WO2023157688A1 - Information processing device, information processing method, program, and manufacturing method - Google Patents

Abstract

The present technology relates to an information processing device, an information processing method, a program, and a manufacturing method which can make it possible to provide a seed mat from which seeds germinate at desired timings. According to a first correspondence between mat specifications of the seed mat and a required period that is required for seeds of a plant species embedded in the seed mat of the mat specifications, a target plant for seeds to be embedded in the seed mat, and a germination time at which the seeds of the target plant are made to germinate, design information is generated, the design information indicating the configuration of the seed mat in which the seeds of a target plant are embedded. The present technology can be applied to, for example, an assistance system which assists in the construction of an extended ecosystem.

Description

Information processing device, information processing method, program, and manufacturing method

The present technology relates to an information processing device, an information processing method, a program, and a manufacturing method, and in particular, for example, an information processing device and an information processing method capable of providing a seed mat in which seeds germinate at a desired timing. , a program, and a manufacturing method.

For example, in Patent Document 1, in order to restore the vegetation around the construction site in the future while increasing the green coverage rate in the early stage of construction, soil seeds collected from the vicinity of the construction site and plants surrounding the construction site using the soil seeds A greening structure has been proposed which includes seeds of plant propagules capable of early greening.

A plant propagule is a plant that is viable immediately after construction, and becomes non-viable for at least one month in the climate of the construction site after the viable period has passed.

JP 2010-259386 A

In recent years, there has been a demand for the formation of a greening base on which an extended ecosystem, such as that constructed by synecoculture (registered trademark), will be constructed.

As a method of forming a greening base, for example, there is a method of sticking (installing) a seed mat on any surface such as the ground surface where you want to form a greening base.

In synecoculture (registered trademark), plant species with different environments required for germination are planted in a mixed and dense state. embedding method is selected.

In addition, in Synecoculture (registered trademark), in order to maintain rich vegetation while harvesting for a long period of time, there are times when multiple timings are set for sowing (embedding) seeds even for seeds of the same plant species.

Therefore, seed mats used for forming a greening base on which an extended ecosystem is constructed in the same manner as in synecoculture (registered trademark) allow seeds to germinate at the desired timing for each plant species or individual plant. Must be a seed mat.

This technology has been developed in view of such circumstances, and enables the provision of a seed mat in which seeds germinate at desired timing.

An information processing device or program according to the present technology includes a first correspondence relationship between a mat specification of a seed mat and a required period required for germination of a seed of a plant species embedded in the seed mat having the mat specification, and Design for generating design information representing the configuration of the seed mat in which the seeds of the target plant are embedded according to the target plant whose seeds are to be embedded in the seed mat and the germination time for germinating the seeds of the target plant. It is an information processing device including a unit, or a program for causing a computer to function as such an information processing device.

The information processing method of the present technology includes a first correspondence relationship between the mat specification of the seed mat and the required period required for germination of seeds of the plant species embedded in the seed mat with the mat specification, and seeds in the seed mat. and generating design information representing the configuration of the seed mat in which the seeds of the target plant are embedded according to the target plant to be embedded and the germination time for the seeds of the target plant to germinate. The method.

In the information processing device, the information processing method, and the program of the present technology, the mat specification of the seed mat and the necessary period required for germination of the seed of the plant species embedded in the seed mat of the mat specification. A design representing the configuration of the seed mat in which the seeds of the target plant are embedded according to the corresponding relationship, the target plant whose seeds are to be embedded in the seed mat, and the germination time for germinating the seeds of the target plant. Information is generated.

The production method of the present technology includes a first correspondence relationship between mat specifications of a seed mat, a necessary period required for germination of seeds of plant species embedded in the seed mat with the mat specifications, and seeds in the seed mat. The seed mat is generated according to design information representing the configuration of the seed mat in which the seeds of the target plant are embedded, which is generated according to a target plant to be embedded and a germination time for germinating the seeds of the target plant. It is a manufacturing method to manufacture.

In the production method of the present technology, a first correspondence relationship between the mat specification of the seed mat and the period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate; The seed mat according to the design information representing the configuration of the seed mat in which the seeds of the target plant are embedded, which is generated according to the target plant to be embedded and the germination time for germinating the seeds of the target plant is manufactured.

It should be noted that the information processing device may be an independent device, or may be an internal block that constitutes one device.

The program can be provided by recording it on a recording medium or transmitting it via a transmission medium.

1 is a diagram illustrating a configuration example of an embodiment of an information processing system to which the present technology is applied; FIG. 2 is a diagram showing an example hardware configuration of a terminal 11; FIG. 2 is a block diagram showing a functional configuration example of a terminal 11; FIG. 3 is a diagram showing an example hardware configuration of a server 12; FIG. 3 is a block diagram showing a functional configuration example of a server 12; FIG. 1 is a perspective view showing an outline of a seed mat manufactured according to design information; FIG. 4 is a diagram illustrating an example of support for construction of an extended ecosystem performed by the information processing system 10; FIG. FIG. 3 is a diagram showing an example of an embedding area for embedding seeds of a target plant that can be set in a seed mat. It is a figure which shows the example of the setting of a target plant and germination time by a user. FIG. 10 is a diagram showing an example of plant information when target plants and germination times are set for each embedding area. 4 is a diagram showing a first example of a required period database that database 51 has; FIG. 4 is a flowchart illustrating a first example of processing of the terminal 11; 4 is a flowchart illustrating a first example of processing of the server 12; FIG. 3 is a diagram showing a first display example of design information of a seed mat; FIG. 4 is a perspective view showing an example of a seed mat manufactured according to design information; FIG. 4 is a diagram showing how a greening base is formed using a seed mat manufactured according to design information; FIG. 10 is a diagram showing a second example of a required period database that the database 51 has; 5 is a diagram showing an example of a specification database held by a database 51; FIG. FIG. 11 is a flowchart illustrating a second example of processing of the server 12; FIG. FIG. 11 is a diagram showing a third example of a required period database held by the database 51; 10 is a flowchart illustrating a second example of processing of the terminal 11; FIG. 11 is a flowchart illustrating a third example of processing of the server 12; FIG. 10 is a flowchart illustrating a third example of processing of the terminal 11; FIG. 13 is a flowchart illustrating a fourth example of processing of the server 12; FIG. FIG. 10 is a diagram showing a second display example of design information of a seed mat; FIG. 4 is a diagram showing an example of a 3D model image as design information that displays the internal environment of the seed mat. FIG. 5 is a diagram showing a first display example of related information; It is a figure explaining a generation area. FIG. 11 is a diagram showing a second display example of related information; 3 is a diagram showing a display example of an initial screen window 110 displayed immediately after an overhead display application is activated on the terminal 11. FIG. 3 is a diagram showing a display example of a design information input screen displayed when a button 111 is operated on the terminal 11. FIG. 3 is a diagram showing a display example of a selection window 120 displayed when a button 112 is operated on the terminal 11; FIG. FIG. 11 is a diagram showing a display example in which related information of all of a plurality of completed mat maps is displayed in a form of comparison; FIG. 4 is a diagram showing a configuration example of a manufacturing apparatus that manufactures a seed mat according to design information of the seed mat; 1 is a diagram showing an overview of a generating device 202 configured with a 3D printer; FIG.

<An embodiment of an information processing system to which this technology is applied>

FIG. 1 is a diagram showing a configuration example of an embodiment of an information processing system to which the present technology is applied.

The information processing system 10, for example, provides design information for a seed mat that can be formed simply by placing a greening base on which an extended ecosystem is constructed, such as in synecoculture (registered trademark), on the ground surface or the like. By providing it, it constitutes a support system that supports the construction of an extended ecosystem.

The seed mat for which the information processing system 10 provides design information is a seed mat on which a greening base on which an extended ecosystem is constructed is formed. Therefore, in the seed mat, seeds germinate at desired timing for each plant species or each individual plant, as in Synecoculture (registered trademark). In this way, in order to germinate seeds at a desired timing for each plant species or each individual plant, the seed mat has a structure (mechanism) for controlling the timing of germination for each plant species or each individual plant. ), inside which a suitable environment is formed for seeds to germinate for each plant species.

A seed mat is also called a vegetation mat or a vegetation sheet, and is a mat-shaped or sheet-shaped material in which seeds are embedded (including attachment).

The information processing system 10 has one or more terminals 11 and one or more servers 12 . The terminal 11 and the server 12 can communicate with each other via a network 13 including a wired LAN (local area network), a wireless LAN, the Internet, a mobile communication network such as 5G, and the like.

When a plurality of servers 12 are provided in the information processing system 10, the plurality of servers 12 can be made to perform the processing described below in a distributed manner. Also, a plurality of servers 12 can be assigned terminals 11 in charge, and each server 12 can be made to perform processing only for the terminal 11 in charge.

Furthermore, in the information processing system 10, the terminal 11 can be caused to perform part or all of the processing performed by the server 12. The information processing system 10 can be configured without the server 12 when the terminal 11 performs all the processing performed by the server 12 .

The terminal 11 is configured by, for example, a PC (personal computer), a mobile terminal such as a smartphone, etc., and is operated by the user. The terminal 11 transmits and receives necessary information from the server 12 (via the network 13).

The server 12 receives information from the terminal 11 (via the network 13), and uses the information from the terminal 11 to perform various processes as necessary. The server 12 also transmits necessary information to the terminal 11 (via the network 13).

<Configuration example of terminal 11>

FIG. 2 is a diagram showing a hardware configuration example of the terminal 11. As shown in FIG.

The terminal 11 has a positioning unit 21, an input/output unit 22, a storage drive 23, a sensor unit 24, a calculation unit 25, and a communication unit 26. The positioning unit 21 through the communication unit 26 are connected to each other via a bus so that information can be exchanged.

The positioning unit 21, for example, constitutes a GNSS (global navigation satellite system), measures (positions) the position of the terminal 11, and outputs position information representing the position, such as latitude and longitude (and required altitude). do.

The input/output unit 22 has a keyboard (not shown), a touch panel, a microphone, etc., and receives operations and other various inputs from the user. The input/output unit 22 also has a display unit 22A and a speaker (not shown), and presents information to the user by displaying images, outputting sounds, and the like.

The storage drive 23 is composed of, for example, an SSD (solid state drive) or HDD (hard disk drive). The storage drive 23 stores (records) programs to be executed by the calculation unit 25, data required for processing by the calculation unit 25, and the like.

The sensor unit 24 includes a camera that captures an image by sensing light, a hygrometer that senses humidity, a thermometer that senses temperature, an angular velocity sensor (gyro sensor) that detects angular velocity, and a distance sensor that measures distance. , and other necessary sensors. The sensor unit 24 senses various physical quantities and outputs sensor information, such as an image, which is the sensing result.

The arithmetic unit 25 has a processor such as a CPU (central processing unit) and DSP (digital signal processor), and a memory such as RAM (random access memory), and executes a program stored in the storage drive 23. and perform various processing.

The program executed by the computing unit 25 can be installed in the computer as the terminal 11 from a removable recording medium such as a DVD (digital versatile disc) or memory card, for example. Also, the program can be downloaded and installed in the computer as the terminal 11 via the network 13 or the like, for example.

The communication unit 26 functions as a transmission unit that transmits information and a reception unit that receives information via the network 13 or the like.

Note that the terminal 11 can be configured without providing one or both of the positioning unit 21 and the sensor unit 24 .

FIG. 3 is a block diagram showing a functional configuration example of the terminal 11. As shown in FIG.

The functional configuration of the terminal 11 in FIG. 3 is functionally realized by executing the program by the computing unit 25 in FIG.

In FIG. 3, the terminal 11 has a user I/F (interface) 31, a transmitter 32, a receiver 33, and a display controller .

The user I/F 31 accepts an operation of the terminal 11 by the user, and in response to the operation, sends a command requesting processing to the server 12, plant information, and other information used for the processing of the server 12 to the transmission unit 32. supply.

The plant information is information about the target plant whose seeds are to be embedded in the seed mat, and includes at least information about the target plant and the germination time for the seed of the target plant to germinate.

By operating the user I/F 31, the user can set the plant whose seeds are to be embedded in the seed mat as the target plant.

If the user wants to produce a seed mat in which plants grow densely (mixed dense seed mat), the user can set multiple plant species as target plants. Furthermore, the user can set a plurality of plant individuals of the same plant species as target plants.

The germination period is the period from when the seed mat is completed until the seeds germinate. In this embodiment, the seed mat is installed immediately after completion, and therefore the timing of completion of the seed mat and the timing of installation can be regarded as the same. When the seed mat is placed after completion, the period from placement of the seed mat to germination is shorter (earlier) than the germination time by the period from completion of the seed mat to placement.

As for the germination time, it is possible to set different germination times not only for different plant species, but also for the same plant species, for some plant individuals and for some other plant individuals.

By setting the germination time for each plant species or individual plant, it is possible to control the timing of germination for each plant species or individual plant.

The user I/F 31 receives user operations and displays images according to the display control of the display control unit 34 . The user I/F 31 can present information to the user by displaying images, outputting sounds, and the like. By presenting information through the user I/F 31, the user can confirm, for example, the operation of a program executed by the calculation unit 25, various information, and the like.

The transmission unit 32 transmits various types of information to the server 12 and the like. For example, the transmission unit 32 transmits plant information and the like from the user I/F 31 to the server 12 .

The receiving unit 33 receives various information from the server 12 and the like. For example, the receiving unit 33 receives design information and the like transmitted from the server 12 and supplies the information to the display control unit 34 .

The design information is information that represents the overall configuration of the seed mat in which the seeds of the target plant are embedded. The design information includes information such as the thickness of the seed mat, the material of each part (area), and the method of embedding the seeds of the target plant (the position on the seed mat where the seeds are to be embedded, the depth of embedding, the density of the seeds to be embedded, etc.). can contain.

　The embedding of seeds in the seed mat includes attaching the seeds to (the surface of the material of) the seed mat. In the present embodiment, the seeds embedded in the seed mat constitute a part of the seed mat (handled as constituent elements of the seed mat).

As the design information, it is possible to adopt a list such as a tabular format representing the configuration of the seed mat, an image of the design drawing (plan view, etc.), an image of the 3D model, etc.

The display control unit 34 performs display control for displaying information on the user I/F 31 . For example, the display control unit 34 causes the user I/F 31 to display design information and the like from the receiving unit 33 .

<Configuration example of server 12>

FIG. 4 is a diagram showing a hardware configuration example of the server 12. As shown in FIG.

The server 12 has an input/output unit 41, a storage drive 42, a communication unit 43, and a computing unit 44. The input/output unit 41 through the arithmetic unit 44 are connected to each other via a bus so that information can be exchanged.

The input/output unit 41 has a keyboard (not shown), a touch panel, a microphone, and the like, and receives operations and other various inputs from the operator of the server 12 and the like. Further, the input/output unit 22 has a display unit (display) and a speaker (not shown), and presents information to an operator or the like by displaying an image, outputting a sound, or the like.

The storage drive 42 is composed of, for example, an SSD, HDD, or the like. The storage drive 42 stores (records) programs to be executed by the calculation unit 44, data required for processing by the calculation unit 44, and the like.

The communication unit 43 functions as a transmission unit that transmits information and a reception unit that receives information via the network 13.

The computing unit 44 has a CPU, a processor such as a DSP, and a memory such as a RAM, and executes programs stored in the storage drive 42 to perform various detections, calculations, evaluations, key events, and the like. Various processes such as processing of various events are performed.

The program executed by the computing unit 44 can be installed in the computer as the server 12 from a removable recording medium such as a DVD or memory card, for example. Also, the program can be downloaded and installed in a computer as the server 12 via the network 13 or the like, for example.

FIG. 5 is a block diagram showing a functional configuration example of the server 12. As shown in FIG.

The functional configuration of the server 12 in FIG. 5 is functionally realized by executing the program by the computing unit 44 in FIG.

In FIG. 5, the server 12 has a database 51 and a design section 52.

It should be noted that the processing performed by the server 12 in FIG. 5 can be divided and performed by a plurality of servers.

That is, when the server 12 is composed of a plurality of servers, the functions of the database 51, the design section 52, or both the database 51 and the design section 52 can be divided into a plurality of servers.

Also, part or all of the processing performed by the server 12 in FIG. 5 can be performed by the terminal 11.

The database 51 has various databases.

For example, the database 51 has a required period database.

Furthermore, the database 51 can have a specification database, a living organism database, a co-occurrence relation database, and the like.

The required period database stores various correspondences with the required period required for seeds of each plant species to germinate.

The specification database stores the correspondence between the specifications of the seed mat and the internal environment (internal environment) of the seed mat formed by the specifications.

The specifications of the seed mat include the material of the seed mat and how the seeds are embedded in the seed mat (depth and density of seed embedding, etc.).

The growing organism database stores information on organisms that grow (inhabit and settle) in the internal environment of the seed mat formed by the specifications for each seed mat.

The co-occurrence relationship database stores information on organism species that have co-occurrence relationships with each plant species.

An external database, such as a database on the Internet, can be used as part or all of the database that the database 51 has.

The design unit 52 receives the plant information transmitted from the terminal 11.

The design unit 52 generates design information for a seed mat in which the seeds of the target plant included in the plant information are embedded, according to the plant information from the terminal 11 and the information stored in the database 51.

For example, the required period database of the database 51 stores the correspondence relationship (first correspondence relationship) between the specification of the seed mat and the required period required for germination of the seed of the plant species embedded in the seed mat of the specification. If yes, the design unit 52 selects the seed mat according to the correspondence stored in the required period database, the target plant included in the plant information from the terminal 11, and the information on the germination time of the seed of the target plant. Generate design information for

The design information generated by the design unit 52 represents the configuration of the seed mat (whole) in which the seeds of each target plant included in the plant information are embedded so as to germinate at the germination time included in the plant information.

The design unit 52 transmits the design information to the terminal 11.

<Outline of the seed mat manufactured according to the design information>

Fig. 6 is a perspective view showing an outline of a seed mat manufactured according to design information.

A seed mat is a structure composed of any material in which seeds of one or more plant species are embedded.

In FIG. 6, three plant species p1, p2, and p3 (a plurality of individual plants thereof) are used as target plants, and seeds of the three target plants p1, p2, and p3 are embedded in the seed mat.

The seed mat can be made of the same material as a whole, or can be made of different materials for each part (area).

In FIG. 6, the seed mat has a flat plate shape, the front right corner is made of material m2, and the rest is made of material m1.

The seed mat can be composed of two types of materials m1 and m2, one type, or an arbitrary number of three or more types of materials with different properties.

The properties of materials are, for example, water retention (drainage), heat retention, and breathability.

For example, each of the three types of materials m1, m2, and m3 with different water retention or drainage properties includes vermiculite, perlite, and a material in which vermiculite and perlite are blended at a volume ratio of 1:1.

Vermiculite has higher water retention than perlite, and perlite has higher drainage than vermiculite. Therefore, the water retentivity is material m1>material m2>material m3, but the drainage property is material m1<material m2<material m3.

In the seed mat, seeds can be embedded in different embedding states (embedding depth, density of embedded seeds, etc.) regardless of whether they are parts of different materials or parts of the same material.

Furthermore, in seed mats, seeds of different plant species or the same plant species can be embedded in different embedding states.

In FIG. 6, the seeds of the plant species p1 are deeply embedded (viewed from above) in the material m1 of the seed mat, and the density varies depending on the location.

The seeds of the plant species p2 are buried shallowly and sparsely in the material m1 of the seed mat.

The seeds of the plant species p3 are shallowly and relatively densely embedded in the material m2 of the seed mat.

<Example of support for building an extended ecosystem by the information processing system 10>

FIG. 7 is a diagram illustrating an example of support for building an extended ecosystem performed by the information processing system 10. FIG.

Fig. 7 shows an example of supporting the construction of an extended ecosystem with a greening base formed by providing seed mat design information and manufacturing and installing seed mats according to the design information.

The user determines one or more types of target plants and the germination time of (the seeds of) the target plants (1).

In FIG. 7, the user has determined (a plurality of) radishes and carrots as target plants. Furthermore, the user determines the germination time for some radishes and carrots after one week, and for the remaining radishes and carrots after two weeks.

By operating the user I/F 31 of the terminal 11, the user inputs the target plant and plant information including germination time (2).

The transmission unit 32 of the terminal 11 transmits the plant information input by the user to the server 12 (3).

In the server 12, the design unit 52 receives the plant information from the terminal 11. The design unit 52 generates seed mat design information based on the plant information from the terminal 11 and various databases in the database 51 (4).

Then, the design unit 52 transmits the design information to the terminal 11 (5).

The receiving unit 33 of the terminal 11 receives the design information from the design unit 52 of the server 12.

Then, the display control unit 34 of the terminal 11 causes the user I/F 31 to display the design information.

The user manufactures the seed mat according to the design information, either manually or using a manufacturing device that manufactures the seed mat.

The seed mat manufactured according to the design information is a seed mat in which the seeds of the target plant set by the user germinate at the germination time set by the user.

Therefore, it is possible to provide a seed mat in which seeds germinate at a desired timing for each plant species or each individual plant, as in the case of sowing seeds in synecoculture (registered trademark).

In addition, by installing such seed mats, the user can easily form a greening base on which an extended ecosystem similar to that of Synecoculture (registered trademark) is constructed. Therefore, it is possible to support the construction of an extended ecosystem.

<Embedded area settings>

FIG. 8 is a diagram showing an example of an embedding area for embedding the seeds of the target plant that can be set in the seed mat.

By operating the user I/F 31, the user can set an embedding area for embedding seeds in the seed mat.

In FIG. 8, four embedded areas #1 to #4 are set by equally dividing the seed mat, which is rectangular in plan view, into four in the horizontal direction.

In FIG. 8, embedded areas #1 to #4 are areas of the same shape, but the embedded areas can be set to have different shapes.

When setting the embedding area, the user can set the target plant (seed) for seed embedding and the germination time for each embedding area by operating the user I/F 31 .

When an embedding area is set, the information about the embedding area is sent from the terminal 11 to the server 12 together with the information on the target plant and germination time, included in the plant information.

<Setting target plants and germination time>

FIG. 9 is a diagram showing an example of setting target plants and germination times by the user.

In FIG. 9, as in FIG. 8, four embedded areas #1 to #4 are set. When the embedding area is set, the target plant in which the seed is to be implanted and the germination time of the seed of the target plant can be set for each embedding area.

In FIG. 9, the user wishes to sow radishes in the embedding areas #1 and #2 and to sow carrots in the embedding areas #3 and #4, and seeds are embedded in the embedding area #1. It is set that the target plant to be planted is radish (embedding radish seeds in embedding areas #1 and #2), and that the target plant whose seeds are to be implanted in embedding areas #3 and #4 is carrot. ing.

Furthermore, in FIG. 9, the user desires to form a greening base on which there are strains at different growth stages, and seeds are embedded in two embedding areas. Settings are made so that the seeds placed in the seed mat germinate one week after the seed mat is placed (manufactured), and the seeds embedded in the other embedding area germinate after another week.

That is, in FIG. 9, the radish seeds embedded in the embedding area #2 and the carrot seeds embedded in the embedding area #3 are set to germinate one week later. The radish seeds embedded in the embedding area #1 and the carrot seeds embedded in the embedding area #4 are set to germinate one week later.

FIG. 10 is a diagram showing an example of plant information when target plants and germination times are set for each embedding area.

In FIG. 10, the plant information includes information on the embedding area #i, target plants for each embedding area (seeds are embedded in the embedding areas), and information on the germination time of the seeds of the target plants.

The information on the embedding area #i is, for example, information on the position and size of the embedding area #i in the seed mat, and the information on the target plant is, for example, the species name of the target plant.

FIG. 10 shows an object in which four embedding areas #1 to #4 are set in the seed mat as shown in FIG. 8, and seeds are embedded in the embedding areas #1 and #2 as shown in FIG. The plant information is shown when it is set that the plant is radish and that the target plant whose seeds are to be embedded in the embedding areas #3 and #4 is carrot.

Furthermore, in FIG. 10, the germination time of the radish seeds embedded in the embedding area #2 and the carrot seeds embedded in the embedding area #3 is set to one week later, and the radish seeds embedded in the embedding area #1. , and plant information when the germination time of the carrot seed to be embedded in the embedding area #4 is set to two weeks later.

It should be noted that the plant information can be configured without including the embedded area information. That is, it is not essential for the user to set the embedded area.

When the plant information does not include information on the embedding area, the design unit 52 of the server 12 determines the area (position) of the seed mat in which the target plant is to be embedded by a predetermined method.

<First example of required period database>

FIG. 11 is a diagram showing a first example of the required period database that the database 51 has.

In FIG. 11, the required period database includes correspondence relationships between specifications of seed mats (hereinafter also referred to as mat specifications) and required periods required for germination of seeds of various plant species embedded in seed mats of the mat specifications ( first correspondence relationship).

In FIG. 11, plant species, mat specifications, and required periods when seeds of the plant species are embedded in seed mats of the mat specifications are associated with each other.

Mat specifications include, for example, the material of the seed mat, information on the state of embedding seeds in the seed mat, and information such as the thickness of the seed mat.

Information on the embedding state includes, for example, information such as the depth at which the seeds are embedded in the seed mat and the density of the seeds embedded in the seed mat.

In FIG. 11, the "ground surface" of the depth at which the seeds are embedded in the seed mat means that the seeds are attached to the surface of the seed mat.

Also, the depth of embedding the seed in the seed mat, "in the ground x [cm]", means that the seed is embedded x [cm] from the surface of the seed mat.

The required period associated with the mat specification in the first correspondence stored in the required period database is the period required for germination of seeds placed in the internal environment of the seed mat formed by the seed mat of the mat specification. represents

Guo, C.; Shen, Y.; Shi, F. Effect of Temperature, Light, and Storage Time on the Seed Germination of Pinus bungeana Zucc. ex Endl.: The Role of Seed-Covering Layers and Abscisic Acid Changes. Forests 2020, 11, 300. (https://doi.org/10.3390/f11030300) ing.

Also, for example, the need period varies with temperature and soil water potential (humidity), see Kent J. Bradford "Applications of hydrothermal time to quantifying and modeling seed germination and dormancy," Weed Science, 50( 2), 248-260, (1 March 2002).

The internal environment of the seed mat varies depending on the external environment of the seed mat (environment in which the seed mat is installed) (external environment), for example, the amount of sunshine, rainfall, and temperature outside. However, here, the internal environment of a seed mat placed in a predetermined (fixed) external environment is used as the internal environment of the seed mat.

<First example of processing of terminal 11>

FIG. 12 is a flowchart explaining a first example of processing of the terminal 11. FIG.

FIG. 12 is a flow chart explaining an example of processing of the terminal 11 when the required period database stores the first correspondence described in FIG.

In the terminal 11, in step S11, the transmission unit 32 transmits the plant information after waiting for the plant information to be input (set) by the user's operation of the user I/F 31, and the process proceeds to step S12. move on.

In step S12, the receiving unit 33 waits for the design information of the seed mat to be transmitted from the server 12, receives the design information, supplies the design information to the display control unit 34, and the process proceeds to step S13. .

At step S13, the display control unit 34 causes the user I/F 31 to display the design information from the receiving unit 33, and the process ends.

Note that the transmission unit 32 can transmit planting plan information, which will be described later, as plant information instead of the plant information input by the user.

<First example of processing by server 12>

FIG. 13 is a flowchart explaining a first example of processing of the server 12. FIG.

FIG. 13 is a flow chart explaining an example of processing of the server 12 when the required period database stores the first correspondence described in FIG.

In the server 12, in step S21, the design unit 52 waits for the plant information to be transmitted from the terminal 11, receives the plant information, stores it in a storage unit (not shown), and proceeds to step S22. proceed to

In step S22, the design unit 52 generates seed mat design information based on the first correspondence stored in the required period database, the target plant included in the plant information from the terminal 11, and the germination time information. is generated, and the process proceeds to step S23.

At step S23, the design unit 52 transmits the design information to the terminal 11, and the process ends.

In the generation of the design information in step S22, for example, the design unit 52 selects from the required period database, for each germination time of the target plant, the mat specifications for which the required period of the plant species of the target plant is close to the germination time. , the mat specification whose required period is closest to the germination time (the difference between the required period and the germination time is the smallest) is retrieved, the mat specification for that germination time is determined, and stored in a storage unit (not shown). do.

Then, the design unit 52 generates design information representing the configuration of the seed mat in which mat specification areas for each germination period of the target plant are arranged.

　The placement of the mat-specification areas for each germination period of the target plant is determined by a predetermined method.

For example, the arrangement of mat specification areas for each germination period of the target plant may be randomly determined, or the target plant in a grown state may be uniformly distributed over the entire seed mat for as long as possible. can decide.

When the arrangement of mat specification areas for each germination period of the target plant is determined so that the target plant in the grown state is uniformly distributed over the entire seed mat for as long as possible, the grown state It is possible to form a greening base on which the target plants are uniformly distributed over a long period of time.

Furthermore, the layout of mat-specification areas for each germination period of the target plant can be determined so that the distribution of plant species with seeds embedded in the seed mat is as complicated as possible.

The complex distribution of plant species is conceptually expressed in the seed mat when the area of the mat specification for each germination period is filled with the color corresponding to the plant species embedding the seeds in that area. It means that the pattern is complicated.

The complexity of the distribution of plant species can be evaluated, for example, by the degree of complexity (degree of mosaic pattern) that represents the complexity of the distribution of plant species.

The design unit 52 can calculate the complexity of the distribution of plant species, for example, as follows.

The design unit 52 groups the target plants whose seeds are to be embedded in the seed mat into groups of the same plant species, and for each group, the center of gravity of the position of the area (where the seeds are to be embedded) of the target plants belonging to the group. is calculated as the centroid of the group.

Then, for each group, the design unit 52 calculates the average value of the distance between the position of the area of the target plants belonging to the group and the center of gravity of the group as the degree of scattering of the target plants of the same plant species belonging to the group. Then, the average value of the scattering degree of all groups is calculated as the complexity of the plant species distribution.

The higher the complexity of the distribution of plant species, the more complex the distribution of plant species can be evaluated.

If the layout of the mat specification areas for each germination stage of the target plant is determined so that the distribution of plant species with seeds embedded in the seed mat is as complex as possible, mats for each germination stage of the target plant It is possible to increase (enhance) the diversity of plant species in a localized area of the seed mat by collecting several adjacent areas in the seed mat among the specified areas.

Note that when the plant information includes information on the embedding area, information on the target plant for each embedding area, and information on the seed germination time of the target plant, as described with reference to FIG. , for each embedding area, the mat specification that has the closest required period to the germination time of the target plant whose seed is to be embedded in that embedding area is determined as the mat specification for that embedding area.

The mat specifications for the embedding area determined for each embedding area are also the mat specifications for the germination period of the target plant whose seeds are embedded in that embedding area.

After determining the mat specification of each embedding area, the design unit 52 generates design information representing the configuration of the seed mat in which each embedding area for which the mat specification has been determined is arranged at the position represented by the information of the embedding area.

<First display example of seed mat design information>

FIG. 14 is a diagram showing a first display example of seed mat design information.

FIG. 14 shows an example of design information when the plant information includes information on the embedding area, information on the target plant for each embedding area, and information on the seed germination time of the target plant, as described in FIG. is shown.

The design information in FIG. 14 is a tabular list that represents the configuration of the seed mat.

In FIG. 14, the design information defines the configuration of the seed mat as follows according to the plant information in FIG. 10 and the required period database in FIG.

That is, first, radish seeds as the target plant are embedded in the embedding area # 1, and the embedding area # 1 is made of material B as a mat specification for setting the germination time of the radish seeds to 2 weeks later. It is stipulated that the depth of burying radish seeds is 1 cm in the ground.

Second, embedding area # 2 is made of material A as a mat specification for embedding radish seeds as a target plant in embedding area # 2 and setting the germination time of the radish seeds after one week. , the depth of burying radish seeds is stipulated to be 1 cm in the ground.

Third, the embedding area #3 is composed of material A as a mat specification for embedding carrot seeds as a target plant in the embedding area #3 and setting the germination time of the carrot seeds after one week. , the ground surface is defined as the depth at which carrot seeds are embedded.

Fourth, the embedding area #4 is composed of material B as a mat specification for embedding carrot seeds as a target plant in the embedding area #4 and setting the germination time of the carrot seeds after two weeks. , the ground surface is defined as the depth at which carrot seeds are embedded.

<Example of seed mat manufactured according to design information>

FIG. 15 is a perspective view showing an example of a seed mat manufactured according to design information.

FIG. 15 shows an example of a seed mat manufactured according to the design information in FIG. 14.

The user constructs embedded areas #1 and #4 with material B, and constructs embedded areas #2 and #3 with material A.

Furthermore, the user embeds radish seeds to a depth of 1 cm in the ground in embedment areas #1 and #2, and embeds (attaches) carrot seeds to the ground surface in embedment areas #3 and #4. , the seed mat having the configuration represented by the design information is completed.

FIG. 16 is a diagram showing how a greening base is formed using a seed mat manufactured according to design information.

The user places, for example, the seed mat shown in FIG.

One week after setting (manufacturing) the seed mat, the radish and carrot seeds in the embedding areas #2 and #3 germinate respectively.

After another week (two weeks after setting the seed mat), the radish and carrot seeds in the embedding areas #1 and #4 germinate, respectively.

<Second example of required period database>

FIG. 17 is a diagram showing a second example of the required period database that the database 51 has.

In FIG. 17, the required period database stores the correspondence relationship (second correspondence relationship) between the environment in which the plant species are placed and the required period required for the seeds of various plant species placed in the environment to germinate. there is

In FIG. 17, humidity is adopted as an environmental parameter (factor). As environmental parameters, in addition to humidity, for example, one or more parameters that affect the environment such as temperature and amount of sunshine can be used.

FIG. 18 is a diagram showing an example of the specification database that the database 51 has.

If the required period database is a database that stores the correspondence (second correspondence) between the environment and the required period as described in FIG. 17, the database 51 has a specification database.

The specification database stores mat specifications such as seed mat materials and seed embedding conditions (seed embedding depth, etc.), and correspondence relationships (third correspondence relationship) with the internal environment of the seed mat formed by these specifications. I remember.

Note that in FIG. 18, humidity (water retention) is adopted as a parameter (factor) of the internal environment. As parameters of the internal environment, in addition to humidity, one or more various parameters that affect the internal environment, such as temperature and light transmittance (amount of sunshine), can be employed.

It is desirable that the environmental parameters (attribute names) in the second correspondence stored in the required period database match the internal environment parameters in the third correspondence stored in the specification database. However, even if the parameters of the environment in the second correspondence relationship and the parameters of the internal environment in the third correspondence relationship do not completely match, it is sufficient that some of the parameters match.

In addition, although the internal environment of the seed mat varies depending on the external environment of the seed mat, in the present embodiment, the internal environment of a seed mat placed in a predetermined external environment is adopted as the internal environment of the seed mat.

The design unit 52 establishes a second correspondence relationship between the environment and the required period stored in the required period database shown in FIG. 17, and a third correspondence relationship between the mat specifications and the internal environment stored in the specification database shown in FIG. can be used as the first correspondence relationship between the mat specification and the required period stored in the required period database of FIG. 11 to generate the design information.

<Second example of processing by server 12>

FIG. 19 is a flowchart explaining a second example of processing of the server 12. FIG.

FIG. 19 illustrates an example of processing by the server 12 when the required period database stores the second correspondence described with reference to FIG. 17 and the specification database stores the third correspondence described with reference to FIG. It is a flow chart to do.

The processing of the terminal 11 when the required period database stores the second correspondence relationship and the specification database stores the third correspondence relationship is the same as in FIG. 12, so description thereof will be omitted.

In the server 12, in step S41, the design unit 52 waits for the plant information to be transmitted from the terminal 11, receives the plant information, stores it in a storage unit (not shown), and proceeds to step S42. proceed to

In steps S42 through S46, the design unit 52 uses the second correspondence stored in the required period database and the third correspondence stored in the specification database as the first correspondence, 1, and the target plant and germination time information included in the plant information from the terminal 11, the design information of the seed mat is generated.

In step S42, the design unit 52 calculates a relational expression E=f(T) between (parameters of) the environment E and the required period T of each plant species according to the second correspondence relationship. Proceed to S43. The relational expression E=f(T) can be calculated by, for example, regression analysis (single regression analysis, multiple regression analysis) or the like.

In step S43, the design unit 52 calculates a relational expression C=g(E) between (parameters of) the internal environment E and the mat specifications C according to the third correspondence relationship, and the process proceeds to step S44. . Calculation of the relational expression C=g(E) can be performed, for example, by regression analysis or the like, similarly to the calculation of the relational expression E=f(T).

In step S44, the design unit 52, for each germination time of the target plant included in the plant information, implements the environment E (range ) is detected, and the process proceeds to step S45.

In step S45, the design unit 52, for each germination time of the target plant included in the plant information, implements the environment E that realizes the required period T close to the germination time according to the relational expression C=g(E), that is, A mat specification C (range of) that forms the environment E detected in step S44 as an internal environment E is detected, and the process proceeds to step S46.

In step S46, the design unit 52 generates design information representing the configuration of the seed mat in which the mat specification areas detected in step S45 are arranged for each germination time of the target plant included in the plant information. Proceed to S47.

At step S47, the design unit 52 transmits the design information to the terminal 11, and the process ends.

Even if the first correspondence cannot be acquired, the design information can be generated by using the second correspondence and the third correspondence as the first correspondence as described above. can be done.

<Third example of required period database>

FIG. 20 is a diagram showing a third example of the required period database that the database 51 has.

In FIG. 20, the necessary period database adds climate information to the first correspondence relationship in FIG. A correspondence relationship (fourth correspondence relationship) is stored between the seeds of various plant species embedded in the seed mat and the necessary period required for germination when the seed mat is placed in a climate location represented by the climate information. there is

Therefore, the third example of the required period database in FIG. 20 is common to the first example of the required period database in FIG. 11 in that it stores the first correspondence relationship between the mat specification and the required period.

However, in the third example of the required period database in FIG. 20, the climate information of the place where the seed mat of each mat specification is installed is stored. It is different from the first example of the required period database in FIG. 11 in that it stores a correspondence relationship (fourth correspondence relationship) with the required period when installed in a location with the indicated climate.

The internal environment of the seed mat differs depending on the external environment where the seed mat is installed, even if the seed mat has the same mat specifications.

The required period associated with the mat specification and the climate information in the fourth correspondence stored in the required period database of FIG. It represents the period required for germination of the seeds placed in the internal environment of the seed mat formed by the seed mat of the mat specification.

Therefore, the required period stored in the required period database of FIG. 20 represents the period required for seeds to germinate in the internal environment of the seed mat considering the influence of the external environment (here, climate) where the seed mat is installed. .

In FIG. 20, materials and the like are stored as the mat specifications, as in the case of FIG.

Also, in FIG. 20, the average amount of rainfall and average amount of sunshine per month are stored as climate information. In addition, as climate information, various kinds of climate information such as humidity, temperature, climate zone, etc. can be used.

<Second example of processing of terminal 11>

FIG. 21 is a flowchart illustrating a second example of processing of the terminal 11. FIG.

FIG. 21 is a flow chart explaining an example of processing of the terminal 11 when the required period database stores the fourth correspondence relationship explained in FIG.

In the terminal 11, in step S51, the transmission unit 32 waits for the plant information to be input (set) by the user's operation of the user I/F 31, transmits the plant information together with the climate identifiable information, The process proceeds to step S52.

In steps S52 and S53, the same processes as steps S12 and S13 of FIG. 12 are performed, respectively, and the process ends.

The climate identifiable information transmitted by the terminal 11 in step S51 is information that can specify the climate information of the planned installation location where the seed mat for which the user is trying to obtain the design information is to be installed.

As the climate identifiable information, for example, the climate information of the planned installation location itself, the location information of the planned installation location, etc. can be used.

The climate information of the planned installation location can be obtained, for example, from climate information databases on the Internet, such as AMeDAS of the Meteorological Agency, by operating the terminal 11 by the user.

The location information of the planned installation location can be obtained, for example, by having the user input the place name, latitude and longitude, etc. of the planned installation location by operating the terminal 11 by the user.

In addition, for example, when the user possesses the terminal 11 and is staying at (a place close to) the planned setting location, the position information of the terminal measured by the positioning unit 21 of the terminal 11 is used as the location of the planned installation location. It can be used as location information.

<Third example of processing by server 12>

FIG. 22 is a flowchart explaining a third example of processing of the server 12. FIG.

FIG. 22 is a flow chart illustrating an example of processing by the server 12 when the required period database stores the fourth correspondence described in FIG.

In the server 12, in step S61, the design unit 52 waits for the plant information and the climate identifiable information to be transmitted from the terminal 11, receives the plant information and the climate identifiable information, and After storing in a storage unit (not shown), the process proceeds to step S62.

In step S62, the design unit 52 identifies the climate information of the location where the seed mat is to be installed from the climate identifiable information, and the process proceeds to step S63.

For example, in step S62, if the climate identifiable information is climate information, the climate information is identified as the climate information of the planned installation location. Further, for example, if the climate identifiable information is the location information of the planned installation location, the climate information of the location (region) represented by the location information is obtained from a database of climate information on the Internet, and the location of the planned installation location identified as climate information for

Thereafter, in steps S63 and S64, the design unit 52 determines the fourth correspondence stored in the required period database, the target plant and germination time information included in the plant information from the terminal 11, and the planned installation location. Generate design information for seed mats according to climate.

In step S63, the design unit 52 filters the information in the required period database of FIG. 20, and extracts a fourth correspondence relationship including climate information similar to the climate information of the planned installation location as a subset of the required period database. , the process proceeds to step S64.

In step S64, the design unit 52 generates seed mat design information according to the fourth correspondence relation as a subset of the required period database and the plant information, and the process proceeds to step S65.

At step S65, the design unit 52 transmits the design information to the terminal 11, and the process ends.

In the extraction of the fourth correspondence as a subset of the required period database in step S63, for example, the fourth correspondence including climate information whose correlation coefficient with the climate information of the planned installation location is equal to or greater than a threshold is extracted. .

The correlation coefficient between the climate information of the planned installation location and the climate information included in the fourth correspondence stored in the required period database is obtained by, for example, normalizing the value of each parameter of the climate information such as the amount of precipitation and the amount of sunshine. can be calculated using the normalized value obtained as a result of the normalization.

The normalized value of the parameter X of the climate information is obtained, for example, by subtracting the average value of the parameter X (of the climate information included in the fourth correspondence) stored in the required period database from the value of the parameter X, and the result is The resulting subtraction value can be calculated by dividing by the standard deviation of the values of parameter X stored in the required period database.

The normalized value of each parameter of the climate information (included in the fourth correspondence) stored in the necessary period database calculated as described above, and the normalized value of each parameter of the climate information of the planned installation location can be used to calculate the correlation coefficient between the climate information stored in the required period database and the climate information of the planned installation site.

In addition, in the extraction of the fourth correspondence relation as a subset of the required period database in step S63, for example, the fourth correspondence including the climate information whose sum of the absolute differences between the weather information of the planned installation location and each parameter is equal to or less than the threshold value. 4 can be extracted as a fourth correspondence containing climate information similar to the climate information of the planned installation location.

In the generation of design information in step S64, design information is generated in the same way as in step S22 of FIG. 13 using the fourth correspondence extracted as a subset of the required period database.

That is, in the generation of the design information in step S64, for example, the design unit 52, from the mat specification included in the fourth correspondence extracted as a subset of the required period database, for each germination time of the target plant, the target plant A mat specification for which the necessary period of the plant species with the condition is closest to the germination time is retrieved, the mat specification for the germination time is determined, and stored in a storage unit (not shown).

Then, the design unit 52 generates design information representing the configuration of the seed mat in which mat specification areas for each germination period of the target plant are arranged.

As described above, by generating the design information using the fourth correspondence relationship including climate information similar to the climate information of the planned installation location, when the seed mat is installed at the planned installation location, the user can set It is possible to generate design information for a seed mat that allows seeds to germinate at a time when there is little error due to the influence of the climate of the planned installation site, with respect to the germination time.

<Third example of processing of terminal 11>

FIG. 23 is a flowchart explaining a third example of processing of the terminal 11. FIG.

In addition to plant information, the user can set the purpose of installing the seed mat, for example, the purpose related to the (extended) ecosystem constructed by installing the seed mat.

Objectives related to ecosystems include, for example, improving biodiversity such as the diversity of microflora and plant species in ecosystems.

FIG. 23 is a flow chart explaining an example of the processing of the terminal 11 when the purpose of installing the seed mat is set as described above.

In the terminal 11, in step S71, the transmitting unit 32 waits for input (setting) of the plant information and the purpose information indicating the purpose of installing the seed mat by the operation of the user I/F 31 by the user. The plant information and purpose information are transmitted, and the process proceeds to step S72.

In steps S72 and S73, the same processing as in steps S12 and S13 of FIG. 12 is performed, respectively, and the processing ends.

<Fourth example of processing by server 12>

FIG. 24 is a flowchart explaining a fourth example of processing of the server 12. FIG.

FIG. 24 is a flow chart explaining an example of the processing of the server 12 when the purpose of installing the seed mat is set.

When the purpose of installing a seed mat is set, the database 51 of the server 12 has, for example, the required period database in FIG. 11, a growing organism database, and a co-occurrence relationship database.

As explained in FIG. 5, the growing organism database stores information on organisms that grow in the internal environment of the seed mat formed by the mat specification for each mat specification. The co-occurrence relation database stores, for each plant species, information on organism species that have a co-occurrence relation with the plant species.

In the server 12, in step S81, the design unit 52 waits for the plant information and purpose information to be transmitted from the terminal 11, receives the plant information and purpose information, and stores them in a storage unit (not shown). , and the process proceeds to step S82.

In step S82, the design unit 52 obtains the first correspondence stored in the required period database, the target plant and germination time information included in the plant information from the terminal 11, the purpose information from the terminal 11, and Design information of the seed mat is generated according to the information stored in the growing organism database and the co-occurrence relation database, and the process proceeds to step S83.

At step S83, the design unit 52 transmits the design information to the terminal 11, and the process ends.

For example, if the purpose represented by the purpose information is to improve the diversity of microbiota, in the generation of the design information in step S82, the seed mat is grown in the internal environment of the seed mat formed by each mat specification stored in the growing organism database. Among the information on (inhabiting) organisms, the information on the microbiota, and among the information on the organisms co-occurring with each plant species stored in the co-occurrence relation database, the information on the microbiota is used.

For example, the design unit 52 searches the required period database for a plurality of mat specifications for each germination time of the target plant in order of the closeness of the required period of the plant species that is the target plant to the germination time.

Further, by referring to the growing organism database, the design unit 52 selects from among a plurality of mat specifications for each germination period of the target plant, for different species of target plants, an internal environment in which as many different microbiota as possible are established. is determined as the mat specification for the germination period, and stored in a storage unit (not shown).

As a result, for example, mat specifications in which seeds of plant species A as a certain target plant are embedded, and mat specifications in which seeds of plant species B different from plant species A are embedded as other target plants, different microflora is fixed (internal environment is formed) mat specification is determined.

Then, the design unit 52 generates design information representing the configuration of the seed mat in which mat specification areas for each germination period of the target plant are arranged.

If the plant information includes information on the embedding area, and therefore includes information on the target plant and germination time for each embedding area, the mat specification for each germination time of the target plant is the embedding area in which seeds of the target plant are to be embedded. , and is arranged according to the information of the embedding area.

If the plant information does not include information about the embedding area, the arrangement of the mat specification areas for each germination stage of the target plant is determined, for example, so that the distribution of the microflora that can colonize the seed mat is as complex as possible. be able to.

The complex distribution of the microbiota is conceptually similar to the distribution of plant species described in FIG. It means that the pattern that appears on the seed mat when filled with the corresponding color is complex.

　The complexity of the distribution of the microbiota can be evaluated, for example, by the complexity that represents the complexity of the distribution of the microbiota.

The complexity of the distribution of microbiota can be calculated in the same way as the complexity of the distribution of plant species described in FIG.

That is, the design unit 52 identifies the microflora that can settle (inhabit) in (the internal environment formed in) the mat specification area for each germination period of the target plant.

For example, of the mat specifications for each germination period of the target plant, the design unit 52 refers to the growing organism database for the mat specifications C for a given germination period of the target plant, and forms the mat specifications C. Identify the microbiota that inhabits (the internal environment of) the seed mat to be treated as the microbiota that can colonize areas of mat specification C.

Furthermore, by referring to the co-occurrence relationship database, the design unit 52 determines that the microbiota that has a co-occurrence relationship with the target plant whose seeds are to be embedded in the mat specification C area can also colonize in the mat specification C area. Identify as

The design unit 52 groups the microbiota that can colonize each area of the mat specification for each germination period of the target plant into groups of the same type of microbiota. Further, the design unit 52 calculates, for each group, the center of gravity of the position of the microbiota area belonging to the group, etc., as the center of gravity of the group.

Then, for each group, the design unit 52 calculates the average value of the distance between the position of the area of the microbiota belonging to the group and the center of gravity of the group as the degree of scattering of the microbiota belonging to the group. The average degree of dispersal is calculated as the distribution complexity of the microbiota.

The design unit 52 determines the arrangement of the mat specification areas for each germination period of the target plant so as to increase the complexity of the distribution of the microbiota calculated as described above. to generate design information representing the configuration of the seed mat in which the areas are arranged.

As described above, by determining the layout of the mat specification areas for each germination period of the target plant so as to increase the complexity of the distribution of the microflora, not only the entire seed mat but also the local With regard to the specific range, it is also possible to generate design information for seed mats capable of achieving the objective of improving the diversity of the microbiota represented by the objective information.

And in the extended ecosystem built on the greening base formed by installing seed mats manufactured according to such design information, diverse microflora are established and ecosystem services are provided by the functions of the diverse microbiota. can enjoy.

It should be noted that, in generating the seed mat design information described above, as the plant information, planting plan information can be used in addition to the target plant set by the user and the plant information including the germination time.

The planting plan information is information representing the planting plan. The planting plan information includes, for example, information on the plant species to be planted in the target space for planting, such as a field, information on the planting possible period for planting the plant species, and planting positions for planting the plant species in the target space. (area) information can be included.

The planting plan information can be generated by any method. For example, the planting plan information provides the user with information on the target space (size, etc.) and information on the cultivation period desired by the user as the period for cultivating plants (the date when the cultivation starts and the date when the cultivation ends). date, etc.), and the target space and the cultivation period information can be used in the server 12 to generate the target space.

For example, the server 12 selects, as candidate plant species, plant species that can grow during each division period in which the cultivation period is subdivided into weeks or months. A candidate plant species is a candidate plant species to be planted in the target space.

The server 12 (virtually) arranges (individuals of) the candidate plant species in the target space for each delimited period.

The placement of the candidate plant species in the target space is performed so that the space occupied by the candidate plant species does not overlap with each other in the grown state of the candidate plant species placed in the target space.

Furthermore, the candidate plant species can be arranged in the target space, for example, in such a way that the biodiversity in the target space increases and the candidate plant species are packed into the target space as much as possible.

Specifically, the candidate plant species are arranged in the target space so that the space filling rate and the diversity rate are greater, for example, the space filling rate × diversity rate is greater (ideally to maximize).

The space filling rate represents the ratio of all candidate plant species placed in the target space to occupy the target space.

The diversity rate means the ratio of the biodiversity of the candidate plant species arranged in the target space to the biodiversity of the candidate plant species (for example, the number of candidate plant species) in the delimited period.

As described above, the server 12 arranges the candidate plant species in the target space for each delimited period, and selects the arranged candidate plant species as the plant species to be planted.

Furthermore, the server 12 identifies the delimited period in which the plant species to be planted in the target space is arranged as the possible planting period in which the plant species can be planted. For example, the cultivation period is divided into N division periods #1, #2, . If so, the delimited periods #i to #i+2 are identified as the plantable period for the plant species A.

Then, the server 12 generates planting plan information including information on the plant species to be planted, information on the planting period of the plant species to be planted, and information on the planting position of the plant species to be planted in the target space (placement position in the target space). do.

The user causes the server 12 to generate planting plan information with the space whose bottom is the seed mat for which design information is to be generated as the target space, receives the planting plan information at the terminal 11, and uses the planting plan information as plant information. It can be transmitted from the terminal 11 to the server 12 . For example, the height of the target space can be set by the user or set by the server 12 according to the size of the seed mat that is the bottom surface of the target space.

The design unit 52 of the server 12 uses the planting plan information from the terminal 11 as plant information to generate seed mat design information.

The design unit 52 uses the plant species information included in the planting plan information as the target plant information, and uses the planting position information included in the planting plan information as the embedding area information.

Then, the design unit 52 calculates the germination time of the target plant from the information on the plantable period of the target plant (the plant species to be planted), which is included in the planting plan information, and generates design information.

In calculating the germination time of the target plant, the design unit 52 sets a predetermined timing within the plantable period, for example, the start timing of the plantable period, for each target plant according to the user's desired seed germination. Set to 1 timing (year/month/day).

Further, the design unit 52 asks the user to set the second timing for manufacturing and installing the seed mat, and calculates the period from the second timing to the first timing as the germination time.

It should be noted that the second timing is not set by the user, but can be set, for example, to the current timing at which the design information is being generated.

As described above, the design unit 52 acquires the information on the target plant, the germination time, and the planting area from the planting plan information, and uses the information to perform the first to fourth examples of the processing of the server 12. Generate design information as in the example.

For example, the design unit 52 determines, for each embedding area, the mat specification that has the closest required period to the germination time of the target plant whose seeds are to be embedded in the embedding area, as the mat specification for that embedding area, according to the information on the embedding area. . Then, the design unit 52 generates design information representing the configuration of the seed mat in which each embedding area for which the mat specifications have been determined is arranged at the position represented by the information of the embedding area.

As described above, when the planting plan information is used as plant information to generate seed mat design information, it is possible to manufacture a seed mat that realizes a planting plan made for the seed mat. becomes.

In addition, the planting plan information generated by arranging the candidate plant species in the target space so as to increase the biodiversity in the target space and cram as many candidate plant species as possible into the target space is When the information is used to generate seed mat design information, it is possible to produce a seed mat on which plants grow densely and a greening base with a high species diversity of plants is formed.

<Second display example of seed mat design information>

FIG. 25 is a diagram showing a second display example of the seed mat design information.

FIG. 25, similar to FIG. 14, shows an example of design information when the plant information includes information on embedding areas, target plants for each embedding area, and information on the germination time of the seeds of the target plants. ing.

In FIG. 25, as shown on the left, the design information is an image of a 3D model representing the configuration of the seed mat. Locations on seed mats are indicated. In addition, the material of each embedding area (Material A and B), the depth of embedding seeds in each embedding area ("embedding at a depth of 1 cm" and "embedding on the ground surface"), and the plant that embeds seeds in each embedding area The various configurations of the seed mat, such as seeds (target plant types) (radish and carrot), are described in letters.

When a 3D model image is used as the design information, the 3D model image includes the composition of the seed mat shown on the left side of FIG. It is possible to employ a predicted transition image that transitions in time series as shown in FIG.

The user can easily understand the design information by displaying the design information as a 3D model image as described above.

　In the image of the 3D model as the design information, it is possible to display the internal environment of the seed mat manufactured according to the design information.

FIG. 26 is a diagram showing an example of a 3D model image as design information that displays the internal environment of the seed mat.

In FIG. 26, among the parameters of the internal environment of the seed mat-embedded areas #1 to #4, for example, the humidity is indicated by shades of color.

In addition, in the 3D model image as design information that displays the internal environment of the seed mat, other internal environment parameters such as temperature can be displayed in addition to humidity.

In addition, in the 3D model image as design information that displays the internal environment of the seed mat, turning on/off the display of the internal environment and parameters of the internal environment to be displayed can be selected by operating the terminal 11.

<Display example of related information>

FIG. 27 is a diagram showing a first display example of related information.

In addition to the design information of the seed mat, the design unit 52 can generate related information related to the seed mat manufactured according to the design information and transmit it to the terminal 11 together with the design information.

As related information, for example, the species diversity of the target plant whose seeds are embedded in the seed mat can be used.

In addition, as related information, for example, the plant species that are the target plants and the biological species that cause (biological) interactions with the plant species are represented by nodes, and the plant species represented by the nodes An evaluation value obtained by evaluating an interaction network in which interactions between species and biological species are represented by links can be adopted.

Furthermore, as related information, for example, when the state in which the target plant has grown in the seed mat is predicted, the space filling rate of the target plant in the grown state can be adopted.

As the species diversity of target plants, for example, the number of plant species that are target plants can be used. In FIG. 27, the number of plant species that are target plants is 50. ing.

As the evaluation value of the interaction network, for example, the species diversity of biological species that interact with the target plant species in the interaction network can be used. Also, for example, as the evaluation value, the number of interactions that occur with the plant species that are the target plants in the interaction network can be used.

In FIG. 27, as an evaluation value of the interaction network, the species diversity of biological species that interact with the target plant species is adopted in the interaction network. Furthermore, in FIG. 27, as the species diversity of the biological species that interact with the target plant species, for example, the number of species of the biological species is adopted, and the number of species is 250. It is kind.

The space filling rate is defined as the ratio of the space occupied by the target plant in a grown state in the cultivation space in which the target plant is cultivated and which has a predetermined height with the bottom surface being the plane of the seed mat. means. In FIG. 27, the space filling rate is 80%.

For example, the height of the cultivation space can be set according to the operation of the terminal 11, or can be set to the height of the tallest target plant among target plants in a grown state.

The related information can be displayed in a tabular format, for example, as shown in FIG.

Also, the related information can be displayed alone, or can be displayed together with the design information shown in FIGS. 14, 25, and 26, for example.

When the related information is displayed together with the design information, the related information can be displayed in the window by providing a window for the related information around the display of the design information.

In the above, it is assumed that the related information is generated for the entire seed mat, but the related information can be generated for each small area by dividing the seed mat into small areas.

A small area that is a unit for generating related information is called a generation area.

FIG. 28 is a diagram explaining the generation area.

When the seed mat is divided into areas configured with at least the same mat specifications, the areas are called unit areas.

Regarding the mat specification area with the seed mat, the entire area can be used as one unit area, or the area can be divided into a plurality of small areas, and each small area can be used as a unit area. can.

The design unit 52 can set the unit area according to the operation of the terminal 11, for example.

For example, if the plant information includes information on the embedding area, the embedding area can be set as a unit area.

In FIG. 28, areas of the same shape obtained by dividing the seed mat into rectangles are unit areas. Note that the shape of the unit area is not limited to a rectangle, and may be other shapes such as a triangle or a hexagon.

For example, the design unit 52 sets one or more adjacent unit areas as the generation area according to the operation of the terminal 11 .

In FIG. 28, 2×2 unit areas are set as the generation area.

Related information can be generated for each generation area as described above.

FIG. 29 is a diagram showing a second display example of related information.

FIG. 29 shows a display example of related information when related information is generated for each generation area.

In the display of related information for each generation area, for example, for each generation area of the image of the seed mat, the related information of the generation area can be displayed in shades of color.

In FIG. 29, the species diversity of target plants in each generation area is displayed in shades of color.

Regarding the shade of color for displaying species diversity, for example, the lightest color and the darkest color are set in advance, and among the species diversity of each generation area that constitutes the seed mat, the minimum species diversity is assigned to the lightest color, and the color shades that display the species diversity of each generation area correspond to each generation area so that the maximum species diversity is assigned to the darkest color. set.

In FIG. 29, the minimum and maximum species diversity are 0 and 25, respectively, with the lightest color assigned the minimum species diversity of 0 and the darkest color the maximum species diversity. Some 25 are assigned.

When the related information generated for each generated area is the space filling rate, the space filling rate of the generated area is calculated (generated) as a cultivation space with the generated area as the bottom surface.

Also, when related information is generated for each generation area, for example, the diversity of the internal environment of the generation area can be adopted as the related information of the generation area in addition to the above-mentioned species diversity.

As the diversity of the internal environment of the generation area, for example, it is possible to adopt the dispersion of parameters such as humidity of each internal environment formed by the mat specification of each unit area that constitutes the generation area.

Parameters such as the humidity of the internal environment of the unit area formed by the mat specifications of the unit area can be identified by referring to the specification database of FIG. 18, for example.

　In the image of the seed mat, the diversity of the internal environment of the generation area can be displayed, for example, in shades of color, similar to the species diversity described above.

Here, when the diversity of the internal environment of the generation area is high, for example, when the dispersion of humidity etc. is high, there is a high potential for plant species suitable for various humidity to grow in the generation area. can improve sexuality.

In FIG. 29, the plane image of the seed mat is used as the image of the seed mat, but the image of the 3D model as shown in FIGS. 25 and 26, for example, is used as the seed mat image. be able to.

On the terminal 11, the design information and related information can be displayed for one seed mat, and can also be displayed for a plurality of seed mats so as to give a bird's-eye view of the plurality of seed mats.

In the terminal 11, when the design information and related information are displayed for one or a plurality of seed mats in a bird's-eye view, for example, an application for bird's-eye display is installed on the terminal 11. is installed.

<Application for overhead display>

FIG. 30 is a diagram showing a display example of the initial screen window 110 displayed (on the user I/F 31) immediately after the bird's-eye display application is activated on the terminal 11. FIG.

The initial screen window 110 has buttons 111 and 112.

The button 111 is operated when inputting (setting) the design information of the seed mat.

The button 112 is operated to display the design information and related information about the seed mat for which the design information has already been input.

FIG. 31 is a diagram showing a display example of the design information input screen displayed when the button 111 is operated on the terminal 11. FIG.

On the input screen, a blank matte map, that is, a matte map with no matte specifications set, is displayed.

A mat map is an image of a seed mat viewed from above.

The mat map is divided into unit areas, and design information can be input by setting the mat specifications that make up the design information for each unit area.

For the unit area of the mat map, the number, size, shape, etc. can be set by operating the terminal 11.

On the input screen, the user can display an information input window by operating the terminal 11.

In the information input window, it is possible to select whether to set the mat specification to the unit area by inputting the mat specification by operating the terminal 11 or by file search.

When setting the mat specifications to the unit area by inputting the mat specifications by operating the terminal 11, the user selects the unit area for which the mat specifications are to be set with the cursor, and operates the terminal 11. , enter the mat specification.

When setting the mat specifications to the unit area by file search, the user must enter the format in which the mat specifications are recorded, such as the CSV (comma separated value) format, which is predetermined for recording the mat specifications. Specify a file.

In the terminal 11, the mat specification is read from the file specified by the user and set in the unit area.

In the matte map, unit areas with matte specifications are displayed with different colors and shades than unit areas without matte specifications. This allows the user to easily recognize the unit area for which the mat specification is set and the unit area for which the mat specification is not set.

By setting the mat specifications for each unit area of the mat map, the user inputs the design information and completes the mat map corresponding to the seed mat generated according to the design information.

As the file in which the mat specifications are recorded, a file in which the design information of the entire seed mat is recorded, for example, a file in which the design information generated by the server 12 is recorded can be specified. In this case, matte specifications are set for each unit area of the matte map according to the design information recorded in the designated file.

In the terminal 11, design information and related information can be displayed for a mat map completed by inputting design information (hereinafter also referred to as a completed mat map). Furthermore, for the completed mat map, one or more adjacent unit areas can be set as the generation area and related information can be displayed.

For multiple completed mat maps, it is possible to display design information and related information by arranging the multiple completed mat maps in a bird's-eye view of the seed mat.

When displaying the design information and related information, the user operates the button 112 in the window 110 of the initial screen in FIG.

FIG. 32 is a diagram showing a display example of the selection window 120 displayed when the button 112 on the terminal 11 is operated.

The selection window 120 has buttons 121, 122, 123, 124, 125, and 126.

The button 121 is operated when design information of the completed mat map (design information input to the completed mat map) is displayed.

When the button 121 is operated, on the terminal 11, for one or more completed mat maps, 3D model images as shown on the left side of FIG. .

A button 122 is operated to display the predicted transition image described with reference to FIG. 25 for the completed matte map.

When the button 122 is operated, on the terminal 11, for example, predicted transition images for one or more completed mat maps are displayed side by side.

The button 123 is operated when displaying the internal environment of the completed matte map.

When the button 123 is operated, the terminal 11 displays, for example, 3D model images displaying the internal environment side by side for one or more completed mat maps, as described with reference to FIG.

The button 124 is operated to display the plant species diversity (species diversity of plant species) described in FIG. 27 for the completed mat map.

When the button 124 is operated, the terminal 11, for example, for one or more completed mat maps, displays the species diversity of the target plant in shades of color for each generation area, as described with reference to FIG. Maps are displayed side by side.

The button 125 is the evaluation value of the interaction network whose node is the target plant described in FIG. 27 for the completed mat map. Manipulated when displaying the species diversity of a species.

When the button 125 is operated, the terminal 11, for example, interacts with the plant species that are the target plants in the interaction network for one or more completed mat maps, as described with reference to FIG. A complete mat map that displays the species diversity of the generated species with color shading for each generation area is displayed side by side.

A button 126 is operated to display the space filling rate described in FIG. 27 for the completed mat map.

When the button 126 is operated, the terminal 11 arranges, for example, one or more completed mat maps that display the space filling rate with color shading for each generation area, as described with reference to FIG. Is displayed.

For multiple completed matt maps, it is possible to display the related information of the entire multiple completed mat maps in a way that compares them.

FIG. 33 is a diagram showing a display example in which related information of the entirety of a plurality of completed mat maps is displayed in comparison.

In FIG. 33, the number of plant species included in the corresponding seed mats (the number of plant species) as plant species diversity, which is one of the related information, for the three completed mat maps is compared in a bar graph. displayed in the form.

For example, the bar graph in FIG. 33 can be displayed side by side with the display of 3D model images as shown on the left side of FIG. 25 as design information for each of the three completed mat maps.

<Configuration example of manufacturing equipment>

FIG. 34 is a diagram showing a configuration example of a manufacturing apparatus that manufactures seed mats according to seed mat design information.

In FIG. 34, the manufacturing device 200 has a conversion device 201 and a generation device 202 .

By operating the terminal 11 , the user connects the terminal 11 and the conversion device 201 so that wired communication or wireless communication is possible, and transmits design information from the terminal 11 to the conversion device 201 .

The conversion device 201 receives the design information from the terminal 11, converts it into a data format that can be handled by the generation device 202, and supplies it to the generation device 202.

The generation device 202 generates a seed mat according to the design information from the conversion device 201.

A dedicated device for generating seed mats can be used as the generating device 202 .

Also, the generation device 202 can be configured by, for example, a 3D printer.

FIG. 35 is a diagram showing an overview of the generating device 202 configured by a 3D printer.

In FIG. 35, the generating device 202 is configured by, for example, an inkjet 3D printer.

The 3D printer has a plurality of tanks, and each tank is filled with various materials such as seed mat materials m1 and m2, and seeds of various plant species such as plant species p1, p2, and p3.

The 3D printer discharges the material and seeds filled in the tank according to the design information to generate a seed mat.

For seed mats, it is necessary for the material discharged from the tank to maintain its mat-like (or sheet-like) shape. For example, the shape of the seed mat can be maintained in the material by mixing the material with an adhesive (adhesive substance) or by discharging the adhesive from a tank filled with the adhesive.

In addition, for example, by discharging the material so as to fill each cell of the base in which cells (small rooms) surrounded by mesh-like fibers are arranged in two dimensions, the material maintains the shape of the seed mat. can be

According to the manufacturing apparatus 200 as described above, it is possible to mass-produce seed mats according to design information.

Here, in this specification, the processing performed by the computer according to the program does not necessarily have to be performed in chronological order according to the order described as the flowchart. In other words, processing performed by a computer according to a program includes processing that is executed in parallel or individually (for example, parallel processing or processing by objects).

Also, the program may be processed by one computer (processor), or may be processed by a plurality of computers in a distributed manner. Furthermore, the program may be transferred to a remote computer and executed.

Furthermore, in this specification, a system means a set of multiple components (devices, modules (parts), etc.), and it does not matter whether all the components are in the same housing. Therefore, a plurality of devices housed in separate housings and connected via a network, and a single device housing a plurality of modules in one housing, are both systems. .

It should be noted that the embodiments of the present technology are not limited to the above-described embodiments, and various modifications are possible without departing from the gist of the present technology.

For example, this technology can take the configuration of cloud computing in which a single function is shared by multiple devices via a network and processed jointly.

In addition, each step described in the flowchart above can be executed by a single device, or can be shared by a plurality of devices.

Furthermore, if one step includes multiple processes, the multiple processes included in the one step can be executed by one device or shared by multiple devices.

In addition, the effects described in this specification are only examples and are not limited, and other effects may be provided.

In addition, this technology can take the following configuration.

<1>
a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. A program for making a computer function as an information processing device with a design department.
<2>
The program according to <1>, wherein the target plants are a plurality of plant species.
<3>
The program according to <1> or <2>, wherein the mat specifications include information on the material of the seed mat and the depth at which seeds are embedded in the seed mat.
<4>
The program according to any one of <1> to <3>, wherein the target plant and the germination time are set by a user.
<5>
For each germination time of the target plant, the design unit selects the mat specification for the germination time in which the required period of the plant species of the target plant is close to the germination time in the first correspondence relationship. The program according to any one of <1> to <4>, wherein the mat specification is determined and the design information representing the configuration of the seed mat in which the mat specification areas for each germination time of the target plant are arranged is generated. .
<6>
The design department
a second correspondence relationship between the environment in which the plant species are placed and the required period required for the seeds of the plant species placed in the environment to germinate;
<1> to <5>, using as the first correspondence relationship, a third correspondence relationship between the mat specification and the internal environment of the seed mat formed by the mat specification. A program as described in any of
<7>
The design department
The mat specification obtained by adding the climate information to the first correspondence relationship, and the climate information and the seed mat embedded in the seed mat when the seed mat is installed in a location with the climate represented by the climate information a fourth corresponding relationship with the necessary period required for germination of seeds of plant species;
The program according to any one of <1> to <5>, wherein the design information is generated according to the target plant, the germination time, and the climate of the place where the seed mat is installed.
<8>
The program according to <7>, wherein the design unit specifies climate information of a planned installation location where the seed mat is to be installed from position information of the planned installation location.
<9>
The program according to any one of <1> to <8>, wherein the design unit generates the design information according to the purpose of installing the seed mat set by the user.
<10>
The program according to <9>, wherein the design unit generates the design information according to a purpose set by the user regarding an ecosystem to be constructed by installing the seed mat.
<11>
If the purpose is to improve the diversity of the microbiota,
For each germination time of the target plant, the design unit selects from among a plurality of mat specifications in which the required period of the plant species of the target plant is close to the germination time, for different species of the target plant. The mat specification for forming an internal environment in which the microflora colonizes is determined to be the mat specification for the germination period, and the configuration of the seed mat in which areas of the mat specification for each germination period of the target plant are arranged. The program according to <10>, which generates design information.
<12>
The design department
It represents a planting plan including information on a plant species to be planted in a space with the seed mat as a bottom surface, information on a possible planting period in which the plant species can be planted, and information on a planting position for planting the plant species in the space. Using the plant species information included in the planting plan information as the target plant information,
using the information on the planting position included in the planting plan information as information on the embedding area for embedding the seeds of the target plant;
calculating the germination time of the target plant from the information on the plantable period included in the planting plan information;
For each embedding area, the mat specification having the required period close to the germination time of the target plant for embedding seeds in the embedding area is determined as the mat specification of the embedding area, and each embedding for which the mat specification is determined. The program according to any one of <1> to <11>, which generates the design information representing the configuration of the seed mat in which the areas are arranged at the positions represented by the information of the embedding areas.
<13>
The design unit determines, for each embedding area, that the required period is close to the germination time of the target plant whose seeds are to be embedded in the embedding area, according to information on the embedding area in which the seeds of the target plant are to be embedded in the seed mat. The mat specification is determined to be the mat specification of the embedding area, and the design information representing the configuration of the seed mat is generated in which each embedding area for which the mat specification is determined is arranged at the position indicated by the information of the embedding area. The program according to any one of <1> to <12>.
<14>
The program according to <13>, wherein the embedded area is set by a user.
<15>
The design unit configures the seed mat by arranging mat specification areas for each germination period of the target plant so that the distribution of plant species embedded with seeds in the seed mat is complicated. The program according to <5>, which generates information.
<16>
The program according to any one of <1> to <15>, wherein the design information is an image of a 3D model representing the configuration of the seed mat.
<17>
The program according to <16>, displaying the internal environment of the seed mat in the image of the 3D model.
<18>
a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. An information processing device having a design department.
<19>
a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. Information processing methods.
<20>
a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded, which is generated according to a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. manufacturing the seed mat according to the manufacturing method.

11 terminal, 12 server, 13 network, 21 positioning unit, 22 input/output unit, 22A display unit, 23 storage drive, 24 sensor unit, 25 calculation unit, 26 communication unit, 31 user I/F, 32 transmission unit, 33 reception Section, 34 Display Control Section, 41 Input/Output Section, 42 Storage Drive, 43 Communication Section, 44 Operation Section, 51 Database, 52 Design Section, 110 Window, 111, 112 Buttons, 120 Selection Window, 121 to 126 Buttons, 200 Manufacturing device, 201 conversion device, 202 generation device

Claims (20)

1. a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
   Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. A program for making a computer function as an information processing device with a design department.
2. The program according to claim 1, wherein the target plants are a plurality of plant species.
3. 2. The program according to claim 1, wherein the mat specification includes information on the material of the seed mat and information on the depth at which seeds are embedded in the seed mat.
4. The program according to claim 1, wherein the target plant and the germination time are set by a user.
5. For each germination time of the target plant, the design unit selects the mat specification for the germination time in which the required period of the plant species of the target plant is close to the germination time in the first correspondence relationship. 2. The program according to claim 1, wherein the design information representing the configuration of the seed mat in which the mat specification for each germination period of the target plant is arranged is determined.
6. The design department
   a second correspondence relationship between the environment in which the plant species are placed and the required period required for the seeds of the plant species placed in the environment to germinate;
   2. The program according to claim 1, wherein the design information is generated by using a third correspondence between the mat specification and the internal environment of the seed mat formed by the mat specification as the first correspondence. .
7. The design department
   The mat specification obtained by adding the climate information to the first correspondence relationship, and the climate information and the seed mat embedded in the seed mat when the seed mat is installed in a location with the climate represented by the climate information a fourth corresponding relationship with the necessary period required for germination of seeds of plant species;
   The program according to claim 1, wherein the design information is generated according to the target plant, the germination time, and the climate of the place where the seed mat is installed.
8. 8. The program according to claim 7, wherein the design unit identifies climate information of a planned installation location where the seed mat is to be installed from position information of the planned installation location.
9. 2. The program according to claim 1, wherein the design unit generates the design information according to a user-set purpose for installing the seed mat.
10. 10. The program according to claim 9, wherein the design unit generates the design information according to a purpose set by the user regarding an ecosystem to be constructed by installing the seed mat.
11. If the purpose is to improve the diversity of the microbiota,
    For each germination time of the target plant, the design unit selects from among a plurality of mat specifications in which the required period of the plant species of the target plant is close to the germination time, for different species of the target plant. The mat specification for forming an internal environment in which the microflora colonizes is determined to be the mat specification for the germination period, and the configuration of the seed mat in which areas of the mat specification for each germination period of the target plant are arranged. 11. The program according to claim 10, which generates design information.
12. The design department
    It represents a planting plan including information on a plant species to be planted in a space with the seed mat as a bottom surface, information on a possible planting period in which the plant species can be planted, and information on a planting position for planting the plant species in the space. Using the plant species information included in the planting plan information as the target plant information,
    using the information on the planting position included in the planting plan information as information on the embedding area for embedding the seeds of the target plant;
    calculating the germination time of the target plant from the information on the plantable period included in the planting plan information;
    For each embedding area, the mat specification having the required period close to the germination time of the target plant for embedding seeds in the embedding area is determined as the mat specification of the embedding area, and each embedding for which the mat specification is determined. 2. The program according to claim 1, which generates said design information representing a configuration of said seed mat in which areas are arranged at positions represented by information of said embedding area.
13. The design unit determines, for each embedding area, that the required period is close to the germination time of the target plant whose seeds are to be embedded in the embedding area, according to information on the embedding area in which the seeds of the target plant are to be embedded in the seed mat. The mat specification is determined to be the mat specification of the embedding area, and the design information representing the configuration of the seed mat is generated in which each embedding area for which the mat specification is determined is arranged at the position indicated by the information of the embedding area. The program according to claim 1.
14. 14. The program according to claim 13, wherein said embedded area is set by a user.
15. The design unit configures the seed mat by arranging mat specification areas for each germination period of the target plant so that the distribution of plant species embedded with seeds in the seed mat is complicated. 6. The program of claim 5, which generates information.
16. 2. The program according to claim 1, wherein said design information is an image of a 3D model representing the configuration of said seed mat.
17. 17. The program according to claim 16, wherein the internal environment of the seed mat is displayed in the image of the 3D model.
18. a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
    Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. An information processing device having a design department.
19. a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
    Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded is generated in accordance with a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. Information processing method.
20. a first correspondence relationship between the mat specification of the seed mat and the required period required for the seeds of the plant species embedded in the seed mat with the mat specification to germinate;
    Design information representing the configuration of the seed mat in which the seeds of the target plant are embedded, which is generated according to a target plant whose seeds are to be embedded in the seed mat and a germination time when the seeds of the target plant are to germinate. manufacturing the seed mat according to the manufacturing method.

Images