JP6912828B2 - Agricultural work progress management device, agricultural work progress management system, agricultural work progress management method, and agricultural work progress management program - Google Patents

Description

The present invention relates to an agricultural work progress management device, an agricultural work progress management system, an agricultural work progress management method, and an agricultural work progress management program.

As disclosed in Patent Document 1, a server device for managing the positions of a plurality of agricultural machines each performing agricultural work and the progress of agricultural work in each of a plurality of fields is known.

By accessing the server device using the external terminal device, the user visually grasps the current position of the desired agricultural machine and the progress of the agricultural work in the desired field on the map. can do.

Japanese Unexamined Patent Publication No. 2016-12243

In the technique according to Patent Document 1, the driver who operates the agricultural machine needs to timely identify the progress of the agricultural work in the field and report the identified progress to the server device through a dedicated device. However, the work of identifying and reporting the progress of agricultural work is complicated and time-consuming for the driver.

An object of the present invention is to provide an agricultural work progress management device, an agricultural work progress management system, an agricultural work progress management method, and an agricultural work progress management program that can specify the progress of agricultural work without any trouble for the driver who operates the agricultural machine. To provide.

The agricultural work progress management device according to the present invention is
Data for repeatedly acquiring identification data for identifying the agricultural machine, position data indicating the current position of the agricultural machine, and exercise status data indicating the movement status of the agricultural machine from each of the plurality of agricultural machines. Acquisition method and
Whether or not the agricultural machine represented by the identification data exists in the field by using the position data each time the identification data, the position data, and the exercise status data are acquired by the data acquisition means. And, using the exercise status data, a discriminating means for discriminating whether or not the agricultural machine is in the agricultural work, and
Based on the number of times the agricultural machine is determined to be present in the field and the agricultural machine is in the field by the discriminating means, and the total amount of agricultural work index representing the size of the field. Progress identification means for identifying the progress of agricultural work in the field by agricultural machinery, and
When an inquiry about the progress of the agricultural work for which the identification data is specified is received from an external terminal device, the field where the agricultural work is performed by the agricultural machine represented by the identification data is specified by the progress specifying means. A data output means for outputting progress data indicating the progress to the external terminal device, and
To be equipped.

The maximum value included in the time series of the physical quantity of the acceleration of the agricultural machine depending on the sum of the magnitudes of the X-axis direction component, the Y-axis direction component, and the Z-axis direction component that are orthogonal to each other. May represent the difference between and the minimum value.

The frequency component included in the time series of the physical quantity in which the motion state data depends on the sum of the magnitudes of the X-axis direction component, the Y-axis direction component, and the Z-axis direction component that are orthogonal to each other in the acceleration of the agricultural machine. May represent.

The repetition cycle of acquisition of the identification data, the position data, and the exercise status data by the data acquisition means may be 5 minutes or more.

The agricultural work progress management system according to the present invention is
The above-mentioned agricultural work progress management device according to the present invention and
A measurement unit attached to each of the plurality of agricultural machines and outputting the identification data, the position data, and the exercise status data to the agricultural work progress management device.
The external terminal device that inquires about the progress of the farm work for which the identification data is specified to the farm work progress management device.
To be equipped.

The data output means of the agricultural work progress management device outputs the position data representing the current position of the agricultural machine represented by the identification data designated by the external terminal device to the external terminal device together with the progress data. By
In the external terminal device, the current position of the agricultural machine and the progress of the agricultural work in the field may be displayed in a form that can be visually grasped on the map.

The agricultural work progress management method according to the present invention is
The computer repeats identification data for identifying the agricultural machine, position data indicating the current position of the agricultural machine, and exercise status data indicating the motion status of the agricultural machine from each of the plurality of agricultural machines. Data acquisition steps to acquire and
Each time the computer acquires the identification data, the position data, and the exercise status data in the data acquisition step, the agricultural machine represented by the identification data exists in the field using the position data. A determination step for determining whether or not the agricultural machine is in the process of farming and using the exercise status data.
The computer is, in the determination step, the and agricultural machinery is present in said field, and a number of pesticidal industry machine is determined to be in farming and to the agricultural total index representing the width of該圃field Based on the progress specification step that specifies the progress of farm work in the field by the agricultural machine,
When the computer receives an inquiry about the progress of the agricultural work for which the identification data is specified from an external terminal device, the field in which the agricultural work is performed by the agricultural machine represented by the identification data is subjected to the progress identification step. A data output step for outputting the specified progress data representing the progress to the external terminal device, and
including.

The agricultural work progress management program according to the present invention is
On the computer
Data for repeatedly acquiring identification data for identifying the agricultural machine, position data indicating the current position of the agricultural machine, and exercise status data indicating the movement status of the agricultural machine from each of the plurality of agricultural machines. Acquisition function and
Whether or not the agricultural machine represented by the identification data exists in the field by using the position data each time the identification data, the position data, and the exercise status data are acquired by the data acquisition function. And using the exercise status data, a discrimination function that determines whether or not the agricultural machine is in the agricultural work, and
Based on the number of times the agricultural machine is determined to be present in the field and the agricultural machine is in the field by the discrimination function, and the total amount of agricultural work index representing the size of the field, the said. A progress specification function that specifies the progress of farm work in the field by the agricultural machine, and
When an inquiry about the progress of the agricultural work for which the identification data is specified is received from an external terminal device, the field where the agricultural work is performed by the agricultural machine represented by the identification data is specified by the progress specifying function. A data output function that outputs progress data indicating the progress to the external terminal device, and
To realize.

According to the present invention, the progress of the agricultural work is specified by using the identification data, the position data, and the exercise status data acquired from each of the plurality of agricultural machines, so that the driver who operates the agricultural machine can perform the progress of the agricultural work. No work is required to identify and report the degree. Therefore, it is possible to specify the progress of farm work without bothering the driver.

The conceptual diagram which shows the structure of the farm work progress management system which concerns on Embodiment 1. The conceptual diagram which shows the structure of the measuring apparatus which concerns on Embodiment 1. FIG. The conceptual diagram which shows the structure of the server apparatus which concerns on Embodiment 1. FIG. The conceptual diagram which shows the structure of the measurement data storage table which concerns on Embodiment 1. The conceptual diagram which shows the structure of the farm work progress management table which concerns on Embodiment 1. The conceptual diagram for demonstrating the agricultural work amount index which concerns on Embodiment 1. The conceptual diagram which shows the function of the server apparatus which concerns on Embodiment 1. FIG. The flowchart of the data acquisition process which concerns on Embodiment 1. The flowchart of the farm work progress management process which concerns on Embodiment 1. The flowchart of the data output processing which concerns on Embodiment 1. FIG. 6 is a conceptual diagram illustrating a display mode on a smartphone according to the first embodiment.

Hereinafter, the agricultural work progress management system according to the embodiment of the present invention will be described with reference to the drawings. In the figure, the same or corresponding parts are designated by the same reference numerals.

[Embodiment 1]
As shown in FIG. 1, the agricultural work progress management system 400 according to the present embodiment uses the measurement unit 100 attached to each of the plurality of agricultural machinery AMs and the measurement data DT acquired from each measurement unit 100. It includes a server device 200 as an agricultural work progress management device for grasping the progress of agricultural work by each agricultural machine AM, and a smartphone 300 as a plurality of external terminal devices that can access the server device 200.

The plurality of measurement units 100, the server device 200, and the plurality of smartphones 300 are communicably connected through the communication line NE. Each of the plurality of measurement units 100 is wirelessly connected to the communication line NE, and the measurement data DT is transmitted to the server device 200 via the radio. Each of the plurality of smartphones 300 is also wirelessly connected to the communication line NE, and the server device 200 can be accessed wirelessly.

Hereinafter, the configuration of each measurement unit 100 will be specifically described.

As shown in FIG. 2, each measurement unit 100 has a GPS (Global Positioning System) module 110. The GPS module 110 detects its position every moment by receiving radio waves from GPS satellites.

Further, the measurement unit 100 has an acceleration sensor 120 as a sensor for detecting the translational motion, the rotational motion, and the vibration of the agricultural machine AM. The acceleration sensor 120 is the sum of the magnitudes of _{the X-axis direction component α X} , the Y-axis direction component α _Y , and the Z-axis direction component α _Z of the acceleration of the agricultural machine AM to which the measurement unit 100 is attached. The dependent physical quantity, specifically, the square root of the sum of squares {(α _X ) ² + (α _Y ) ² + (α _Z ) ² } ^0.5 is detected every moment.

Further, the measurement unit 100 is shown in FIG. 1 in a predetermined repetition cycle (hereinafter, referred to as a measurement data transmission cycle) through the communication unit 130 connected to the communication line NE shown in FIG. 1 and the communication unit 130. It has a microcomputer 140 that transmits measurement data DT to the server device 200. The measurement data transmission cycle is 10 [minutes] in this embodiment.

The measurement data DT includes identification data DT1 registered in advance in the microcomputer 140, position data DT2 which is the detection result of the GPS module 110, and motion status data DT3 obtained by using the detection result of the acceleration sensor 120. included.

The identification data DT1 is an ID (identification) for identifying the agricultural machine AM to which the measuring unit 100 is attached from other agricultural machines AM. The position data DT2 represents the current position of the agricultural machine AM. The movement status data DT3 represents the status of the acceleration movement of the agricultural machine AM.

Hereinafter, the processing performed by the microcomputer 140 will be specifically described. The microcomputer 140 acquires the detection result of the acceleration sensor 120 over a predetermined measurement period less than the period length of the measurement data transmission cycle. Specifically, the measurement period is 1 [second], and the sampling frequency of the acceleration sensor 120 is 100 [1 / second] or more.

Next, the microcomputer 140 identifies the maximum value and the minimum value in the time series of the detection result of the acceleration sensor 120 over the measurement period. Next, the microcomputer 140 obtains a value obtained by subtracting the minimum value from the maximum value (hereinafter, referred to as an acceleration fluctuation range). This acceleration fluctuation range is used as the motion status data DT3.

As described above, the microcomputer 140 generates the motion status data DT3 representing the acceleration fluctuation width for each measurement data transmission cycle, and the generated motion status data DT3 is used together with the position data DT2 and the identification data DT1 in FIG. It is transmitted to the server device 200 shown in.

Next, the configuration of the server device 200 shown in FIG. 1 will be specifically described.

As shown in FIG. 3, the server device 200 includes a communication unit 210 connected to the communication line NE. The measurement data DT transmitted from the measurement unit 100 shown in FIG. 2 is taken into the server device 200 through the communication line NE and the communication unit 210.

Further, the server device 200 includes an auxiliary storage unit 220 as a storage means for storing the measurement data storage table 221 in which the measurement data DT is stored and the farm work progress management table 222 for managing the progress of the farm work.

As shown in FIG. 4A, the measurement data storage table 221 stores the item 221a in which the identification data DT1 for identifying the agricultural machine AM is stored in advance, and the date and time when the measurement data DT is acquired from the measurement unit 100 shown in FIG. It has an item 221b, an item 221c in which the position data DT2 included in the acquired measurement data DT is stored, and an item 221d in which the exercise status data DT3 included in the acquired measurement data DT is stored.

As shown in FIG. 4B, the agricultural work progress management table 222 identifies the item 222a in which the identification data for identifying the agricultural machine AM is stored in advance, and the geographical area of the field where the agricultural work is performed by the agricultural machine AM. Item 222b in which the field area identification data is stored in advance, item 222c in which the total amount of agricultural work index indicating the total amount of agricultural work required in the field is stored in advance, and the amount of agricultural work currently completed in the field. It has an item 222d in which a progress index representing the above is stored, and an item 222e in which the progress of agricultural work in the field is stored.

Hereinafter, the definitions of the total agricultural work index, the progress index, and the progress will be specifically described.

As shown in FIG. 5, the geographical area FA of the field (hereinafter referred to as the field area) FA can be regarded as a collection of a plurality of strip-shaped unit areas UA. Each unit area UA represents the area in which the agricultural machine AM shown in FIG. 1 finishes the agricultural work during the measurement data transmission cycle described above. Since the agricultural machine AM performs agricultural work while proceeding and the traveling speed of the agricultural machine AM is considered to be constant, the size of each unit area UA is equal.

Specifically, in the present embodiment, the agricultural machine AM is a harvester that cuts sugar cane as a crop while proceeding. Agricultural work refers to reaping. That is, the agricultural machine AM finishes cutting sugarcane in the unit region UA during the measurement data transmission cycle described above.

The total agricultural work index represents the number of unit areas UA required to cover the field area FA. That is, the total amount of agricultural work index depends on the size of the field area FA, and the total amount of agricultural work required to cut sugar cane over the entire field area FA is required to cut sugar cane in the unit area UA. Indicates how many times the amount of farm work (hereinafter referred to as unit farm work). The total agricultural work index is a fixed value for each field.

The progress index means how many times the amount of farm work currently completed in the field area FA is the unit farm work amount. The progress index is a value that can be updated for each measurement data transmission cycle. The value obtained by dividing the progress index by the total amount of farm work index represents the progress of farm work in the field.

Returning to FIG. 3, the explanation will be continued. The auxiliary storage unit 220 of the server device 200 also stores an agricultural work progress management program 223 that defines a processing procedure for specifying the progress of agricultural work by each agricultural machine AM shown in FIG.

Further, the server device 200 temporarily stores the CPU (Central Processing Unit) 230 that executes the farm work progress management program 223, the farm work progress management program 223, the measurement data DT, and the like when the CPU 230 executes the farm work progress management program 223. The main storage unit 240 is provided.

Hereinafter, the function of the server device 200 realized by the CPU 230 executing the farm work progress management program 223 will be specifically described.

As shown in FIG. 6, the CPU 230 repeats the measurement data DT including the above-mentioned identification data DT1, position data DT2, and exercise status data DT3 from each of the agricultural machinery AM shown in FIG. 1 at each measurement data transmission cycle. It has the function of the data acquisition unit 231 as the data acquisition means to acquire.

Each time the data acquisition unit 231 acquires the measurement data DT, the items 221b, 221c, and 221d of the measurement data storage table 221 shown in FIG. 4A are added.

Further, as shown in FIG. 6, the CPU 230 determines whether or not the agricultural machine AM exists in the field, and determines whether or not the agricultural machine AM is in the agricultural work. Has the function of.

The determination unit 234 determines whether or not the agricultural machine AM exists in the field by using the position data DT2 acquired by the data acquisition unit 231 and included in the measurement data DT stored in the measurement data storage table 221. It has a position determination unit 232.

Further, the discrimination unit 234 determines whether or not the agricultural machine AM is in the agricultural work by using the exercise status data DT3 acquired by the data acquisition unit 231 and included in the measurement data DT stored in the measurement data storage table 221. It also has an exercise state determination unit 233 for determining.

Further, the CPU 230 has a function of the progress specifying unit 235 as a progress specifying means for specifying the progress of the agricultural work by the agricultural machine AM. The progress determination unit 235 stores the progress index described above in the item 222d of the agricultural work progress management table 222 shown in FIG. 4B based on the determination results of the position determination unit 232 and the exercise state determination unit 233. To identify.

Further, the progress specification unit 235 calculates the progress of the agricultural work by dividing the specified progress index by the total agricultural work index stored in the item 222c of the agricultural work progress management table 222 shown in FIG. 4B. ..

Further, the CPU 230 has a function of a data output unit 236 as a data output means for transmitting / receiving data to / from the smartphone 300. The data output unit 236 receives an inquiry from the smartphone 300 about the progress of the agricultural work for which the identification data DT1 is specified.

Then, the data output unit 236 describes the progress data DP representing the progress calculated by the progress identification unit 235 and the position of the agricultural machine AM for the field where the agricultural work is performed by the agricultural machine AM represented by the identification data DT1. The position data DT2 representing the above is output to the smartphone 300.

Next, with reference to FIGS. 7A to 7C, the data acquisition process performed by the data acquisition unit 231, the agricultural work progress management process performed by the discrimination unit 234 and the progress identification unit 235, and the data output process performed by the data output unit 236 are specifically described. To explain.

Although data acquisition processing, agricultural work progress management processing, and data output processing are individually shown in FIGS. 7A to 7C for easy understanding, the CPU 230 is used for all the agricultural machinery AMs shown in FIG. Data acquisition processing, agricultural work progress management processing, and data output processing can be executed in parallel. Further, the CPU 230 can also execute the data acquisition process, the agricultural work progress management process, and the data output process for one agricultural machine AM in parallel.

With reference to FIG. 7A, first, the data acquisition process performed by the data acquisition unit 231 will be described. The data acquisition unit 231 determines whether or not the measurement data DT has been transmitted from the agricultural machine AM (step S11), and if the measurement data DT has not been transmitted (step S11; NO), returns to step S11. When the measurement data DT is transmitted from the agricultural machine AM (step S11; YES), the data acquisition unit 231 acquires the measurement data DT (step S12).

Note that this step S12 is an example of a data acquisition step of acquiring measurement data DT for each measurement data transmission cycle.

Then, the data acquisition unit 231 updates the measurement data storage table 221 shown in FIG. 4A every time the measurement data DT is acquired. Specifically, the data acquisition unit 231 first adds a line to be added by collating the identification data DT1 included in the acquired measurement data DT with the identification data stored in advance in item 221a of FIG. 4A. Identify.

Next, the data acquisition unit 231 enters the date and time when the measurement data DT was acquired in the item 221b of the specified line, stores the position data DT2 included in the measurement data DT in the item 221c, and stores the item. The exercise status data DT3 included in the measurement data DT is stored in 221d. In this way, the position data DT2 and the exercise status data DT3 are stored in association with each other.

When the measurement data storage table 221 is updated as described above, the process returns to step S11 again.

With reference to FIG. 7B, the farm work progress management process performed by the discrimination unit 234 and the progress identification unit 235 will be described next. In FIG. 7B, the progress index stored in the item 222d of the agricultural work progress management table 222 shown in FIG. 4B is represented by a variable N which is a natural number. It is assumed that the value of the variable N has been initialized to zero in advance.

The determination unit 234 determines whether or not the measurement data DT has been transmitted from the agricultural machine AM, that is, whether or not the measurement data storage table 221 shown in FIG. 4A has been updated by the data acquisition unit 231 (step S21), and the measurement is performed. If there is no data DT transmission (step S21; NO), the process returns to step S21.

On the other hand, when the measurement data DT is transmitted from the agricultural machine AM (step S21; YES), the position determination unit 232 uses the agricultural machine AM represented by the identification data DT1 included in the measurement data DT acquired by the data acquisition unit 231. Is present in the corresponding field (step S22).

Specifically, the position determination unit 232 displays the field area identification data corresponding to the identification data DT1 included in the measurement data DT acquired by the data acquisition unit 231 in the item 222b of the agricultural work progress management table 222 shown in FIG. 4B. Identify. Then, the position determination unit 232 is the current agricultural machine AM represented by the position data DT2 acquired by the data acquisition unit 231 and stored in the measurement data storage table 221 in the field area FA represented by the specified field area identification data. Determine if the position of is included.

When the current position of the agricultural machine AM is included in the field area FA, that is, when the agricultural machine AM exists in the corresponding field (step S22; YES), the agricultural work by the agricultural machine AM progresses. In order to check whether or not there is, the exercise state determination unit 233 determines whether or not the agricultural machine AM is in the agricultural work (step S23).

Specifically, the movement state determination unit 233 has the above-mentioned acceleration fluctuation width represented by the movement status data DT3 acquired by the data acquisition unit 231 and stored in the measurement data storage table 221 while the agricultural machine AM is stopped. It is determined whether or not the threshold indicating the existence is exceeded.

Here, "the agricultural machine AM is stopped" means that the running of the agricultural machine AM is stopped, and it does not matter whether the engine of the agricultural machine AM is stopped or not. When the engine is stopped for the measurement data transmission cycle, the acceleration fluctuation range is theoretically zero.

In addition, when the agricultural machine AM is stopped without performing agricultural work with the engine running over the measurement data transmission cycle, the agricultural machine AM vibrates, so that the acceleration fluctuation range can take a value exceeding zero. .. However, since the amplitude of the vibration is smaller than that in the case where the agricultural machine AM is performing the agricultural work while traveling, the value of the acceleration fluctuation width is also sufficiently small.

Therefore, when the acceleration fluctuation range represented by the exercise status data DT3 is equal to or less than the above threshold value as a predetermined upper limit value, it can be specified that the agricultural machine AM is stopped and therefore not in the agricultural work. Further, when the acceleration fluctuation range represented by the exercise status data DT3 exceeds the above threshold value, it can be specified that the agricultural machine AM is performing the agricultural work while traveling.

In steps S22 and S23 described above, a determination step of determining whether or not the agricultural machine AM exists in the field and whether or not the agricultural machine AM is in the agricultural work is performed for each measurement data transmission cycle. This is an example.

When the agricultural machine AM is in the agricultural work (step S23; YES), since the agricultural work by the agricultural machine AM is in progress, the progress identification unit 235 stores it in the item 222d of the agricultural work progress management table 222 shown in FIG. 4B. The progress index N is counted up (step S24). That is, the progress specifying unit 235 increases the value of the progress index N by 1.

As described above, in the progress index N, the position determination unit 232 determines that the agricultural machine AM exists in the field, and the exercise state determination unit 233 determines that the agricultural machine AM is in the agricultural work. Represents the number of times The progress identification unit 235 divides the progress index N by the total agricultural work index associated with the progress index N in the agricultural work progress management table 222, and stores the obtained numerical value as the progress in the item 222e. do.

In step S24, the progress of the agricultural work in the field by the agricultural machine AM is determined based on the number of times that the agricultural machine AM is present in the field and the agricultural machine AM is determined to be in the agricultural work. This is an example of the progress specification step to be specified.

Next, the progress determination unit 235 determines whether or not the time when the value of the progress index N should be reset (hereinafter referred to as the reset time) has arrived (step S25). Further, when the current position of the agricultural machine AM is not included in the field area FA in step S22 (step S22; NO), and when the agricultural machine AM is not in the agricultural work in step S23 (step S23; NO), agriculture Since the agricultural work by the machine AM has not progressed, the process proceeds to step S25 without counting up the progress index N.

Here, the "reset time" refers to the time between a typical harvest period of a crop and the next harvest period. Specifically, when sugarcane as a crop is harvested every year from December to April, the reset time refers to any time from May to November, for example, June 1.

If the reset time has come (step S25; YES), the progress identification unit 235 has already harvested the crops in this term and does not need to grasp the progress of the farm work, so that the next harvest period The progress index N is reset to zero in preparation for the above (step S26). If the reset time has not arrived (step S25; NO), or after the progress index N has been reset to zero in step S26, the process returns to step S21 again.

With reference to FIG. 7C, the data output process performed by the data output unit 236 will be described next. First, the data output unit 236 determines whether or not there is an inquiry about the progress of the farm work for which the identification data DT1 is specified from the smartphone 300 (step S31).

When the data output unit 236 receives an inquiry from the smartphone 300 (step S31; YES), the data output unit 236 indicates the progress of item 222e corresponding to the identification data DT1 specified by the smartphone 300 in the agricultural work progress management table 222 shown in FIG. 4B. , In the measurement data storage table 221 shown in FIG. 4A, the position data DT2 of the item 221c corresponding to the identification data DT1 designated by the smartphone 300 is specified. The position data DT2 referred to here refers to the data stored in the measurement data storage table 221 shown in FIG. 4A with the youngest data acquisition date and time shown in item 221b.

Then, the data output unit 236 outputs the progress data DP representing the progress and the position data DT2 to the smartphone 300 (step S32). That is, step S32 is an example of a data output step for outputting the progress data DP to the smartphone 300.

The smartphone 300 downloads the progress data DP and the position data DT2 from the server device 200. As a result, the current position of the agricultural machine AM and the progress of the agricultural work in the field are displayed on the smartphone 300.

FIG. 8 shows a display mode on the display unit 310 of the smartphone 300. The display unit 310 has a set of an icon 311a indicating the current position of the agricultural machine AM corresponding to the designated identification data DT1 and an icon 312a indicating the progress of the agricultural work in the field where the agricultural machine AM performs the agricultural work. It is displayed on the map.

The position of the agricultural machine AM indicated by the icon 311a is specified by the position data DT2 downloaded from the server device 200. The progress indicated by the icon 312a is specified by the progress data DP from the server device 200.

Further, the position of the field indicated by the icon 312a is specified by the identification data DT1 designated in the server device 200. That is, in the present embodiment, in the smartphone 300, it is assumed that the identification data DT1 and the geographical position of the field where the agricultural work is performed by the agricultural machine AM represented by the identification data DT1 are associated in advance.

However, the data output unit 236 may send the geographic data specifying the field area FA corresponding to the identification data DT1 designated by the smartphone 300 to the smartphone 300. In that case, the location of the field indicated by the icon 312a is specified by the geographical data.

Note that FIG. 8 assumes a case where three types of identification data DT1 are specified from the smartphone 300 to the server device 200. Therefore, a pair of an icon 311b indicating the current position of another agricultural machine AM and an icon 312b indicating the progress of agricultural work in the field where the agricultural machine AM performs agricultural work, and the current position of yet another agricultural machine AM. A set of the icon 311c indicating the above and the icon 312c indicating the progress of the agricultural work in the field where the agricultural machine AM performs the agricultural work is also displayed.

As described above, by accessing the server device 200 using the smartphone 300, the display unit 310 of the smartphone 300 shows the current position of each of the one or more agricultural machinery AMs and the agricultural work in each of the plurality of fields. The progress of is displayed in a form that can be visually grasped on the map.

According to the embodiment described above, the following effects can be obtained.

Since the server device 200 specifies the progress of the agricultural work using the measurement data DT acquired from each of the plurality of measurement units 100, the work of the driver who operates the agricultural machine AM identifies and reports the progress of the agricultural work. Not needed. Therefore, it is possible to specify the progress of farm work without bothering the driver.

Further, the server device 200 simplifies the progress of the agricultural work by determining whether or not the agricultural machine AM exists in the field and whether or not the agricultural machine AM is in the agricultural work in two stages. To specify. Moreover, the repetition cycle of such simple discrimination, that is, the measurement data transmission cycle is as long as 10 minutes. Therefore, the processing performed by the server device 200 can be simplified, and the load on the CPU 230 can be reduced. Further, since the measurement unit 100 may transmit the measurement data DT at a pace of once every 10 minutes, the burden on the microcomputer 140 is reduced.

In the present embodiment, the measurement data transmission cycle is set to 10 minutes, but the measurement data transmission cycle may be, for example, 5 minutes. Even in that case, the burden on the CPU 230 and the microcomputer 140 is reduced as compared with the case where the measurement data transmission cycle is, for example, several seconds.

Further, the data necessary for specifying the progress of the agricultural work in the server device 200 is the identification data DT1 for identifying the agricultural machine AM, the position data DT2 for indicating the position of the agricultural machine AM, and the motion status data DT3 for indicating the acceleration fluctuation range. Yes, there is no time series data in either case. Therefore, the amount of information of the measurement data DT transmitted from the measurement unit 100 to the server device 200 can be suppressed as compared with the case where a plurality of types of time series data are transmitted from the measurement unit 100 to the server device 200 in real time. Specifically, the measurement data DT can be suppressed to, for example, 12 bytes or less.

Further, in the server device 200, the data necessary for determining whether or not the agricultural machine AM is in the agricultural work is the exercise status data DT3. Then, only one acceleration sensor 120 is required to obtain the motion status data DT3. Therefore, apart from the GPS module 110, the communication unit 130, and the microcomputer 140, the state of the sensor for detecting the yield, the sensor for detecting the operation of the traveling clutch included in the agricultural machine AM, and the state of the threshing device provided in the agricultural machine AM. Compared with the case where a large number of sensors such as a detection sensor are attached to the agricultural machine AM, the complexity of the configuration of the agricultural machine AM can be suppressed.

Further, as described above, the acceleration sensor 120 depends on the sum of the magnitudes _{of the X-axis direction component α X} , the Y-axis direction component α _Y , and the Z-axis direction component α _{Z of the acceleration of the agricultural machine AM.} Detect physical quantities. The X-axis, Y-axis, and Z-axis are fixed to the acceleration sensor 120, and the acceleration sensor 120 has an X-axis direction component α _X , a Y-axis direction component α _Y , and a Z-axis direction component α _Z. Since the physical quantity depending on the sum of the sizes of each of the above is detected, it is not necessary to align the X-axis, the Y-axis, and the Z-axis with respect to the agricultural machine AM. That is, the detection result of the acceleration sensor 120 is unlikely to change regardless of the position and orientation of the acceleration sensor 120 attached to the agricultural machine AM. Therefore, it is easy to attach the measurement unit 100 of the agricultural machine AM.

[Embodiment 2]
In the first embodiment, the motion status data DT3 represents the acceleration fluctuation range which is the difference between the maximum value and the minimum value included in the time series of the acceleration magnitude of the agricultural machine AM. The motion status data DT3 is not particularly limited to the acceleration fluctuation range as long as it represents the motion status of the agricultural machine AM. Hereinafter, a specific example in which the motion status data DT3 represents a frequency component included in the time series of the magnitude of acceleration of the agricultural machine AM will be described.

In the present embodiment, the microcomputer 140 shown in FIG. 2 performs a fast Fourier transform on the time series of the detection results of the acceleration sensor 120 over the measurement period described above, and in the power spectrum waveform obtained by the fast Fourier transform. The peak frequency is obtained, and the peak frequency is transmitted to the server device 200 as motion status data DT3.

In step S23 of FIG. 7B, the exercise state determination unit 233 shown in FIG. 6 determines whether or not the peak frequency represented by the exercise status data DT3 exceeds the frequency threshold value indicating that the agricultural machine AM is stopped.

The peak frequency when the agricultural machine AM is stopped tends to be smaller than the peak frequency when the agricultural machine AM is running and performing agricultural work. Therefore, the exercise state determination unit 233 can identify that the agricultural machine AM is stopped and therefore not in the agricultural work when the peak frequency represented by the exercise status data DT3 is equal to or less than the predetermined frequency threshold value. Further, when the peak frequency represented by the exercise status data DT3 exceeds the above threshold value, it can be specified that the agricultural machine AM is performing the agricultural work while traveling.

Also in the second embodiment, the same effect as that of the first embodiment can be obtained. Since the fast Fourier transform is performed in the measurement unit 100, the amount of information in the motion status data DT3 can be significantly suppressed as compared with the case where the time series of the detection result of the acceleration sensor 120 is fast Fourier transformed in the server device 200.

The embodiment of the present invention has been described above. The present invention is not limited to this, and the modifications described below are also possible.

In the first embodiment, the case where the agricultural machine AM and the field where the agricultural machine AM performs the farm work correspond to 1: 1 is illustrated, but the agricultural machine AM and the field are not necessarily 1: 1. It does not have to be supported. When farming a plurality of fields with one agricultural machine AM, the server device 200 may specify the progress of the farming work for the field represented by the position data DT1 acquired from the measurement unit 100. Further, when a plurality of agricultural machinery AMs perform agricultural work in one field, the server device 200 sets the sum of the progresses of the agricultural work performed by each of the plurality of agricultural machinery AMs as the progress of the field. Just do it.

In the first embodiment, the case where the agricultural work is the cutting of agricultural products has been described, but the agricultural work may be harvesting, seeding, transplanting, fertilizer spraying, pesticide spraying, or the like. The agricultural machine AM is not limited to the harvester, and may be a tractor, a combine, a rice transplanter, or the like.

By installing the agricultural work progress management program 223 shown in FIG. 3 on a computer, the computer can function as the server device 200. The agricultural work progress management program 223 can be distributed through a communication line, or can be stored and distributed in a computer-readable recording medium such as an optical disk or a flash memory.

100 ... Measuring unit,
110 ... GPS module,
120 ... Accelerometer,
130 ... Communication Department,
140 ... Microcomputer,
200 ... Server device (agricultural work progress management device),
210 ... Communication Department,
220 ... Auxiliary storage,
221 ... Measurement data storage table,
221a-221d ... Item,
222 ... Agricultural work progress management table,
222a-222e ... Item,
223 ... Agricultural work progress management program,
230 ... CPU,
231 ... Data acquisition unit (data acquisition means),
232 ... Position determination unit,
233 ... Exercise state determination unit,
234 ... Discrimination unit (discrimination means),
235 ... Progress identification unit (progress identification means),
236 ... Data output unit (data output means),
240 ... Main memory,
300 ... Smartphone (external terminal device),
310 ... Display 311a-311c ... Icon indicating agricultural machinery,
312a-312c ... Icon showing the progress of farm work,
400 ... Agricultural work progress management system,
AM ... Agricultural machinery,
DP ... Progress data,
DT ... Measurement data,
DT1 ... Identification data,
DT2 ... Position data,
DT3 ... Exercise status data,
FA ... Field area,
NE ... Communication line,
UA ... Unit area.

Claims (8)

Data for repeatedly acquiring identification data for identifying the agricultural machine, position data indicating the current position of the agricultural machine, and exercise status data indicating the movement status of the agricultural machine from each of the plurality of agricultural machines. Acquisition method and
Whether or not the agricultural machine represented by the identification data exists in the field by using the position data each time the identification data, the position data, and the exercise status data are acquired by the data acquisition means. And, using the exercise status data, a discriminating means for discriminating whether or not the agricultural machine is in the agricultural work, and
Based on the number of times the agricultural machine is determined to be present in the field and the agricultural machine is in the field by the discriminating means, and the total amount of agricultural work index representing the size of the field. Progress identification means for identifying the progress of agricultural work in the field by agricultural machinery, and
When an inquiry about the progress of the agricultural work for which the identification data is specified is received from an external terminal device, the field where the agricultural work is performed by the agricultural machine represented by the identification data is specified by the progress specifying means. A data output means for outputting progress data indicating the progress to the external terminal device, and
Agricultural work progress management device equipped with. The maximum value included in the time series of the physical quantity of the acceleration of the agricultural machine depending on the sum of the magnitudes of the X-axis direction component, the Y-axis direction component, and the Z-axis direction component that are orthogonal to each other. Represents the difference between and the minimum value,
The agricultural work progress management device according to claim 1. The frequency component included in the time series of the physical quantity in which the motion state data depends on the sum of the magnitudes of the X-axis direction component, the Y-axis direction component, and the Z-axis direction component that are orthogonal to each other in the acceleration of the agricultural machine. Represents,
The agricultural work progress management device according to claim 1. The repetition cycle of acquisition of the identification data, the position data, and the exercise status data by the data acquisition means is 5 minutes or more.
The agricultural work progress management device according to any one of claims 1 to 3. The agricultural work progress management device according to any one of claims 1 to 4,
A measurement unit attached to each of the plurality of agricultural machines and outputting the identification data, the position data, and the exercise status data to the agricultural work progress management device.
The external terminal device that inquires about the progress of the farm work for which the identification data is specified to the farm work progress management device.
Agricultural work progress management system equipped with. The data output means of the agricultural work progress management device outputs the position data representing the current position of the agricultural machine represented by the identification data designated by the external terminal device to the external terminal device together with the progress data. By
In the external terminal device, the current position of the agricultural machine and the progress of the agricultural work in the field are displayed in a form that can be visually grasped on the map.
The agricultural work progress management system according to claim 5. The computer repeats identification data for identifying the agricultural machine, position data indicating the current position of the agricultural machine, and exercise status data indicating the motion status of the agricultural machine from each of the plurality of agricultural machines. Data acquisition steps to acquire and
Each time the computer acquires the identification data, the position data, and the exercise status data in the data acquisition step, the agricultural machine represented by the identification data exists in the field using the position data. A determination step for determining whether or not the agricultural machine is in the process of farming and using the exercise status data.
The computer is, in the determination step, the and agricultural machinery is present in said field, and a number of pesticidal industry machine is determined to be in farming and to the agricultural total index representing the width of該圃field Based on the progress specification step that specifies the progress of farm work in the field by the agricultural machine,
When the computer receives an inquiry about the progress of the agricultural work for which the identification data is specified from an external terminal device, the field in which the agricultural work is performed by the agricultural machine represented by the identification data is subjected to the progress identification step. A data output step for outputting the specified progress data representing the progress to the external terminal device, and
Agricultural work progress management method including. On the computer
Data for repeatedly acquiring identification data for identifying the agricultural machine, position data representing the current position of the agricultural machine, and exercise status data representing the movement status of the agricultural machine from each of the plurality of agricultural machines. Acquisition function and
Whether or not the agricultural machine represented by the identification data exists in the field by using the position data each time the identification data, the position data, and the exercise status data are acquired by the data acquisition function. And using the exercise status data, a discrimination function that determines whether or not the agricultural machine is in the agricultural work, and
Based on the number of times the agricultural machine is determined to be present in the field and the agricultural machine is in the field by the discrimination function, and the total amount of agricultural work index representing the size of the field, the said. A progress specification function that specifies the progress of farm work in the field by the agricultural machine, and
When an inquiry about the progress of the agricultural work for which the identification data is specified is received from an external terminal device, the field where the agricultural work is performed by the agricultural machine represented by the identification data is specified by the progress specifying function. A data output function that outputs progress data indicating the progress to the external terminal device, and
Agricultural work progress management program to realize.

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