TWM483503U - Farm remote managing system - Google Patents

Abstract

The present creation provides a farm remote managing system, the present system is mainly composed of a farm end, a server end and an user end, by allowing the user to monitor and to control the plurality of interactive device remotely, one of the main features of the present creation is capable of improving the data presenting means by providing a graphical user Interface (GUI), moreover, the interacting functions of the present creation allows the user to experience and lead the process of irrigation, fertilization and illumination of the remote farm so as to achieve the goal of remote management of farm.

Description

Remote farm management system

This creation is about a remote farm management system, and in particular, this creation is about using an imaged interface to improve data presentation and allowing users to experience and dominate irrigation, fertilization, lighting, etc. through the web. Remote farm management system.

Most of the traditional leisure farms provide planned animal husbandry interactions to allow consumers to interact with nature for entertainment. In addition, some operators provide land rental and escrow services. After the consumers can rent the fields and designate the crops, the operators can farm and harvest at the harvest to enjoy the fun of a day farmer. In addition to this, there is also a model for recognizing the field, where the farmer will do the farming, and the crop house produced by the field will be allocated to the adopter and the like.

On the other hand, in addition to real agricultural products, games that use online programs to virtual farms, such as Happy Farm, can be found on the market. In the aforementioned happy farm game, the user can choose to plant various unused plants on the virtual agricultural land, and perform activities such as weeding, deworming, harvesting, and selling. At the same time, it also has to interact with other users on the Internet to observe, weed, deworm, harvest and other activities in other users' virtual farms.

In addition, some companies have combined the concepts of the two to develop a management system for a farmland, such as the Patent No. 099103080 of the Republic of China, which is an example of an integrated real-time screen monitoring system and far In the creation of the terminal instructions, the user can select the real field image obtained from the instant screen monitoring system to select his preferred field area and rent it for a specified period, such as two months. At the same time, the system itself will help the consumer to select the type of crop to be planted according to the specified period to ensure that the user can harvest before the end of the land lease period. After selecting the type of field and crop, the manufacturer will take care of the crops until the harvest, while the industry will continue to report the way the crops are treated to consumers. After the product is harvested, the consumer has to choose to hand over the crop to the processing manufacturer for processing before delivery. Designated store.

The above is the current state of the art of related art such as the remote farm system.

One of the scope of this creation is to provide a remote image farm system, which differs from the prior art in that the creation can be analyzed according to the state of the real crop (such as appearance) and various planting data and parameters. An imaged interface is used to represent the user so that the user can learn the state of the crop and its surrounding parameters by means of a finished, simplified pattern. For example, when the crop system is judged to be in the seedling stage by the system, the system displays a pattern of the seedlings to indicate the state of the crop, and at the same time, it also displays various patterns on the imaged interface, such as represented by a thermometer. Temperature, humidity, the color of the background represents the brightness of the farming area, and the weather state is represented by patterns such as the sun and clouds.

In addition, the difference from the conventional remote management system is that in addition to one-way observation, each user's account is assigned access and control rights of multiple monitoring devices. Users can use the graphical interface to manually control or access various monitoring devices around the crop, such as cameras, temperature and humidity photosensors, irrigation, fertilization, growth-assist illumination, and water switches. Grasp the growth status of crops and their corresponding parameters and adjust and control them so that users can dominate the entire planting process.

Furthermore, the system of the creation has a parameter green function. With a green program, the type of crop and various parameters will be recorded in the server for later use, and the user can obtain the aforementioned image. The interface is used to access and analyze the parameters. At the same time, another difference from the conventional system is that the system also has a transaction procedure, which provides a function of information, agricultural products exchange and transaction. Each user has to be served by the server or by the user. Inviting others to communicate or trade the growth status of crops and their corresponding parameters or even agricultural products, in addition to increasing interaction and fun, it also helps breeders pursue the goal of optimizing plant yield.

In summary, the system of the creation provides a management system with an image interface, which reduces the difficulty of reading data, and allows users to experience and dominate irrigation, fertilization, lighting, etc. through the network experience. The process, in addition, because the various parameters during planting will be automatically recorded green, so in addition to being limited by time, space, etc., to achieve the purpose of the network farmer In addition, the data quantification design of this creation will also be used as a remote breeding test or research.

The advantages and spirit of this creation can be further understood by the following detailed description of the creation and the drawings.

1‧‧‧Remote Farm Management System

10‧‧‧ Farm

11‧‧‧ farming area

12‧‧‧Monitor

13‧‧‧Command display device

14‧‧‧Regional Network Server

20‧‧‧Server side

30‧‧‧User side

31‧‧‧Imaged interface

311‧‧‧ seedlings schematic

312‧‧‧ Growing diagram

313‧‧‧Mature diagram

Figure 1 depicts a system diagram of the remote farm management system of the present invention in a preferred embodiment.

FIG. 2 depicts a system diagram of the remote farm management system of the present invention in another embodiment.

Figure 3 depicts a schematic diagram of the graphical interface of the present remote farm management system in the preferred embodiment.

Figure 4 depicts a functional block diagram of the remote farm management system of the present invention in the preferred embodiment.

Please refer to FIG. 1 , FIG. 3 and FIG. 4 . FIG. 1 is a schematic diagram of the system of the remote farm management system 1 of the present invention in a specific embodiment, and FIG. 3 depicts the remote farm management system of the present invention. A schematic diagram of an imaged interface in a preferred embodiment. Figure 4 depicts a functional block diagram of the remote farm management system of the present invention in the preferred embodiment.

As can be seen from the figure, the system 1 of the present invention is roughly composed of three parts: a farm end 10, a server end 20 and a user end 30. As a simple example, when the application is applied, the user has to rent or otherwise obtain a license for the farming section 11 to the system operator. At this point, the system operator will give the user a set of account numbers and passwords. The user can connect to the server terminal 20 through the Internet. After logging in through the group account and password, an image interface can be obtained. 31 (Graphical User Interface, GUI) accesses and acquires the usage rights of the respective monitoring devices 12 corresponding to the farming section 11, as depicted in FIG. At this time, the user has to select the crop to be planted and its state. After the determination, the request will be transmitted to the farm 10 via the server, and the operator of the farm 10 will follow the instruction displayed by the instruction display device 13. The user's request is to sow or to plant plants that have grown to a certain extent in the tilling section 11. However, the above-mentioned human work can also be replaced by a device such as an automatic tiller, a planter, a plant mobile vehicle or a combination thereof, and the devices are also connected to the network for being controlled by the user and being a monitoring device. One of the 12.

At the same time, various data of the farm terminal 10 will be synchronously transmitted to the server terminal 20, and the data is collected by the server terminal 20 and transmitted to the user terminal 30 so that the imagery interface 31 can be used for farming. The crops in section 11 are monitored and the monitoring device 12 is controlled as needed for remote control.

The components of this creation will be further explained below. Referring to FIG. 1, it can be seen that the farm end 10 of the present invention comprises a farming section 11 suitable for the growth of crops (or objects), a plurality of monitoring devices 12, and an instruction display device 13. In this example, the monitoring device 12 is capable of generating a corresponding monitoring data depending on the state of the crop or the farming section 11. In use, each user has access to or control over the monitoring device 12 in his farming section 11. The term crop mentioned above refers to various farming methods, such as soil cultivation, hydroponic cultivation and film cultivation, and various flower, fruit, rhizome and leafy crops. In addition, the crop carrier of this creation can also be used as a container. Separate.

On the other hand, the aforementioned monitoring device 12 is, but not limited to, an electronic thermometer and hygrometer, an electronic luminance meter, a plurality of network cameras (IP CAM), an electronically controlled fluid valve, a growth auxiliary light source, and the like. Either or a combination thereof, or other device not mentioned but monitored or controlled to perform specific actions on the farming section 11. Correspondingly, in this example, the monitoring data can be humidity, illuminance, brightness, water flow, fertilizer flow, optical image data captured by a webcam (still photos, video or live video streams), location of the device , rate, etc., or a combination thereof. In this example, each monitoring device 12 of the farm terminal 10 is separately connected to the server terminal 20, and after the aforementioned various monitoring data are generated, the monitoring data is automatically transmitted through the Internet or the regional network. The network connection means is transmitted to the server terminal 20. However, the creation is not limited to this. In the application, the monitoring data is first integrated by a regional network server 14 and then transmitted to the server terminal 20, as depicted in FIG. Do not impose more restrictions on this.

As described above, after receiving the monitoring data, the server terminal 20 initiates a green program to store the plurality of monitoring data, and the user can later use the image forming interface 31 to Access.

At the same time, the server terminal 20 also has to start an analysis program to automatically analyze the plurality of monitoring data to generate a corresponding imaged interface signal and transmit it to the server. The user terminal 30 is considered to be used later.

On the other hand, the user terminal 30 is connected to the server terminal 20 by a network connection, and the user terminal 30 obtains the imaged interface signal from the server terminal 20 by an image program. And converted into an image interface and displayed to the user by an image output program with an output interface 31. The output interface is referred to as a display screen in this example.

It is worth mentioning that the aforementioned server end 20 may include a network server, and the user terminal 30 may include a personal computer or an electronic device that is portable and accessible to the network. Such as laptops, tablets, smart phones, etc., for example. The aforementioned network server and various computers each have a storage device (hard disk or memory) and a central processing unit, the hard disk can store various data, data and programs, and the central processor is based on The program is used to perform the corresponding actions. Because the detailed methods of automatic storage and program execution should be non-new, in order to maintain the simplicity of this article, it will be omitted. The term "program" can be interpreted as a program, and data, values or data can be understood as various information contained or represented in a network transmission packet.

The above-mentioned imaged interface 31 refers to a user interface that combines a plurality of characters, lines, artwork, animation, or a combination thereof. However, the patterned interface of this creation is not limited to the artwork.

In addition, in the application, the designer also needs to add an image browsing program to the user terminal 30 for the user to browse the monitoring data through the imaging interface 31. For example, when the monitoring device 12 is a network. When the camera (IP CAM) and the monitoring data are optical image data, the user has to use the image browsing program to view the photos, videos or instant video streams captured by the aforementioned various network cameras (IP CAM).

Further, the user terminal further has a user control program stored in the user terminal 30 for the user to control the monitoring device 12 by using the imaging interface 31. Taking the monitoring device 12 as an image capturing device as an example, the user has to control the position, shooting angle, magnification or other basic optical parameters of the network camera (IP CAM) by using the imaging interface 31. Clearly observe the growth status of crops. Of course, when the monitoring device 12 includes at least one irrigation device adapted to irrigate the crop, the user terminal 30 can utilize the user control program to control the irrigation device by the imaging interface 31.

In addition to the foregoing functions, the foregoing analysis program further includes an image recognition subroutine adapted to analyze the at least one optical image data to determine the growth condition of the crop and output a crop condition data. Forming at least a portion of the imaged interface signal. That is, the server can obtain the status of the crop by image analysis, for example, when the color of the crop changes from green to red or the size and shape of the crop are changed from the appearance judgment, the server The image recognition subroutine will be identified and generate a corresponding crop condition data to allow the patterned interface of the user terminal 30 to be displayed.

For example, when the height of the crop is less than 10 cm, the image recognition subroutine will judge it as a seedling, and the information of the farm as a seedling is transmitted to the user end 30 by the crop condition data, and the user After obtaining the crop condition data, the end 30 will display a seedling map 311 in the patterned interface to represent the state of the crop. Correspondingly, when the height of the crop reaches 20 cm and 30 cm, the patterned interface will represent the state of the crop with a growing schematic 312 and a mature schematic 313.

Furthermore, in order to confirm the identity of the user, the user terminal 30 may store a user verification program and a verification data, and the verification program is adapted to obtain a user data from the user and compare it with the verification data. In order to determine the identity of the user, the user may obtain or be assigned the various materials in the corresponding monitoring device on the farm or the read, save or control of each monitoring device 12.

Finally, the server side 20 of the system stores a transaction program to provide a transaction function. The transaction program is adapted to store the user at the server terminal 20 or all or part of the monitoring data obtained instantaneously from the monitoring device 12 for access by another user. In addition, in addition to monitoring data, the access and control rights of the monitoring device 12 may also be partially or completely shared or transferred using the aforementioned transaction program. In addition to the access and control rights of the monitoring device 12, the user may also transfer part or all of the ownership of the crop. It should be noted that the term "transaction" as used above is not limited to the transaction of value, and it can also be traded free of charge. In this way, each user has to cooperate with the server terminal 20 or the user actively invites others to think about the growth parameters of the crop, the monitoring device 12 and the agricultural products, so as to increase the interaction and interest.

In summary, the system of the creation provides a management system with an image interface, which reduces the difficulty of reading data and allows users to experience and dominate the network. Irrigation, fertilization, lighting and other planting processes, in addition, because the various parameters during planting will be automatically recorded green, so free from time, space and other restrictions, and to achieve the purpose of the network farmers, the data of this creation Quantitative design will also be used as a remote breeding test or study.

The features and spirit of the present invention are more clearly described in the above detailed description of the preferred embodiments, and the scope of the present invention is not limited by the preferred embodiments disclosed herein. On the contrary, it is intended to cover all kinds of changes and equivalences within the scope of the patent application to which the present invention is intended. Therefore, the scope of the patent scope applied for in this creation should be interpreted broadly according to the above description so that it covers all possible changes and equivalence arrangements.

1‧‧‧Remote Farm Management System

10‧‧‧ Farm

12‧‧‧Monitor

13‧‧‧Command display device

20‧‧‧Server side

30‧‧‧User side

Claims (9)

A remote farm management system comprising: a farm end having a plurality of tilling sections each having a plurality of monitoring devices and planted with at least one crop, the plurality of monitoring devices being adapted to be based on the tilling interval or The state of the crop produces a corresponding monitoring data, each of the farming sections being respectively associated with a user authority, the user authority comprising access or control authority of the plurality of monitoring devices; a server end And the farm is coupled by a network connection, the server end storing: an analysis program, analyzing the plurality of monitoring data to generate a corresponding imaged interface signal; and using The server end is connected to the server end by a network connection, and the user end stores an image processing program, and the image interface signal is obtained from the server end and converted into an image interface. An image output program for displaying a graphical interface to a user via an output interface; and a user control program for the user to use the graphical interface Controlling the plurality of monitoring means. The remote farm management system of claim 1, wherein the server end includes a green program adapted to store the plurality of monitoring data, and the user can use the imaged interface. Access to the monitoring data. The remote farm management system of claim 2, wherein the server end stores a transaction program, the transaction program being adapted to control the data, the control authority of the monitoring device, part or all of The ownership of the crop is transferred or shared with another user. The remote farm management system of claim 1, wherein the plurality of monitoring devices comprise an image capturing device adapted to obtain an optical image data from the crop to be at least a portion of the monitoring data. At the same time, the analysis program of the server end includes an image recognition subroutine, and the image recognition subroutine is adapted to analyze the at least one optical image data to determine the growth condition of the crop and output a crop condition data to form The imaged interface signal is at least a portion of the signal. The remote farm management system of claim 1, wherein the image forming interface comprises a seedling schematic, a growing schematic or a mature schematic, the seedling schematic, the growing schematic or the mature schematic It corresponds to the state of the crop. The remote farm management system of claim 1, wherein the plurality of monitoring devices comprise an image capturing device adapted to obtain an optical image data from the crop to be at least a portion of the monitoring data. The optical image data system includes a still image. The image interface further stores an image browsing program for the user to browse the optical image data of the monitoring data through the image forming interface. The remote farm management system of claim 1, wherein the plurality of monitoring devices comprise an image capturing device adapted to obtain an optical image data from the crop to be at least a portion of the monitoring data. The optical image data system includes a video or an instant video stream, and the image forming interface further stores an image browsing program for the user to browse the optical image data of the monitoring data by using the image forming interface. . The remote farm management system as described in claim 1, wherein the plural The monitoring device comprises at least one irrigation device adapted to irrigate the crop, the user end further storing a user control program for the user to control the irrigation device by the image interface . The remote farm management system of claim 1, wherein the server end stores a user verification program and a verification data, the user verification program being adapted to be from the user via the user end A user data is obtained and compared with the verification data to determine the identity of the user to enable the user to obtain the user authority.