EP2771860A2 - Agricultural and soil management - Google Patents
Agricultural and soil managementInfo
- Publication number
- EP2771860A2 EP2771860A2 EP12844020.3A EP12844020A EP2771860A2 EP 2771860 A2 EP2771860 A2 EP 2771860A2 EP 12844020 A EP12844020 A EP 12844020A EP 2771860 A2 EP2771860 A2 EP 2771860A2
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- European Patent Office
- Prior art keywords
- data
- crop
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- planted
- crop treatment
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q50/00—Information and communication technology [ICT] specially adapted for implementation of business processes of specific business sectors, e.g. utilities or tourism
- G06Q50/02—Agriculture; Fishing; Forestry; Mining
-
- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01B—SOIL WORKING IN AGRICULTURE OR FORESTRY; PARTS, DETAILS, OR ACCESSORIES OF AGRICULTURAL MACHINES OR IMPLEMENTS, IN GENERAL
- A01B79/00—Methods for working soil
- A01B79/005—Precision agriculture
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q10/00—Administration; Management
- G06Q10/06—Resources, workflows, human or project management; Enterprise or organisation planning; Enterprise or organisation modelling
- G06Q10/063—Operations research, analysis or management
- G06Q10/0637—Strategic management or analysis, e.g. setting a goal or target of an organisation; Planning actions based on goals; Analysis or evaluation of effectiveness of goals
- G06Q10/06375—Prediction of business process outcome or impact based on a proposed change
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A40/00—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production
- Y02A40/10—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production in agriculture
- Y02A40/22—Improving land use; Improving water use or availability; Controlling erosion
Definitions
- ALLOCATION CREDITS with attorney docket number TRMB-303 1 , and assigned to the assignee of the present patent application.
- a modern crop farm may be thought of as a complex biochemical factory optimized to produce corn, wheat, soybeans or countless other products, as efficiently as possible.
- the days of planting in spring and waiting until fall harvest to assess results are long gone. Instead, today's best farmers try to use all available data to monitor and promote plant growth throughout a growing season. farmers influence their crops through the application of fertilizers, growth regulators, harvest aids, fungicides, herbicides and pesticides.
- Precise crop monitoring - to help decide quantity, location and timing of field applications - has a profound effect on cost, crop yield and pollution.
- Normalized difference vegetative index (NDVI) is an example of a popular crop metric.
- NIR is around 770 nm
- VIS is around 660 nm.
- NDVI correlates well with biomass, plant height, nitrogen content or frost damage.
- a crop's yield potential is the best yield obtainable for a particular plant type in a particular field and climate.
- NDVI measurements on plants in other parts of the field are compared with those from the N-rich strip to see if more nitrogen is needed to help the field keep up with the strip.
- NDVI measurements may be obtained from various sensor platforms, each with inherent strengths and weaknesses.
- Aerial imaging such as satellite or atmospheric imaging can quickly generate NDVI maps that cover wide areas.
- satellites depend on the sun to illuminate their subjects and the sun is rarely, if ever, directly overhead a field when a satellite acquires an image. Satellite imagery is also affected by atmospheric phenomena such as clouds and haze. These effects lead to an unknown bias or offset in NDVI readings obtained by satellites or airplanes. Relative measurements within an image are useful, but comparisons between images, especially those taken under different conditions or at different times, may not be meaningful.
- GreenSeeke Ground based systems
- a GreenSeeker is an active sensor system that has its own light source that is scanned approximately one meter away from plant canopy. The light source is modulated to eliminate interference from ambient light. Visible and near-infrared reflectivity are measured from illumination that is scanned over a field.
- Ground-based sensors like the GreenSeeker can be mounted on tractors, spray booms or center-pivot irrigation booms to scan an entire field.
- GreenSeekers and other ground-based sensors may also be hand-held and, optionally, used with portable positioning and data collection devices such as laptop computers, portable digital assistants, smart phones or dedicated data controllers.
- Active, ground-based sensors provide absolute measurements that may be compared with other measurements obtained at different times, day or night. It does take time, however, to scan the sensors over fields of interest.
- FIG. 1 shows a schematic map of nine farm fields with management zones, according to various embodiments.
- Fig. 2 shows one of the fields of Fig. 1 in greater detail, according to various embodiments.
- FIG. 3 shows a schematic satellite image of the fields of Fig. 1 , according to various embodiments.
- Fig. 4 shows a block diagram of a wide-area field prescription system, according to various embodiments.
- Fig. 5 shows a block diagram of a method to combine satellite and ground data acquired at different times, according to various embodiments.
- FIGs. 6A and 6B show a schematic graph of NDVI data obtained at different times via different methods, according to various embodiments.
- Figure 7 is a block diagram of an example wide-area farming infomiation collection and dissemination network, according to various embodiments.
- Figure 8 is a block diagram of an example computer system with which or upon which various embodiments described herein may be implemented.
- Figure 9 illustrates a flow diagram of an example method of agricultural monitoring and prediction, according to various embodiments.
- Figure 10 is a block diagram of an example GNSS receiver used in accordance with one embodiment.
- Figure 1 1 illustrates a flow diagram of an example method of managing water erosion, according to various embodiments.
- Figure 12 illustrates a defined area and methods for collecting topographic data in accordance with various embodiments.
- Figure 13 is a block diagram of an example water erosion management system in accordance with one embodiment.
- Figure 14 illustrates an example crop treatment applicator in a planted field, in accordance with various embodiments.
- Figure 1 5 shows a schematic of nine farm fields, according to various embodiments.
- Figure 1 6 is a block diagram of an example crop treatment compatibility system, in accordance with various embodiments.
- Figures 1 7A- 1 7B illustrate a flow diagram of an example method of ensuring crop treatment compatibility, according to various embodiments.
- Figure 1 8 is an example diagram of a watershed area in accordance with various embodiments.
- Figure 1 9 is a block diagram showing examples of water allocation in accordance with various embodiments.
- Figure 20 is a flow diagram of an example method of exchanging water allocation credits in accordance with one embodiment.
- Figure 21 is a block diagram of an example crop characteristic estimation system, in accordance with various embodiments.
- Figure 22 illustrates an example estimated crop characteristic map for an unharvested field, according to one or more embodiments.
- Figure 23 illustrates an example of a harvest path generated for an unharvested field, according to one or more embodiments.
- Figures 24A, 24B, and 24C illustrate a flow diagram of an example method of crop characteristic estimation, according to various embodiments.
- the electronic computing device manipulates and transforms data represented as physical (electronic) quantities within the electronic computing device's processors, registers, and/or memories into other data similarly represented as physical quantities within the electronic computing device's memories, registers and/or other such information storage, processing, transmission, or/or display components of the electronic computing device or other electronic computing device(s). Under the direction of computer-readable instructions, the electronic computing device may carry out operations of one or more of the methods described herein.
- Section 1 describes wide-area agricultural monitoring and prediction.
- Section 2 describes water erosion management incorporating topography, soil type, and weather statistics.
- Section 3 describes aspects of crop treatment compatibility.
- Section 4 describes aspects of exchanging water allocation credits.
- Section 5 describes crop characteristic estimation.
- one or more items of information pertaining to a particular field or farm may be collected by one or more individuals and/or sensors and utilized by a farmer or other entity to make decisions related to: that field, crops planted in that field, one or more other fields, or crops planted in one or more other fields.
- Each section tends to focus on collection and/or use of a particular type or types of information. Although discussed independently, these various types of information are, in some embodiments, stored in various combinations with one another.
- an individual sensor, reporting source, and/or platform described herein may collect only a single item of information during a period of time or during conduct of a particular activity, while in other instances two or more items of information may be collected during single period of time or during conduct of a particular activity.
- a single type of collected information may be used in isolation or in a combination with one or more other types of collected information.
- Wide-area agricultural monitoring and prediction encompasses systems and methods to generate calibrated estimates of plant growth and corresponding field prescriptions.
- Data from ground and satellite based sensors are combined to obtain absolute, calibrated plant metrics, such as NDVI, over wide areas. Further inputs, such as soil, crop characteristics and climate data, are stored in a database.
- a processor uses the measured plant metrics and database information to create customized field prescription maps that show where, when and how much fertilizer, pesticide or other treatment should be applied to a field to maximize crop yield.
- Ground data are used to remove the unknown bias or offset of overhead aerial images thereby allowing images taken at different times to be compared with each other or calibrated to an absolute value.
- Soil, crop and climate data may also be stored as images or maps.
- the volume of data stored in the database can be quite large depending on the area of land covered and the spatial resolution. Simulations of plant growth may be run with plant and climate models to build scenarios such that a farmer can predict not just what may happen to his crops based on average assumptions, but also probabilities for outlying events.
- Fig. 1 shows a schematic map of nine farm fields. 101 . 102 ... 109, delineated by solid boundary lines. Dashed lines in the figure show the boundaries of field management zones which are labeled by circled numbers 1 , 2 and 3. Management zones are areas of common growing characteristics. Qualities that define a zone may include drainage, soil type, ground slope, naturally occurring nutrients, weed types, pests, etc. Regardless of how zones differ, plants within a zone tend to grow about the same. Targeted fertilizer application within a zone can help smooth out growth variation. Plants in different zones may require markedly different fertilizer prescriptions.
- Fig. 2 shows field 107 of Fig. 1 in greater detail.
- the field overlaps three management zones labeled by circled numbers 1 , 2 and 3.
- Path 205 shows the track that a ground-based NDVI scanner like a GreenSeeker takes as it measures plant growth in the field.
- Ground-based scanners can be deployed on tractors, spray trucks or other equipment and can be programmed to record data whenever the equipment moves over a growing area. (Groundbased scanners may also be hand-held and connected to portable data collection and/or positioning equipment.) Ground-based scanners are often used for real-time, variable-rate application, but because the scanners are automated, they can run any time, not just during fertilizer application. [0007] In Fig. 2.
- gray stripe 21 0 marks the location of an N-rich strip.
- the N-rich strip is an area where an excess of nitrogen fertilizer has been applied. Plant growth in the N-rich strip is not limited by the availability of nitrogen, so those plants exhibit the maximum yield potential of similar plants in the field. Because N-rich strips are useful for yield potential calculations, measurement of NDVI in an N-rich strip is often part of a real-time, variable-rate application procedure. N-rich strips are not always needed, however. The performance of the top 10% of plants in a representative part of a field may provide an adequate standard for maximum yield potential, for example.
- Fig. 3 shows a schematic satellite image of the fields of Fig. 1 .
- the area of land illustrated in Fig. 3 i the same as the area shown in Fig. 1 .
- the land in Fig. 3 has been divided into pixels (e.g., 301 , 302, 303, 304) similar to those that may be obtained by satellite imaging.
- Fig. 3 is drawn for purposes of illustration only; it is not to scale. Pixels in an actual satellite image may represent areas in the range of roughly 1 nr to roughly 100 nr.
- the resolution of today's satellite images is suitable for agricultural purposes; it is no longer a limiting factor as was the case several years ago.
- Scale 305 in Fig. 3 is a schematic representation of an NDVI scale. Darker pixels represent higher values of NDVI. Although only five relative NDVI levels are shown in Fig. 3, much higher precision is available from actual satellite images. Actual satellite images, however, do not provide absolute NDVI with the high accuracy available using ground-based sensors. Variations in lighting (i.e., position of the sun), atmospheric effects (e.g., clouds, haze, dust, rain, etc.), and satellite position all introduce biases and offsets that are difficult to quantify.
- NDVI measurements for the set of fields shown in Figs. 1 and 3 may be obtained by either ground or satellite sensors.
- Ground measurements provide absolute NDVI at high accuracy while satellite measurements provide relative NDVI over wide areas.
- the ground data may be used to resolve the unknown bias or offset in the satellite data.
- field 107 in Fig. 1 is measured by a GreenSeeker scan and fields 101 through 109 (including 107) are measured by satellite imaging, then overlapping ground and satel lite data for field 1 07 can be used to calibrate the satellite data for all of the fields.
- the accuracy of ground-based data has been extended to a wide area.
- times that are not too far apart ' ' are within a few days of one another; however, the actual maximum time difference for useful calibration depends on how fast plants are growing. Measurements must be closer together in time for fast-growing crops. Methods to estimate plant growth rate and extend the amount by which ground and satellite measurements can be separated in time are discussed below.
- Fig. 4 shows a block diagram of a wide-area field prescription system.
- ground data 405 and satellite data 41 0 are inputs to a database 429 and processor 430 (which may be part of a computer system).
- the output from the database and processor is a field prescription 435; i.e., a plan detailing how much chemical application is needed to optimize yield from a farm field.
- a field prescription may be visualized as a map showing when, where and how much fertilizer or pesticide is required on a field.
- the prescription may be used by an automated application system such as a spray truck with dynamically controllable spray nozzles.
- Soil data 41 5, crop data 420 and climate data 425 may also be inputs to the database 429 and processor 430 although not all of these data may be needed for every application. All of the data sources 405 through 425, and other data not shown, are georeferenced. Each data point (soil type, crop type, climate history, NDVI from various sources, etc.) is associated with a location specified in latitude and longitude or any other convenient mapping coordinate system. The various data may be supplied at different spatial resolution. Climate data, for example, is likely to have lower spatial resolution than soil type.
- Data inputs 405 through 425 are familiar to agronomists as inputs to plant yield potential algorithms.
- Database 429 and processor 430 are thus capable of generating wide-area field prescriptions based on any of several possible plant models and algorithms.
- the ability to run different hypothetical scenarios offers farmers a powerful tool to assess the risks and rewards of various fertilizer or pesticide application strategies. For example, a farmer might simulate the progress of one of his fields given rainfall and growing degree day scenarios representing average growing conditions and also growing conditions likely to occur only once every ten years. Furthermore, the farmer may send a ground-based NDVl sensor to scan small parts of just a few of his fields frequently, perhaps once a week, for example. These small data collection areas may then be used to calibrate satellite data covering a large farm. The resulting calibrated data provides the farmer with more precise estimates of future chemical needs and reduces crop yield uncertainty.
- Fig. 5 shows a block diagram of a method to combine satellite and ground data acquired at different times.
- ground data 505 e.g., NDVl obtained by a GreenSeeker.
- satellite data 510 are inputs to a plant growth model 515. Results from the model are used to generate an
- NDVl map 520 for any desired time. Most plants ' growth is described approximately by a sigmoid function; the part of the sigmoid of interest to farmers is the main growth phase which is approximately exponential. Furthermore, for data not separated too far in time, plants' exponential growth may be approximated by a linear growth model.
- Figs. 6 A and 6B show a schematic graph of NDVl data obtained at different times via different methods.
- Fig. 6A shows a schematic graph of NDVl data obtained at different times via different methods.
- NDVl is plotted versus time for a small area, for example a single data point in a farm field, or a small section of a field.
- NDVl measurements 605 and 610 are obtained by a ground-based system at times t
- Satellite-derived data point 614 has a bias or offset.
- the bias in data point 614 may be calculated by fitting line 620 to ground-derived data points 605 and 610.
- the result is that the actual NDVl measured by the satellite at time t 3 (for the specific ground area under consideration in Fig. 6A) is represented by data point 616, the value of the function represented by line 620 at t 3 .
- the longer the interval between t 2 and t 3 the less confidence may be placed in linear extrapolation 620.
- the result is likely more accurate than simply forcing data point 614 to have the same value as data point 61 0, for example.
- Fig. 6B The situation plotted in Fig. 6B is similar to that of Fig. 6A except for the order in which data is obtained.
- NDVI measurements 625 and 635 are obtained by a ground-based system at times t 4 and t 6 respectively, while NDVI measurement 628 is obtained from a satellite image at an intermediate time .
- Satellite-derived data point 628 has a bias or offset.
- the bias in data point 628 may be calculated by fitting line 640 to ground-derived data points 625 and 635.
- the result is that the actual NDVI measured by the satellite at time t 5 (for the specific ground area under consideration in Fig. 6B) is represented by data point 632, the value of the function represented by line 640 at t 5 .
- Figs. 6A and 6B have been described in a simplified scenario in which plant growth is assumed to be easily modeled as a function of time. However, it may be more realistic to express plant growth as a function of heat input, represented for example by growing degree days since planting. If the number of growing degree days per actual day does not change (an idealized and somewhat unlikely scenario), then plant growth versus time or heat input will have the same functional form. In general, the time axis in Figs. 6A and 6B may be replaced by a model which may include heat input, moisture, rainfall, sunlight intensity or other data that affect growth rate.
- Sparse spatial NDVI sampling may be sufficient to calibrate wide-area satellite data. More dense sampling is needed for smaller management zones which are often associated with more rapidly varying topography, while less dense sampling is sufficient for larger management zones which are often associated with flatter topography.
- Aerial images may be captured from a high altitude platforms, like satellites or high flying aircraft, such that a single overhead image encompasses all or a large portion of a designated geographic area. Aerial images may also be captured by low flying platforms such that a single overhead image encompasses only a small fraction of a designated geographic area.
- a crop duster flying less than 50 feet above a field may capture one or more (e.g., a series) of aerial images while applying a treatment, with a single image encompassing only a small portion of the geographic area of a field being treated, but an entire series of the captured images encompassing all or nearly all of the field being treated.
- arterial data comprises data obtained from one or more satellite, airplane, helicopter, balloon and UAV imaging platforms.
- ground-based data comprises data obtained from sensors that may be mounted on a truck, tractor or other vehicle or object that is land-bound, or that may be captured by a hand-held sensor or mobile device utilized by a human user.
- FIG. 7 is a block diagram of an example wide-area farming information collection and dissemination network 700, according to various embodiments.
- some aspects of network 700 may be utilized for monitoring and prediction (which includes synthesizing) as described herein.
- processor 430 and database 429 may be part of or coupled with a computer system 750.
- one or more reporting agents 710 (71 0- 1 to 710-n) report farming related information regarding multiple farms which are dispersed from one another over a wide area such as across one or more counties, states, countries, and/or continents.
- one or more mobile devices 701 communicate with database 429 and processor 430 via communication network 715.
- Each of mobile device(s) 701 is configured with a respective reporting agent 710- 1 disposed thereon for reporting farming related events and data to database 429 and processor 430.
- mobile device(s) 701 comprise handheld devices including, but not limited to, personal digital assistants (PDAs), cellular telephones, smart phones, laptop computers, digital notebooks, digital writing pads, or the like which are configured for permitting a user to enter, store, and/or transmit data.
- PDAs personal digital assistants
- the form factor of a mobile device is small enough that it is hand-holdable by a human user.
- mobile devices 701 are preconfigured with a GNSS (Global Navigation Satellite System) receiver, or may readily have one communicatively coupled thereto, for recording/reporting a position of the mobile device 701 .
- mobile device(s) 701 communicate with database 429 and processor 430 via a wireless communication network (e.g., 71 5).
- a wireless communication network e.g., 71 5
- mobile device(s) 701 can also communicate via a wired network, or a
- a reporting agent 710- 1 may comprise an application on a mobile device 701 , an item or hardware communicatively coupled with a mobile device 701 , or some combination.
- a single mobile device 701 may comprise multiple reporting agents 710- 1 .
- Reporting agent(s) 71 0- 1 can report user input data (such as by a farmer, agronomist, or other user) and/or report sensor data regarding a crop and/or field that may be provided by a sensor of or coupled with a mobile device 701 .
- network 700 additionally or alternatively comprises one or more vehicle monitor(s) 702 having respective reporting agents 710-2 disposed thereon. Vehicle monitor(s) 702 communicate with database 429 and processor 430 via communication network 71 5.
- vehicle monitor(s) 702 communicate with database 429 and processor 430 via a wireless communication network (e.g., 71 5), or can be coupled with a wired communication network, or a combination of wired and wireless communication links.
- vehicle monitor(s) 702 are disposed upon ground or aerial vehicles which are used for various operations in the planting, monitoring, and harvesting of crops. Examples of vehicles implementing vehicle monitor(s) 702, include, but are not limited to, tractors, trucks, harvesters, earthmoving equipment, airplanes, crop dusting aircraft, helicopters, balloons, un-manned aerial vehicles (UAVs), etc.
- a single vehicle or vehicle monitor 702 may comprise multiple reporting agents 710-2.
- reporting agent(s) 710-2 are coupled with or disposed as a part of a controller, or other data processing device disposed in a vehicle.
- a controller or other data processing device disposed in a vehicle.
- many tractors and harvesters utilize a GNSS receiver and controller for determining the position of the vehicle, navigation, recording, and guidance and vehicle control.
- reporting agent(s) 710-2 may be coupled with or disposed as a portion of the controller for the GNSS guidance and control of the vehicle.
- reporting agent(s) 710-2 are used to record and/or report the position, condition, or activity of the respective vehicle upon which is it disposed. This information can also be derived from equipment operated by, or coupled with a particular vehicle.
- Such equipment includes, but is not limited to, ploughs, sprayers, planters, earthmoving implements such as bulldozer blades or backhoe buckets, chemical storage tanks (e.g., of fertilizers, herbicides, fungicide, pesticides, etc.), or other implements which can be coupled with a vehicle.
- Reporting agent(s) 710-2 can also be used to report conditions of the vehicles with which they are coupled. This can include operating parameters of the vehicle's engine, the speed, location, and direction of travel of the vehicle, fuel status, identity of the vehicle's operator, etc.
- Reporting agent(s) 710-2 can also report data regarding a crop such as the moisture content of a harvested crop, the amount of crop harvested (e.g., being held in the grain tank of a harvester), or other data received from sensors coupled with the vehicle such as the NDVI levels described above.
- an operator of a vehicle can manually enter data which is conveyed by reporting agent(s) 710-2 such as the type of fertilizer, pesticide, herbicide, fungicide or other treatment being applied to a field, the crop varietal being planted, or other operation being performed such as NDVI monitoring of N-rich strip 21 0.
- network 700 additionally or alternatively comprises one or more fixed asset(s) 703 having respective reporting agents 710-3 disposed thereon.
- Fixed asset(s) 703 communicate with database 429 and processor 430 via communication network 715.
- fixed asset(s) 703 communicate with database 429 and processor 430 via a wireless communication network (e.g., 715), or can be coupled with a wired communication network, or a combination of wired and wireless communication links.
- fixed asset(s) 703 comprise devices for monitoring various events and/or conditions associated with an agricultural operation.
- fixed asset(s) 703 can comprise, but are not limited to, rainfall monitors, pump monitors, remote weather sensing stations, storage facilities (e.g., fuel, water, or chemical storage, storage of harvested crops, feed, seed, hay, etc.), water allocation monitors, or other devices used to measure and gather metrics of interest to an agricultural operation.
- a single fixed asset 703 may comprise multiple reporting agents 710-3.
- network 700 further additionally or alternatively comprises one or more computing devices (e.g., a personal computer (PC) such as PC 704) having respective reporting agents 710-4 disposed thereon.
- PC personal computer
- PC 704 In many agricultural operations, farmer uses PC 704 to enter data which they have collected. For example, many farmers collect data at their farm including, but not limited to, local weather conditions, treatments applied to fields such as fertilizers, pesticides, herbicides, fungicide, growth regulators, and harvest aids, crops planted, crop yields, fuel costs, equipment operational data, soil data, pest and disease infestations, and the like. Such information may be input via a PC 704 or even via a mobile device 701 .
- the farmers will use data analysis techniques to determine long-term patterns, or to predict future performance and/or yields based upon similar conditions in the past.
- some farmers perform a private soil analysis of their property in which soil samples are collected at regular intervals (e.g., every 100 meters) across their property and labeled to identify the location from which they were collected. The collected samples are then sent for analysis to determine the soil composition of the farmer ' s property and variations in the soil composition across the farmer's property. In so doing, the farmer can determine field management zones as shown above with reference to Figure 1. The granularity of determining the soil composition across the farmer's property is dependent upon the sampling interval used in the collection of soil samples.
- network 700 may additionally or alternatively include one or more reporting agents 710-n, other than those described above, which communicate with database 429 and processor 430 to provide user input or sensor collected farming information.
- fanners may be required to monitor and report the location and time when various applications such as fertilizers, herbicides, fungicides, pesticides, or other chemicals are applied to fields. Collection of information to support compliance and/or certification can be particularly important on and around organic farms. For example organic farming operations often have to monitor or limit application of chemicals in the vicinity of their fields by third parties such as other farmers and highway road crews. Often, the farmers do not own the application equipment themselves and pay a third party, such as a crop dusting company or farmer's cooperative to apply the treatments.
- the farmer, the third party, or some other party may utilize a reporting agent 71 0 to manually or automatically report application of fertilizers, herbicides, fungicide, pesticides, or other chemicals are applied to fields. Reporting of this data may be coupled with reporting of other data, such as position data and/or timestamp data.
- Other farming information monitored by fanners and reported via a reporting agent 710 may pertain to, but is not limited to, one or more of: water use, soil erosion, crop disease, insect management, weed management, and overall crop health.
- a reporting agent 710 may report manually input/sensed information regarding one or more of: how much water is drawn from a canal or underground aquifer at a particular location; the type and location of weeds in a field; the type, location, and level of infestation of insects in a field; the location and level of soil erosion in a field; and/or the type, location, and progression of a crop disease in a field. While farmers often collect this data for private use, it is not typically collected in a useful manner for distribution over a wider area.
- database 429 and processor 430 is also coupled with public data sources 730 via communication network 715. Examples of public data sources 730 include, but are not limited to. public agronomists, government agencies, research institutions, universities, commodities markets, equipment suppliers, vendors, or other entities that which collect or generate data of interest to agricultural operations.
- database 429 and processor 430 is also coupled with private data sources 740.
- private data sources 740 include private for-profit entities which collect and distribute data of interest to agricultural operations.
- private companies which distribute satellite imagery such as TerraServer® can be contracted for a fee.
- a farmer who has contracted with a private data source 740 can arrange to make that data available to database 429 and processor 430.
- an account with a private data source 740 can be made by the operator of database 429 and processor 430.
- Some other private sources include seed producing/vending companies, herbicide producing/vending companies, pesticide producing/vending companies, fungicide producing/fending companies, fertilizer producing/vending companies, and/or farmers cooperatives.
- mobile device(s) 701 , vehicle monitor(s) 702, and fixed asset(s) 703 can be coupled with PC 704 which in turn stores the data collected by these devices and forwards the data to database 429 and processor 430.
- one or more of mobile device(s) 701 , vehicle monitor(s) 702, and fixed asset(s) 703, and PC 704 are integrated into a network used by a farmer to monitor his respective agricultural operations.
- a wireless personal area network is used to communicate data between mobile device(s) 701 , vehicle monitor(s) 702, fixed asset(s) 703, and PC 704.
- data may also be transferred via a removable data storage device from a non-networked connected device to a networked device (e.g., a device communicatively coupled with network 71 5) and then to database 429 and processor 430 from the networked device. Data may also be transferred to database 429 and processor 430 when one of the devices (e.g., mobile device 701 ) is connected with a data transfer interface or docking station that is coupled with communication network 71 5.
- reporting agents 710- 1 . 710-2, and 710-3 are compliant with various software platforms.
- reporting agents 71 0- 1 may be compliant with the Java Platform, Micro-Edition (Java ME), the Windows Mobile® platform, or the like for facilitating the use of handheld devices to report data, conditions, and events pertinent to agricultural operations.
- a reporting agent 710 (710- 1 to 71 0-n) periodically determines whether data has been collected which is to be forwarded to database 429 and processor 430.
- a reporting agent 71 0 (710-1 to 710-n) can be manually configured by a user to indicate which types of data are to be conveyed to database 429 and processor 430, PC 704. or another entity, as well as a polling interval to determine how often to report this data.
- a reporting agent 710 (710-1 to 710-n) automatically forwards collected data when it is recorded. For example, when an operator of mobile device 701 records data and indicates that the data is to be saved, or forwarded, reporting agent 710- 1 will automatically forward the data to database 429 and processor 430. As discussed above, the data will forwarded via a wireless communication network (e.g., communication network 71 5). In accordance with various embodiments, a reporting agent 710 (710- 1 to 710-n) automatically appends additional data.
- a reporting agent 71 0 (710-1 to 710-n) automatically appends the position of the device in the message conveying collected data to database 429 and processor 430. Furthermore, a timestamp can be appended to each message when the message is sent.
- a reporting agent 710 initiates deleting data which has been transmitted to database 429 and processor 430 in response to a message indicating that the data has been received and stored in database 429.
- a reporting agent 710 determines whether communications with communication network 715 have been established and to automatically forward the data to database 429 and processor 430 when it has been determined that communications have been established. Until the confirmation message has been received, the data will be stored locally on the respective device which has collected it. It is noted that a reporting agent 710 (710- 1 to 710- n) reports data to PC 704 and the reporting agent 710-4 operating thereon as well.
- reporting agents 710- 1 , 71 0-2, and 710-3 will automatically forward collected data to PC 704 and automatically initiate deleting the data from their respective devices in response to a message from PC 704 confirming that the data has been received.
- Reporting agent 710-4 of PC 704 will then be responsible for forwarding the data to database 429 and processor 430 as described above.
- monitoring and prediction network 700 facilitates gathering, sorting, and distributing data relevant to agricultural operations based upon the participation of farmers over a wide area.
- the data collected by a farmer is typically used by that farmer, with the addition of information from public sources such as the Department of Agriculture, the National Weather Service, local agronomists, publ ished research articles, etc.
- data collected by an individual farmer may be utilized by another entity such as a farm product producer/vendor (e.g., a seed producer/vendor).
- a farm product producer/vendor e.g., a seed producer/vendor
- monitoring and prediction network 700 allows farmers, and other entities involved in agricultural operations, to gather, filter, and distribute data over a larger region in a timely manner.
- this information can be sent to database 429 and processor 430.
- a subscriber to the services provided by monitoring and prediction network 700 can determine whether his farm in danger of the infestation or disease and can take timely action such as applying treatments to the crops to prevent damage to his crops.
- a subscriber to monitoring and prediction network 700 can also participate in the distribution of goods, services, inventories, and commodities among other participants. For example, a fanner can report an excess, or shortage, of a commodity or resource to other participants in monitoring and prediction network 700.
- the data sent by reporting agents 710-1 , 710-2, 710-3, and 710-4 is stored in database 429.
- Aggregating agent 760 accesses database 429 and filters the data (which comprises data from numerous users across a wide area) for information which is relevant to a particular user and or a particular field.
- Such filtering may be based on one or more parameters, such as soil type, crop type, applied products (e.g., herbicide, pesticide, fungicide, and/or fertilizer) seed type, crop maturity, weather, etc.
- aggregating agent 760 automatically generates reports 770 of requested information and alerts 780 based upon predetermined parameters.
- aggregating agent 760 can filter data collected across a wide geographic area based on those parameters for the particular agricultural field which are input. Data across the wide geographic area which is acquired from other agricultural fields with common parameters to those input and filtered on are filtered out and aggregated into a report 760 that is relevant to particular agricultural field.
- parameters of a particular agricultural field e.g.. seed type, growing period, soil type, and weather for example
- aggregating agent 760 can filter data collected across a wide geographic area based on those parameters for the particular agricultural field which are input. Data across the wide geographic area which is acquired from other agricultural fields with common parameters to those input and filtered on are filtered out and aggregated into a report 760 that is relevant to particular agricultural field.
- a farmer in Kansas who enters parameters for an agricultural field in Hamilton county may receive a report which includes relevant data acquired from a first agricultural field in Hall county Louisiana (a neighboring county), relevant data acquired from a second agricultural field in Iowa (a neighboring state), and relevant data acquired from a third agricultural field in Argentina (a separate country has similar parameters but an opposite growing season).
- a farmer may apply a treatment to a field which is incompatible with crops in adjacent fields owned by other farmers.
- the treatment is carried by the wind to the neighboring farmer's fields, the neighbor's crops may be inadvertently killed off. This is especially problematic when crop dusting is used to apply treatments to fields as the potential for downwind distribution of chemicals to neighboring fields is greatly increased.
- the farmer applying the treatment to his field can enter the location of the field and the treatment being applied using, for example, reporting agent 710-2 disposed upon the vehicle applying the treatment. This information can be conveyed wirelessly using communication network 715 to database 429 and processor 430.
- database 429 and processor 430 When database 429 and processor 430 receives this information, it can access current weather conditions in the area, as well as what crops are being grown in that area, and determine if there is a danger that the treatment being applied is harmful to crops growing downwind or crops growing in the field which is being/about to be treated. If it is determined that there is a danger of downwind contamination or danger to the crop in the field being treated, aggregating agent 760 can generate an alert 780 which is conveyed to the farmer/third party applying the treatment to the field, to the vehicle applying the treatment if they are in different locations, and/or to any farmers downwind from the treatment whose crops may be affected. Additionally, alert 780 can be generated and received in real time so that the application of the treatment can be prevented from occurring.
- Figure 8 is a block diagram of an example computer system 750 with which or upon which various systems, networks, and/or method embodiments described herein may be implemented. With reference no to Figure 8, all or portions of some embodiments described herein are composed of computer-readable and computer-executable instructions that reside, for example, in computer-usable/computer-readable storage media of a computer system. That is, Figure 8 illustrates one example of a type of computer (computer system 750) that can be used in accordance with or to implement various embodiments which are discussed herein.
- Computer system 750 of Figure 8 is only an example and that embodiments as described herein can operate on or within a number of different computer systems including, but not limited to, general purpose networked computer systems, embedded computer systems, server devices, client devices, various intermediate devices/nodes, stand-alone computer systems, cloud computing systems, handheld computer systems, multi-media devices, and the like.
- Computer system 750 of Figure 8 is well adapted to having peripheral tangible computer- readable storage media 802 such as. for example, a floppy disk, a compact disc, digital versatile disc, other disc based storage, universal serial bus "thumb" drive, removable memory card, and the like coupled thereto.
- the tangible computer-readable storage media is non-transitory in nature.
- System 750 of Figure 8 includes an address/data bus 804 for communicating
- system 750 is also well suited to a multi-processor environment in which a plurality of processors 430A, 430B, and 430B are present. Conversely, system 750 is also well suited to having a single processor such as, for example, processor 430A. Processors 430A, 430B, and 430B may be any of various types of microprocessors. System 750 also includes data storage features such as a computer usable volatile memory 808, e.g., random access memory (RAM), coupled with bus 804 for storing information and instructions for processors 430A, 430B, and 430B.
- RAM random access memory
- System 750 also includes computer usable non-volatile memory 810, e.g., read only memory (ROM), coupled with bus 804 for storing static information and instructions for processors 430A, 430B, and 430B. Also present in system 750 is a data storage unit 812 (e.g., a magnetic or optical disk and disk drive) coupled with bus 804 for storing information and instructions. System 750 also includes an optional alphanumeric input device 8 14 including alphanumeric and function keys coupled with bus 804 for communicating information and command selections to processor 430A or processors 430A, 430B, and 430B.
- ROM read only memory
- System 750 also includes an optional cursor control device 816 coupled with bus 804 for communicating user input information and command selections to processor 43 OA or processors 430A, 430B, and 430B.
- system 750 also includes an optional display device 81 8 coupled with bus 804 for displaying information.
- optional display device 81 8 of Figure 8 may be a liquid crystal device, cathode ray tube, plasma display device or other display device suitable for creating graphic images and alphanumeric characters recognizable to a user.
- Optional cursor control device 816 allows the computer user to dynamically signal the movement of a visible symbol (cursor) on a display screen of display device 81 8 and indicate user selections of selectable items displayed on display device 818.
- cursor control device 816 are known in the art including a trackball, mouse, touch pad, joystick or special keys on alphanumeric input device 814 capable of signaling movement of a given direction or manner of displacement.
- a cursor can be directed and/or activated via input from alphanumeric input device 814 using special keys and key sequence commands.
- System 750 is also well suited to having a cursor directed by other means such as, for example, voice commands.
- System 750 also includes an I/O device 820 for coupling system 750 with external entities.
- I/O device 820 is a modem for enabling wired or wireless communications between system 750 and an external network such as. but not limited to, the Internet.
- a database 429, an operating system 822, applications 824, modules 826, and data 828 are shown as typically residing in one or some combination of computer usable volatile memory 808 (e.g., RAM), computer usable non-volatile memory 81 0 (e.g..
- ROM read-only memory
- data storage unit 812 data storage unit 812.
- all or portions of various embodiments described herein are stored, for example, as collected data in database 429, an application 824 and/or a module 826 in memory locations within RAM 808, computer-readable storage media within data storage unit 812, peripheral computer-readable storage media 802. and/or other tangible computer-readable storage media.
- aggregating agent 760 may be implemented as an application 824 which includes stored instructions for accessing database 429 and for controlling operation of computer system 750.
- FIG. 9 is a flow diagram 900 of an example method of agricultural monitoring and prediction, according to various embodiments. Although specific procedures are disclosed in flow diagram 900, embodiments are well suited to performing various other procedures or variations of the procedures recited in flow diagram 900. It is appreciated that the procedures in flow diagram 900 may be performed in an order different than presented, that not all of the procedures in flow diagram 900 may be performed, and that additional procedures to those illustrated and described may be performed. All of, or a portion of, the procedures described by flow diagram 900 can be implemented by a processor or computer system (e.g.. processor 430 and/or computer system 750) executing instructions which reside, for example, on computer- usable/readable media.
- a processor or computer system e.g. processor 430 and/or computer system 750
- the computer-usable media can be any kind of non-transitory storage that instructions can be stored on.
- Non-limiting examples of the computer-usable/readable media include but are not limited to a diskette, a compact disk (CD), a digital versatile device (DVD), read only memory (ROM), flash memory, and so on.
- aerial data is obtained.
- the obtained aerial data represents relative measurements of an agricultural metric in a particular geographic area.
- the aerial data and the relative measurements that it represents have an unknown bias.
- Such aerial data may be communicated from a reporting agent on an aerial platform (satellite, aircraft, etc.) or acquired from a stored location in a public data source 730 or private data source 740.
- ground-based data is obtained.
- the obtained ground-based data represents absolute measurements of the agricultural metric within the geographic area.
- the ground-based data may be obtained from a ground based reporting agent 710 which is coupled with a ground-based source (e.g., mobile device 701 , vehicle monitor 702, fixed asset 703, and/or PC 704).
- a ground-based source e.g., mobile device 701 , vehicle monitor 702, fixed asset 703, and/or PC 704
- the ground-based data is used to calibrate the aerial data, thereby synthesizing absolute measurements of the agricultural metric in parts of the geographic area from the aerial data.
- the ground-based data which is used overlaps w ith a portion of the aerial data and the delta between overlapping portions can be used to determine the bias of the aerial data and thus calibrate all of the aerial data.
- the synthesized absolute measurements are stored in a database with along with the ground-based data.
- other farming data is stored in the same database (or a communicatively coupled database).
- the other farming data is collected across a wide geographic area that is larger than the geographic area represented by the ground-based data and may be larger than the geographic area represented by the aerial data.
- the geographic area represented by the aerial data may represent a single field of 80 acres or perhaps several square miles, while the wide geographic area for which farming data has been collected may represent an entire county, several counties, a state, several states, a country, several countries, a continent, or multiple continents.
- the method of flow diagram 900 further includes filtering data collected across the wide geographic area based on attributes common with those of a particular agricultural field in order to generate a report relevant to the particular agricultural field.
- the synthesized absolute measurements may be for a particular field, and one or more parameters associated with the particular field or another field may be utilized to filter and aggregate relevant data (which shares one or more of these parameters) from various other, different agricultural fields across the wide geographic area represented by data stored in database 429.
- this filtering of data and aggregating it into a report 770 may be performed by aggregating agent 760.
- a report 770 may be presented in any of a variety of formats.
- a report 750 may spatially represent the aggregated data on a visual representation (e.g., a line drawing, map, or image) of the particular field.
- a report 770 may present aggregated data in a multi-column form such as with a latitude in first row of a first column, a longitude in a first row of a second column, and aggregated data associated with this latitude and longitude appearing in first rows of additional columns (with aggregated data for other coordinates similarly presented in a corresponding fashion in other respective rows of these columns).
- the method of flow diagram 900 further includes combining data representing the ground-based and synthesized absolute measurements with additional spatial agricultural data to generate a prescription for the application of chemicals to an agricultural field.
- a field prescription may be generated by processor 430 from data stored in database 429.
- Figure 10 shows an example GNSS receiver 1000 in accordance with one
- a GNSS receiver such as GNSS receiver 1000 may be coupled with or disposed as a portion of a reporting agent 710.
- received L I and L2 signals are generated by at least one GPS satellite. Each GPS satellite generates different signal L I and L2 signals and they are processed by different digital channel processors 1 052 which operate in the same way as one another.
- Antenna 1 032 may be a magnetically mountable model commercially available from Trimble Navigation of Sunnyvale, Calif.
- Master oscillator 1048 provides the reference oscillator which drives all other clocks in the system.
- Frequency synthesizer 1038 takes the output of master oscillator 1048 and generates important clock and local oscillator frequencies used throughout the system. For example, in one embodiment, frequency synthesizer 1038 generates several timing signals such as a 1 st (local oscillator) signal LO l at 1400 MHz, a 2nd local oscillator signal L02 at 1 75 MHz, an SCLK (sampling clock) signal at 25 MHz, and a MSEC (millisecond) signal used by the system as a measurement of local reference time.
- 1 st local oscillator
- L02 2nd local oscillator signal
- SCLK sampling clock
- MSEC millisecond
- a filter/LNA (Low Noise Amplifier) 1 034 performs filtering and low noise
- the downconvertor 1 036 mixes both L I and L2 signals in frequency down to approximately 1 75 MHz and outputs the analogue LI and L2 signals into an IF (intermediate frequency) processor 1050.
- I F processor 1050 takes the analog L I and L2 signals at approximately 175 MHz and converts them into digitally sampled L I and L2 inphase (LI I and L2 1) and quadrature signals (L I Q and L2 Q) at carrier frequencies 420 KHz for L I and at 2.6 MHz for L2 signals respectively.
- At least one digital channel processor 1052 inputs the digitally sampled L I and L2 inphase and quadrature signals. All digital channel processors 1052 are typically are identical by design and typically operate on identical input samples. Each digital channel processor 1052 is designed to digitally track the L I and L2 signals produced by one satellite by tracking code and carrier signals and to from code and carrier phase measurements in conjunction with the microprocessor system 1 054. One digital channel processor 1052 is capable of tracking one satellite in both LI and L2 channels.
- Microprocessor system 1054 is a general purpose computing device which facilitates tracking and measurements processes, providing pseudorange and carrier phase measurements for a navigation processor 1058. In one embodiment, microprocessor system 1054 provides signals to control the operation of one or more digital channel processors 1052.
- Navigation processor 1058 performs the higher level function of combining measurements in such a way as to produce position, velocity and time information for the differential and surveying functions.
- Storage 1060 is coupled with navigation processor 1058 and microprocessor system 1054. It is appreciated that storage 1060 may comprise a volatile or non-volatile storage such as a RAM or ROM, or some other computer readable memory device or media. In one rover receiver embodiment, navigation processor 1 058 performs one or more of the methods of position correction.
- microprocessor 1 054 and/or navigation processor 1058 receive additional inputs for use in refining position information determined by GNSS receiver 1000.
- corrections information is received and utilized.
- corrections information can include differential GPS corrections, RTK corrections, and/or wide area augmentation system ( WAAS) corrections.
- topsoil Preventing, or minimizing, the effects of erosion and topsoil runoff are critical to the success of farming operations.
- the topsoil generally hosts the highest
- Figure 1 1 is a flow diagram 1 100 of an example method of water erosion
- topographical data is received indicating the topography of a defined area.
- topographical data can be collected from a variety of sources, which may be referred to as "reporting sources.”
- processor 430 and/or database 429 can receive topographical data from reporting sources such as, but not limited to, mobile device(s) 701 , vehicle monitor(s) 702, public data sources 730. private data sources 740, or other sources which are configured to detect, collect, or report topographical data.
- a reporting agent 710 may transmit or allow access of the topographical data of a reporting source.
- these reporting sources may provide the topographical data as a part of or in conjunction with capturing and providing absolute measurements of one or more agricultural metrics. Such reporting sources may also transmit or provide access to one or more of soil composition data 1320, weather data 1330, user input 1 340, and subscriber data 1350. [0057
- a farmer can traverse a defined area such as a field (e.g., field 1201 of Figure 12.
- the farmer can be walking across field 1201 in one or more linear passes such as shown by paths 1210- 1 , 1210-2, 1210-3 . ..
- a farmer can generate in an ad-hoc manner topographic data 13 10 which can be used later to generate a topographic map of field 1201 .
- the farmer could make a series of stops at discreet sites such as shown by sites 1220-1 , 1220-2, 1 220-3 ... 1220-n.
- the farmer could be holding or carrying mobile device 701 which is configured with a GNSS receiver such as GNSS receiver 1000 of Figure 10.
- GNSS receiver 1000 periodically determines the position of mobile device 701 such as when the farmer is traversing field 1201 .
- the determination of the position of GNSS receiver 1000 includes determining its elevation.
- GNSS receiver can generate a plurality of data points which can be used to develop a topographic map of field 1201 . More specifically, a plurality of data points describing the elevation of GNSS receiver 1000, as well as its position, can be collected, stored, and sent using mobile device 701.
- a plurality of data points describing the elevation of GNSS receiver 1000, as well as its position can be collected, stored, and sent using mobile device 701.
- topographic data 1310 comprises position data as well as an elevation which is correlated with the position data.
- a vehicle monitor 702 can develop data points describing the elevation of GNSS receiver 1000, as well as its position, when a fanner is driving across field 1201 , such as when plowing, applying a treatment, or harvesting a crop at field 1201.
- mobile device 701 and/or vehicle monitor 702 performs this function in a manner which does not require manual intervention by a respective user.
- configuration information can be sent to mobile device 701 , vehicle monitor 702, or other devices, which configures them to collect this information in a manner which is transparent to the operator of these devices.
- GNSS receiver 1000 when traversing field 1201 , is generating a continuous, or near continuous, stream of topographical data points which include the position and elevation of GNSS receiver at a given time. It is further noted that traversing the field can be performed in other patterns than shown in Figure 12 such as in a grid pattern, etc.
- GNSS receiver 1000 generates the topographic data points including position and elevation of GNSS receiver 1 000 at a particular time, at discreet sites as shown by points 1220- 1 , 1220-2, 1220-3 .. . 1220-n.
- a farmer can traverse field 1201 and collect soil samples at points 1220- 1 , 1220-2, 1220-3 .. . 1220-n.
- the analysis of the soil samples tells the farmer what the soil composition is at each point where the samples were taken. This permits developing a detailed mapping of soil composition across a defined area such as field 1201.
- a farmer can use mobile device 701 , or vehicle monitor 701 to generate the position data which describes where each soil sample was taken.
- GNSS receive 1000 when GNSS receive 1000 is used to generate a position fix (e.g., in response to a user action, it also automatically derives the elevation at that point as well.
- a farmer collects soil samples at sites 1220- 1 , 1220-2, 1220-3 ... 1220-n.
- the farmer uses GNSS receiver 1000 to determine the position of sites 1 220- 1. 1 220-2, 1220-3 ... 1220-n for use in the soil analysis.
- GNSS receiver 1000 also collects the elevation at each of these sites as well.
- the position and elevation data can be stored in an electronic file and sent, as topographic data 1310, via communication network 715 as it is collected.
- topographic data 1310 via communication network 715 as it is collected.
- the position and elevation data can be manually recorded by the famier and later sent to computer system 750. It is noted that in one embodiment, the collection of topographic data, including position and elevation data, occurs simultaneous with the collection of soil samples used to determine soil composition. In another embodiment, these operations can occur at different times, or can be derived from separate sources.
- a model generator e.g., model generator 1 360 of Figure 1 3
- processor 420 may be provided with instructions to implement model generator 1 360, in some embodiments.
- other sources of topographical data 13 10 can be used to develop model 1370 described above including, but not limited to. survey data, or similar data received from public data source 730 and/or private data source 740.
- data is received indicating a soil composition found at the defined area.
- a farmer can collect soil samples at intervals across a defined area such as field 1201.
- soil samples may be collected in another manner.
- one or more electromagnetic induction sensors which can sense conductivity, may be utilized for mapping relative differences in soil characteristics in an agricultural field.
- An example of such as sensor is the EM38 sensor from Geonics Limited of Ontario, Canada.
- Such an electromagnetic sensor relies on detecting induced electric currents at depth in response to a magnetic field. The strength of the induced currents is determined by the electrical conductivity of the soil, often driven by the moisture profile in the soil matrix.
- Model 1370 Data logged from an electromagnetic sensor at various locations in a field can be utilized to map soil composition for the field.
- a reporting agent 71 0 is coupled with such an electromagnetic induction sensor for automatic reporting of collected soil composition data.
- model generator 1 360 can include in model 1370, data showing the soil composition of field 1201 . It is noted that model 1370 also shows how soil composition varies at different locations of field 1201 .
- using the soil samples collected, for example, every 100 yards permits developing this information with a greater degree of granularity than is possible using many other sources of soil composition data such as government databases. For example, a
- soil composition may change. For example, sand and fine silt may collect in low-lying areas of a farmer's field due to it being conveyed in runoff. Thus, the tops of hills and ridges may have a higher composition of clay than areas of a field at the base of these terrain features which have a higher percentage of sand and silt. However, this may not be reflected in the soil composition maps retained at the federal, state, or county levels which typically map soil composition with much less detail.
- model generator 1360 generates one of more model(s) 1370 which predicts water runoff patterns from field 1201 based upon the topography of field 1201 and the soil composition of field 1201 .
- model 1370 shows how soil composition varies at different locations of field 1201 .
- soil composition as well as the steepness of terrain found at field 1201 is used to develop model 1 370.
- model generator 1360 can access weather data (e.g., weather data 1330 of Figure 1 3 ) in the development of model 1 370.
- weather data 1 330 comprises historic weather data and/or predicted weather data.
- Weather data 1 330 can be obtained from public sources such as the National Weather Service, or from private sources.
- a private source of weather data 1330 is weather records maintained by the owner of field 1201 .
- Another example of a private source of weather data 1330 is data collected by other farmers who live in the region of field 1201 and who have provided that data to wide-area farming information collection and dissemination network 700.
- model generator 1 360 can include in model 1370 a prediction of water runoff patterns at field 1201 based upon the available data.
- Model 1370 can also predict soil erosion, flooding, or other effects at field 1201 based upon the topographic data, soil composition, and weather data.
- model 1 370 can utilize historic rain fall data associated with various time periods, including but not limited to: several recent years (e.g., the most recent 5 year period); a time period of historic drought; a time period of historic wetness; a time period of historically high rainfall (e.g., a one day maximum; a one week maximum; rain fall associated with a 25, 50, or 100 year flood event; and the like).
- Other data can include overland flooding data, crop damage due to high winds, fire, or other events.
- other farmers who also subscribe to wide-area farming information collection and dissemination network 700 can provide observed data which correlates soil composition, topographic data, and observed precipitation data. This facilitates adjusting the predicted water runoff patterns which are generated by model generator 1 360 to more accurately model real-world conditions.
- wide-area farming information collection and dissemination network 700 can provide a farmer a tool which is used to predict water runoff conditions at a defined area based upon topography, soil composition, and real, or hypothetical weather patterns.
- user input 1340 of Figure 13 permits a user to input other data such as existing land features, vegetation, and the like which change the topographic data of model 1370.
- a farmer can interact with model generator 1360 using mobile device 701 , or PC 704 to change variables which are used to generate model 1 370.
- a farmer can change the topographic data of model 1 370 to predict how water runoff conditions are affected by various terraforming operations.
- model generator 1360 will generate a new model 1 370 which predicts the water runoff conditions which will result.
- Other operations which can be represented by model generator 1 360 include, but are not limited to, the effects of installing drainage, sub-surface drainage, irrigation, changing the size, location, or course of existing water features, effects of planted vegetation on water runoff and erosion, etc.
- changes to model 1370 can be based in part upon data (e.g., subscriber data 1 350 of Figure 13) from other subscribers to wide-area farming information collection and dissemination network 700 who have implemented or observed similar conditions on their property.
- model generator 1 360 permits a user to determine what actions to take to minimize erosion and/or control water runoff patterns on their property .
- model generator can access construction data which indicates or estimates the cost of various activities a user can model.
- model 1370 can include information showing that it is estimated to cost $ 10,000 for a farmer to perform proposed terraforming operations on field 1201. This facilitates a cost/benefits analysis of various actions to determine not only whether the proposed terraforming operation will result in a desired outcome, but whether it is economically sound to perform a given terraforming operation.
- wide-area farming information collection and dissemination network 700 can also generate alerts 780 which can warn a farmer of potentially dangerous situations.
- computer system 750 can access model 1370 and current weather predictions to determine if, for example, flooding will occur based upon projected rainfall in the next 72 hours. Knowing the terrain conformation of field 1201 and the soil composition at various sites across field 1201 , computer system 750 can predict the capacity for the soil at field 1201 to absorb predicted rainfall within a given period. This prediction can be made more accurate by leveraging existing knowledge of other variables such as the current moisture content of the soil at field 1201 , or of past flooding events which occurred under similar circumstances. As another example, computer system 750 can use data regarding flood levels upstream and/or downstream of field 1201 , as well as the topographic data 1310 and soil composition data 1320, to predict whether Hooding and/or erosion will occur at field 1201.
- Section 3 Crop Treatment Compatibility
- crop treatment applicators include, but are not limited to: mounted sprayers, toying device and trailed (towed) sprayers, self-propelled sprayers (e.g., Hagie type sprayers), and aerial sprayers (e.g., spray planes/crop dusting aircraft), and combination applicators (i.e., a tractor with a mounted applicator towing a towed sprayer).
- crop treatments include herbicides, fungicides, insecticides, and fertilizers. In some instances a particular crop treatment may not be compatible with application to a crop growing in a field where it is to be applied.
- a particular crop treatment may not be compatible with a crop growing in a bordering field to the field where the crop treatment is to be applied.
- some field crops are bred or engineered with resistance to certain herbicides while others are not.
- some field crops are unaffected by some selective herbicides, while others will be killed by the same selective herbicide.
- bordering fields occasionally a crop treatment may migrate or drift (either in the air or in the soil) from the field where it is applied and a bordering field. If an incompatible crop treatment is applied to a crop results can include decreased yield and possible death/total loss of the crop.
- Various techniques, methods, systems, and devices, as described herein, may assist in ensuring compatibility of crop treatments with the crops that they are applied to and/or with crops growing in neighboring fields (such as the fields which border a field where a crop treatment is to be applied).
- herbicides include, but are not limited to: glyphosate (utilized, for example, in the Roundup® line of herbicides), which is a non-selective herbicide; glufosinate (utilized, for example, in some Basta®, Rely®, Finale®, Ignite®, Challenge® and Liberty® lines of herbicides), which is a non-selective herbicide; and 2,4-Dichlorophenoxyacetic acid, which is a selective herbicide commonly referred to as "2,4-D.”
- glyphosate utilized, for example, in the Roundup® line of herbicides
- glufosinate utilized, for example, in some Basta®, Rely®, Finale®, Ignite®, Challenge® and Liberty® lines of herbicides
- 2,4-Dichlorophenoxyacetic acid which is a selective herbicide commonly referred to as "2,4-D.”
- FIG. 14 illustrates an example crop treatment applicator 1 400 in a planted field 105, in accordance with various embodiments.
- Crop treatment applicator 1400 comprises a tractor 1410 coupled with a towed sprayer 1420. It is appreciated that the description with respect to crop treatment applicator 1400 is extensible to and equally applicable to other types of crop applicators, such as aerial crop applicators, mounted crop applicators, combination applicators, and self-propelled crop applicators, to name several.
- towed sprayer 1420 is controlled from tractor 1410.
- Tractor 1410 comprises one or more vehicle monitor(s) 702 having respective reporting agents 710-2 disposed thereon.
- Vehicle monitor 702 and/or reporting agent 710-2 may be additionally or alternatively be coupled with towed sprayer 1420.
- Vehicle monitor 702 is coupled with tractor control bus 1412 and can receive and communicate information via tractor control bus 1412.
- Vehicle monitor 702 is also coupled with or includes a GNSS receiver (e.g., GNSS receiver 1000) for determining a realtime location (e.g., latitude/longitude) 1460 of crop treatment applicator 1400.
- GNSS receiver 1000 e.g., GNSS receiver 1000
- Various offsets may be applied to determine a real-time location of any portion of crop treatment applicator 1400.
- vehicle monitor 702 communicates with database 429 and/or processor 430 via communication network 715.
- This communication can comprise providing a real-time location of crop treatment applicator 1400, information such as a description of the type of crop treatment 1430 resident in crop treatment applicator 1400 (e.g.. glyphosate herbicide), and whether or not crop treatment initiation mechanism 141 1 is in an on or off position.
- an operator of crop treatment applicator 1400 may manually input information, such as via a user-interface of reporting agent 71 0-2. which is also communicated to database 429 and/or processor 430.
- An example of manually input information may be a description of crop treatment 1430 (e.g.. "holding tank 1421 is filled with Roundup UltramaxTM herbicide").
- a sensor such as sensor 1422. in crop treatment applicator 1400 automatically determines the nature of crop treatment 1430 (e.g.. type of herbicide, fungicide, insecticide, or fertilizer) and provides such descriptive information about crop treatment 1430 to reporting agent 710-2.
- Crop treatment 1430 is resident in a holding tank 1421 of crop treatment applicator 1400. and can be applied in a spray 1440 to planted crop 1450 when an operator engages crop treatment initiation mechanism 141 1 .
- Crop treatment initiation mechanism 141 1 may be a switch or other interlock which, when actuated to an "on' " position causes crop treatment 1430 to flow and be discharged as spray 1440, and when deactuated to an "off position causes flow of crop treatment 1430 to cease and discharge of spray 1440 to cease.
- crop treatment initiation mechanism 141 1 is communicatively coupled with a control bus 1412 of tractor 1410 such that when actuation signal or deactuation signal indicating the state of crop treatment initiation mechanism 141 1 is transmitted on control bus 1412. Such signal(s) may be routed to a control system associated with tractor 1410 and/or with crop treatment applicator 1400.
- the signal(s) may also be received by vehicle monitor 702 and serve as a trigger to reporting agent 710-2, such that in response to actuation or deactuation of crop treatment initiation mechanism 141 1 , reporting agent 710-2 transmits one or more of a real-time location of crop treatment applicator 1400, a description of crop treatment 1430, and/or on/off state of crop treatment initiation mechanism 141 1 to database 429 and/or processor 450.
- reporting agent 710-2 may receive an "enable application command” or a "disable application command” transmitted wirelessly as a signal from computer system 750 via communication network 715.
- An enable application command is passed on to vehicle monitor 702 and may either serve as a second of two enable signals required to initiate spray 1440.
- a control system of crop treatment applicator 1400 may require actuation of crop treatment initiation mechanism 141 1 and an enable signal from vehicle monitor 702, before initiation of spray 1440 and thus application of crop treatment 1430.
- a disable application command may be passed from reporting agent 710-2 to vehicle monitor 702. Vehicle monitor 702 then sends a disabling signal on bus 1412 to cause spray 1440 to cease or to prevent initiation of spray 1440, thus disabling application of crop treatment 1430.
- Figure 15 shows a schematic of nine farm fields 101 - 1 09, according to various embodiments. For purposes of example, these are the same nine farm fields illustrated in Figure 1 .
- the location or positional bounds of fields 1 01 - 109 are known or stored in database 429.
- Location 1460 is shown in the Northwest corner of field 105.
- Arrow 1505 indicates a direction of wind across field 1 05, which may be reported to computer system 750 as part of weather data 1 330.
- Weather data 1 330 may include other information such as the speed of the wind, the temperature, and a forecast for the odds of precipitation in a region encompassing field 105.
- FIG. 16 is a block diagram of an example crop treatment compatibility system 1 600, in accordance with various embodiments.
- System 1600 includes a computer system 750 with a processor 430.
- Computer system 750 includes or is coupled with database 429 (although depicted in Figure 1 6 as being a part of computer system 750, database 429 may reside in one or more locations remote from computer system 750 and be communicatively coupled with processor 430).
- Computer system 750 further includes crop treatment compatibility determiner 1660 and crop treatment action initiator 1670. either or both of which may be implemented as hardware, a combination of hardware and firmware, or a combination of hardware and software.
- one or more of crop treatment compatibility determiner 1 660 and crop treatment action initiator 1670 may be implemented by processor 430 from instructions accessed from a computer-readable medium.
- Computer system 750, wireless communication network 715, reporting agent 710, processor 430, and database 429 have been previously described and operate in a manner consistent with previous description, with differences and additions identified below.
- processor 430 may implement one or more of aggregator 760 and/or model generator 1360 (and/or other components described herein) in addition to implementing crop treatment compatibility determiner 1660 and/or crop treatment action initiator 1670.
- Reporting agent 71 0 may be coupled with a crop treatment applicator and report treatment information that is automatically or manually gathered at the location of the crop treatment applicator.
- reporting agent 710-2 as illustrated in Figure 14, is coupled with crop treatment applicator 1400 and reports crop treatment information 1605 to computer system 750 and crop treatment compatibility determiner 1660.
- Database 429 includes planted crop information 1665 for a plurality of planted fields.
- planted crop information 1665 for fields 101 - 109 may reside in database 429.
- Other information for these and other fields may be stored in database 429. If for example, a crop treatment is to be applied to field 105, database 429 thus includes planted crop information 1 665 for field 105 and also includes planted crop information 1665 for one or more surrounding fields ( 101 . 102, 103. 104. 1 06. 107, 108, 1 09) which border field 105.
- Planted crop information 1 665 may be populated in database 429 by any means, including, but not limited to: user input 1640, automated input from a reporting agent 71 0, and/or by accessing public and private data sources such as government crop surveys and crop insurance databases.
- Planted crop information 1665 may include, among other information, the type of the crop, the age of the crop, genetic traits of the crop, and/or growing restrictions applicable to the crop.
- the type of the crop refers to the type of plant/seed that is being grown, some examples of different crop types include, but are not limited to: corn, wheat, soybeans, rice, cotton, canola, sunflower, sugarbeet, oats, spelt, sorghum, fescue, and alfalfa.
- traits include selectively bred and genetically engineered traits. Some examples of traits with applicability to crop treatment compatibility include, but are not limited to: glyphosate resistance (often referred to as RoundupReady®); and glufosinate resistance (often referred to as LibertyLink®).
- the age of the crop may be determined from the day of planting, day of sprouting, or day of known or estimated germination of the planted crop.
- Growing restrictions may include restrictions such as no use of pesticides, or no use of any manmade crop treatments. Growing restrictions are often associated with organic crops and may also be associated with fields where organic crops are grown or will be grown.
- Crop treatment compatibility determiner 1660 receives crop treatment information 1605 related to a crop treatment applicator and determines if a crop treatment is compatible with a field in which the crop treatment applicator is located or in which the crop treatment will be applied.
- Crop treatment information 1 605 is received from sources such as user input 1640 (e.g., an electronic work order for an applicator to apply a particular crop treatment in a particular field/location). Such user input may be via a computer, personal digital assistant, smartphone, etc.
- Reporting agent 710 may also supply crop treatment information 1605, such as from an operator of a crop treatment applicator or automatical ly from a crop treatment applicator.
- Crop treatment information 1605 includes one or more of: a real-time location (e.g., a GNSS location) of a crop treatment applicator; a scheduled location of crop treatment application (such as from a work order); and a description of a crop treatment resident in the crop treatment applicator.
- Crop treatment compatibility determiner 1660 makes a compatibility determination by accessing, from database 429, planted crop information 1 665 for a field which encompasses the real-time location of the crop treatment applicator, and then evaluating the planted crop information 1665 and the crop treatment resident in the crop treatment system for compatibility based upon one or more stored crop treatment compatibility rules 1667.
- Such crop treatment compatibility rules 1667 may be stored in database 429. crop treatment compatibility determiner 1660, or any location where they can be accessed as needed.
- crop treatment compatibility rules 1667 include: 1 ) 2,4-D containing herbicide is incompatible with application to soybeans; 2) 2,4-D containing herbicide is compatible with application to fescue; 3) 2,4-D containing herbicide is compatible with application to corn; 4) glyphosate containing herbicide is incompatible with application to any crop which does not possess a glyphosate resistant trait; 5) glyphosate containing herbicide is compatible with application to any crop which possesses a glyphosate resistant trait; 6) glufosinate containing herbicide is incompatible with any planted crop which does not possess a glufosinate resistance trait; 7) glufosinate containing herbicide is compatible with any planted crop which possesses a glufosinate resistance trait; 8) no herbicide is compatible with application to a certified organic planted crop; 9) no herbicide is compatible with application within 100 feet of a certified organic planted crop; 10) analyze compatibility for bordering planted fields that are down
- compatibility rules 1 667 may or may not include some or all of these example compatibility rules 1667.
- Compatibility rules 1667 may also be included or utilized for other crop treatments such as pesticides, fungicides, and fertilizers.
- Compatibility rules 1667 may take into account the age of a planted crop to determine if a crop treatment is being applied within a treatment window for which that crop treatment is compatible. Crop age is used to determine the lifecycle stage that a planted crop is in at any particular time, as some crop treatments which may normally be compatible with a planted crop may be incompatible at certain lifecycle stages such as before or during germination, or during pollination. For example, it may be desirable to apply fungicide to corn only before pollination to prevent yield loss. Likewise, application of a pre-emergent herbicide may only be compatible after a planted crop has germinated.
- One or more crop treatment compatibility rules 1667 may be applied by crop treatment compatibility determiner 1660 to determine compatibility of a crop treatment with a field in which it is to be applied (or in which it is being applied).
- One or more crop treatment compatibility rules 1667 may also be applied by crop treatment compatibility determiner 1660 to determine compatibility of a crop treatment with a field which borders a field in which a crop treatment is to be applied (or in which it is being applied).
- One output of crop treatment compatibility determiner 1660 is a compatible/not compatible determination based on the application of one or more crop treatment compatibility rules 1667 to a planted field which encompasses a real-time location of a crop treatment applicator.
- Another output of crop treatment compatibility determiner is a compatible/not compatible determination based on the application of one or more crop treatment compatibility rules 1 667 to one or more bordering planted fields which border or surround the planted field which encompasses a real-time location of a crop treatment applicator.
- Such compatibility/non- compatibility determinations are provided to crop treatment action initiator 1670 which may initiate one or more actions 1680 based on the compatibility determination for a planted field which encompasses the real-time location of the crop treatment applicator, or for one or more planted fields which border that planted field.
- Crop treatment action initiator 1670 is a part of computer system 750 and is coupled ith crop treatment compatibility determiner 1 660. Crop treatment action initiator 1670 initiates, in real-time (in several seconds or less of receiving crop treatment information at computer system 750). one or more crop treatment actions 1680. Actions 1 680 may be implemented, for example, in real-time from computer system 750 in response to the crop treatment compatibility/incompatibility determination that is made for a planted field in which a crop treatment is being applied or will be applied, or for one or more planted fields which border that planted field.
- Compatibility actions may be initiated in response to a compatibility determination
- incompatibility actions may be initiated in response to an incompatibility determination.
- some entities such as farmers or owners of fields may sign up as recipients of such actions 1 680 and/or provide crop treatment information 1605 and/or planted crop information 1665 to computer system 750 in order to achieve reductions in crop insurance rates and/or improve peace of mind.
- crop treatment application companies and operators of crop treatment applicators may sign up as recipients of such actions 1680 and/or provide crop treatment information 1605 to computer system 750 to improve accurate delivery of crop treatment, to reduce liability, and/or to decrease insurance/bonding costs.
- Other entities such as crop insurance companies may sign up for receipt of certain actions 1 680 and/or provide planted crop information 1 665 in an effort to reduce crop insurance risk.
- a disable application command 1680-2 may be sent to reporting agent 710-2.
- An owner of field 105 may also be text messaged a planted field incompatibility notification 1 680-4, as a warning.
- a glyphosate containing herbicide is about to be sprayed on corn in field 105 and this planted crop does not have a glyphosate resistant trait and is therefore not compatible with application of this herbicide.”
- Another example of a crop treatment incompatibility action is an email message to a crop treatment company such as "Crop treatment applicator is in field 1 05 attempting to apply a crop treatment, which a work order has listed as scheduled for field application in field 102. " ' Such incompatibility actions may be performed in isolation or in combination, in various embodiments.
- a crop treatment compatibility action such as texting a planted field compatibility notification 1680-3 to an owner of a planted field 105 is initiated, in real-time, in response to a determination by crop treatment compatibility determiner 1660 that a crop treatment 1430 is compatible with application to planted crop.
- An example of such a text message is "2-4,D is about to be sprayed on planted fescue in field 105 and this planted crop is compatible with application of this herbicide.
- an enable application command 1680- 1 may also be sent to reporting agent 71 0-2 of crop treatment applicator 1400. Such compatibility actions may be performed in isolation or in combination, in various embodiments.
- Crop treatment action initiator 1670 may initiate a bordering field incompatibility action 1680-6. in real-time, in response to crop treatment compatibility determiner 1660 determining that the crop treatment for planted field 105 is not compatible with at least one of the bordering planted fields to planted field 1 05.
- crop treatment applicator 1400 is located at location 1460 (in planted field 105) and crop treatment compatibility determiner 1660 determines that crop treatment 1430 is incompatible with application to the planted crop in field 1 04.
- An example of a bordering field crop treatment incompatibility action 1680-6 is placing an automated phone call to an owner of bordering field 104 stating "2-4, D is about to be sprayed on field 105 and this herbicide is not compatible with soybeans planted in field 104 which is downwind from field 1 05."
- Another example of a bordering field crop treatment incompatibility action 1680-6 is sending a pager message to an operator of crop treatment applicator 1400 stating "An herbicide is about to be sprayed in field 105, and this is incompatible with being sprayed within 100 feet of certified organic oats planted in field 102."
- crop treatment action initiator may send a disable application command 1680-2 to reporting agent 71 0-2 in response to determining that application of a crop treatment in a first field is
- incompatible with planted crops in a bordering field may be taken in isolation or in combination in one or more embodiments.
- Crop treatment action initiator 1670 may initiate a bordering field compatibility action 1680-5, in real-time, in response to crop treatment compatibility determiner 1660 determining that the crop treatment for planted field 105 is compatible with at planted crops in all of the bordering planted fields to planted field 105.
- Crop treatment action initiator 1670 may initiate a bordering field compatibility action 1680-5, in real-time, in response to crop treatment compatibility determiner 1660 determining that the crop treatment for planted field 105 is compatible with at planted crops in all of the bordering planted fields to planted field 105.
- bordering field crop treatment compatibility action 1680-6 is placing an sending an email message to an owner of bordering field 104 stating "A glyphosate containing herbicide is about to be sprayed on a planted crop in field 105 and this herbicide is compatible with the glyphosate resistant trait of the soybeans planted in field 105.”
- Various compatibility actions, with respect to a bordering field may be taken in isolation or in combination in one or more embodiments.
- Figure 16 illustrates a variety of actions 1680 which may be available in one or more embodiments, in other embodiments, a more limited set or more extensive set of actions 1 680 may be available.
- a more limited set of actions 1680 or more extensive set of actions 1680 may include only a subset of the illustrated actions 1680- 1 to 1680-6.
- a more limited set actions 1680 may include only planted field
- incompatibility notification 1680-4 from the illustrated actions 1680- 1 to 1680-6.
- Other subsets of the illustrated actions 1680-1 to 1680-6 may be available in other embodiments.
- FIGS 1 7A and 17B illustrate a flow diagram 1700 of an example method of ensuring crop compatibility, according to various embodiments. Although specific procedures are disclosed in flow diagram 1 700, embodiments are well suited to performing various other procedures or variations of the procedures recited in flow diagram 1 700. It is appreciated that the procedures in flow diagram 1 700 may be performed in an order different than presented, that not all of the procedures in flow diagram 1700 may be performed, and that additional procedures to those illustrated and described may be performed. All of.
- the procedures described by flow diagram 1 700 can be implemented by a processor or computer system (e.g., processor 430 and/or computer system 750) executing instructions which reside, for example, on computer-usable/readable media.
- the computer-usable/readable media can be any kind of non- transitory storage media that instructions can be stored on.
- Non-limiting examples of the computer-usable/readable media include, but are not limited to a diskette, a compact disk (CD), a digital versatile device (DVD), read only memory (ROM), flash memory, and so on.
- crop treatment information is received at a computer system. As described above, this can comprise receiving crop treatment information 1605 at computer system 750, processor 430, and/or crop treatment compatibility determiner 1660.
- Crop treatment information 1605 comprises a real-time location of a crop treatment applicator and description of a crop treatment resident in the crop treatment applicator. It is appreciated that one or both of the real-time location and the description of the resident crop treatment may be received from a reporting agent 710 that is coupled with a crop treatment applicator 1400.
- crop treatment information 1 605 may also be received in the form of a reported work order for a crop treatment applicator 1400 and/or via user input 1640 of a farmer, owner of a field, crop treatment application company, or operator of crop treatment applicator 1400.
- planted crop information 1665 is accessed for a planted field which encompasses the real-time location supplied as part of crop treatment information 1605.
- crop treatment compatibility determiner 1660 requests, receives, or retrieves such planted crop information 1665 from database 429 or other location.
- the planted crop information 1665 comprises a description of a planted crop in a field with a known location.
- Planted crop information 1665 describes at least a type of crop seed planted in the planted field (e.g., wheat seed, corn seed, soybean seed, etc.). In some
- the planted crop information 1 665 may also describe a trait of the crop seed or lack of a trait of the crop seed. In some embodiments, the planted crop information 1665 may also describe an age of the planted crop.
- crop treatment compatibility determiner 1 660 makes this determination. This determination can be made after crop treatment compatibility determiner 1660 evaluates the planted crop information 1665 and the crop treatment 1430 resident in crop treatment applicator 1400 for compatibility based upon one or more stored compatibility rules 1667. Numerous non-limiting examples of such compatibility rules 1667 have previously been given and reference is made thereto.
- a crop treatment incompatibility action in response to determining the crop treatment resident in the crop treatment applicator is not compatible with application to the planted crop in the field which encompasses the reported location of the crop treatment applicator, a crop treatment incompatibility action is initiated.
- the crop treatment incompatibility action is initiated in real-time, from the computer system that has received crop treatment information 1605.
- crop treatment action initiator 1670 initiates one or more actions 1680 that are associated with crop treatment incompatibility. Such actions can include sending a disable application command 1 680-2 and/or sending a planted field incompatibility notification 1 680-4.
- the crop treatment incompatibility notification 1680-4 may be sent by any electronic means (e.g., phone call, voice mail, text message, facsimile message, pager message, e-mail message, etc.) to an entity such as an owner of the planted field, a farmer of the planted field, an operator of the crop treatment applicator, a crop treatment application company, a crop insurance company, and/or a reporting agent 710 coupled with the crop treatment applicator.
- sending a real-time disable application command 1680-2 to a reporting agent, such as reporting agent 71 0-2, which is coupled with a control system and/or control bus of the crop treatment applicator 1400 (such as through a vehicle monitor 702), causes the control system to disable application of crop treatment 1430.
- the method as described in 1 710 - 1 740 further includes initiating a crop treatment compatibility action in response to determining the crop treatment is compatible with the planted crop.
- the crop treatment compatibility action is initiated in real-time from computer system that has received crop treatment information 1 605.
- crop treatment action initiator 1670 initiates one or more actions 1 680 that are associated with crop treatment compatibility. Such actions can include sending an enable application command 1680-1 and/or sending a planted filed compatibility notification 1680-3.
- the crop treatment compatibility notification 1680-3 may be sent by any electronic means (e.g., phone call, voice mail, text message, facsimile message, pager message, e-mail message, etc.) to an entity such as an owner of the planted field, a farmer of the planted field, an operator of the crop treatment applicator, a crop treatment application company, a crop insurance company, and/or a reporting agent 710 coupled with the crop treatment applicator.
- sending a real-time enable application command 1680-1 to a reporting agent, such as reporting agent 710-2, which is coupled with a control system and/or control bus of the crop treatment appl icator 1400 (such as through a vehicle monitor 702), causes the control system to enable application of crop treatment 1430.
- the method as described in 1710 - 1 740 further includes accessing planted crop information 1665 for one or more bordering planted fields to the planted field in which a crop treatment is being, or is to be, applied.
- Bordering fields are those fields which border the field that encompasses the real-time location supplied as part of crop treatment information 1605. For example, if field 105 encompasses the real-time location, then fields 101 , 102, 103, 104, 106, 107, 1 08, and 109 would be considered bordering fields.
- crop treatment compatibility determiner 1660 requests, receives, or retrieves such planted crop information 1665 from database 429 or other location.
- the planted crop information 1665 for a bordering field, comprises a description of a planted crop in a field with a known location.
- Planted crop information 1 665. for a bordering field describes at least a type of crop seed planted in the bordering planted field (e.g., wheat seed, corn seed, soybean seed, etc.).
- the planted crop information 1665. for a bordering field may also describe a trait of the crop seed or lack of a trait of the crop seed.
- the planted crop information 1665, for a bordering planted field may also describe an age of the planted crop in the bordering planted field.
- the method as described in 1760 further includes determining if application of the crop treatment in the planted field is compatible with one or more bordering planted fields. This comparison is based at least on planted crops of the one or more bordering planted fields.
- crop treatment compatibility determiner 1660 makes this determination. This determination can be made after crop treatment compatibility determiner 1 660 evaluates the planted crop information 1665 for the one or more bordering planted fields and the crop treatment 1430 resident in crop treatment applicator 1400 for compatibility based upon one or more stored compatibility rules 1667. Numerous non- limiting examples of such compatibility rules 1667 have previously been given and reference is made thereto.
- the method of flow diagram 1 770 further includes in response to determining the crop treatment is not compatible with at least one of the bordering planted fields, initiating a bordering field crop treatment
- bordering field crop treatment incompatibility action is initiated in real-time, from the computer system that has received crop treatment information 1 605.
- crop treatment action initiator 1670 initiates one or more actions 1680 that are associated with bordering field crop treatment incompatibility. Such actions can include sending a disable application command 1680-2 and/or sending a bordering planted filed incompatibility notification 1680-6.
- the bordering field crop treatment incompatibility notification 1680-6 may be sent by any electronic means (e.g., phone call, voice mail, text message, facsimile message, pager message, e-mail message, etc.) to an entity such as an owner of the planted field, a farmer of the planted field, an owner of the bordering planted field, a farmer of the bordering planted field, an operator of the crop treatment applicator, a crop treatment application company, a crop insurance company, and/or a reporting agent 710 coupled with the crop treatment applicator.
- sending a real-time disable application command 1 680-2 to a reporting agent, such as reporting agent 710-2. which is coupled with a control system and/or control bus of the crop treatment applicator 1400 (such as through a vehicle monitor 702), causes the control system to disable application of crop treatment 1430.
- the method of flow diagram 1 770 may further include in response to determining that the crop treatment is compatible with all of the bordering planted fields (or at least all of the bordering planted fields for which planted crop information is accessible), initiating a bordering field crop treatment compatibility action.
- the bordering field crop treatment compatibility action is initiated in real-time, from the computer system that has received crop treatment information 1605.
- crop treatment action initiator 1670 initiates one or more actions 1 680 that are associated with bordering field crop treatment compatibility. Such actions can include sending an enable application command 1680-1 and/or sending a bordering planted filed compatibility notification 1680-5.
- the bordering field crop treatment compatibility notification 1680-5 may be sent by any electronic means (e.g., phone call, voice mail, text message, facsimile message, pager message, e-mail message, etc.) to an entity such as an owner of the planted field, a farmer of the planted field, an owner of the bordering planted field, a farmer of the bordering planted field, an operator of the crop treatment applicator, a crop treatment application company, a crop insurance company, and/or a reporting agent 71 0 coupled with the crop treatment applicator.
- electronic means e.g., phone call, voice mail, text message, facsimile message, pager message, e-mail message, etc.
- a reporting agent such as reporting agent 710-2
- a control system and/or control bus of the crop treatment applicator 1400 such as through a vehicle monitor 702
- wide-area farming information collection and dissemination network 700 can be used to monitor, aggregate, and broker the sale or exchange of water allocation credit between users.
- fixed assets 703 comprise pumps, or other devices such as flow meters or monitor, which provide or monitor water delivered to a home, farm, industrial operation, etc.
- Reporting agent 710-3 automatically monitors and/or reports the amount of water which is pumped by fixed asset 703, or which flows past reporting agent 71 0-3. In one embodiment, reporting agent 710-3 is automatically stores this information locally. Additionally, reporting agent 710-3, in some embodiments, automatically forwards information related to water allocation, such as the amount of water that has flowed past reporting agent 710-3, to aggregating agent 760.
- a farmer or other water user, can collect the data from reporting agent 710-3 (e.g., using reporting agent 710- 1 of mobile device 701 ).
- a farmer can manually enter the data into PC 704 which reports the water allocation data to aggregating agent 760 using reporting agent 710-4.
- FIG. 8 is an example diagram of a watershed area 1800 in accordance with various embodiments.
- a watershed area such as watershed area 1850, may comprise any one or some combination of water sources such as a river, canal, reservoir, aquifer, or the like.
- farms 1801 , 1 802, and 1 803 draw water from river 1850.
- river 1 850 For simplicity of illustration and discussion, only river 1 850 is discussed, however discussion with respect to river 1 850 is equally applicable to other watershed water sources and combinations thereof.
- metropolitan area 1820 also draws water from river 1850.
- farms 1801 , 1 802, and 1 803 use reporting agents 710-3 A, 710-3B, and 710-3C respectively for monitoring and reporting of water drawn from river 1850.
- reporting agents 710-3 A, 710-3B. and 710-3C measure and report how much water a farmer has drawn from a water source such as river 1 850.
- This data is sent to aggregating agent 760 of computer system 750 which acts as a broker system for exchanging water allocation credits.
- farm 1 810 has received enough rainfall, it may not need all, or any, of its allocated water.
- computer system 750 can act as a broker to farms 1802 and 1 803 which may be experiencing drier than anticipated rainfall and need water in excess of the water allocation which has been paid for.
- a farmer who needs additional water can use the unused water allocation credit of another farmer who does not need it. For example, if farm 1 801 has excess water, it can sell water allocation credits for the unused water allocation to farm 1 803 which is located downstream of farm 1801 . Additionally, this can be done without reducing the supply of water to other entities downstream of farm 1 803 such as metropolitan area 1 820.
- the excess water allocation credit from multiple subscribers to wide-area farming information collection and dissemination network 700 can be aggregated and sold to another party. For example, the excess water allocation credit from each of farms 1 801 , 1 802, and 1 803 may be too small to be individually purchased by metropolitan area 1820. However, by aggregating the excess water allocation credits from farms 1 801 . 1 802, and 1 803 into a single, larger aggregated water allocation credit, wide-area farming information collection and dissemination network 700 can act as a broker to sell that larger aggregated water allocation credit to metropolitan area 1 820.
- wide-area farming information collection and dissemination network 700 can be leveraged to predict future precipitation projections and to send reports 770 to farmers (e.g., operators of farms 1 801 , 1802, and 1803) advising them that it is possible and/or advisable to sell some of their water allocation credit to another party.
- farmers e.g., operators of farms 1 801 , 1802, and 1803
- wide-area farming information collection and dissemination network 700 can act as an agent or broker for selling excess water allocation credit to another subscriber, or to another party. This can be based upon knowledge of the soil, topography, crops, weather patterns, current water levels of lakes and rivers, and other data which can be accessed by wide-area farming information collection and dissemination network 700. This permits generating a prediction of how much water a particular user will require from a water source.
- wide-area farming information collection and dissemination network 700 can be used to determine a cost/benefits analysis of drawing additional water from a water source in excess of the farmer ' s paid for water allocation. In some instances, farmers pay a higher rate when drawing additional water in excess of their normal water allocation.
- wide-area farming information collection and dissemination network 700 can analyze the soil, weather, crops, and other variables, and generate a report 770 which describes whether a higher crop yield will recoup the cost of drawing additional water from a water source.
- FIG 20 is a flow diagram of an example method 2000 of exchanging water allocation credits in accordance with one embodiment.
- data is accessed describing a water allocation credit reserved for a first user.
- a farmer buys in advance the right to draw water from a water source.
- the farmer does not draw all of the water he paid for at that time, but instead will draw the water over an extended period such as the following year, or following growing season.
- the farmer receives water credits for drawing a given amount of water which is allocated to him.
- wide-area farming information collection and dissemination network 700 can gather information regarding various aspects of farming operations including irrigation and water allocation credit data.
- a farmer can report the volume, and price paid, for his yearly allocation of water from a water source such as river 1 850.
- a farmer e.g., operating farm 1801 of Figure 1 8 can report his yearly water allocation as represented by water allocation 1901 .
- Wide-area farming information collection and dissemination network 700 can compare agricultural data for farm 1 801 with historical records and/or subscriber data from other subscribers (e.g., farms 1802 and 1 803) of wide-area farming information collection and dissemination network 700. Examples of this data include, but are not limited to, soil composition data, weather data (e.g., current weather patterns and forecasts, as well as historical data records), crop data, and the like. Using this information, wide-area farming information collection and dissemination network 700 can make a prediction of the amount of water which may be needed to meet a stated objective of the farmer.
- wide-area farming information collection and dissemination network 700 can compare the agricultural data for the farmer at farm 1 801 with similar data from other subscribers to more accurately model and predict the yield for the farmer based upon, for example, how much of a farmer ' s water allocation is needed or will be used to meet stated objective of the farmer.
- wide-area farming information collection and dissemination network 700 can compare the agricultural data for the farmer at farm 1 801 with similar data from other subscribers to more accurately model and predict the yield for the farmer based upon, for example, how much of a farmer ' s water allocation is needed or will be used to meet stated objective of the farmer.
- wide-area fanning information collection and dissemination network 700 can generate a message which predicts the farmer's crop yield if the farmer decides to sell his unused water allocation credit, or compare what additional gains in crop yield the farmer w ill realize for using additional amounts of the unused water allocation credit on his farm.
- an unused amount of the water allocation is determined which will not be used by the first user.
- wide-area farming information collection and dissemination network 700 can be used to determine how much water (e.g., used water allocation credit 1901 A of Figure 19) a farmer will need or use to meet a stated objective of a farmer. Thus, in some instances, a farmer will not necessarily need to use all of his water allocation for a given period or growing season. As a result, wide-area farming information collection and dissemination network 700 can determine an unused amount (e.g., unused water allocation credit 190 I B of Figure 19) of a farmer's given water allocation based upon this analysis.
- wide-area farming information collection and dissemination network 700 will generate a message to a farmer stating that, while meeting the farmer ' s stated objectives, some amount of the farmer's water allocation credit remains, or will remain, unused.
- wide-area farming information collection and dissemination network 700 may generate a message stating that in order to meet another farmer's stated objective, more water than the farmer ' s current water allocation will be needed.
- a farmer can determine whether using more water allocation credits will result in a higher yield, or if he will benefit more by selling the unused water allocation credits to another party.
- a reporting agent 710-3 coupled with a fixed asset 703 such as a pump, or flow meter of an irrigation system, can be used to report the actual amount of the allocated water a farmer has already used.
- wide-area farming information collection and dissemination network 700 can act as a broker for one, or a plurality of, subscribed users to sell goods, services, and commodities such as water for irrigation purposes.
- wide-area farming information collection and dissemination network 700 can be implemented in the role of a broker for selling water allocation credits.
- the farmer operating farm 1 801 can sell, via wide-area farming information collection and dissemination network 700, unused water allocation credit 190 I B to the farmer(s) operating farms 1 802 and/or 1 803.
- wide-area farming information collection and dissemination network 700 can act as a broker between a plurality of farmers (e.g., operating farms 1 801 and 1802) to another party.
- the farmers operating farm 1 801 and 1 802 can, through aggregating agent 760, aggregate their unused water allocation credits (e.g., 190 I B and 1902 of Figure 1 9) to create aggregated water allocation credit 1910.
- Wide-area farming information collection and dissemination network 700 can then act as a broker to sell aggregated water allocation credit 1910 to another party.
- wide-area farming information collection and dissemination network 700 can sell aggregated water allocation credit 1 91 0 to another party.
- the other party may be elsewhere in watershed area 1 800 outside of watershed area 1800.
- the other party to which aggregated water allocation credit 1910 is sold may be downstream along river 1 850. such as farm 1803, or metropolitan area 1820.
- wide-area farming information collection and dissemination network 700 can aggregate the credit for unused water allocation credits, and broker their sale.
- FIG. 21 is a block diagram of an example crop characteristic estimation system 21 00. in accordance with various embodiments.
- System 2100 includes a computer system 750 with a processor 430.
- Computer system 750 includes or is coupled with database 429 (although depicted in Figure 21 as being a part of computer system 750, database 429 may reside in one or more locations remote from computer system 750 and be communicatively coupled with processor 430).
- Computer system 750 further includes plant growth model correlator 2160 and crop characteristic estimator 21 65, either or both of which may be implemented as hardware, a combination of hardware and firmware, or a combination of hardware and software.
- system 750 may further include one or more of estimated crop characteristic map generator 2170 and harvest path generator 2175, either or both of which may be implemented as hardware, a combination of hardware and firmware, or a combination of hardware and software.
- estimated crop characteristic map generator 2170 and harvest path generator 2175 may be implemented by processor 430 from instructions accessed from a computer-readable medium.
- Computer system 750, wireless communication network 715, reporting agent 710, processor 430, and database 429 have been previously described and operate in a manner consistent with previous description, with differences and additions identified below.
- processor 430 may implement one or more components or functions described herein in addition to implementing any or all of plant growth model correlator 21 60, crop characteristic estimator 21 65, estimated crop characteristic map generator 21 70, and/or harvest path generator 21 75.
- Reporting agents 710 may be coupled with mobile device(s) 701 , vehicle monitor(s) 702. fixed asset(s) 703, personal computer(s) 704, and other communication hardware.
- a reporting agent 710 coupled a combine provides actual crop characteristic data (ACCD) 2105 from a harvested field.
- Such crop characteristic data may be data such as yield (i.e..
- Actual crop characteristic data may also be provided to database 429 via one or more other sources, such as being sent from a personal computer of a farmer following the harvest of a field, or being sent from a mobile device of a farmer, agronomist, seed dealer or the like who samples a crop at a particular location in a field and then performs tests on the sampled crop to determine one or more items of crop characteristic data (e.g., moisture content %, protein content %, test weight, etc.).
- items of crop characteristic data e.g., moisture content %, protein content %, test weight, etc.
- a user of system 21 00 such as a farmer, custom cutter, combine operator, or the like may provide a specified crop characteristic value (SCCV) 21 10 as an input for use in generating a harvest path to harvest a crop which satisfies the specified crop characteristic value 21 10.
- SCCV specified crop characteristic value
- Such an input specified crop characteristic 21 10 is then forwarded to computer system 750 and harvest path generator 21 75 via communication network 71 5 by a reporting agent 710.
- specified crop characteristic value 21 10 includes, but are not limited to: estimated yield within a specified value range; estimated yield at or below a specified value; estimated yield at or above a specified value; estimated test weight within a specified value range; estimated test weight at or below a specified value; estimated test weight at or above a specified value; estimated moisture content within a specified value range;
- test weight and moisture content are very closely related, however, some entities prefer using one term rather than the other to describe a unit of grain.
- test weight is a commonly accepted measure of quality used in the commercial exchange of bulk grain, while moisture content is a large sub-component in the overall test weight.
- Database 429 includes planted crop information 1665 for a plurality of planted fields, plant growth models 515 for a plurality of fields, and actual crop characteristic data 2105 for a plurality of fields. It is appreciated that these data overlap.
- database 429 will include planted crop information 1 665, plant growth model information, and actual crop characteristic data 2105 for each of one or more field which have been planted, grown and harvested.
- database 429 may include NDVI maps 520, soil data 415, crop data 420, climate data 425 and/or other information for various harvested and unharvested fields.
- Plant growth model correlator 2160 is communicatively coupled with database 429.
- plant growth model correlator 2160 is able to search database 429 to determine at least one harvested field which has a plant growth model that correlates with the plant growth model for at least a portion of an unharvested field. For example, if field 102 of Figure 1 has been harvested and has a plant growth model which is available in database 429, plant growth model correlator 21 60 may determine that regions with an NVDI shade of 2 (see Figure 3) within management zone 1 (see Figure 1 ) of field 102 correlate in their modeled plant growth with portions of field 103 which have an NVDI shade of 2 (see Figure 3).
- plant growth model correlator 2160 may determine that regions with an NVDI shade of 1 (see Figure 3) within management zone 1 (see Figure 1 ) of field 104 correlate in their modeled plant growth with portions of field 103 which have an NVDI shade of 1 (see Figure 3).
- Crop characteristic estimator 2165 estimates a crop characteristic (i.e., estimated crop characteristic data 2180) for an unharvested field based on actual crop characteristic data obtained from at least one harvested field that has been correlated with the unharvested field.
- estimated crop characteristic data 21 80 may be output from computer system 750 in an electronic form, such as a spread sheet which links such estimated crop characteristics to locations (e.g., latitude/longitude) within an unharvested field.
- Such a spreadsheet would typically have at least three columns, one for the estimated crop characteristic data, one for a latitude, and one for a longitude. Other formats for providing estimated crop characteristic data 2180 are possible and anticipated.
- Estimated crop characteristic data 2180 may be forwarded via communication network 715 to any location/entity which can accept and display/utilize its content.
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 2 (see Figure 3) and a management zone of 1 will also have a wheat protein content of 15%.
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 1 (see Figure 3) and a management zone of 1 will also have a wheat protein content of 13%. It is appreciated that other information may be taken into account in making crop characteristic estimates. Some examples of such other information include, but are not limited to: growing days for the correlated fields, weather data for the con-elated fields, and time since harvest of the harvested field(s).
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 2 (see Figure 3) and a management zone of 1 will also have a moisture content of corn which is at or below 19%.
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 1 (see Figure 3) and a management zone of 1 will also have a moisture content of corn which is at or below 1 7%. It is appreciated that other information may be taken into account in making crop characteristic estimates. Some examples of such other information include, but are not limited to: growing days for the correlated fields, weather data for the correlated fields, and time since harvest of the harvested field(s).
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 2 (see Figure 3) and a management zone of 1 will also have a test weight for soybeans which is at or above 62 pounds/bushel.
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 1 (see Figure 3) and a management zone of 1 will also have a test weight for soybeans which is at or above 55 pounds/bushel. It is appreciated that other information may be taken into account in making crop characteristic estimates. Some examples of such other information include, but are not limited to: growing days for the correlated fields, weather data for the correlated fields, and time since harvest of the harvested field(s).
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 2 (see Figure 3) and a management zone of 1 will also produce an average of 85 bushels/acre for barley.
- crop characteristic estimator 2165 will, in one embodiment, estimated that portions of field 103 which have an NVDI shade of 1 (see Figure 3) and a management zone of 1 will also have a yield for barley which is at or above 70 bushels/acre. It is appreciated that other information may be taken into account in making crop characteristic estimates. Some examples of such other information include, but are not limited to: growing days for the correlated fields, weather data for the correlated fields, and time since harvest of the harvested field(s).
- estimated crop characteristic map generator 2170 generates and outputs an estimated crop characteristic map 2185.
- Estimated crop characteristic map 2185 visibly illustrates and portrays the estimated crop characteristic(s) relative to locations within an unharvested field.
- Figure 22 illustrates an example estimated crop characteristic map 2185A for an unharvested field (field 103 of Figure 1 ), according to one or more embodiments.
- Region 2210 is illustrated as having a first estimated crop characteristic
- region 2220 is illustrated as having a second and different estimated crop characteristic.
- Estimated crop characteristic map 2185A, of Figure 22 may be printed, electronically displayed, and/or provided via
- harvest path generator 2 1 75 generates a harvest path 2190 for an unharvested field based on the estimated crop characteristic map.
- the harvest path 2190 may be generated to harvest crops of a certain estimated crop characteristic separately from crops of a differing estimated crop characteristic.
- a user may input or specify one or more items of information which are utilized by harvest path generator 2175.
- specified information include a desired direction of harvest for hilled row crops (e.g., to prevent harvesting across the hills); a width of a combine head/number of rows which a combine head can handle; and a specified crop characteristic value 21 1 0 for which the harvest path 2190 is to be generated.
- An example of a specified crop characteristic value 21 1 0 may be protein content above or below a value or within a range.
- Another example of a specified crop characteristic value 21 10 may be moisture content above or below a value or within a range.
- a farmer may wish to generate a harvest path 2190 to harvest wheat with a specified average protein content % in order to fulfill a contract which requires wheat at or above a certain protein content %.
- a fanner may which to generate a harvest path 2190 to harvest corn with a moisture content within a specified average moisture content % in order to deliver the grain directly to a local cooperative without being docked in price for drying and shrinkage.
- a farmer may which to generate a harvest path 2190 to harvest soybeans with test weight above specified value in order to take advantage of a favorable prevailing market price for such a crop.
- FIG 23 illustrates an example of a harvest path 2190A generated for an unharvested field (field 103 of Figure 1 ), according to one or more embodiments.
- Harvest path 2190A of Figure 23 is configured to harvest of a region 221 0 of a crop in the illustrated region of field 103 which possesses a particular estimated crop characteristic value that is different from an estimated crop characteristic value of the crops growing in region 2220.
- harvest path 2190A attempts to harvest only region 2210 in an efficient manner while avoiding region 2220.
- harvest path 2190A is forwarded via communication network 715 to a steering control of a combine and utilized to auto steer the combine through field 103.
- FIGS 24A. 24B, and 24C illustrate a flow diagram 2400 of an example method of crop characteristic estimation, according to various embodiments. Although specific procedures are disclosed in flow diagram 2400, embodiments are well suited to performing various other procedures or variations of the procedures recited in flow diagram 2400. It is appreciated that the procedures in flow diagram 2400 may be performed in an order different than presented, that not all of the procedures in flow diagram 2400 may be performed, and that additional procedures to those illustrated and described may be performed.
- All of, or a portion of, the procedures described by flow diagram 2400 can be implemented by a processor or computer system (e.g., processor 430 and/or computer system 750) executing instructions which reside, for example, on computer-usable/readable media.
- the computer-usable/readable media can be any kind of non- transitory storage media that instructions can be stored on.
- Non-limiting examples of the computer-usable/readable media include, but are not limited to a diskette, a compact disk (CD), a digital versatile device (DVD), read only memory (ROM), flash memory, and so on.
- a database containing plant growth models for a plurality of fields is accessed.
- This can comprise, for example, computer system 750 and/or plant growth model correlator 2160 accessing database 429 to acquire or search plant growth models 51 5 and/or other crop related information available in database 429.
- At 2420 of flow diagram 2400 in one embodiment, at least one harvested field with a first plant growth model is determined which correlates with a second plant growth model for at least a portion of an unharvested field.
- This can comprise, for example, computer system 750 and/or plant growth model correlator 2160 accessing database 429 to acquire or search plant growth models 5 15 available in database 429.
- the determination of a correlating harvested field may be based on recent data (same growing season), historical data (past growing seasons), or a combination thereof.
- the correlation of the first and second plant growth models may be further based upon other factors, including, but not limited to: a commonality of management zones between portions of the harvested and unharvested fields; correlation between growing days between the harvested and unharvested fields; and/or correlation between weather data for the harvested and unharvested fields.
- a correlation may be found if items being correlated correlate above some threshold, such as a statistical correlation of between 0.75 and 1 .0, a statistical correlation between 0.90 and 1 .0, a statistical correlation between 0.95 and 1 .0.
- Such correlations may be preset and/or user defined. In general, certain correlations may need to be stronger than others in order to achieve reliable estimations of crop characteristics.
- the correlation between management zones of harvested and unharvested fields is required to be stronger than the correlation between plant growth models of the same harvested and unharvested fields.
- in one embodiment in one embodiment, in one
- the correlation between management zones of harvested and unharvested fields is required to be 1 .0 while the correlation between plant growth models of the same harvested and unharvested fields is required to be 0.95 or higher. Other correlation ranges are possible and anticipated.
- a crop characteristic for the unharvested field is estimated based on actual crop characteristic data obtained from the at least one harvested field.
- the estimated crop characteristic in various embodiments, may be a yield, moisture content, protein content, test weight, or other crop characteristic that can be measured from the harvested crop. This estimation is performed, in one embodiment, by crop
- the estimate comprises estimating correlated portions of the harvested and unharvested field to have identical crop characteristics.
- the estimate can be adjusted away from identical or specified as a range based on a variety of factors such as the strength of correlation, weather, growing days, time since harvest, etc. For example, given a strong or identical correlation between a harvested and unharvested field, estimations for a characteristic such as moisture content of corn may decrease with an increase growing time for the unharvested field as compared to the harvested field, in general this is because after a certain period of growing time moisture content may decrease at a fairly predictable rate but will not increase further.
- the method as described in 2410 - 2430 further includes generating an estimated crop characteristic map 21 85 of the unharvested field.
- estimated crop characteristic map generator 2170 generates the estimated crop characteristic map 2185.
- Estimated crop characteristic map 21 85 illustrates the estimated crop character! stic(s) relative to locations within the unharvested field.
- estimated crop characteristic map 21 85 is generated and output in a tangible form by computer system 750. such as by sending estimated crop characteristic map 21 85 to a printer. In other embodiments, this may comprise providing an electronic version of estimated crop characteristic map 21 85 which may be displayed on a display device, printed, or utilized in another manner.
- Estimated crop characteristic map 21 85 A of Figure 22 provides one example of an estimated crop characteristic map 21 85.
- the method as described in 2440 further includes generating a harvest path 2190 for the unharvested field based on the estimated crop characteristic map 2 1 85.
- harvest path generator 2175 generates the harvest path 2190.
- the harvest path 2190 may be generated based upon the estimated crop characteristic map 2190 and a specified crop characteristic value 21 10.
- the specified crop characteristic value 21 10 may be above or below a certain estimated value for a crop characteristic, or a range of estimated values for the crop characteristic.
- Harvest path 2190A of Figure 23 illustrates one example of a harvest path 2190.
- this writing discloses a water erosion management incorporating topography, soil type, and weather statistics. It discloses further a method of water erosion management comprises receiving a topographic datum indicating the topography of a defined area. Data is received indicating a soil composition found at the defined area. A model is created predicting a water runoff pattern for said defined area based upon the topography of the defined area and the soil composition of the defined area.
- this writing discloses exchanging water allocation credits. It further discloses a method of exchanging water allocation credits comprises accessing data describing a water allocation credit reserved for a first user. An unused amount of the water allocation credit which will not be used by the first user is then determined. A sale is then brokered of the unused amount of the water allocation credit to another user.
- this writing discloses crop treatment compatibility. It further discloses a method of ensuring crop treatment compatibility crop treatment information is received at a computer system.
- the crop treatment information comprises a real-time location of a crop treatment applicator and a description of a crop treatment resident in the crop treatment applicator.
- Planted crop treatment information is accessed for a planted field which encompasses the real-time location.
- the planted crop information comprises a description of a planted crop in the planted field. It is determined whether the crop treatment is compatible with application to the planted crop. In response to determining the crop treatment is not compatible with application to the planted crop, a crop treatment incompatibility action is initiated in real-time from the computer system.
- a system for estimating a crop characteristic comprises a database, a plant growth model correlator, and a crop characteristic estimator.
- the database includes plant growth models for a plurality of fields.
- the plant growth model correlator is communicatively coupled with the database.
- the plant growth model correlator is configured for determining at least one harvested field with a first plant growth model which correlates with a second plant growth model for at least a portion of an unharvested field.
- the crop characteristic estimator is configured for estimating a crop characteristic for the unharvested field based on actual crop characteristic data obtained from the at least one harvested field.
- this writing discloses wide-area agricultural monitoring and prediction. It further discloses a system for agricultural monitoring and prediction comprises a first reporting agent a second reporting agent a database, and a processor.
- the first reporting agent is configured for reporting aerial data representing relative measurements of an agricultural metric in a geographic area, the relative measurements having an unknown bias.
- the second reporting is configured for reporting ground-based data representing absolute measurements of the agricultural metric for a portion of the geographic area.
- the database is configured for storing the absolute measurement data and the relative measurement data along with other farming data for a wide geographic area.
- the processor is configured for accessing the database and using the ground-based data for the portion of the geographic area to calibrate the aerial data, thereby synthesizing absolute measurements of the agricultural metric for the geographic area from the aerial data.
- a method of water erosion management comprising:
- a system for management of water erosion comprising:
- a first reporting source configured to report a plurality of topographic data defining a location and an elevation of a plurality of sites at a defined area
- a second reporting source configured to report a soil composition data of at least one of said locations within said defined area
- a model generator configured to generate a model which conveys a three-dimensional (3-
- a database coupled with said model generator and configured for storing said plurality of topographic data and said soil composition data
- an aggregating agent configured for coupling said database and for filtering data collected across a wide geographic area based on attributes common with said defined area.
- a non-transitory computer-readable storage medium having computer readable instructions stored thereon which, when executed, cause a processor to perform a method of water erosion management, said method comprising:
- a method of exchanging water allocation credits comprising:
- Concept 23 The method recited in Concept 21 or 22, further comprising: accessing a set of agricultural data for said first user, said set of agricultural data selected from the group consisting of soil composition data, weather data, and crop data;
- a subscriber data set from a subscriber to a wide-area farming information collection and dissemination network said data selected from the group consisting of soil composition data, weather data, and crop data.
- a subscriber data set from a subscriber to a wide-area farming information collection and dissemination network said data selected from the group consisting of soil composition data, weather data, and crop data ;
- said subscriber data set with a second set of agricultural data for a second user, said second set of agricultural data said set of agricultural data selected from the group consisting of soil composition data, weather data, and crop data;
- a non-transitory computer-readable storage medium having computer readable instructions stored thereon which, when executed, cause a processor to perform a method of exchanging water allocation credits comprising:
- a subscriber data set from a subscriber to a wide-area farming information collection and dissemination network said data selected from the group consisting of soil composition data, weather data, and crop data.
- a subscriber data set from a subscriber to a wide-area farming information collection and dissemination network said data selected from the group consisting of soil composition data, weather data, and crop data
- said second set of agricultural data said set of agricultural data selected from the group consisting of soil composition data, weather data, and crop data:
- a water allocation credit exchange system comprising:
- a reporting agent configured to report a water allocation credit reserved for a first user; a database configured to access data describing said water allocation credit reserved for a first user;
- an aggregating agent configured to aggregate an unused amount of a second water allocation credit with said unused amount of said water allocation credit to create an aggregated water allocation credit
- said processor which is further configured to broker a sale of said aggregated water allocation credit to another user.
- said processor is further configured to compare said subscriber data set with a second set of agricultural data for a second user, and to generate a predicted crop yield for said second user based upon said sale of said unused amount of said water allocation credit, said second set of agricultural data and said set of agricultural data selected from the group consisting of soil composition data, weather data, and crop data.
- a method of ensuring crop treatment compatibility comprising:
- said crop treatment information comprising a real-time location of a crop treatment applicator and a description of a crop treatment resident in said crop treatment applicator;
- planted crop information for a planted field which encompasses said real-time location, said planted crop information comprising a description of a planted crop in said planted field;
- a system crop treatment compatibility system comprising:
- a crop treatment compatibility determiner disposed in a computer system, said crop treatment compatibility determiner configured for:
- a database coupled with said crop treatment compatibility determiner and configured with planted crop information for a plurality of planted fields including said planted field which encompasses said real-time location, said planted crop information comprising a description of planted crops in each of said plurality of planted fields;
- a crop treatment action initiator disposed as a portion of said computer system, coupled with said crop treatment compatibility determiner, and configured for initiating, in real-time from said computer system, a crop treatment incompatibility action in response to said crop treatment compatibility determiner determining that said crop treatment is not compatible with application to said planted crop.
- a reporting source coupled with said crop treatment applicator and configured for wirelessly reporting said real-time location and said description of a crop treatment resident in said crop treatment applicator.
- a crop treatment applicator comprising:
- a reporting agent coupled with a control bus of said crop treatment applicator and configured for wirelessly reporting a real-time location of said crop treatment applicator and a description of a crop treatment resident in said crop treatment applicator to a remote computer system in response to actuation of said crop treatment initiation mechanism by an operator of said crop treatment applicator.
- a system for estimating a crop characteristic comprising:
- a plant growth model correlator communicatively coupled with said database and configured for determining at least one harvested field with a first plant growth model which correlates with a second plant growth model for at least a portion of an unharvested field; and a crop characteristic estimator configured for estimating a crop characteristic for said unharvested field based on actual crop characteristic data obtained from said at least one harvested field.
- an estimated crop characteristic map generator configured for generating and outputting an estimated crop characteristic map illustrating said estimated crop characteristic relative to locations within said unharvested field.
- a harvest path generator configured for generating a harvest path for said unharvested field based on said estimated crop characteristic map.
- a method of estimating a crop characteristic comprising:
- a system for agricultural monitoring and prediction comprising:
- a first reporting agent configured for reporting aerial data representing relative measurements of an agricultural metric in a geographic area, the relative measurements having an unknown bias
- a second reporting agent configured for reporting ground-based data representing absolute measurements of the agricultural metric for a portion of the geographic area
- a database configured for storing said ground-based data and said aerial data along with other farming data for a wide geographic area; and a processor configured for accessing the database and using said ground-based data for the portion of said geographic area to calibrate said aerial data, thereby synthesizing absolute measurements of the agricultural metric for said geographic area from said aerial data.
- a system for agricultural monitoring and prediction comprising: a data source of aerial data representing relative measurements of an agricultural metric in a geographic area, the relative measurements having an unknown bias;
- a reporting agent configured for reporting ground-based data representing absolute measurements of the agricultural metric for a portion of the geographic area
- a database configured for storing said ground-based data and said aerial data along with other farming data for a wide geographic area
- a processor configured for accessing the database and using said ground-based data for the portion of said geographic area to calibrate said aerial data, thereby synthesizing absolute measurements of the agricultural metric for said geographic area from said aerial data.
- Concept 88. The system of Concept 87. further comprising an aggregating agent configured for coupling with said database and filtering data collected across said wide geographic area based on attributes common with those of a particular agricultural field to generate a report relevant to said particular agricultural field.
- aerial data representing relative measurements of an agricultural metric in a geographic area, said aerial data having an unknown bias
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Applications Claiming Priority (6)
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US13/280,312 US8855937B2 (en) | 2010-10-25 | 2011-10-24 | Crop characteristic estimation |
US13/280,310 US9408342B2 (en) | 2010-10-25 | 2011-10-24 | Crop treatment compatibility |
US13/280,315 US8768667B2 (en) | 2010-10-25 | 2011-10-24 | Water erosion management incorporating topography, soil type, and weather statistics |
US13/280,306 US9846848B2 (en) | 2010-10-25 | 2011-10-24 | Exchanging water allocation credits |
US13/280,298 US9058633B2 (en) | 2010-10-25 | 2011-10-24 | Wide-area agricultural monitoring and prediction |
PCT/US2012/061681 WO2013063106A2 (en) | 2011-10-24 | 2012-10-24 | Agricultural and soil management |
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