JP2020014481A - Farm field information display system - Google Patents

Abstract

To specify a farm field sensor displayed on a portable terminal, and simply confirm farm field information.SOLUTION: A farm field information display system includes: a farm field sensor which acquires positional information of an installed position and information of an installed farm field, and transmits the positional information and the farm field information; a data center which receives the positional information and the farm field information from the farm field sensor, stores individual information of each farm field sensor while linking to the positional information and the farm field information, and is constituted so as to be capable of transmitting the individual information, the positional information and the farm field information of the linked farm field sensor; a portable terminal which acquires positional information of the present position and orientation information of a terminal, transmits the positional information, and receives the individual information, the positional information and the farm field information of the farm field sensor which are transmitted from the data center, in which a farm field sensor included in an image captured by an imaging device built in the portable terminal is specified on the basis of the positional information of the farm field sensor and the positional information of the portable terminal, and the orientation information, and farm field information acquired by the specified farm field sensor is displayed on a display device.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a system for acquiring information on a plurality of fields and displaying the results on a portable terminal.

  Conventionally, a field observation device that observes environmental information such as temperature, humidity, solar radiation, water level, and crop growth information in each field is installed, real-time measurement of field information is performed, and at the same time, each device installed in the field is installed. Field observation robots that perform control are known. For example, Patent Document 1 discloses a specific configuration of a field observation device.

  Further, a system has been constructed in which measurement data acquired by a plurality of field observation devices is transmitted to a management server via a network, and the management server collects the measurement data in real time and manages the data collectively. Remote monitoring is possible through this network.

JP-A-2005-220997

  Farming managers not only check field information through a monitoring system from a remote location, but also actually go to the field to visually check the soil status, crop growth status, pest occurrence status, etc. Patrol work is essential. During such patrol work, there is a demand for confirming the measured information on the field on the spot.

  However, when there are a plurality of fields and the field observation devices are installed by the number, even if the individual number of the field observation device and the installation position on the map data are known, the farming manager is in any field. Therefore, it is not easy to determine on the site which data of a field observation device should be confirmed. That is, at the site where the farming manager is located, which field observation device should be used to check the measurement data, it is difficult to understand the corresponding relationship, and the operation at the site when actually going to the field is troublesome. is there.

  The present invention is a system for acquiring and displaying information on a plurality of fields, a position information acquisition unit installed in each field and acquiring position information of the installation position, a detection for acquiring information on the installed field. Means, and a field sensor including a transmission unit that transmits the position information acquired by the position information acquisition unit and the field information acquired by the detection unit, and can receive the position information and the field information transmitted from the field sensor, A data center configured to be able to store the individual information of each field sensor in association with the position information and the field information, and to be able to transmit the individual information, the position information, and the field information of the associated field sensor; A receiver that obtains position information of a position, a direction sensor that detects the direction of the terminal, an imaging device, and a display device that displays an image captured by the imaging device; And a mobile terminal including a communication device that transmits the position information acquired by the receiver, and receives the individual information of the linked field sensor transmitted from the data center, the position information, and the field information. The field sensor included in the video captured by the imaging device of the portable terminal is specified based on the position information of the field sensor and the position information of the mobile terminal, and the output of the direction sensor. The acquired field information is displayed on a display device.

  According to the present invention, it is possible to easily confirm desired field information by grasping a positional relationship between the current position and the field and specifying a field sensor existing in a direction to be displayed on the mobile terminal.

FIG. 1 is a diagram showing a first embodiment of a field information display system. The figure which shows a field sensor. The figure which shows the data stored in a data center. The figure which shows a portable terminal. The chart figure of a field information display system. The figure which shows an example of the target field. The figure which shows an example of the display of field information. The figure which shows an example of the display of field information. The figure which shows an example of the display of field information. The figure which shows an example of the display of field information. The figure which shows 2nd embodiment of a field information display system. The chart figure of a field information display system. The figure which shows an example of the display of field information. The figure which shows 3rd embodiment of a field information display system. The figure which shows an example of the display of field information. The figure which shows 4th Embodiment of a field information display system.

[First embodiment]
The configuration of the field information display system 1 will be described with reference to FIGS. First, a schematic configuration of the system will be described with reference to FIG. The field information display system 1 includes a field sensor 10, a data center 20, and a mobile terminal 30.

  The field sensor 10 includes a GNSS receiver that obtains position information of the installation position, various measuring instruments that obtain field information such as water level, water temperature, water quality, temperature, humidity, and sunshine duration of the installed field, and position information and various A transmitter for transmitting data measured by the measuring device. The “position information of the installation position” is a value of latitude, longitude, and altitude at which the field sensor 10 is installed, and is acquired by receiving a signal from a GNSS satellite by a GNSS receiver. The field sensor 10 is provided with a power supply device for operating these devices. As the power supply device, a battery, a secondary battery, a solar battery, or the like is preferable.

  The field sensor 10 performs wireless data communication with the data center 20. The field sensor 10 transmits position information and measurement data to the data center 20 using wireless data communication via a network. The data center 20 includes a communication device that transmits and receives data by wireless data communication, a storage device that stores received data, and the like. On the data center 20 side, the individual information of the field sensor 10 (information specifying the source field sensor 10) is stored in association with the position information and the measurement data. The data center 20 functions as a management server that collectively manages data received from each field sensor 10.

  The mobile terminal 30 includes a GNSS receiver that acquires position information of the terminal, a sensor that detects the posture and orientation of the terminal, an imaging device, a display device, and a communication device that transmits and receives data by wireless data communication. The “terminal position information” is the values of the latitude, longitude, and altitude at the current position of the mobile terminal 30, and is acquired by receiving a signal from a GNSS satellite by a GNSS receiver. In addition, “terminal attitude” indicates a three-dimensional inclination of the terminal, and “terminal direction” indicates a shooting direction of the imaging device, and is detected by a gyro sensor, a geomagnetic sensor, an acceleration sensor, or the like. Is done. The mobile terminal 30 transmits to the data center 20 the information on the position and the orientation of the terminal by wireless data communication via a network.

  As described above, various data are transmitted from the field sensor 10 and the mobile terminal 30 to the data center 20. In the data center 20, the field sensor 10 existing within the shooting range of the imaging device of the mobile terminal 30 is specified based on the position information of the field sensor 10, the position information and the orientation information of the mobile terminal 30. Then, the data center 20 transmits to the mobile terminal 30 the position information on the specified field sensor 10 and the measurement data detected by the field sensor 10. The mobile terminal 30 displays field information (measurement data) on the display device according to the position information of the terminal and the position information of the field sensor 10 received from the data center 20.

  FIG. 2 shows an example of the field sensor 10. The field sensor 10 is installed in a field by embedding a leg in the field. The field sensor 10 includes various measuring devices for acquiring field information. The field sensor 10 includes a water level measuring instrument 11 for measuring the water level of the field, a water temperature measuring instrument 12 for measuring the water temperature of the field, a thermometer 13 for measuring the temperature of the field, a hygrometer 14 for measuring the humidity of the field, and position information. A GNSS receiver 15 for acquisition and a communication device 16 for performing wireless data communication are provided. In the present embodiment, the configuration is such that the water level, water temperature, temperature, and humidity of the field are measured.However, depending on the crop to be grown, the state of the target field, the timing, and the like, the content of the measurement is appropriately changed by changing the measuring device. It is also possible to select. For example, it is also possible to provide a sunshine meter to measure the sunshine duration or to provide a water quality meter to measure the water quality according to the crop to be grown.

  FIG. 3 shows an example of a data group stored in the data center 20. The storage device 21 of the data center 20 stores the individual information of the field sensor 10, the position information as the values of the latitude, longitude, and altitude of the installation position, and the measurement data (acquisition time, measurement value) acquired by the measuring device in each field. It is stored in a form corresponding to the sensor 10. That is, the storage device 21 stores the measurement data in time series by storing the measurement data acquired by each field sensor 10 as the acquisition time and the measurement value. By accumulating the measurement data in time series in this way, it is possible to use the data as data for estimating the growth status of the crop.

  FIG. 4 shows an example of the mobile terminal 30. The mobile terminal 30 includes a GNSS receiver 31 for acquiring position information of the terminal, a gyro sensor 32 for detecting the orientation and orientation of the terminal, an external camera 33 as an imaging device, a display 34 as a display device, and communication for performing wireless data communication. The device 35 includes an operation system and application software. In the present embodiment, an image photographed by the external camera 33 is displayed on the display 34 by application software installed in the mobile terminal 30, and desired information is displayed over the image.

  Next, an example of displaying field information on the portable terminal 30 will be described with reference to FIGS. FIG. 5 is a chart diagram of the field information display system 1. FIG. 6 is a diagram illustrating an example of a target field. FIG. 7 is a diagram illustrating an example of the field information display.

  The individual information and the position information of the field sensors 10 are transmitted from the respective field sensors 10 installed in the first to sixth fields to the data center 20 and received by the data center 20. Then, the field information measured by each field sensor 10 is transmitted to the data center 20 every predetermined time. The data center 20 stores the individual information of each field sensor 10 and the field information in association with each other. The interval at which measurement data is sent from the field sensor 10 to the data center 20 can be set as appropriate.

  Then, the position information and the attitude and orientation information of the terminal are transmitted from the portable terminal 30 to the data center 20. The data center 20 specifies a shooting range of the external camera 33 based on the position information and the attitude and orientation information of the mobile terminal 30. For example, the position of the mobile terminal 30 is specified by using the position information acquired by the GNSS receiver 31 on map data stored in advance in the storage device 21, and the external camera is determined from the detection result of the gyro sensor 32. It is calculated by specifying the shooting direction of 33 and the three-dimensional inclination of the mobile terminal 30. Next, the data center 20 specifies the field sensors 10 included in the specified shooting range. The individual information (field name where the field sensor is installed), the position information, and the field information of the field sensor 10 specified in this manner are transmitted to the mobile terminal 30.

  The mobile terminal 30 displays the received individual information of the field sensor 10 and the field information on the corresponding field sensor 10 in the video displayed on the display 34. Here, “overlapping display” means displaying information corresponding to the side of the appearance of the field sensor 10 displayed on the display 34, and displaying the field information on the display 34 in an overlay manner. Means

  As described above, according to the field information display system 1, the position and orientation of the mobile terminal 30 (that is, the current position of the user and the direction in which the mobile terminal 30 is facing) and the positional relationship between the field sensors 10 are determined. By changing the display on the display 34, the positional relationship between the current position and the field can be easily grasped, and the desired field information can be easily confirmed. Further, in the on-site patrol work, it is possible to compare the user's bodily sensation with accurate measurement data, thereby improving the patrol accuracy.

  As shown in FIG. 8, the data center 20 stores the measurement data acquired by the field sensor 10 in chronological order together with the acquisition time, so that the operation is performed on the application software side of the mobile terminal 30. Thus, the past data of the field sensor 10 can be requested and received from the data center 20, and the present measurement data and the past measurement data or the transition status of the measurement data from the past can be displayed simultaneously. In this way, by comparing the measurement data from the past relating to the crop growing situation with the actual growing situation by visual observation, it is possible to improve the persuasiveness of the field tour results.

  As a display mode of the display 34 in the mobile terminal 30, in addition to the display mode illustrated in FIG. 7, the display method illustrated in FIGS. 9 and 10 can be adopted.

  In the display method shown in FIG. 9, the individual information and the field information of the field sensor 10 displayed on the display 34 are large according to the distance from the mobile terminal 30 and small according to the distance. The display priority has been changed. In other words, when a plurality of field sensors 10 are included in the shooting range of the external camera 33, the field information of the field sensor 10 that is close to the mobile terminal 30 is displayed with priority. The distance from the mobile terminal 30 is determined based on the position information of the mobile terminal 30 and the position information of each field sensor 10. As described above, by preferentially displaying the field sensor 10 installed at a position close to the mobile terminal 30, the correspondence between the field sensor 10 and the field information can be more easily understood, and the work on site can be efficiently performed. It is possible to do.

  In the display method shown in FIGS. 9 and 10, map data indicating the positional relationship between the position of the portable terminal 30 (the current position of the user) and each field is displayed as a part of the video displayed on the display 34. Further, by superimposing and displaying the photographing range of the external camera 33 on the map data, the positional relationship between the current position and the field can be more easily understood. As the map data, data stored in the data center 20 may be used, or application software of the mobile terminal 30 may be used. As described above, by displaying the positional relationship between the current position and the field on the display 34 of the mobile terminal 30, the operability of the mobile terminal 30 can be improved, and the look-around efficiency can be improved.

[Second embodiment]
The configuration of the field information display system 2 will be described with reference to FIGS. The field information display system 2 includes a field sensor 10 and a mobile terminal 30. The difference between the field information display system 2 and the field information display system 1 is that a data center 20 as a management server is not included. In other words, in the field information display system 2, the portable terminal 30 and each field sensor 10 independently perform wireless data communication.

  Individual information and position information of the field sensor 10 are transmitted from the field sensors 10 installed in the first field to the sixth field to the mobile terminal 30 and received by the mobile terminal 30. Next, the mobile terminal 30 confirms its own position information and posture and orientation information, and specifies the shooting range of the external camera 33 from the position information and the posture and orientation information of the mobile terminal 30. Then, the field sensors 10 included in the specified shooting range are specified.

  The mobile terminal 30 sends a data transmission request to the specified field sensor 10. The field sensor 10 that has received the data transmission request transmits field information (measurement data) and individual information to the mobile terminal 30. The mobile terminal 30 displays the received individual information of the field sensor 10 and the field information on the corresponding field sensor 10 in the video displayed on the display 34.

  At this time, it is also possible to display, as a part of the image displayed on the display 34, map data indicating the positional relationship between the position of the mobile terminal 30 (the current position of the user) and each field. Further, by superimposing and displaying the photographing range of the external camera 33 on the map data, the positional relationship between the current position and the field can be more easily understood. As described above, by displaying the positional relationship between the current position and the field on the display 34 of the mobile terminal 30, the operability of the mobile terminal 30 can be improved, and the look-around efficiency can be improved.

  As described above, according to the field information display system 2, the position and orientation of the portable terminal 30 (that is, the current position of the user and the direction in which the portable terminal 30 is facing) and the positional relationship between the field sensors 10 are determined. By changing the display on the display 34, the positional relationship between the current position and the field can be easily grasped, and the desired field information can be easily confirmed. Further, in the on-site patrol work, it is possible to compare the user's bodily sensation with accurate measurement data, thereby improving the patrol accuracy.

  Further, by adopting a configuration in which data communication with the data center 20 is not performed as in the field information display system 1, wireless data using short-range communication between the field sensor 10 and the portable terminal 30 without using a network. Communication can be employed.

  Further, also in the field information display system 2, by accumulating the measurement data on the field sensor 10 side or the portable terminal 30 side, similarly to the field information display system 1, the current measurement data and the past measurement data or the measurement data are stored. It is also possible to simultaneously display the transition status of the data from the past. This makes it possible to improve the persuasiveness of the field inspection results by comparing the past measurement data relating to the crop growth status with the actual visual growth status.

[Third embodiment]
The configuration of the field information display system 3 will be described with reference to FIGS. The field information display system 2 includes a field sensor 10 and a mobile terminal 30. The difference between the field information display system 3 and the field information display system 1 is that a data center 20 as a management server is not included. Further, a difference between the field information display system 3 and the field information display system 2 is a display mode by application software of the mobile terminal 30.

  In the field information display system 3, the field sensor 10 located within a predetermined range is displayed on the display 34 based on the positional information and the orientation information of the mobile terminal 30 and the positional relationship guided by the position information of the field sensor 10. . That is, the position information of the field sensor 10 is acquired by the mobile terminal 30, and the field sensor 10 located within the predetermined range is specified based on the positional relationship between the position information and the orientation information of the terminal and the position information of the field sensor 10. Then, the field information of the field sensor 10 is displayed together with the positional relationship with the field sensor 10. Then, similarly, the received field information of the field sensor 10 is superimposed and displayed on the corresponding field sensor 10 in the image displayed on the display 34.

  As described above, according to the field information display system 3, the display on the display 34 changes according to the orientation and the position of the mobile terminal 30 and the positional relationship between the field sensors 10, and thus the current position and the position of the field The relationship can be grasped intuitively, and the desired field information can be easily confirmed. Further, in the on-site patrol work, it is possible to compare the user's bodily sensation with accurate measurement data, thereby improving the patrol accuracy.

[Fourth embodiment]
As shown in FIG. 16, in the field information display system 4, one of the field sensors 10 is configured as a management server such as the data center 20 of the field information display system 1. In this way, it is also possible to accumulate measurement data using one of the field sensors 10 as a server.

  1: field information display system, 10: field sensor, 20: data center, 30: portable terminal, 33: external camera (imaging device), 34: display (display device)

Claims (1)

A system for acquiring and displaying information on a plurality of fields,
Position information acquisition means installed in each field and acquiring position information of the installation position, detection means for acquiring information on the installed field, and position information acquired by the position information acquisition means and acquired by the detection means A field sensor comprising transmitting means for transmitting the obtained field information,
Position information and field information transmitted from the field sensor can be received, individual information of each field sensor can be stored in association with the position information and field information, and individual information and position of the linked field sensor can be stored. A data center configured to be able to transmit information and field information;
A receiver for acquiring the position information of the current position, an orientation sensor for detecting the orientation of the terminal, an imaging device and a display device for displaying an image captured by the imaging device, and transmitting the position information acquired by the receiver, and A portable terminal including a communication device that receives the individual information, the position information, and the field information of the linked field sensor transmitted from the data center,
A field sensor included in the video imaged by the imaging device of the mobile terminal, based on the position information of the field sensor and the position information of the mobile terminal, and based on the orientation sensor output,
A field information display system, wherein field information acquired by the specified field sensor is displayed on a display device.

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