SYSTEM AND METHOD FOR CONTROL AND AUDIT OF CHEMICAL PRODUCTS APPLICATION MADE BY VEHICLES

Abstract

The present invention relates to a system for control and audit of chemical products application made by vehicles for the agriculture, pestilence, plague, or insects control, or other chemical applications in determined areas to receive these chemical products such the agrochemical application made by manned or unmanned vehicles, being these vehicles aerial, land or watercraft with the aim of treating soil and/or seeds and/or plants characterized by the system comprises a web server running an application; a database application; an internet communication method between the application cloud environment and its end users; desktop computers running web browsers; mobile devices to access the application through the internet; and a GPS device from where GPS files are collected by a device, being the GPS embedded in a vehicle where these files are used as input data for generating the final application reports which contains all detailed information about how much and in which areas (plots) the product was applied.

Description

TECHNICAL FIELD

The present invention relates to the field of chemical products application for the agriculture, pestilence, plague, or insects control, or other chemical applications in determined areas to receive these chemical products such the agrochemical application made by manned or unmanned vehicles, being these vehicles aerial, land or watercraft with the aim of treating soil and/or seeds and/or plants.

BACKGROUND OF THE INVENTION

Agricultural aviation is one of the possible applications of chemicals that has numerous advantages, such as: no contact with the ground, thus avoiding the kneading of culture and soil compaction; not cause stress in plants; early entry in the area, even after rain and immediate control of pests and diseases.

However, aerial application has its disadvantages, such as: disrespect to the contracted application range, causing the loss of efficiency of pesticides and exceeding the area limits; these limits when are not respected, can generate application on surrounding areas, permanent protection areas (APP), schools, water sources and others causing numerous losses to the environment, people and the producers.

The current application of chemicals made by tractors also presents problems with regard to failure to apply in relation to the area where the product should be applied and it was not applied by a tractor driver error and also problems with excess or lack of such chemical products application because such control is also made by the tractor driver.

Thus, both the land applications as the aerial applications of chemicals products used in agriculture, or even for the treatment and/or control pests in rural or urban areas, it is necessary to control both the vehicle's path used for the dump chemical product as well as the timing and amount of chemical product to be applied in a certain area.

The present system ensures that the land and the aerial space of the farm is traversed by the vehicle in the most efficient manner following an optimized predetermined path in opposition to a manual operation of an agricultural vehicle may result in gaps or the non-optimal use of fuel or agricultural materials.

SUMMARY OF THE INVENTION

One of the objectives of the invention is to provide a system and a method that identifies the following factors in the application of chemical products: what was the range of application used, if the limits of the pre-established application areas were respected, if applications were made duplicate, and if has applied the correct amount of product.

The system generates reports with all data above in hectares, thus allowing analyzing and quantifying the losses safely. When the report is generated to the producer, the system provides all exemplified data above. Another feature is the audit of the correct costs of the application of chemical products by means of vehicles in a certain area.

The system allows a clear and safe identification of the details of the losses arising from the misapplication of the chemical products, such as aerial and/or land applications of agrochemicals.

The system aims to solve the problem of product losses in the process of applying of chemical products in a certain area in a simply way.

The system allows the registration of companies that distribute products applied by air, land or water, the pilots (in the case of manned vehicles) and vehicles (such as aircraft) that provide services to the producer. It also allows the registration of all the plots of their georeferenced properties by importing GPS files of the vehicle responsible by distributing the agrochemical product.

Such system allows the monitoring of the distribution of chemical products by manned or unmanned land, aeronautical, or water vehicles, in rural or urban areas, as well as in forest areas.

The present system can also be applied in the application of seeds and any other products to being distributed by means of vehicles in a predetermined and georeferenced area.

The vehicle guidance system involves the reception of a position indication signal which allows a control unit on the vehicle to determine its position. Commonly, the position indication signal is taken from a Global Navigation Satellite System (GNSS) satellite based positioning system such as the American Global Positioning System (GPS) and/or the Russian GLONASS System and/or the European Galileo system signal or the more accurate differential satellite signal.

The system generates the application reports of chemical products based on files generated by GPS or similar system embedded in the vehicle. Thus, the report states in which plots the chemical product were applied, the products used and all the statistical results of the application.

The system performs hundreds of topographic calculations and displays the report ready in seconds allowing the producer to view the results on a computer screen, laptop, cell phone, palmtop, tablet, or any device that has remote access to the internet. This report can be saved or printed.

The system has the following features:

• • Application Management: through the system it is possible to have confidence that the product application range contracted by the producer was respected by the pilot and all the limits of the areas were respected;
  • Area and Cost control: The system provides an individual control for area informing, by report, which products were used, the costs of application and efficiency of the same;
  • Remote control: even if not present in the property, the producer receives notifications on your smartphone or any other mobile device with Internet access with the application report of these areas;
  • Control by property: regardless of the number of areas, the release of information in the system will be separated by properties or pre-established public areas enhancing the management of such areas;
  • Printed reports with QR-Code: the system allows printing reports with QR-Code that can be read by any smartphone or any other mobile device with internet access allowing access to the report in detail. Such reports can be provided with any technology that allows quick access to the information from the system; and
  • Corrective measures: These measures are generated by the vehicle's GPS (or similar device) during application thereby achieving images of the flight or path of the aquatic or terrestrial application, and if it detects any product application error in the established area, corrective measures can be taken remotely by the system.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows the overall system architecture of the first embodiment of the present invention.

FIG. 2 shows the system detailed report generation flow of the first embodiment of the present invention.

FIG. 3 shows the overall system architecture of the second embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The system described in the present invention was named as Perfect Flight system.

First Embodiment

Follows bellow a process overview of the use of the system in a first embodiment.

To use the Perfect Flight system, the user must follow some steps.

First, the raw GPS log files, of the embedded GPS in the vehicle, must be acquired from the GPS device. This can be done by using a flash drive directly connected to the device's USB port. The user must use the export function of the GPS embed system to copy the files to the flash drive. Once the files are available, it can be copied to the computer with internet access to the Perfect Flight system to make the transference of these files to the system.

The user must access the URL of the web system.

The user must provide his credentials (e-mail address and password) to login to the system.

The system will then check for the credentials and provide access in case it has been successfully validated.

Inside the web system, the user must register his application provider companies and its pilots/drivers.

Next, the user must register his farm properties or the area where the chemical product will be applied. Then the user can generate the application reports based on the GPS copied files through the Perfect Flight system.

The diagram shown in FIG. 1 related with a first embodiment of the present invention describes how the application works and its parts and how each part connect with the others.

There is a web server running the Perfect Flight application (1). This web server also provides file system storage for this application.

There is a database application (2) responsible for all the information used in this application. This database server can be running inside the same physical server (1) or in another one.

The internet (3) is the provided communication method between the Perfect Flight cloud environment and its end users. Other remote communication systems can be used such radio communication systems.

This application can be accessed by desktop computers (4) running web browsers. In this desktop (4) access it is possible to upload the GPS collected files containing all the information necessary to generate the final application report (7).

This application is also accessible by mobile devices (5) such as smartphones and tablets, but it has limited features since it is not possible to upload the GPS files directly from mobile devices. In this case, the user is able to view previously generated reports as well as other related information.

A GPS device from where GPS files (6) are collected by the device used in the application method. It may be generated by GPS embedded into agricultural aircrafts or tractors. These files are used as input data for generating the final application reports (7).

The final product of this process is the final application report (7), which contains all detailed information about how much product was applied and in which areas (plots) on the ground. It also contains a financial information about the relation between products/dosage/costs for this application.

The report also shows a success rate for the application. The report information's are: property name, pilot, aircraft, total costs, success costs, application's beginning/ending date and time, average application speed, application spray width, total traveled distance, total plots area, total application area, external application costs, application rate, overlap area, success area, external area, not covered area and success rate.

FIG. 2 is a detailed step by step chemical product application and report generation flow. It describes how all the needed information is gathered and how the calculations are made in order to generate the final report (7) that constitutes a method for control and audit the chemical products application made by a vehicle.

In the step (101) the process starts by a pre-processing routine to initialize the application variables.

In the step (102), the user is prompted to inform which plots this application was supposed to be done. Next, the system will load, from the desktop web application (4) to the Perfect Flight Application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files.

In the step (103), the application's sprays polygons are loaded from the GPS input files (6). The raw GPS log files, of the embedded GPS in the vehicle, is acquired from the GPS device by using a flash drive directly connected to the device's USB port and the user must use the export function of the GPS embed system to copy the files to the flash drive and after that the user upload the GPS input files (6) to the Perfect Flight Application (1) from the desktop web application (4).

In the step (104), the chemical product application traveled path is also loaded from the GPS input files (6).

In the step (105), the information about company, pilot/driver information are also collected by the user.

In the step (106), the list provided by the user containing each applied product, dosage and costs is also loaded into memory for the financial report.

In the step (107), with all needed information collected from the desktop web application (4) by the user and loaded into memory at the Perfect Flight Application (1), the system can now start processing the application report (7).

In the step (108), the application beginning/ending date and time are read from the GPS input files (6).

In the step (109), the application's average spray width is loaded from the GPS input files (6).

In the step (110), the vehicle traveled distance is calculated by the traveled path from the GPS input file (6).

In the step (111), the chemical product application's average speed is calculated based on the GPS input file (6).

In the step (112), the system generates a new polygon based on the union between all the applied plots informed by the user. This is the supposed goal target area for the application and all next calculations are done based on this resulting polygon.

In the step (113), the area in hectares is calculated for this resulting polygon.

In the step (114), the system also generates a new polygon resulting by the union between all chemical product application sprays.

In the step (115), the area of the resulting application spray polygon is calculated.

In the step (116), calculate the resulting polygon for the overlap application spray areas. The overlap area id caused when the application is done more than twice in the same region, causing waste of applied products.

In the step (117), calculate the resulting polygon of no application area. This indicates areas that were not covered by any spray application.

In the step (118), the system can now calculate the successfully applied polygon. This indicates areas inside the plots informed by the user that actually were covered by the application.

In the step (119), the external application polygon is calculated and indicates areas outside the plots indicated by the user. It also represents waste of applied products.

In the step (120), based on all the calculated area information, the system can now generate the financial report, which indicates the total cost of this application and the cost represented by the success and wasted areas, as well as the cost per applied hectare.

In the step (121), the final report (7) is now processed and ready to be delivered to the end user, even by desktop (4) or mobile (5) access.

In the step (122), the system will save this report into the application database (2) in order to reduce loading time the next time the user tries to review this report.

This is important, since the processing of the report involves heavy calculation.

In the step (123), a new identification hash code is generated for the report (7) and a QRCode is also created based on this hash code. The QRCode is displayed in the print form of the report (7). It is used to easily reopen the application report (7) in the computer (4) or mobile (5) device by simply reading the printed QRCode on the paper report (7). Reports can also be exported as PDF (Portable Document File) files for offline access outside the system.

In the step (124), all the resulting calculated polygons during the generation process are saved into application database (2) files in the server's file system. These files will be opened for later reviewing of the report (7).

In the step (125), the final calculated information is saved in the application database (2) which provides fast access to the most important information of the report (7) and also provides ease for the end user to find and filter generated reports.

Second Embodiment

Follows bellow a process overview of the use of the system in a second embodiment.

The difference between the first and the second embodiment is that on the first one the user input the data into the desktop web application (4), the pilot proceeds with the chemical product application into the plot area based on the georeferenced area that the user gave to the pilot, and, after the chemical product application the user get the GPS files (6) from the vehicle and upload it to the Perfect Flight application (1) to process and generates the final application report (7) with the audit results identifying if the pilot comply with the contracted about the area of application of the chemical product and the amount of product to be applied.

So, in the first embodiment of the present invention, the user will take providences after the application of the chemical products based on the audit of the vehicle GPS files (6) information.

In the second embodiment, the user will input the data into the desktop web application (4) that will transmit the information and parameters of the chemical product application pathway and amount of product to be delivered and the wide of the spray application to the Perfect Flight Application (1). The system will calculate the chemical product application plan and, by a remote communication system, will transmit the plan to the vehicle control unit (8) that will control the vehicle (9 to 12) actualizing its pathway plan based on the GPS embedded system. This vehicle could be manned or unmanned and its pathway will be remotely controlled by the vehicle control unit (8) that will control all the procedures of the chemical product application.

So, the second embodiment of the present invention control and correct the chemical product application in real time and remotely avoiding errors in the chemical product application.

The diagram shown in FIG. 3 related with a second embodiment of the present invention describes how the application works and its parts and how each part connect with the others.

There is a web server running the Perfect Flight application (1). This web server also provides file system storage for the application.

There is a database application (2) responsible for all the information used in this application. This database server can be running inside the same physical server (1) or in another one.

The internet (3) is the provided communication method between the Perfect Flight (1) cloud environment and its end users. Other remote communication systems can be used such radio communication systems.

This application can be accessed by desktop computers (4) or mobile devices (5) running web browsers. In this desktop (4) or mobile devices (5) access it is possible to upload the GPS collected (6) files containing all the information necessary to control the vehicle (9-12) and generate the final application report (7) through the vehicle control unit (8) that connects with the desktop (4) or mobile devices (5) by a remote communication system protocol.

A vehicle control unit (8) embedded in the vehicle (9-12) is responsible by the navigation of this vehicle and the control of the chemical product application. The vehicle control unit (8) uses the GPS device information to guarantee its geolocation and pathway that is real time informed to the Perfect Flight application (1) that monitor and adjust the vehicle position and pathway and the chemical product application procedure based in the data provided by the user.

GPS device from where GPS files (6) are collected by the vehicle control unit (8). It may be generated by GPS embedded into agricultural aircrafts (9), boats (10), tractors (11) or drones (12). These files are used as input data for generating the final application reports (7) and to guide the vehicle control unit in the vehicle pathway.

The final product of this process is the final application report (7), which contains all detailed information about how much product was applied and in which areas (plots) on the ground. It also contains a financial information about the relation between products/dosage/costs for this application.

The report also shows a success rate for the application. The report information's are: property name, pilot, aircraft, total costs, success costs, application's beginning/ending date and time, average application speed, application spray width, total traveled distance, total plots area, total application area, external application costs, application rate, overlap area, success area, external area, not covered area and success rate.

FIG. 4 is a detailed step by step chemical product application and report generation flow. It describes how all the needed information is gathered and how the calculations are made in order to manage the chemical product application by means a vehicle (9-12) and generate the final report (7) that constitutes a method for control and audit the chemical products application made by a vehicle.

To use the Perfect Flight system, in this second embodiment, the user must follow some steps.

First, step (301), the user, from desktop computers (4) or mobile devices (5), must access the Perfect Flight application (1) URL of the web system and provide his credentials (e-mail address and password) to login to the system. The system will then check, step (302), for the credentials and provide access in case it has been successfully validated or deny access backing to the previous step.

Inside the web system, step (303), the user must register his chemical product application provider companies and its pilots/drivers.

In the step (304), the user must register the georeferenced parameters of his farm properties or area where the chemical product will be applied detailing which plots the chemical product application have to be done. The system will load, from the desktop web application (4) to the Perfect Flight Application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files.

In the step (305), the user must register the list of each chemical product to be applied, dosage, spray width and rate, and costs.

In the step (306), the Perfect Flight application (1) calculates the chemical product application vehicle (9-12) pathway and its average speed.

In the step (307), the Perfect Flight application (1) sets the vehicle control unit (8) with the chemical product application parameters such application pathway, average speed, dosage, spray width and rate.

After all the chemical product application parameters be set the vehicle (9-12) is ready to begin the chemical product application, step (308).

Once initiated the application, in the step (309), the Perfect Flight application (1) monitor the GPS (6) information, by a pre-configured time, and, with this information, compare the vehicle (9-12) position with the application pathway calculated in the step (306).

If, step (310), the vehicle is going in the correct pathway, the vehicle (9-12) maintain its way, otherwise, the Perfect Flight application (1), step (311), send a command to the vehicle control unit (8) to correct the application pathway.

Based on the GPS (6) information, in the step (312), the Perfect Flight application (1) compare the chemical product application parameters that are being sprayed with the pre-set parameters from step (307).

If, step (313), the applications parameters that are being sprayed are not in accordance with the parameters established on step (307), the Perfect Flight application (1), in the step (314), will correct the application parameters to the parameters from step (307). Otherwise, will continue with the chemical product application.

Finally, in the step (315), the Perfect Flight application (1) compare the GPS (6) position information and check if the application pathway arrived to the end position.

If, step (316), the end position was achieved, the chemical product application is stopped and the vehicle (9-12) returns to the base, step (317), and the Perfect Flight application (1) process the steps (101) to (126) to generates the application report (7), otherwise, continue with the chemical product application.

Claims

1. SYSTEM FOR CONTROL AND AUDIT OF CHEMICAL PRODUCTS APPLICATION MADE BY VEHICLES characterized by the system comprises a web server running an application (1), this web server also provides file system storage for this application;a database application (2) responsible for all the information used in the application (1), where this database server (2) can be running inside the same physical server or in another one;an internet communication method (3) between the application (1) cloud environment and its end users;desktop computers (4) running web browsers where it is possible to upload the GPS collected files (6) containing all the information necessary to generate the final application report (7);mobile devices (5) to access the application (1) through the internet (3) where the user is able to view previously generated reports as well as other related information; and aGPS device from where GPS files (6) are collected by a device, being the GPS embedded in a vehicle where these files are used as input data for generating the final application reports (7) which contains all detailed information about how much and in which areas (plots) the product was applied, financial information about the relation between products/dosage/costs, success rate for the application, property name, pilot, aircraft, total costs, success costs, application's beginning/ending date and time, average application speed, application spray width, total traveled distance, total plots area, total application area, external application costs, application rate, overlap area, success area, external area, not covered area and success rate;wherein the system process starts, step (101), by a pre-processing routine to initialize the application variables;then, step (102), the user is prompted to inform which plots the chemical product application was supposed to be done; next, the system will load, from the desktop web application (4) to the application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files;the application's sprays polygons are loaded from the GPS input files (6), step (103), the raw GPS log files, of the embedded GPS in the vehicle, is acquired from the GPS device by using a flash drive directly connected to the device's USB port and the user must use the export function of the GPS embed system to copy the files to the flash drive and after that the user upload the GPS input files (6) to the application (1) from the desktop web application (4);the chemical product application, step (104), traveled path is also loaded from the GPS input files (6);the information, step (105), about company, pilot/driver information are also collected by the user;the list, step (106), provided by the user containing each applied product, dosage and costs is also loaded into memory for the financial report;with all needed information, step (107), collected from the desktop web application (4) by the user and loaded into memory at the application (1), the system can now start processing the application report (7);the application, step (108), beginning/ending date and time are read from the GPS input files (6);the application's average spray width, step (109), is loaded from the GPS input files (6);the vehicle traveled distance, step (110), is calculated by the traveled path from the GPS input file (6);the chemical product application's average speed, step (111), is calculated based on the GPS input file (6);the system generates, step (112), a new polygon based on the union between all the applied plots informed by the user, this is the supposed goal target area for the application and all next calculations are done based on this resulting polygon;the area in hectares, step (113), is calculated for this resulting polygon;the system also generates, step (114), a new polygon resulting by the union between all chemical product application sprays;the area, step (115), of the resulting application spray polygon is calculated;calculate, step (116), the resulting polygon for the overlap application spray areas, the overlap area id caused when the application is done more than twice in the same region, causing waste of applied products;calculate, step (117), the resulting polygon of no application area, this indicates areas that were not covered by any spray application;the system, step (118), can now calculate the successfully applied polygon, this indicates areas inside the plots informed by the user that actually were covered by the application;the external application polygon, step (119), is calculated and indicates areas outside the plots indicated by the user, it also represents waste of applied products;based on all the calculated area information, step (120), the system can now generate the financial report, which indicates the total cost of this application and the cost represented by the success and wasted areas, as well as the cost per applied hectare;the final report (7), step (121), is now processed and ready to be delivered to the end user, even by desktop (4) or mobile (5) access;the system, step (122), save this report into the application database (2) in order to reduce loading time the next time the user tries to review this report, this is important, since the processing of the report involves heavy calculation;a new identification hash code, step (123), is generated for the report (7) and a QRCode is also created based on this hash code, the QRCode is displayed in the print form of the report (7), it is used to easily reopen the application report (7) in the computer (4) or mobile (5) device by simply reading the printed QRCode on the paper report (7), reports can also be exported as PDF (Portable Document File) files for offline access outside the system;all the resulting calculated polygons, step (124), during the generation process are saved into application database (2) files in the server's file system, these files could be opened for later reviewing of the report (7);finally, the final calculated information, step (125), is saved in the application database (2) which provides fast access to the most important information of the report (7) and also provides ease for the end user to find and filter generated reports.

2. METHOD FOR CONTROL AND AUDIT OF CHEMICAL PRODUCTS APPLICATION MADE BY VEHICLES characterized by comprising the following steps step (101), starts by a pre-processing routine to initialize the application variables;step (102), inform which plots the chemical product application was supposed to be done; next, the system will load, from the desktop web application (4) to the application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files;step (103), load the application's sprays polygons from the GPS input files (6), the raw GPS log files, of the embedded GPS in the vehicle, is acquired from the GPS device by using a flash drive directly connected to the device's USB port and the user must use the export function of the GPS embed system to copy the files to the flash drive and after that the user upload the GPS input files (6) to the application (1) from the desktop web application (4);step (104), load from the GPS input files (6) the chemical product application and traveled path;step (105), collect the information about company, pilot/driver information;step (106), load, into memory for the financial report, the list provided by the user containing each applied product, dosage and costs;step (107), start processing the application report (7) with all needed information collected from the desktop web application (4) by the user and loaded into memory at the application (1);step (108), read, from the GPS input files (6), the application beginning/ending date and time;step (109), load, from the GPS input files (6), the application's average spray width;step (110), calculate the vehicle traveled distance by the traveled path from the GPS input file (6);step (111), calculate the chemical product application's average speed based on the GPS input file (6);step (112), generates, a new polygon based on the union between all the applied plots informed by the user that is the supposed goal target area for the application and all next calculations are done based on this resulting polygon;step (113), calculate the area in hectares for the resulting polygon from step (112);step (114), generates a new polygon resulting by the union between all chemical product application sprays;step (115), calculate the area of the resulting application spray polygon;step (116), calculate the resulting polygon for the overlap application spray areas;step (117), calculate the resulting polygon of no application area;step (118), calculate the successfully applied polygon;step (119), calculate the external application polygon;step (120), generate the financial report;step (121), process the final report (7);step (122), save the final report (7) into the application database (2);step (123), generate a new identification hash code and a QRCode based on this hash code for the report (7);step (124), save all the resulting calculated polygons into application database (2) files in the server's file system; and finallystep (125), save the final calculated information in the application database (2).

3. SYSTEM FOR CONTROL AND AUDIT OF CHEMICAL PRODUCTS APPLICATION MADE BY VEHICLES characterized by the system comprises a web server running an application (1), this web server also provides file system storage for the application;a database application (2) responsible for all the information used in this application, this database server can be running inside the same physical server (1) or in another one;an internet (3) communication method between the application (1) cloud environment and its end users;desktop computers (4) or mobile devices (5) running web browsers to access the application (1), in this desktop (4) or mobile devices (5) access it is possible to upload the GPS collected (6) files containing all the information necessary to control the vehicle (9-12) and generate the final application report (7) through the vehicle control unit (8) that connects with the desktop (4) or mobile devices (5) by a remote communication system protocol;a vehicle control unit (8) embedded in the vehicle (9-12) responsible by the navigation of this vehicle and the control of the chemical product application, and uses the GPS device information to guarantee its geolocation and pathway that is real time informed to the application (1) that monitor and adjust the vehicle position and pathway and the chemical product application procedure based in the data provided by the user;GPS device from where GPS files (6) are collected by the vehicle control unit (8), it may be generated by GPS embedded into agricultural aircrafts (9), boats (10), tractors (11) or drones (12), these files are used as input data for generating the final application reports (7) and to guide the vehicle control unit in the vehicle pathway;where the final product of this system is the final application report (7), which contains all detailed information about how much product was applied and in which areas (plots) on the ground, the financial information about the relation between products/dosage/costs for this application, the success rate for the application, and the report information's are: property name, pilot, aircraft, total costs, success costs, application's beginning/ending date and time, average application speed, application spray width, total traveled distance, total plots area, total application area, external application costs, application rate, overlap area, success area, external area, not covered area and success rate;wherein the system process starts at step (301), the user, from desktop computers (4) or mobile devices (5), must access the application (1) URL of the web system and provide his credentials (e-mail address and password) to login to the system;the system will then check, step (302), for the credentials and provide access in case it has been successfully validated or deny access backing to the previous step;inside the web system, step (303), the user must register his chemical product application provider companies and its pilots/drivers;the user, step (304), must register the georeferenced parameters of his farm properties or area where the chemical product will be applied detailing which plots the chemical product application have to be done, the system will load, from the desktop web application (4) to the application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files;the user, step (305), must register the list of each chemical product to be applied, dosage, spray width and rate, and costs;the application (1), step (306), calculates the chemical product application vehicle (9-12) pathway and its average speed;the application (1), step (307), sets the vehicle control unit (8) with the chemical product application parameters such application pathway, average speed, dosage, spray width and rate;after all the chemical product application parameters be set the vehicle (9-12) is ready to begin the application, step (308);once initiated the product application, step (309), the application (1) monitor the GPS (6) information, by a pre-configured time, and, with this information, compare the vehicle (9-12) position with the application pathway calculated in the step (306);if, step (310), the vehicle is going in the correct pathway, the vehicle (9-12) maintain its way, otherwise, the application (1), step (311), send a command to the vehicle control unit (8) to correct the application pathway;based on the GPS (6) information, in the step (312), the application (1) compare the chemical product application parameters that are being sprayed with the pre-set parameters from step (307);if, step (313), the applications parameters that are being sprayed are not in accordance with the parameters established on step (307), the application (1), in the step (314), will correct the application parameters to the parameters from step (307), otherwise, will continue with the application;finally, in the step (315), the application (1) compare the GPS (6) position information and check if the application pathway arrived to the end position;if, step (316), the end position was achieved, the chemical product application is stopped and the vehicle (9-12) returns to the base, step (317), and the application (1) process the steps (101) to (126) to generates the application report (7), otherwise, continue with the chemical product application.

4. METHOD FOR CONTROL AND AUDIT OF CHEMICAL PRODUCTS APPLICATION MADE BY VEHICLES characterized by comprising the following steps step (301), access the application (1) URL of the web system and provide user credentials (e-mail address and password) to login to the system from desktop computers (4) or mobile devices (5);step (302), check for the user credentials and provide access in case it has been successfully validated or deny access backing to the previous step;step (303), register the chemical product application provider companies and its pilots/drivers;step (304), register the georeferenced parameters of user farm properties or area where the chemical product will be applied detailing which plots the chemical product application have to be done, the system will load, from the desktop web application (4) to the application (1) through the internet (3), each plot polygon area, based on previously georeferenced imported files;step (305), register the user list of each chemical product to be applied, dosage, spray width and rate, and costs;step (306), calculates the chemical product application vehicle (9-12) pathway and its average speed;step (307), sets the vehicle control unit (8) with the chemical product application parameters such application pathway, average speed, dosage, spray width and rate;step (308), begin the chemical product application;step (309), monitor the GPS (6) information, by a pre-configured time, and, with this information, compare the vehicle (9-12) position with the application pathway calculated in the step (306);step (310), if the vehicle is going in the correct pathway, the vehicle (9-12) maintain its way, otherwise, the application (1), step (311), send a command to the vehicle control unit (8) to correct the application pathway;step (312), compare the chemical product application parameters that are being sprayed with the pre-set parameters based on the GPS (6) information from step (307);step (313), if the applications parameters that are being sprayed are not in accordance with the parameters established on step (307), the application (1), in the step (314), will correct the application parameters to the parameters from step (307), otherwise, will continue with the chemical product application;step (315), compare the GPS (6) position information and check if the application pathway arrived to the end position;step (316), if the end position was not achieved, continue with the chemical product application backing to step (309); otherwisestep (317), stop the chemical product application and returns the vehicle (9-12) to the base, and process the steps (101) to (126) to generate the application report (7).