition search unit 47.
The search result output unit 15 includes a search result output unit 48, a price calculation unit 49, a unit price file 50, and a search result display unit 51.
The order reception unit 16 includes an order information reception unit 52, a total price calculation unit 53, an order content payment method confirmation display unit 54, and an order information transmission unit 55 (specific information transmission unit).
The data relay unit 17 includes a spatial information output unit 56, a spatial information transmission unit 57, and a relay processing unit 58.

Further, as illustrated in FIG. 6, the mediation device 1 authenticates a user with an application server 60 and an external communication device 69 (http server, Web server) (an example of a communication device or an input device) as hardware. And a user authentication server 70.
The application server 60 includes a central processing unit 61 (CPU), a storage device 62 (memory such as RAM), a display device 63 (display), an input device 64 (keyboard / mouse), a storage medium reading / writing device 65 (CD / (DVD RW drive) (storage medium reading / writing device 65 is also an example of an input device), external storage device 66 (hard disk), printing device 67 (printer), and storage medium 68 (CD / DVD) hardware Each hardware is connected via a bus 71.

Next, each process shown in FIG. 2 will be described in detail based on the configuration and function of the spatial data mediation system shown in FIGS.
(1 ′) The metadata storage unit 10 acquires the spatial data or the metadata of the spatial information from the spatial data provider server 3 or the spatial information providing server 4, arranges it in a predetermined format, and registers it in the metadata database 18.
First, the metadata input unit 31 reads, for example, the spatial data stored in the storage medium 68 or the metadata of the spatial information by the storage medium reading / writing device 65 and stores it in the storage device 62 or the like. Alternatively, the metadata input unit 31 acquires spatial data or metadata of spatial information from the spatial data provider server 3 or the spatial information providing server 4 via the external communication device 69 and stores it in the storage device 62 or the like. Further, the metadata input unit 31 additionally inputs information not included in the metadata read by the storage medium reading / writing device 65 via the input device 64, converts the information into a predetermined format, and converts the information into a predetermined format. And so on.
Next, the format determination unit 32 and the format conversion unit 33 convert the metadata input by the metadata input unit 31 into a predetermined format by the central processing unit 61 based on the information stored in the character string database 35 and the correspondence information database 36. The data is converted and stored in the storage device 62 or the like. Processing for converting the metadata format will be described later.
Then, the metadata registration unit 34 stores the metadata converted by the format determination unit 32 and the format conversion unit 33 into a predetermined format in the metadata database 18. The metadata database 18 is a storage device (for example, an external storage device 66) that stores metadata.

The spatial information storage unit 11 acquires spatial information from the spatial information providing server 4 and stores it in the spatial information database 19. That is, when the intermediary device 1 stores not only the spatial information metadata but also the spatial information itself in advance, the spatial information storage unit 11 acquires the spatial information itself and stores it in the spatial information database 19.
First, the spatial information input unit 37 inputs spatial information via the input device 64 or the storage medium reading / writing device 65 and stores it in the storage device 62 or the like. Alternatively, the spatial information input unit 37 acquires the spatial information from the spatial information providing server 4 via the external communication device 69 and stores it in the storage device 62 or the like.
Next, the spatial information registration unit 38 registers the spatial information input by the spatial information input unit 37 in the spatial information database 19. The spatial information database 19 is a storage device (for example, an external storage device 66) that stores spatial information. Further, the spatial information registration unit 38 may display the content of the spatial information input by the spatial information input unit 37 before registration on the display device 63 or the like so that the broker can confirm the information.

The provider registration information input unit 39 of the provider management unit 12 inputs the spatial data provider registration information from the spatial data provider server 3 when the spatial data provider registers spatial data for the first time. Through the provider management database 40. Similarly, when the spatial information provider registers spatial information for the first time, the provider registration information input unit 39 inputs the spatial information provider registration information from the spatial information providing server 4 to the external communication device 69 or the like. Through the provider management database 40. The provider management database 40 is a storage device (for example, an external storage device 66) that stores registration information of the spatial data provider and registration information of the spatial information provider.
Here, the registration information of the spatial data provider or the spatial information provider is, for example, the address of the spatial data provider server 3 or the spatial information provider server 4, the spatial data provider name, the spatial information provider name, or the like.

(2 ′) The user terminal 2 performs user registration with the mediation device 1.
Then, the user registration information input unit 41 of the user management unit 13 accepts input of user registration information from the user terminal 2 via the external communication device 69 and stores it in the user management database 42. The user management database 42 is a storage device (for example, an external storage device 66) that stores user registration information.
Here, the user registration information is, for example, the address of the user terminal 2, the user name, the number of a credit card used for settlement, and the like.

  (3 ′) (4 ′) When the search screen display unit 43 of the search unit 14 receives an instruction to input the search information from the user terminal 2 through the external communication device 69 or the like, the search screen display unit 43 receives the catalog information and the guide information. 2 through the external communication device 69 to display a search condition input screen on the user terminal 2.

  (5 ') The user terminal 2 transmits to the intermediary device 1 search information that specifies search conditions for searching for spatial data of an area (interested area) where the user wants to purchase spatial data based on the catalog information. Here, the user terminal 2 transmits information indicating the area of interest to the mediation apparatus 1 as search information together with other search conditions. That is, here, the search condition includes a position condition indicating a position and other conditions.

(6 ′) The search unit 14 receives search information from the user terminal 2 and performs a search from the metadata database 18.
First, the search information receiving unit 44 receives search information indicating a search condition from the user terminal 2 via the external communication device 69 and stores it in the storage device 62 or the like.
Next, the search condition interpreting unit 45 interprets the search condition indicated by the search information received by the search information receiving unit 44 by the central processing unit 61, and allows the data to be searched from the metadata database 18 or the spatial information database 19. Is converted by the central processing unit 61 and stored in the storage device 62 or the like.
Then, the search condition search unit 46 searches for metadata corresponding to the search condition converted by the search condition interpretation unit 45 from the metadata stored in the metadata database 18 by the central processing unit 61. Further, the position condition search unit 47 searches the metadata database 18 for metadata by the central processing unit 61 based on only the position condition included in the search condition indicated by the search information input by the search information receiving unit 44 and stores it therein. 62 and so on. Here, the position condition search unit 47 performs the search based only on the position condition, but the search may be performed not only based on the position condition but also by adding other conditions.

Next, the search result output unit 15 transmits the search result searched by the search unit 14 to the user terminal 2 via the external communication device 69.
First, the search result output unit 48 outputs (stores) the metadata searched by the search condition search unit 46 and the position condition search unit 47 from the metadata database 18 to the storage device 62 or the like.
Next, the price calculation unit 49 refers to the unit price file 50, calculates the price of the spatial data and the spatial information corresponding to the metadata output by the search result output unit 48 by the central processing unit 61 and stores it in the storage device 62. Remember. The unit price file 50 is a storage device (such as an external storage device 66) that stores the unit price of spatial data or spatial information. The unit price is, for example, a price per unit area.
Then, the search result display unit 51 transmits the metadata output by the search result output unit 48 together with the price calculated by the price calculation unit 49 to the user terminal 2 via the external communication device 69, and the search result is displayed to the user terminal 2. The metadata output by the output unit 48 is displayed.

  (7 ') (8') The user terminal 2 determines whether to download the spatial data based on the spatial data metadata received from the spatial data provider server 3a. When downloading the spatial data, the user terminal 2 transmits the order information to the mediation device 1. When the user terminal 2 needs to pay the price, the user terminal 2 pays the price together with the order information.

(9 ′) (10 ′) (11 ′) The order receiving unit 16 receives input of spatial data or order information of spatial information from the user terminal 2 via the external communication device 69, or the input device 64 or storage. The information is received via the medium reading / writing device 65 and transferred to the spatial data provider server 3 or the spatial information providing server 4 via the external communication device 69.
First, the order information receiving unit 52 receives input of spatial data or order information of spatial information from the user terminal 2 via the external communication device 69 and stores it in the storage device 62 or the like.
Next, the total price calculation unit 53 calculates the total amount of the spatial data or the spatial information indicated by the order information received by the order information reception unit 52 by the central processing unit 61 based on the price calculated by the price calculation unit 49. And stored in the storage device 62.
Next, the order content payment method confirmation display unit 54 sends the order content indicated by the order information received by the order information reception unit 52 and the total amount calculated by the total price calculation unit 53 to the user terminal 2 via the external communication device 69. Send through.
Next, the order information receiving unit 52 receives order confirmation information and settlement information from the user terminal 2 via the external communication device 69.
Then, the order information transmitting unit 55 transmits the order information and settlement information received by the order information receiving unit 52 to the spatial data provider server 3 or the spatial information providing server 4 via the external communication device 69. Here, the order information is information including at least spatial data or specific information that can identify the spatial information (spatial data or identification information of the spatial information). The order information transmitted to the spatial data provider server 3 includes at least terminal identification information that can identify the user terminal 2 that is the order source. The transfer at (8 ′) may be directly credited to the spatial data provider server 3a, or it may be credited to the intermediary device 1, and the spatial data from the intermediary device 1 as settlement information at (10 ′). It may be transmitted to the provider server 3a.

  (12 ') The spatial data provider server 3 or the spatial information providing server 4 transmits the spatial data or spatial information specified from the specific information included in the order information to the user terminal 2 identified from the terminal identification information. In other words, the user terminal 2 identified from the terminal identification information is permitted to download spatial data or spatial information identified from the specific information. When the spatial information providing server 4 transmits the spatial information to the user terminal 2, the relay processing unit 58 of the data relay unit 17 receives the spatial information from the spatial information providing server 4 via the external communication device 69 and performs external communication. It transmits to the user terminal 2 through the device 69. Note that information specifying the destination user terminal 2 may be received from the spatial information providing server 4 together with the spatial information. When the spatial information stored in advance in the spatial information database 19 is transmitted to the user terminal 2, the spatial information output unit 56 receives information identifying the spatial information and the user terminal 2 from the spatial information providing server 4. Then, based on the received information, the spatial information is acquired from the spatial information database 19, and the spatial information transmission unit 57 transmits it to the user terminal 2.

  (13 ') The spatial data provider server 3a transfers the brokerage fee and the advertisement fee to the brokerage device 1.

  As described above, in the spatial data mediation system according to this embodiment, the mediation device 1 mediates the delivery of spatial data or spatial information between the user terminal 2 and the spatial data provider server 3 or the spatial information providing server 4. Thus, the user terminal 2 is provided with a data search environment in a unified format. Therefore, the user terminal 2 can easily acquire desired spatial data or spatial information.

  Further, in the spatial data mediation system according to this embodiment, the mediation device 1 does not hold the spatial data to be provided to the user terminal 2 but holds only the metadata used for searching the spatial data. Therefore, the storage capacity of the storage device of the mediation device 1 can be reduced, and there is no risk of leakage of spatial data or spatial information from the mediation device 1.

Embodiment 2. FIG.
In the first embodiment, the mediation device 1 mediates between the user terminal 2 and the spatial data provider server 3 or the spatial information providing server 4 to provide the user terminal 2 with a data search environment in a unified format. I explained that. In this embodiment, a search condition input screen and a search result display screen provided by the mediation device 1 to the user terminal 2 when searching for spatial data or spatial information will be described.
Here, the search condition input screen corresponds to information transmitted to the user terminal 2 by the search screen display unit 43 in (3 ′) (4 ′) of the first embodiment. The search result display screen corresponds to the information transmitted to the user terminal 2 by the search result display unit 51 in (6 ′) of the first embodiment.

FIG. 7 is a diagram illustrating an example of a parent screen (top page) of a search condition input screen provided by the mediation device 1 to the user terminal 2. Further, FIGS. 8 to 11 are diagrams showing examples of the sub-screens of the search condition input screen that are transitioned from the parent screen shown in FIG.
First, the parent screen shown in FIG. 7 will be described.
The parent screen is a search column for free keywords, a search column that transitions to each sub-screen that searches for spatial data and spatial information (displayed as “Examine”), a report on satellite operation information and spatial data and spatial information by other users. Information exchange column that can be obtained (displayed as “information exchange”), purchase column used when purchasing spatial data and spatial information (displayed as “buy”), and sites that provide spatial data and spatial information are introduced. An introduction column (displayed as “sell”) is provided. In addition, the main screen includes a new report column for displaying new data, a latest news column for displaying the latest news on spatial data and spatial information, an image display column for displaying recently released images (spatial data and spatial information), and the like. Prepare.
That is, on the parent screen, a display field is divided for each process performed by the user so that the user can perform a desired process.

Next, each sub-screen will be described with reference to FIGS. FIG. 8 is a diagram showing an example of a sub-screen used when searching from a simple catalog. FIG. 9 is a diagram illustrating an example of a sub-screen used when searching from a spatial data providing provider. FIG. 10 is a diagram illustrating an example of a sub-screen used when searching from a sensor that has acquired spatial data. FIG. 11 is a diagram illustrating an example of a sub-screen used when performing a detailed search.
The sub-screen used when searching from the simple catalog shown in FIG. 8 can specify only conditions that are considered to be used mainly for searching. In FIG. 8, as an example, an area can be designated by displaying a map and selecting a position on the map. In addition, either the earth observation satellite or the aircraft can be specified as the sensor platform. In addition, with respect to sensors, spatial data providing providers, areas (positions), and acquisition dates of spatial data, only generally specified ones can be specified as search conditions.
In the sub-screen used when searching from the spatial data providing provider shown in FIG. 9, the spatial data providing provider registered in the intermediary device 1 can be specified as a search condition.
In the sub-screen used when searching from the sensor that acquired the spatial data shown in FIG. 10, the sensor registered in the mediation device 1 can be specified as a search condition.
In the sub-screen used when the detailed search shown in FIG. 11 is performed, the search can be performed by designating arbitrary information for all items registered as catalog information. Although not shown, when each link shown in FIG. 11 is transitioned, the screen transitions to a screen where search conditions can be made.

FIG. 12 is a diagram illustrating an example of a search result display screen.
The search result display screen shown in FIG. 12 includes an all search result display unit 91 that indicates a result of search based on all input search conditions, and a position search result display that indicates a result of search based only on the position condition indicating the position. Part 92.
The all search result display unit 91 displays thumbnail images of spatial data and spatial information corresponding to all input search conditions, and other metadata. That is, the entire search result display unit 91 displays information included in the metadata searched by the search condition search unit 46.
The position search result display unit 92 displays a thumbnail image of spatial data and spatial information excluding the spatial data and spatial information that satisfy only the positional conditions and excluding the spatial data and spatial information corresponding to all the search conditions. . That is, the position search result display unit 92 displays information included in the metadata searched by the position condition search unit 47. In addition, the position search result display unit 92 displays metadata other than the thumbnail image by pressing a “detail” button (link) shown in the vicinity of the thumbnail image.
That is, on the search result screen, not only the spatial data and the spatial information satisfying the input search condition are displayed, but also the spatial data and the spatial information satisfying only the position condition included in the input search condition are displayed.
Here, the position search result display unit 92 displays spatial data and spatial information that satisfy only the position condition included in the input search condition, but also satisfies a predetermined condition other than the position condition together with the position condition. Spatial data and spatial information may be displayed.

As described above, the intermediary device 1 according to this embodiment enables various search conditions to be input on the search condition input screen so that the user can easily search for desired spatial data and spatial information.
In addition, the search result screen displays not only the spatial data and the spatial information that satisfy the input search condition but also the spatial data and the spatial information that satisfy only the position condition included in the input search condition. In general, when searching for spatial data, the position to be acquired is generally determined, but for example, a provider of spatial data, sensors, and the like are often uncertain. Therefore, even when a spatial data provider or sensor is specified as a search condition, it is possible to improve user convenience by displaying spatial data and spatial information that satisfy only the position condition. .
Moreover, according to the mediation apparatus 1 according to this embodiment, when the user searches for spatial data, the spatial information including the searched position is also displayed. Therefore, a user who searches for spatial data can discover spatial information with added value to the spatial data.

Embodiment 3 FIG.
In this embodiment, a method for arranging the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format so that a search can be performed in a unified manner from the spatial data of each spatial data provider server 3. explain.
That is, in this embodiment, the process executed in (1 ′) of the first embodiment will be described.

First, the configuration of spatial data and spatial information metadata will be described with reference to FIGS. 13 and 14. FIG. 13 is a diagram illustrating an example of metadata of a general satellite image. FIG. 14 is a diagram illustrating an example of metadata configured using XML. Note that the metadata shown in FIGS. 13 and 14 shows only a part of general metadata.
The metadata shown in FIG. 13 includes data name, data size, manufacturing date, sensor name, observation position, west limit point coordinate, north limit point coordinate, east limit point coordinate, south limit point coordinate, observation date, browse (thumbnail image). ) Etc. On the other hand, the metadata shown in FIG. 14 includes a data creation date, a data type, a sensor platform name, a thumbnail image, coordinates, a provider name, and the like. That is, information such as sensor platform name, data type, observation position, observation date and time, thumbnail image is included in any metadata. However, the item name (tag name in the case of XML) indicating each information and the order in which each information is described are different. Note that only a part of the metadata is shown here for simplicity, and each item can be easily found because it is given an easily recognizable item name. Since a lot of information is included, and the item names are abbreviated names such as alphabets, each information cannot be easily found.
Therefore, when catalog information is received from each spatial data provider server 3 and a search is performed based on the catalog information of each spatial data provider server 3 in the processing flow as shown in FIG. It is very time-consuming to find items to be used for searching from catalog information. In particular, if there are a plurality of spatial data provider servers 3 on which a search is performed, the time and effort is required for the number of spatial data provider servers 3.
Therefore, it is necessary to arrange the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format so that the search can be performed from the spatial data of each spatial data provider server 3 by a unified method.

Next, a process (metadata conversion process) for arranging the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format will be described. FIG. 15 is a flowchart showing the flow of metadata conversion processing.
First, the character string database 35 and the correspondence information database 36 used in the metadata conversion process shown will be described.
The character string database 35 is a storage device (for example, an external storage device 66) that stores a predetermined character string for each spatial data metadata format. Each metadata format includes a character string that can specify the metadata format. The character string database 35 stores a character string that can specify the metadata format for each metadata format. For example, in the case of the metadata shown in FIG. 13, fixed information (for example, a character string “AAA sensor”) is entered in the sensor name, and the sensor name (character string “AAA sensor”) is included in the metadata. If included, the metadata can be determined to be in the format shown in FIG. That is, in the case of the metadata shown in FIG. 13, the sensor name is a character string that can specify the metadata format. Further, if the character string “XX Inc.” is included in the metadata, it can be determined that the metadata is in the format shown in FIG. In other words, the character string database 35 stores, for each format of spatial data metadata, a character string included in a certain type of metadata but not included in another type of metadata.
The correspondence information database 36 is a storage device (for example, an external storage device 66) that stores correspondence information indicating a correspondence relationship between metadata items and database items for each metadata format. That is, the correspondence between the satellite image metadata items shown in FIG. 13 and the metadata database 18 items (corresponding to the arrows in FIG. 13), XML format metadata tags shown in FIG. 14, and the metadata database. The correspondence with 18 items (information corresponding to the arrow in FIG. 14) is stored.

Next, the metadata conversion process shown in FIG. 15 will be described.
It is assumed that the character string database 35 and the correspondence information database 36 store the information described above before the start of the process shown in FIG.
(S1): When the metadata input unit 31 inputs metadata, the format determination unit 32 of the metadata storage unit 10 stores the character string database 35 from the character strings included in the metadata input by the metadata input unit 31. The central processing unit 61 retrieves the character string that has been processed. Then, the format determination unit 32 determines the format of the metadata by the central processing unit 61 based on the character string included in the metadata. That is, for example, if the character string “AAA sensor” is included in the metadata, the format determination unit 32 determines that the metadata is in the format shown in FIG.
(S2): Next, the format conversion unit 33 converts the metadata format to the central processing unit based on the correspondence information for converting the metadata format determined by the format determination unit 32 into the format of the metadata database 18. 61 is converted. That is, for example, when the format determination unit 32 determines that the metadata is in the format illustrated in FIG. 13, the format conversion unit 33 acquires the corresponding correspondence information (information on the arrow illustrated in FIG. 13), In accordance with the correspondence information, the order of metadata items is changed, and the data type and the like are changed to the data type of the corresponding item in the metadata database 18.
(S3): The metadata registration unit 34 stores the metadata converted by the format conversion unit 33 in the metadata database 18.
As a result, the metadata of the spatial data acquired from any spatial data provider server 3 can be stored in the metadata database 18 in the format shown in FIG.

  As described above, the intermediary device 1 according to this embodiment arranges the metadata of the spatial data acquired from each spatial data provider server 3 into a predetermined format and is unified from the spatial data of each spatial data provider server 3. Make search possible. Thereby, the user does not need to create a search condition for each spatial data provider server 3 and perform a search, and can perform a search efficiently.

According to the spatial data mediation system according to the above-described embodiment, a user who wants to purchase spatial data can search for a spatial data providing provider, and can also use a plurality of products provided by each spatial data providing provider. You can search and order.
As a result, a mechanism for distributing spatial data is provided, and distribution can be promoted. For example, as users, construction / civil engineering / surveying companies, power / gas / water supply companies, transportation / distribution companies, broadcasting / media companies, cartography / sales companies, tourism companies, insurance companies, GIS (geographic information system) content production A company can be considered. In addition, various forecasting services in the meteorological field, information-added value services, reconnaissance in the security field, land classification / thematic map 4D map, mobile monitoring, fishing ground exploration in the fisheries / fishery field, sea condition information service, red tide Prediction, damage situation assessment in the field of disaster / land management, recovery / reconstruction planning, farming / forestry field, crop condition prediction, farmland / forest management, overseas plantation management, spatial information utilization field, mapping, various GIS, resources / energy field Resource exploration, navigation safety monitoring, water resources management in the environment field, global warming monitoring / prediction, illegal dumping monitoring, digitized teaching materials in the education field, game software in the entertainment field, advertisements, various navigation systems, reports in the broadcast media field, etc. Possible use. In other words, in these users and fields, spatial data can be used more actively and the industry can be developed.

  In the above description, the storage device 62 or the external storage device 66 stores a program for executing the functions described as “˜units” and other programs. The program is read and executed by the central processing unit.

  In addition, what is described as “to part” in the above description may be “to circuit”, “to device”, “to device”, “to means”, and “to function”. ”,“ ˜procedure ”, or“ ˜processing ”. In addition, what is described as “˜device” may be “˜circuit”, “˜device”, “˜equipment”, “˜means”, “˜function”, and “˜step”, “ ~ Procedure "," ~ process ". Furthermore, what is described as “to process” may be “to step”. That is, what is described as “˜unit” may be realized by firmware stored in the ROM. Alternatively, it may be implemented only by software, only hardware such as elements, devices, substrates, wirings, etc., or a combination of software and hardware, and further a combination of firmware. Firmware and software are stored as programs in the storage device 62, the external storage device 66, and the like. The program is read by the central processing unit and executed by the central processing unit. That is, the program causes a computer or the like to function as the “˜unit” described above. Alternatively, the computer or the like is caused to execute the procedures and methods of “to part” described above.

  That is, “mediation device 1” can be read as “mediation program” or “mediation method” of mediation device 1. Then, what has been described as the “˜part” included in the “mediation device 1” may be read as “˜processing” if it is a “mediation program” and “˜step” if it is a “mediation method”. Is possible. That is, in the above description, the mediating apparatus 1 has been described. However, the above description is not limited to “apparatus”, but may be related to “program” and “method”.

  Metadata is defined as “data relating to data elements including data description, and data relating to data owner, access route, access right, and degree of change of data” in “Information Processing Term (Database)” in JIS. Has been. The metadata is data describing the location, content, quality, usage conditions, and the like of spatial data (geographic information) in the field of geographic information systems (GIS). Geographic information users can examine this metadata to determine if the geographic information is available.

The figure which shows the flow of the spatial data acquisition process in the case of not via the mediation apparatus 1. The figure which shows the flow of the spatial data acquisition process in the case of passing through the mediation apparatus 1. The figure which shows an example of metadata. The whole figure of a spatial data mediation system. The functional block diagram of the mediation apparatus 1. FIG. The figure which shows an example of the hardware constitutions of the mediation apparatus. The figure which shows an example of the main screen (top page) of a search condition input screen. The figure which shows an example of the subscreen used when searching from a simple catalog. The figure which shows an example of the subscreen used when searching from a spatial data provision provider. The figure which shows an example of the subscreen used when searching from the sensor which acquired spatial data. The figure which shows an example of the subscreen used when performing a detailed search. The figure which shows an example of a search result display screen. The figure which shows an example of the metadata of a general satellite image. The figure which shows an example of the metadata comprised using XML. The flowchart which shows the flow of a metadata conversion process.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Mediation apparatus, 2 User terminal, 3 Spatial data provider server, 4 Spatial information provision server, 10 Metadata storage part, 11 Spatial information storage part, 12 Provider management part, 13 User management part, 14 Search part, 15 Search result output , 16 Order reception part, 17 Data relay part, 18 Metadata database, 19 Spatial information database, 31 Metadata input part, 32 Format determination part, 33 Format conversion part, 34 Metadata registration part, 35 Character string database, 36 Corresponding information database, 37 Spatial information input unit, 38 Spatial information registration unit, 39 Provider registration information input unit, 40 Provider management database, 41 User registration information input unit, 42 User management database, 43 Search screen display unit, 44 Receive search information Part, 45 Search condition interpretation part, 46 Search condition search unit, 47 Position condition search unit, 48 Search result output unit, 49 Price calculation unit, 50 Unit price file, 51 Search result display unit, 52 Order information reception unit, 53 Total price calculation unit, 54 Order content payment method confirmation Display unit, 55 Order information transmission unit, 56 Spatial information output unit, 57 Spatial information transmission unit, 58 Relay processing unit, 60 Application server, 61 Central processing unit, 62 Storage device, 63 Display device, 64 Input device, 65 Storage medium Read / write device, 66 External storage device, 67 Printing device, 68 Storage medium, 69 External communication device, 70 User authentication server, 71 Bus, 81 Directory data portion, 82 Inventory data portion, 83 Image portion, 84 Provider name, 85 Sensor platform name, 86 Data type, 87 Observation date and time, 88 Observation range 89 thumbnail images 91 all search results display unit, 92 position the search result display section.

Claims (5)

A spatial data conversion device that converts metadata of spatial data into a predetermined format and registers it in a database.
A character string storage unit that stores a predetermined character string in the storage device for each metadata format of the spatial data;
A metadata input unit for inputting spatial data metadata via an input device;
The processing device searches for a predetermined character string stored in the character string storage unit from the character string included in the metadata input by the metadata input unit, and the format of the metadata by the character string included in the metadata A format determination unit for determining
A correspondence information storage unit that stores correspondence information indicating a correspondence relationship between metadata items and database items in a storage device for each metadata format of the spatial data;
A format conversion unit that acquires correspondence information of the format determined by the format determination unit from the correspondence information storage unit, and converts the metadata into a predetermined format by a processing device based on the acquired correspondence information;
A spatial data conversion apparatus comprising: a metadata registration unit that registers the metadata converted by the format conversion unit into the predetermined format in a database. The character string storage unit stores a character string included in a certain type of metadata and not included in another type of metadata for each spatial data metadata format. The spatial data conversion apparatus according to claim 1, wherein A spatial data conversion program that converts the metadata of spatial data into a predetermined format and registers it in a database.
Metadata input processing to input spatial data metadata;
A predetermined character string stored in a storage device in advance for each metadata format of the spatial data is searched from the metadata input in the metadata input process, and the metadata format is determined by the character string included in the metadata. A format determination process for determining
Acquire the correspondence information of the format determined in the format determination process from a storage device that stores the correspondence information indicating the correspondence between the metadata item and the database item for each metadata format of the spatial data. Format conversion processing for converting the metadata into a predetermined format based on the corresponding information,
A spatial data conversion program for causing a computer to execute a metadata registration process for registering in a database the metadata converted into the predetermined format by the format conversion process. In the format determination processing, for each metadata format of spatial data, a storage device that stores in advance a character string that is included in metadata in a certain format and that is not included in metadata in other formats The spatial data conversion program according to claim 3, wherein each character string is acquired from the metadata, and the acquired character string is searched from the metadata. It is a spatial data conversion method for converting the metadata of spatial data into a predetermined format and registering it in a database.
A metadata input step in which the input device inputs spatial data metadata;
The processing device searches for a predetermined character string stored in the storage device in advance for each metadata format of the spatial data from the metadata input in the metadata input step, and the character string included in the metadata A format determination step for determining the format of the metadata;
The processing device obtains the correspondence information of the format determined in the format determination step from the storage device that stores in advance the correspondence information indicating the correspondence relationship between the metadata item and the database item for each metadata format of the spatial data. A format conversion step of converting the metadata into a predetermined format based on the acquired correspondence information;
A spatial data conversion method, comprising: a metadata registration step in which the processing device registers the metadata converted into the predetermined format in the format conversion step in a database.

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