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NZ716586B2 - Monitoring and control of soil conditions - Google Patents
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NZ716586B2 - Monitoring and control of soil conditions - Google Patents

Monitoring and control of soil conditions Download PDF

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Publication number
NZ716586B2
NZ716586B2 NZ716586A NZ71658612A NZ716586B2 NZ 716586 B2 NZ716586 B2 NZ 716586B2 NZ 716586 A NZ716586 A NZ 716586A NZ 71658612 A NZ71658612 A NZ 71658612A NZ 716586 B2 NZ716586 B2 NZ 716586B2
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NZ
New Zealand
Prior art keywords
soil
samples
activity zone
water
plant
Prior art date
Application number
NZ716586A
Other versions
NZ716586A (en
Inventor
Estanislao Martinez Martinez Phd
Original Assignee
Agq Technological Corporate Sa
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Agq Technological Corporate Sa filed Critical Agq Technological Corporate Sa
Publication of NZ716586A publication Critical patent/NZ716586A/en
Publication of NZ716586B2 publication Critical patent/NZ716586B2/en

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Classifications

    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01CPLANTING; SOWING; FERTILISING
    • A01C21/00Methods of fertilising, sowing or planting
    • A01C21/007Determining fertilization requirements
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01GHORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
    • A01G29/00Root feeders; Injecting fertilisers into the roots
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/10Devices for withdrawing samples in the liquid or fluent state
    • G01N1/14Suction devices, e.g. pumps; Ejector devices
    • G01N2033/245
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N27/00Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
    • G01N27/02Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N33/00Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
    • G01N33/24Earth materials
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B15/00Systems controlled by a computer
    • G05B15/02Systems controlled by a computer electric
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D11/00Control of flow ratio
    • G05D11/02Controlling ratio of two or more flows of fluid or fluent material
    • G05D11/13Controlling ratio of two or more flows of fluid or fluent material characterised by the use of electric means
    • G05D11/135Controlling ratio of two or more flows of fluid or fluent material characterised by the use of electric means by sensing at least one property of the mixture
    • G05D11/138Controlling ratio of two or more flows of fluid or fluent material characterised by the use of electric means by sensing at least one property of the mixture by sensing the concentration of the mixture, e.g. measuring pH value

Abstract

Disclosed is a method to achieve certain soil conditions. The method comprises: A composition of a fertilizer solution (FS) that has been supplied to a soil substrate including a root activity zone of a plant species is obtained by a computing device. A chemical composition within the root activity zone is obtained by the computing device. The chemical composition is determined by analysis of an aqueous sample obtained from a suction probe positioned within the root activity zone after the FS is supplied to the soil substrate. The nutrient utilization by the plant species based at least in part upon the FS composition and the chemical composition of the root activity zone is determined by the computing device. An amount of additive that is added to irrigation water to produce a subsequent FS that is supplied to the soil substrate is provided by the computing device. zone is obtained by the computing device. The chemical composition is determined by analysis of an aqueous sample obtained from a suction probe positioned within the root activity zone after the FS is supplied to the soil substrate. The nutrient utilization by the plant species based at least in part upon the FS composition and the chemical composition of the root activity zone is determined by the computing device. An amount of additive that is added to irrigation water to produce a subsequent FS that is supplied to the soil substrate is provided by the computing device.

Description

MONITORING AND CONTROL OF SOIL CONDITIONS CROSS REFERENCE TO RELATED APPLICATIONS This application claims priority to copending US. provisional application entitled “MONITORING AND CONTROL OF SOIL CONDITIONS” having serial no. 61/603,680, filed ry 27, 2012, which is hereby incorporated by reference in its entirety.
BACKGROUND As population continues to increase, food tion becomes an ever expanding problem. Effective use of water resources affects the productivity of ltural farms. In addition, fertilization has become one of the main factors enhancing productivity and quality of agricultural farms. This has resulted in sed consumption of fertilizers worldwide, raising new issues such as increased production costs and contamination effects from agricultural activity.
BRIEF DESCRIPTION OF THE DRAWINGS Many aspects of the invention can be better understood with reference to the following gs. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present ion. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views. is a graphical entation rating the monitoring of the condition of the soil using a plurality of suction probes according to s embodiments of the present disclosure. is a graphical representation of an e a suction probe of according to various embodiments of the present disclosure. is a flow chart illustrating an example of monitoring and control of the soil condition ing to various embodiments of the present disclosure. is a flow chart illustrating an example of sample analysis ing to various embodiments of the present disclosure. is a table illustrating the onship between various additives and their effect in a plant according to various embodiments of the present disclosure. is a flow chart illustrating an example of the composition and/or utilization evaluation of according to various embodiments of the present disclosure. is an example of a system that may be utilized in the monitoring and control of soil conditions according to various embodiments of the present disclosure.
DETAILED DESCRIPTION Disclosed herein are various embodiments related to monitoring and control of soil conditions in, e.g., agricultural applications. Reference will now be made in detail to the description ofthe ments as illustrated in the drawings, wherein like reference numbers te like parts throughout the several views.
Controlled application of water and fertilizers can enhance the productivity of agricultural farms in a sustainable n, ing greater ability, food safety, and environmental preservation. Monitoring the nutritional conditions of the crops may be used to control the application of available resources (e.g., water and fertilizer) to fulfill the plants nutritional needs throughout their evolution; thereby improving productivity and quality of the resulting produce while reducing inputs and loss through Iixiviation.
Analysis of the chemical composition of the soil and/or liquids about the roots of the , as well as diagnosis of the plant condition, can provide an indication of nutrient absorption by the plants which may be used to control ng and/or fertilization. Monitoring of the soil condition may be accomplished using suction probes installed at different depth levels of the root profiles ofthe crops. By extracting aqueous solutions from the soil substrate about the roots, the interaction ofthe root activity and soil conditions may be monitored and used to control the application of nutrients to the soil substrate. For example, the reaction and behavior ofthe inputs (e.g., water, effluents, fertilizers, coadyuvants, chelates, etc.) added to the soil and the on of the soil to these inputs, as well as root activity for nutrient absorption, may be evaluated throughout the phenological cycle of the plants to provide indications that may be used for controlling the application of additives such as, e.g., chemical nutrients in a cyclic or continuous manner.
Referring to shown is a graphical representation illustrating the monitoring of the condition of the soil 103 using one or more suction probes 106 according to various embodiments of the present disclosure. For example, plants 109 of the same species are d in the soil substrate 103 with their roots extending h a root ty zone 112. Water and/or fertilizer solutions 115 may be provided to the plants 109 through drip lines, sprinklers, or other delivery system.
In the example of suction probes 106 are located at a plurality of depths (or ) within the root activity zone 112 of the plant(s) 109. For example, n probes 106 may be placed at two depths (e.g., about 15 cm and about 30 cm) for vegetable crops or three depths (e.g., about 20 cm, about 40 cm, and about 60 cm) for woody plants. Suction probes 106 may also be d at other depths as can be understood. The depth(s) may vary based upon the plant species. In on, probes may be installed at a depth below the root activity zone 112 to monitor for propagation of unused nutrients through the root activity zone 112. Additional suction probes 106 at the same or different depths may also be utilized. For ce, suction probes 106 may be distributed, either individually or in groups, at different locations within a row, bed, and/or field to monitor for variations within the field.
In other implementations, one or more suction probes 106 may be placed at one or more depths in the soil substrate 103 for environmental monitoring such as, e.g., where lixiviation is monitored. For e, in the metal or mining industries where washes and flushing are often used, monitoring for metal or other contamination in the soil ate 103 may be implemented using suction probes 106. Possible ations may include, but are not limited to, static leaching, site monitoring for decontamination, medium and long term monitoring of restoration and/or rehabilitation of affected spaces, leakage and/or spoilage monitoring, etc. using one or more suction probes to obtains samples from a soil substrate. s samples may be analyzed for chemical composition to monitor for variations in the soil substrate 103. Remedial or corrective actions may be taken based upon the red sample composition. Analysis of the samples may be used to provide warnings and/or alarms and/or to propose corrective measures to eliminate or reduce the environmental effects. illustrates an example a suction probe 106 of The suction probe 106 of includes a porous capsule 203 of, e.g., porcelain attached to one end of a tube 206 of inert material such as, e.g., hard rubber, polyethylene, or PVC.
For e, the porous capsule 203 may be about 50mm in diameter and extend from the end of the tube by about 85mm. The porous porcelain may have a thickness of about 5mm with a porosity of about 25-23% and an average porous diameter of about 8-10A. Other chemically inert materials may also be used for the porous capsule 203 such as, e.g., porous c. The porous characteristics of the material used in the porous capsule 203 allow for hydraulic conductivity of aqueous solutions from the soil when a vacuum is drawn inside the n probe 106. The porosity of the porous capsule 203 should allow the monitored chemical composition to enter the suction probe 106 without difficulty. In addition, other shapes and dimensions may also be used for the porous capsule 203 and/or suction probe 106.
A cap 209 (e.g., rubber or PVC) seals the opposite end of the tube 206. A g 212 attached to the cap 209 allows for connection to a vacuum pump to draw a vacuum within the hollow suction probe 106. The fitting 212 may include a valve to allow the vacuum pump to be disconnected while maintaining the vacuum within the suction probe 106.
Referring back to the suction probes 106 are installed in a vertical position within the soil 103 at a plurality of depths within the root ty zone 112.
For example, a hole may be drilled into the soil 103 and the n probe 106 may be inserted to the appropriate depth. In general, a group of n probes 106 are installed in an area of good root activity under the same plant or under neighboring plants that are in the same phenological stage. For example, a group of suction probes may be installed along a crop row of plants that were planted together. The location of the suction probes 106 may also take into account the position of the irrigation system. For instance, a suction probe 106 may be located in the center of a wet area under a drip line. Also, suction probes 106 should be adequately spaced apart (e.g., about 20-30 cm) to allow room for adequate sampling of aqueous solutions from the surrounding soil without competing with an adjacent suction probe 106.
In some implementations, the porous capsules 203 ( of the suction probes 106 may be submerged in water (e.g., for about 15-20 minutes) to allow for hydration of the porous capsules 203. Hydration of the porous capsules 203 can improve the hydraulic connection between the soil 103 and the porous capsules 203.
Hydration may also facilitate insertion of the suction probe 106 into the soil 103. The surrounding soil 103 may also be packed around the suction probe 106 (e. 9., using a wire) to ensure a good hydraulic connection between the porous e 203 and the soil 103. Samples of the soil 103 at various depths (e.g., 0—30 cm and 30-60 cm) may be obtained during installation ofthe suction probes 106. A soil sample may be ed for each of the probe depths. A soil sampling protocol may be followed to ensure that the samples represent a true indication of the soil composition. Analysis of the soil samples can provide base line information about the composition of the soil substrate 103.
After lation of the suction probes 106, s solutions may be ted from the substrate nding the roots of the plant(s) by drawing a vacuum in the suction probes 106. A vacuum pump (not shown) may be connected to the fitting 212 ( to draw a vacuum within a hollow suction probe 106. For example, the vacuum may be in the range of about 0.5 atmosphere (atm) to about 1.0 atm, in the range of about 0.6 atm to about 0.9 atm, in the range of about 0.7 atm to about 0.8 atm, or about 0.8 atm. A meter may be used to indicate the vacuum within the suction probe 106. Once the vacuum has been drawn within the suction probe 106, a valve included in fitting 212 may be closed to maintain the vacuum in the suction probe 106. In some cases, the size of the suction probe 106 may allow a vacuum to be drawn with a manual pump.
The vacuum within a n probe 106 hydraulically ts an aqueous solution from the surrounding soil 103 into the suction probe 106 through the porous capsule 203 (. The volume of the collected solution will depend on the hydraulic conductivity of the soil ate 103 and the water content of the soil 103, as well as the tion time during which the vacuum is maintained in the suction probe 106. For example, the extraction period may be about 2 days to about 4 days.
Vacuum conditions and air tightness depends upon porous characteristics of the al of the porous capsule 203 and the connection with the surrounding soil 103.
In some entations, the vacuum may be maintained within a range of values over the extraction period.
At the end of the extraction period (9.9., after about 48 hours), an aqueous sample is collected from the suction probe 106. An aqueous sampling protocol may be followed to ensure that the samples represent a true indication of the chemical composition of the aqueous sample. For example, the aqueous sample may be ed through a micro tube that passes through the open fitting 212 ( to the porous capsule at the end of the suction probe 106. A syringe (or other extraction device) may be used to extract the aqueous sample from the suction probe 106 through the micro tube. s samples of 30ml or more may be obtained and provided for analysis. In some implementations, a 125ml aqueous sample is obtained. In some embodiments, a separate sampling tube is provided for obtaining aqueous samples through the cap 209 ( of the suction probe 106.
The sampling tube may pass through a separate hermetically sealed opening in the cap 209. A valve in the sampling tube may be used to close off the sampling tube WO 28232 during the extraction period. The valve may then be opened to allow the aqueous sample to be ed from the suction probe 106. The aqueous s from the suction probe 106 may then be provided for chemical analysis and further evaluation.
In addition to the aqueous samples from the suction probe 106, samples of a fertilizer solution (FS) 115 ( that is supplied to the plants 109 may be obtained during irrigation of the plants 109 (. The F8 115 includes irrigation water that may be mixed with additives such as, e.g., fresh or filtered water, residue water, fertilizers, ls, chemicals and/or other nutrients. A sampling protocol may be followed to ensure that the samples represent a true tion of the FS ition. For example, one or more tion device(s) located in the vicinity of the suction probes 106 collect FS 115 during plant irrigation. A plurality of collection devices may be distributed at different locations within a row, bed, and/or field to monitor for ions in distribution of the FS 115 within the field. In the case of drip irrigation, a collection device such as, e.g., an appropriately sized liquid container may receive FS 115 from the drip line through an adapter near the group of suction probes 106 (. Thus, when the plants 109 are being irrigated, the collection device ts a sample of the FS 115 being applied. In the case of sprinkler irrigation, a collection device such as, e.g., an open container may be positioned in the vicinity of the group of suction probes 106 to collect an F8 sample from the discharge of the sprinkler. These examples provide a sample of the FS 115 that is representative of that provided over the entire irrigation time period.
The F8 samples may then be provided for analysis. Analysis of the FS 115 provides information regarding the fertilizer contributions and the conditions of assimilation (e.g., pH, ical conductivity, and ionic relationship). When considered with the aqueous solution analysis and the soil sample analysis, it is possible to evaluate the interaction of the FS 115 with the plant 109 and soil 103 (. For example, plant absorption and/or ation of nts as well as soil interactions such as itation, solubility, ion desorption, etc. may be evaluated.
Samples of irrigation water and tissue of the plants 109 may also be obtained and provided for is. Sampling protocols may be followed to ensure that the samples represent a true indication of the irrigation water composition.
Irrigation water samples may be obtained at the source, before filtering, after filtering, and/or before addition of one or more additives such as, e.g., nutrients and/or chemicals to form the FS 115. Composition of the tion water may be used as, e.g., a baseline in determining adjustments to the additive(s) for the FS 115. For example, mineral salt content may be ed based on the analysis of the irrigation water to meet the nutritional needs of the plants 109. Sampling protocols may also be followed to ensure that the samples represent a true indication of the plant tissue composition. Plant tissue samples may be leaves that are neither old nor too young such as, e.g., the first 5-6 leaves after the apex of a shoot of the plant 109. Other tissue samples include sap, stems, roots, flowers fruit, seeds, etc. that may be obtained during the growth of the plant 109. Sampling protocols may be different for various plant materials such as, e.g., leaf ation, sap, fruit, and flowers.
Sampling protocols will depend upon the species of the plant 109. Analysis of the tissue samples can provide information of the nutritional status of the plant 109 indicating absorption and/or utilization of the additives supplied in the FS 115.
Analysis may take into account evolutionary interpretations ering seasonal changes of the type of plant materials and y level and static interpretations without consideration of seasonal changes.
The analysis of the soil samples, aqueous samples, irrigation water samples, and/or plant tissue samples provides information that may be used in the evaluation of the availability, balances, intakes, and rate of use of the nutrients over the growth cycle ofthe plant 109. For example, analysis of the soil sample at each depth can provide information about the availability of leaching nutrients, allowing evaluation of the ion dynamics within the soil 103 (. In addition, it allows for evaluation of the rate of ation of the fertilizers in the root activity zone 112 ( and/or the behavior of ent additives when added to the soil 103. The information may be used, at least in part, to determine adjustments and/or changes to the FS 115 ( that is applied to the soil 103 with the root activity zone 112.
The ition and analysis of aqueous samples may also be used for static leaching processes. For example, the process may be applied in "Heap" and "Dump" leaching for, 6.9., copper ation, oxidized and primary minerals as porphidic or e sulphides, with the participation of microorganisms in the catalysis of chemical reactions. In addition, monitoring and control of the soil condition may be applied to uranium leaching, gold leaching from oxidized materials or in free form, and/or aching of gold in sulphides ls.
In general, static leaching processes are based on bed packed percolation techniques, which are prepared for that purpose and may be distinguished as two main groups: "heap leaching" and "dumping leaching." The difference between the two groups is based on the volume, control of the process, and the concentrations of the substances to be extracted in the solid matter. "Heap leaching" requires less time to Iixiviate, lower volumes of materials, r legal requirements, and r operational control. In both cases, the process is based on gaining accurate and le information about what happens inside the piles during the heap and dump leaching. Three chemical phases interact in the chemical processes: solid material, the leaching agent, and gas that is dissolved in the liquid or introduced in a forced manner. Moreover, in many cases leaching procedures count on the participation of microorganisms. These proceedings add onal information to the historical analysis of percolation, which allows operational measures to be taken to correct and improve the oning of the process.
Initially, a number of suction probes 106 are installed within the pile as described above. The number of probes 106 may be based upon the volume and surface being examined. The n probes 106 may be situated at various depths to obtain the widest range of information possible. For heap leaching, probe placement can be carried out during construction. Dump leaching may also have one or more suction probe(s) 106 installed during construction but, due to the longevity and long term exploitation, suction probes 106 may be installed after the dump has been built. This may be accomplished by forming (e.g., drilling) a small perforation to introduce a suction probe 106. After installation, aqueous samples may be obtained using the suction probes 106 as described above. The ng schedule (and durations) may be based upon the red process. The ted s samples may be ed to determine data such as, e.g., temperature, oxygen and other dissolved gases, pH, electro conductivity, metal concentrations, other dissolved cations and anions, concentration and/or types of rganisms, and/or organic substances produced as a result of bacterial digestions. Based on the is data, recommendations may be offered in terms of, e.g., volumes of flow, concentration of lixiviating agents, and/or air or gas flow to be injected.
The "in situ" on site monitoring may also be applied in solid-liquid extraction processes used in the cleaning and decontamination of contaminated lands. Applications can include metal contaminated soil close to urban areas or other large facilities which make extraction and transport of the contaminated soil too complicated. Examples e, but are not limited to, metallurgic facilities (smelting, steel industry, ormers, etc), zones with high concentrations of minerals and metals, and/or stations or ties where materials are transferred, loaded or unloaded. In cases where the treatment is made in soil that has not been moved to an al waste management platform, suction probes 106 may be used to permit operational performance follow-ups. The suction probes 106 allow for a simple implementation that can be used for environmentally friendly monitoring. Suction probes 106 may be placed and aqueous samples obtained as described above. The information gained from the analysis of the aqueous samples may be used to prove the efficiency of the applied processes and to determine any r adjustments or corrections to conclude the decontamination task. ing decontamination of soil or other degraded spaces, medium or long term monitoring may be ished using installed suction probes 106. Suction probes can be placed for effective monitoring. In l, for homogenous grounds suction probes 106 are placed a various depths for sampling throughout the soil substrate. In non-homogenous grounds, probes 106 may be positioned to account for the soil variations. Aqueous s can be obtained from the probes 106 to monitor and identify possible metabolites from substances that are not recovered completely. Samples may be analyzed to determine the behavior of substances within the soil and how they degrade and/or ze under different climatic conditions. Once the behavior is known, scheduling of measurements can be optimized and the number of and time n each sampling may be spaced out.
When fully optimized, it may be that suction probes 106 will not provide liquid phase samples, which may indicate good functioning of the monitored system and a lack of a liquid phase in the activity zone. Whenever the ion changes, a gathered sample may be ed and the parameters associated with the origin of the contamination. Corrective actions may be proposed based at least in part upon the analysis results, followed by additional ring and g. n probes 106 may also be installed and used to e alerts and/or prevent leaks and spoilages in processes where barriers are used to protect surrounding environments. In situations where there is a risk of spoilage or possible transfer of products or residues to the ground, early detection of seepage into the surrounding soil can allow for a rapid response.
For example, monitoring may be applied in industrial ties with risk of leakage or losses such as, " and/or "dump" leaching of different metals 9.9., "heap (e.g., copper, uranium, gold, , or others), dumping sites for hazardous wastes, urban garbage dumps or sites, and/or chemical industrial areas with pools or ponds.
The use of cial protection barriers and/or highly impermeable layers in combination with monitoring with suction probes 106 reduces the chance of economic loss or negative environmental impact. The configuration and extent of the barrier used can be taken into consideration to determine the placement of suction probes 106. The suction probes 106 may be vertically situated outside the barrier at one or more depths and/or one or more angles of inclination. A sampling schedule may be defined detailing the frequency and analysis of aqueous samples obtained from the suction probes 106. Immediate notification may be provided to an operator upon detection of an aqueous sample. A protocol may define the type of reporting when there is an s sample as well as when no aqueous solution is t for sampling. Analysis of the aqueous sample can be used to determine if the leak is a similar composition to the substances used by the facility. In some cases, corrective measures may be recommended based at least in part upon the analysis results.
Referring to shown is a flow chart illustrating an example of monitoring and control of the soil condition according to various embodiments of the present disclosure. Beginning with block 303, one or more suction probes 106 ( may be led at one or more depths in the soil substrate 103 (. The soil substrate 103 may include a root activity zone 112 ( of a plant species in the soil substrate 103. One or more of the suction s) 106 may be within the root activity zone 112. The suction probes 106 include porous capsules 203 ( that allow for hydraulic conduction of aqueous solutions from the soil substrate 103 and/or root activity zone 112 when a vacuum is drawn. Holes may be drilled into the soil substrate 103 and one or more suction probe(s) 106 inserted at one or more depths. Samples of the soil substrate 103 may also be obtained at a variety of depths at this time and analyzed to determine the composition of the soil substrate 103. In block 306, a fertilizer solution 115 ( may be supplied to the plants 109 ( by irrigating with, 9.9., a drip line or a sprinkler. A sample of the F8115 may also be collected over a portion of the entire irrigation period in block 306.
Samples are ed in block 309. For instance, a sample (or samples) of aqueous solution(s) may be ed from the n s) 106 (. A vacuum is drawn on each suction probe 106 to induce hydraulic tion of aqueous ons from the soil substrate 103 and/or root activity zone 112 (.
After a predefined time period (9.9., 48 hours), one or more sample(s) of the aqueous solution is extracted from the suction probe(s) 106 and provided for analysis in block 312. The s samples may be analyzed for pH; electrical WO 28232 tivity; anions such as, e.g., N03] H2PO4', HCOa', COJ, 804:, and/or Cl‘; cations such as, e.g., Ca”, Mg”, K+, Na+, and/or NH4+; and microelements such as, e.g., B, Fe, Mn, Cu, Zn, Mo, and/or Urea. A sample of the FS 115 collected over the irrigation period may also be ed from a collection device in block 309 and the composition analyzed in block 312. Plant tissue samples and/or an irrigation water sample may also be obtained in block 309 and analyzed in block 312. The F8 sample, as well as an tion water sample, may be analyzed for the same elements as the aqueous solutions. The tissue sample may be analyzed for, e.g., nitrogen, phosphorous, sulfur, chlorine, calcium, magnesium, sodium, potassium, boron, iron, ese, copper, zinc, and/or molybdenum.
In block 315, the chemical composition and/or the nutrient utilization evaluated based at least in part upon the sample analysis of block 312. Chemical, mineral, and/or nutrient levels in the root activity zone 112 ( may be examined and compared to ined levels associated with the plant species. In some implementations, the levels used for comparison may vary with the phenological stage of the plant 109. Concentrations of marker ions (which are present in the root activity zone 112 but are generally not absorbed by the plant 109) such as, e. g., chlorides and/or sodium at the different depths may also be examined and used to evaluate, e.g., crop absorption of water and evaporation . In addition, ion trations with respect to one or more marker ions may be used to evaluate the utilization of various nutrients. For example, chlorides may be used to determine utilization of nitrogen and/or other anions such as, e.g., NOg', H2PO4', and 804:, sodium may be used to determine utilization of potassium, calcium, magnesium and/or other cations such as, e.g., NH4+, and the combination of chlorides and sodium (e.g., the average of both) may be used to determine utilization of phosphorous or other chemicals and/or nutrients. Based at least in part upon the utilization, consumption of the ions, chemicals, and/or nutrients may also be determined. Effects of the soil composition may also be taken into account during the evaluations. Also, plant tissue analysis may also be used to evaluate the absorption and/or utilization of nutrients by the plants. The evaluation may also take into account variations in the analyzed sample obtained over the growth ofthe plants as well as those ed at different locations within the field. In some cases, analysis information may be compared with broader agricultural segment information during the evaluation.
Corrective (or remedial) measures are provided in block 318 based at least in part upon the evaluation of block 315. For example, corrective measures may include increasing the water dosage to dilute the ions in the root ty zone 112 and/or the soil substrate 103. In some implementations, corrective es may include tion of the plants 109 using irrigation water without the addition of other additives such as, e.g., fertilizers or chemicals. In other cases, the amount of additive(s) to be included in the FS 115 or adjustments to proportions between the chemical components in the FS 115 may be provided. In some implementations, the corrective measures may be automatically applied to the next application of FS 115.
In some entations, other factors may also be considered when determining corrective measures. For e, weather conditions (e.g., temperature, rainfall, wind, etc.) and applied ization strategies (e.g., UF, fractionation, anticipate DFR, etc.) may be accounted for.
The flow chart s the monitoring and control of the soil condition by returning to block 306 where r FS 115, which is based upon the adjustments provided in block 318, is again ed to the plants 109. In this way, the condition ofthe soil may be monitored and controlled in a cyclic or continuous manner to improve crop growth and production. illustrates examples of the composition evaluation that may be carried out on various ed samples in block 315 (. For example, analysis of a sample of the irrigation water 403 may provide information 406 including, e.g., pH level, ical conductivity (CE), l contributions, onates, salty ions, etc. In addition, analysis of the FS 115 may provide information 409 about the irrigation water 406 may include, e.g., pH level, electrical conductivity (CE), the contribution of additives such as, e.g., chemicals and/or nutrients on the irrigation solution, etc. Soil solutions 412 (e.g., aqueous ons and/or soil samples) may also be analyzed to determine soil composition information 415 such as, e.g., chemical and/or nutrient absorption, leaching, pH level, electrical conductivity (CE), salinity levels, etc. Samples of the plant 109 may also be obtained for foliar analysis 418 which may be used to diagnose the nutritional status 421 of the plant 109.
Each condition of the obtained samples may be analyzed and evaluated individually or in conjunction with conditions of the same or other samples in block 315 ( to determine the corrective measures of block 318 (. For example, pH level may be evaluated hout the root activity zone 112 of the plants 109 to quantify the acidity of the soil substrate 103 ( and determine corrective solutions if needed. In general, pH levels are ined in a range of about 6—8, about 6.5—8, or about 5 by adjusting the ition of the supplied FS 115 (. Lower pH levels can pose a risk by increasing the solubility of metals such as, e.g., Al, Mn, Fe, Cu, and Zn. A pH < 5 could produce Aland Mn concentrations that may be toxic. Higher pH levels reduce the solubility of metals, WO 28232 but may need to use chelating agents for Mn, Fe, and Zn. For example, EDTA may be used for a pH < 6.7, DTPA may be used for a pH between 6.7 and 7.8, and EDDHA may be used for a pH > 7.8. Conditions based upon the analysis of the soil samples may also be considered when evaluating the effect of the FS 115 on pH levels.
The salinity condition throughout the root activity zone 112 may also be evaluated based upon, e.g., electrical conductivity (EC) and chloride and sodium content within the aqueous samples to provide an tion of salts and/or fertilizer accumulation and salt leaching in the root activity zone 112. Criteria to te the EC throughout the root activity zone 112 will depend on the plant species. An example of general criteria that may be used to evaluate the chloride and Na concentration ratios is provided in TABLE 1 below. The de concentration ratio (CRci) is the ratio of the average Cl level in the aqueous samples from hout the root activity zone 112 to the CI level in the supplied FS 115 and the sodium concentration ratio (CRNa) is the ratio of the average Na level in the aqueous samples from throughout the root activity zone 112 to the Na level in the supplied FS 115.
CI concentration ratio Medium 1.5—2 1.2-1.5 Na concentration ratio Medium 1.5-2 1.2-1.5 TABLE 1.
The concentration ratio may also be d to other ions, chemicals, and/or nutrients within the root activity zone 112 and the FS 115. For e, the concentration ratio for an ion, chemical, or nutrient X in an aqueous sample may be expressed as: CRx = XAs/XFs where XAS is the average level of the ion, chemical, or nutrient X in the aqueous samples from the various depths of the root activity zone 112 and XFS is the level of the ion, chemical, or nutrient X in the supplied FS 115.
The EC tration ratio (CREC) may also be used to evaluate salinity conditions within the root activity zone 112. The CREC is the ratio of the average EC level in the aqueous samples from throughout the root activity zone 112 to the EC of the supplied FS 115. When the CREC is about 1-1.2, this can indicate that the soil 103 is very permeable. In this case, CRCI and CRNa being about 1—1.2 can indicate low plant activity and/or high drainage. When CRCI and CRNa are > 1.5, this can indicate high plant activity and/or limited drainage. If the EC decreases progressively with depth, this may indicate a strong response from the plant root system (absorption) that is reducing salts from the root activity zone 112. In the case where the CREC tes low permeability (>15), salts are ng the root activity zone 112 faster than they are removed by the plant roots or drained from the root activity zone 112. High root absorption may be indicted by high rates of fertilizer use while low plant activity may be indicated by low rates of fertilizer use.
Crop development and productivity can be limited by the high saline levels indicated by high EC. lf high levels of Cl" and Na+ are present, there is a risk of phytotoxicity, nism, osmotic stress, and soil ation. Washing irrigations and ining the soil moisture at field capacity can reduce the concentrations, however Cl'/N03‘ and Na+/(K++Ca+++Mg++) ratios should to be accounted for by maintaining the ratios at 1 um). If high levels of 8042‘, Ca”, and Mg++ are present, then the irrigation is lly osmotic and washing tions and maintaining the soil moisture at field capacity is . High Ca++ and Mg++ levels can antagonize K+ absorption and H2P04‘ precipitation, so an increase in these nutrient supplies is desirable. Where a mix of both conditions is present, a mix of corrective measures may be used. Acceptable salinity levels and/or limits can vary based upon the plant species and tive measures may be determined accordingly.
Macronutrients such as, e.g., phosphorous, nitrogen, potassium, calcium, and magnesium may also be analyzed and evaluated for availability and to identify nt imbalances and risks of fertilizer leaching. Concentration ratios (CR) may be determined based upon one or more ion levels in the aqueous samples and FS 115.
A utilization rate (UR) of the nutrients with respect to a marker ion may also be determined based at least in part upon the corresponding CRs. For an ion, chemical, or nutrient X, the utilization rate may be expressed as: URX = (1 — (XAs/(XFS x CRMKR») x 100 where XAS is the average level of the ion, chemical, or nutrient X in the aqueous samples from the various depths of the root activity zone 112, XFS is the level of the ion, chemical, or nutrient X in the ed FS 115, and CRMKR is the concentration ratio of the marker ion(s) such as, e.g., chlorides and/or sodium. A ption index (CI) of the nutrients may also be determined based at least in part upon the corresponding URs. For an ion, chemical, or nutrient X, the consumption index may be expressed as: CIX = (URX / 100) x XFs.
The URX and CIX of the ion, chemical, or nt X may be used as key indicators in the evaluation. For example, the URx and CIX may be compared with predefined levels or ranges to determine if corrections may be recommended.
For phosphorous, the ion of H2PO4' may be examined. in the aqueous samples from the root ty zone 112, HZPO4‘ < 10 ppm can indicate low availability, H2PO4‘ in the range of 10-20 ppm can indicate medium availability, and HgPO4‘ > 20 ppm can indicate high availability. In the FS 115, H2P04‘ < 20 ppm can provide a low contribution, H2PO4‘ in the range of 20-40 ppm can provide a medium contribution, and H2PO4‘ > 40 ppm can provide a high bution. The H2P04‘ level in the FS 115 should not be higher than 10% of the NO; level. The utilization rate and consumption index for phosphorous may be determined based upon the levels of H2P04'. Broadcast fertilization may be periodically applied with H2PO4‘ < 6 ppm.
For nitrogen, the condition of N03”, NH4+ and Urea may be analyzed and evaluated. In the aqueous samples from the root activity zone 112, N03‘ < 2 meq/l can te low availability, NO; in the range of 2-4 meq/l can indicate medium availability, and N03_ > 4 meq/l can indicate high availability. A high N03‘ level at the bottom of the root activity zone 112 may indicate a risk of leaching. The nitrogen utilization rate (URN) may also be considered where: URN = (1 — (NAs/(NFs X CRCl)» X 100 where NAS is the average level of N within the root activity zone 112, which may be estimated as the average of N03“ + NH4+ + Urea in the aqueous samples at each depth, NFS is the level of N in the FS 115 ted by the average of N03_ + NH4+ + Urea, and CR0 is the concentration ratio of the chloride marker ion. A URN < 33% can indicate a low use (9.9., ive contribution or low activity during the period), URN in the range of 33-66% ppm can indicate a medium use (e.g., adequate contribution), and URN > 66% can indicate a high bution (e.g., a high activity period or insufficient bution). The nitrogen consumption index may also be determined where: CIN = (URN / 100) x NFs.
The CIN may also be evaluated based upon predefined levels or ranges.
An example of general criteria that may be used to te the nitrogen and chloride ratio is provided in TABLE 2 below. Indications of NH4+ concentrations > 0.3 meq/l may be an indication of an incipient ng environment that can lead to root suffocation problems. Reducing environments may be corrected by, e.g., reduction of FS doses, pulse irrigation, or application of strong oxidizing chemicals such as, e.g., potassium permanganate and/or others.
NICI‘ ratio Adequate Fertilizer Solution Aqueous Solution TABLE 2.
For potassium, the condition of K+ may be analyzed and ted. In the aqueous samples from the root ty zone 112, a level of K+ < 0.3 meq/l can indicate low availability, K+ in the range of 0.3-0.6 meq/l can indicate medium availability, and K+ > 0.6 meq/l can indicate high availability. In the FS 115, K+ < 0.75 meq/l can provide a low bution, K+ in the range of 0.75-1.5 meq/l can provide a medium contribution, and K+ > 1.5 meq/l can provide a high contribution.
The potassium utilization rate (URK) may also be considered where: URK = (1 — (KAs/(KFs X CRCI)» X 100 where KAs is the average level of K+ in the aqueous samples at each depth in the root activity zone 112, Kps is the level of K+ in the FS 115, and CR0. is the concentration ratio of the chloride marker ion. A URK < 33% can indicate a low use (e.g., excessive bution or low activity during the period), URK in the range of 33—66% ppm can te a medium use (e.g., adequate contribution), and URK > 66% can indicate a high contribution (e.g., high activity period or insufficient contribution). The potassium consumption index may also be determined where: CIK = (URK/ 100) x Kps.
The CIK may also be evaluated based upon predefined levels or ranges.
In addition, the ratio of K+ with respect to other cations (or anions), which may affect utilization of K+ by the plant 109, may be examined. For example, the ratio of + + Ca++ + Mg”) may also be evaluated. An example of general criteria that may be used to evaluate the level of Na+ + Ca++ + Mg++ and the K+ ratio is ed in TABLE 3 below.
Na+ + Ca++ K* I (Na+ + Ca“ + Mg”) level + Mg++ level Low Adequate Fertilizer Solution Aqueous Solution TABLE 3.
For calcium, the condition of Ca++ may be analyzed and evaluated. In the aqueous samples from the root activity zone 112, Ca++ < 3 meq/l can indicate low availability, Ca++ in the range of 3-4 meq/l can indicate medium availability, and Ca” > 4 meq/I can indicate high bility. The calcium utilization rate: URCa = (1 — (CaAs/(Caps x CRNa))) x 100 2012/002718 and/or calcium consumption index: CICa = (URCa / 100) X can. may also be considered, where CaAs is the average level of Ca++ in the aqueous samples at each depth in the root activity zone 112, (3an is the level of Ca++ in the FS 115, and CRNa is the concentration ratio of the sodium marker ion. The URCa and/or CICa may be evaluated based upon predefined levels or ranges.
In addition, the ratio of Ca++ with respect to other cations (or anions), which may affect ation of Ca++ by the plant 109, may be examined. For example, the ratios of Ca"+/Na+ and CaH/Mg++ may also be evaluated. Examples of l criteria that may be used to evaluate the ratios are provided in TABLES 4 and 5 below.
Na+ level CaH/ Na+ ratio Adequate Fertilizer Solution Aqueous Solution TABLE 4.
For magnesium, the condition of Mg++ may be ed and evaluated. in the aqueous samples from the root ty zone 112, Mg“ < 1.5 meq/l can indicate low availability, Mg++ in the range of 1.5-2 meq/l can indicate medium availability, and Mg‘L+ > 2 meq/l can indicate high availability. The magnesium utilization rate: URMg = (1 — (MgAs/(Mng x CRNa))) x 100 and/or magnesium consumption index: CIMg = (URMg / 100) x Mng. may also be considered, where MgAs is the average level of Mg++ in the aqueous samples at each depth in the root activity zone 112, Mng is the level of MgJ’+ in the FS 115, and CRNEl is the tration ratio of the sodium marker ion. The URMg and/or CIMg may be evaluated based upon ined levels or ranges.
In addition, the ratio of Mg++ with respect to other cations (or anions), which may affect utilization of Mg++ by the plant 109, may be examined. For example, the ratio of CaH/Mg++ may also be evaluated. An example of general criteria that may be used to evaluate the ratio is provided in TABLE 5 below.
Ca++ level CaHI Mg++ ratio Fertilizer Solution Aqueous Solution TABLE 5. lements (or micronutrients) such as, 9.9., iron, manganese, zinc, copper, boron, etc. may also be analyzed and evaluated for availability and to identify toxicity risks and nutrient imbalances. An example of general criteria that may be used to evaluate microelements in the root activity zone 112 and FS 115 is provided in TABLE 6 below.
Fe Mn Zn Cu B (ppm) (ppm) (ppm) (ppm) (ppm) < 0.5 < 0.25 < 0.15 0.5—2 0.25-1 0.15-0.6 TABLE 6.
The effect(s) of nutrients in the FS 115 on the plant 109 is also considered when determining a corrective measure such as adjusting nt levels in the FS 115 for the next application. illustrates the relationship between added nutrients and their effect in the plant 109. The absorption synergies of the nutrients may also be taken into account when determining the corrective measure of block 318 (. An example of the synergies between the nts is provided in TABLE 7 below.
Reduces the Increases the Assimilation of: assimilation of: assimilation of: Mn, P, 8, Cl Ca, Mg, K, M0 Mn (acidic soils) Mn (basic soils) TABLE 7.
Evaluation of the conditions for ination of the appropriate corrective measures may vary based upon plant species. For example, fruits and vegetables may flourish under very different nutrient conditions. In on, the tolerance of the plant 109 to various ion, chemical and/or nutrient concentrations may also affect the proposed tive measures. Appendix A includes examples of tion ines for peach and nectarine plant species. Appendix A includes guidelines for evaluation of irrigation water quality, foliar (plant tissue), FS and aqueous soil samples. In addition, Appendix A outlines allocation of irrigation according to the growth cycle for both young and adult plants and includes diagnosis and observed corrections based upon aqueous sample evaluation. Correction factors are determined based upon various evaluated conditions to determine the irrigation allocation. The amount of one or more additive(s) may be further refined based upon the chemical composition of the s samples and the irrigation water.
WO 28232 Monitoring and control of the soil conditions may be implemented as an application executable by a computing device. For example, evaluation of the analyzed samples (block 315 of , as well as determination and provision of corrective measures (block 318 of , may be implemented with a soil ring and control application. Corrective measures may be determined based at least in part upon evaluation of the analyzed samples using n recognition, neural network evaluation, and/or other rule based identification methods as can be iated. In addition, supplying a fertilizer solution (FS) (block 306 of , obtaining samples (block 309 of , and/or analyzing the samples (block 312 of may be automated and controlled by the soil monitoring and control application. The soil monitoring and control application may also allow access to stored analysis data through generated network pages or other graphical displays.
Appendix B includes examples of graphical displays that may be rendered for use by a user of the soil ring and l application. The graphical displays may allow the user to access the chemical and/or nutritional monitoring of monitored crops by accessing, e.g., user profiles, evolutionary dynamics, phytomonitoring, ison of plot information, and benchmarking. Evolutionary dynamics allow the user to monitor changes or patterns in s chemical and/or nutrient trations in the aqueous samples (soil solution), plants, fruit, or other contributing factors such as, e.g., irrigation and fertilization. Upper and lower limits may be included as guidelines in the graphical representations. These limits may vary over the life cycle of the plant species. Comparison of plots (or monitored areas) allows corrective measures to be tailored for each monitored area.
Phytomonitoring allows the user to compare the s of multiple parameters to other monitored environmental conditions. As indicated in Appendix A, the allocation of irrigation can vary with the crop cycle of the plant s as well as with the ofthe plant.
Evaluation results for various parameters for irrigation water, soil composition, and plants may also be presented for user access. The evaluation results may also include corrective measures as discussed above, which are identified based upon the tion results. For example, the soil monitoring and control application may provide one or more additives for addition to the irrigation water to improve the chemical composition of the root ty zone to increase growth and productivity. A user may also access client ses to evaluate historical data. One or more monitored parameter(s) may be selected for rendering.
The historical information may be displayed as a spread sheet or may be ed in one of a plurality of graphical formats.
In addition, a variety of reports may be generated by the soil monitoring and control ation. For e, automatic interpretations of the sample analysis may be provided in a report such as, e.g., nutritional analysis of the root activity zone as shown in Appendix C. Such a report can include profile information related to, e.g., salinity, pH, nutritional/chemical composition, and micro and/or macro elements. The report may also include corrective actions that may be implemented to restore and/or maintain the chemical composition of the soil substrate in balance. For example, the report may indicate suitable washes and/or additive(s) for ation to the soil substrate. The report may also include the amount of additive(s) that should be added to irrigation water, based at least in part upon the results of the s solution analysis, to restore a desirable chemical/nutritional composition to the root ty zone and/or soil substrate. The amount of additive(s) may be based upon the evaluated levels of ions, chemicals, and/or nutrients. For example, a table or database may provide a recommended amount based at least in part upon the concentration levels, concentration ratio (CR), utilization rate (UR), and/or consumption index (CI). In other implementations, the ended amount may be determined based at least in part upon the evaluations of the concentration levels, CR, UR, and/or CI using pattern ition, neural network evaluation, and/or other rule based identification s as can be appreciated.
Referring next to shown is a flow chart illustrating an example of the evaluation that may be carried out in block 315 of al composition, concentration ratio (CR), utilization rate (UR), and/or consumption index (CI) can be evaluated based at least in part upon the sample analysis of block 312 (.
Each condition ofthe obtained samples may be analyzed and evaluated individually or in ction with conditions of the same or other samples to determine the tive measures of block 318 (. Beginning with block 603, a plant species is determined for the evaluation of the ed samples. For example, a user may identify the species of the plant 109 ( h a user interface or the species may be determined based upon information associated with the obtained samples or the location the samples were obtained from (e.g., from a user profile stored in a data store). The stage in the growth cycle of the identified plant species is determined in block 606. For example, the stage in the growth cycle may be based upon the current time of the year. The growth cycle may be defined in terms of different growth stages during the growing season at the location of the plant species. In some implementations, the growth cycle is defined by the month of the year. Months in which the plant species are dormant may not be considered. The stage ofthe growth cycle may also be adjusted based at least in part upon the maturity of the plant (e.g., a young plant or adult plant). The age of the plant may also be determined.
Results ofthe analysis ofthe aqueous samples, plant tissue samples, fertilizer on (FS) samples, and/or tion water samples may be used in the evaluation of the availability, balances, intakes, and rate of use of the nts over the growth cycle of the plant 109. For example, in block 609 the analysis results of the aqueous samples may be evaluated to determine the condition of the root activity zone 112 (. Chemical, mineral, nutrient, ion, and/or conductivity levels ofthe aqueous samples may be examined and compared to predefined levels associated with the plant species. The predefined levels may define two or more . The ranges may be defined for an average level of the chemical, mineral, nutrient, ion, and/or conductivity throughout the root activity zone 112 or for each depth of the root activity zone 112. For instance, the predefined levels may define a d range based upon upper and/or lower limits. For example, the level of N03‘ and Cl’ within the root ty zone 112 can be examined and compared to predefined levels associated with the plant species. Tables 1 and 6 illustrate examples of predefined levels for low, medium (or desired), and high ranges for some al compounds and microelements in the root activity zone 112. in other entations, a desired level may be specified with defined upper and lower tolerances. In some cases, predefined levels may be specified for other combinations of ranges such as, 9.9., very low, low, desired, high, and very high.
In addition, concentration ratios with respect to other ions, chemicals, and/or nutrients in the aqueous samples may also be determined and evaluated.
For example, the level of other combinations such as, e.g., K+/Na+, K+/Mg++, Ca”/Na+, CaH/Mg“, and/or NO_o,‘/NH4+ within the root activity zone 112 may also be 2012/002718 evaluated based upon predefined levels. Tables 2-5 illustrate examples of predefined levels for low and adequate (or desired) ranges for various ratios of ions or combinations of ions. The predefined levels for the concentrations and/or ratios may be based at least in part upon historical data and the growth patterns of the plant species. The levels (or ranges) may be varied based at least in part upon the growth cycle and/or maturity of the identified plant species. The predefined levels may change as the growth cycle moves from initial growth to producing blooms to development and ripening of the fruit. The predefined levels may also vary with the maturity of the plant. As the plant species ages, the ional needs of the plant changes. In on, as the root depth changes the predefined levels may adjust for different depth levels of the root activity zone 112.
In block 612, the condition of the plant 109 may be evaluated based at least in part upon the analysis of the plant tissue samples. Plant tissue samples may be taken from, e.g., the foliage, stem, fruit, flowers, and/or roots of the plant 109 and analyzed in block 312 of Chemical, mineral, nutrient, and/or conductivity levels of the plant tissue samples may be examined and compared to predefined levels ated with the plant species. tration ratios with respect to other ions, als, and/or nutrients in the plant tissue samples may also be determined and evaluated. As bed above, the predefined levels may be defined as a plurality of ranges, which may be based at least in part upon historical data and the growth cycle of the plant species. The predefined levels (or ranges) may be varied based at least in part upon where the plant tissue sample was obtained, the growth cycle, and/or maturity ofthe identified plant species. The growth cycle may be defined in terms of different growth stages during the growing season at the location ofthe plant species. In some implementations, the growth cycle is defined by the month of the year and may include months in which the plant species are dormant.
In block 615, the condition of the FS 115 ( is evaluated based at least in part upon the sample analysis of block 312 (. Chemical, mineral, nutrient, and/or conductivity levels of the FS samples may be examined and compared to predefined levels. Concentration ratios with respect to other ions, chemicals, and/or nutrients in the plant tissue samples may also be determined and evaluated. The concentrations and/or ratios may be the same or different than those evaluated for the aqueous samples. The predefined levels may define a ity of ranges such as, e.g., a d range based upon high and/or low level limits for some ions, chemicals, nutrients, and/or microelements in the FS 115. In other entations, a desired level may be specified with defined upper and lower tolerances. In some cases, predefined levels may be specified for other combinations of ranges such as, e.g., very low, low, desired, high, and very high.
The predefined levels (or ranges) may be varied based at least in part upon the growth cycle of the plant 109.
The interaction n the different conditions of the aqueous samples, the plant tissue samples, and/or FS samples in evaluated in block 618. As discussed with respect to the utilization, absorption, and/or consumption of some ions, chemicals and nutrients may be affected by the concentration of other ions, chemicals, lements and/or other nutrients. Different combinations of elements in the aqueous, plant tissue, and FS samples may be evaluated in block 618. Key tors that may be used in the evaluation include the concentration ratio (CR), utilization rate (UR), and consumption index (CI) for various ions, chemicals, and/or nts. For example, the CR, UR, and/or CI may be determined and evaluated for one or more of anions such as, e.g., N033 H2PO4', HCOg‘, CO3=, and/or 804:; cations such as, e.g., Ca”, Mg”, K+, and/or NH4+; and/or microelements such as, e.g., B, Fe, Mn, Cu, Zn, Mo, and/or Urea. The UR for the anions may be determined using, e.g., Cl' as the marker ion and the UR for the cations may be determined using, e.g., Na+ as the marker ion. The CR, UR, and/or CI may also be determined and evaluated for one or more macronutrients such e.g., phosphorous and/or nitrogen based upon one or more anions and/or cations.
The CR, UR, and/or CI may be compared to predefined levels defining a plurality of ranges, which may be varied based at least in part upon the growth cycle and/or maturity of the identified plant species.
Recommendations for corrective measures are then determined in block 621. The recommendations may be determined based at least in part upon the evaluations of the analyzed s using, e.g., pattern recognition, neural network tion, and/or other rule based identification methods as can be appreciated.
The recommendations can include, but are not limited to, changes to the al ition of the FS 115. The recommendations may be take into account the ion (or quality) of the irrigation water (block 624) as determined from analysis of irrigation water samples and/or the condition of the soil in the ty zone 112 (block 627), which may have been determined from the initial samples taken during the installation ofthe suction probes 106. Chemical, nutrient and/or ion concentrations and/or ratios of different chemicals, nutrients, or ions may be determined as described above. The recommendation may also account for the unused portion of the als, nutrients, and/or ions that remain at the s depths of the root activity zone 112 and/or the portions of the chemicals, nutrients, and/or ions that are lost. Recommendation may include the current condition of the chemicals, microelements, pH, electrical conductivity, and/or other nutrients in the activity zone 112, the plant tissue, and/or the FS 115 as well as ended corrections to return the conditions to their desired levels. The recommendations may include specified amounts of chemicals and/or nutrients to the FS 115. The addition of a specific chelating agent may also be recommended based upon the current or projected pH of the activity zone 112. In other cases, the endations may also include the addition of irrigation water to the FS 115 to reduce levels of certain elements. The recommendations may be based upon ion, al and nutrient levels hout the root activity zone 112. ln some cases, the endations may take into account the concentrations at different depths within the activity zone 112.
For example, current nitrogen levels may be compared to desired levels at that stage in the growth cycle to determine if ments may be recommended.
This may include comparison of concentrations at one or more of the probe depths to determine whether the corresponding nitrogen levels need to be adjusted.
Current levels in the FS 115 can also be considered in the evaluation. Key indicators such as CRN, URN, and/or CIN may be determined and utilized to determine the recommendations for corrective measures to eliminate or reduce the environmental effects. The relationship between the analyzed levels and predefined levels ponding to the plant 109 may be used to determine if the nitrogen level of the FS 115 should be adjusted by sing or reducing the levels of, 9.9, NO3' and/or NH4+. If the nitrogen is below or above the desired range, then the current condition may be ed and recommendations may be provided to adjust the conditions. In some cases, the amount of increase or decrease in the chemicals and/or nutrients added to the FS 115 may be determined based at least in part upon the deviation from the d range. In addition, the frequency of the addition may be provided.
Changes between the t and previous nitrogen levels in plant samples from the leaves, stalks, sap, etc, as well as variations from historical profiles over the growth cycle of the plant 109 may also be evaluated and used to determine the recommended adjustment. The interaction with other chemicals and/or nutrients and the effect on absorption and ation by the plant 109 may also be accounted for. For instance, the relationship between the concentrations of N03‘ and Cl" can be examined to determine ifthe appropriate ratio exists for the plant 109. Based upon these relationships, recommendations regarding ments to the FS 115 may be adjusted. For example, if analysis of the aqueous and plant samples indicates that the nitrogen levels are above the predefined level in the root activity zone 112 but are below the predefined level in the plant, the recommendation may be to maintain the current nitrogen level in the FS 115 to ensure that the needs of the plant 109 are met. This recommendation may take into t the stage in the growth cycle and/or the historical profile of the plant 109, as well as current pH level and electrical conductivity.
Similar tions may be carried out for other ions, chemicals and/or nutrients such as, e.g., phosphorus, potassium, calcium, magnesium, um, chlorides, , and/or microelements such as, e.g., iron, manganese, copper, zinc, boron, and/or molybdenum. Key indicators such as CR, UR, and/or CI can be determined for one or more of these ions, chemicals and/or nutrients and utilized to determine a recommendation. The relationship between the analyzed levels and predefined levels corresponding to the plant 109 may be used to determine if the chemical and/or nutrient level of the FS 115 should be adjusted. The interaction with other chemicals and/or nutrients and the effect on absorption, utilization and consumption by the plant 109 may also be accounted for. For potassium, the relationships between the concentrations of K+ and Na+ and/or K+ and Mg++ can be examined to determine if the appropriate ratios exist for the plant 109. For calcium, the relationships between the concentrations of Ca++ and Na+ and/or Ca++ and Mg“ can be ed to determine if the appropriate ratios exist. For magnesium, the relationship between the concentrations of Ca++ and Mg++ can be examined to determine if the appropriate ratio exists. The recommendation of one chemical and/or nt may be ed to take into account changes in the endation of another chemical and/or nutrient.
If lation of one or more microelement(s) is detected, then an appropriate chelating agent (e.g., EDTA, DTPA, EDDHA) may be recommended, while taking into account the current and/or projected pH levels of the root ty zone 112. Adjustment to amino acids, monium phosphate, monopotasium phosphate, magnesium nitrate, and/or calcium fertilizers that are provided to the plant 109 may also be recommended based upon the evaluation of the analysis information. Recommendations regarding adjustments to the irrigation patterns and/or amounts may also be ended based upon the available information.
Drainage and on ions may also be evaluated.
The recommendations may also take into account the locations of the different samples within the field where the plants 109 are located. For example, adjustments to the configuration of the irrigation system may be recommended based at least in part upon differences in the chemical and/or nutrient levels at different locations within the field. Differences in the soil composition at different locations within the field may also be accounted for by recommending different 2012/002718 ization solutions 115 for use in different areas of the field. In addition, corrections to the irrigation practices may be recommended such as, e.g., increasing or decreasing the irrigation cycle. In some cases, variations in weather conditions (current and/or predicted) may also be taken into account when determining the corrective recommendations. Other cultivation operations may also be recommended based at least in part upon the evaluation of the aqueous, plant tissue, and FS samples Referring now to shown is an example of a system 700 that may be utilized in the monitoring and control of soil ions. The system 700 includes one or more computing device(s) 703 and one or more user device(s) 706. The computing device 703 includes at least one processor circuit, for e, having a processor 709 and a memory 712, both of which are d to a local interface 715.
To this end, the computing device(s) 703 may se, for example, a server computer or any other system providing ing capability. The computing device(s) 703 may include, for e, one or more display devices such as cathode ray tubes (CRTs), liquid l display (LCD) screens, gas plasma-based flat panel displays, LCD projectors, or other types of display devices, etc. The computing device(s) 703 may also include, for example various peripheral devices.
In particular, the peripheral devices may include input devices such as, for example, a keyboard, keypad, touch pad, touch screen, microphone, scanner, mouse, joystick, or one or more push buttons, etc. Even though the computing device 703 is ed to in the singular, it is understood that a plurality of computing devices 703 may be employed in the various arrangements as described above. The local interface 715 may comprise, for example, a data bus with an accompanying address/control bus or other bus structure as can be appreciated.
Stored in the memory 712 are both data and several components that are executable by the processor 709. In particular, stored in the memory 712 and executable by the processor 709 are a soil monitoring and control application 718 and potentially other applications. Also stored in the memory 712 may be a data store 721 and other data. The data stored in the data store 721, for example, is associated with the operation of the s applications and/or functional entities described below. For example, the data store may include sample analysis s, corrective measures, and other data or information as can be understood. In addition, an operating system 724 may be stored in the memory 712 and executable by the processor 709. The data store 721 may be may be located in a single computing device or may be dispersed among many different devices.
The user device 706 is representative of a plurality of user devices that may be communicatively coupled to the ing device 703 through a network 727 such as, e.g., the Internet, intranets, extranets, wide area ks (WANs), local area networks (LANs), wired networks, wireless networks, networks configured for communication over a power grid, or other suitable networks, etc, or any combination of two or more such networks. In some embodiments, a user device 706 may be directly connected to the computing device 703.
The user device 706 may se, for e, a processor-based system such as a computer system. Such a computer system may be embodied in the form of a desktop er, a laptop computer, a personal digital assistant, a cellular telephone, web pads, tablet computer s, or other devices with like capability. The user device 706 includes a display device 730 upon which various network pages 733 and other content may be rendered. The user device 706 may be configured to e various applications such as a browser application 736 and/or other applications. The browser application 736 may be executed in a user device 706, for example, to access and render k pages 733, such as web pages, or other network content served up by the computing device 703 and/or other servers. The user device 703 may be configured to execute applications beyond browser application 736 such as, for e, e-mail ations, instant message (IM) applications, and/or other applications.
The components executed on the computing device 703 include, for example, a soil monitoring and control application 718 and other systems, applications, services, processes, engines, or functionality not discussed in detail herein. The soil ring and control application 718 can generate network pages 733 such as web pages or other types of network content that are provided to a user device 706 in response to a t for the purpose of viewing stored data or recommended corrective measures.
It is understood that there may be other applications that are stored in the memory 712 and are executable by the processor 709 as can be appreciated.
Where any component discussed herein is implemented in the form of re, any one of a number of programming languages may be employed such as, for example, C, C++, C#, Objective C, Java, Java Script, Perl, PHP, Visual Basic, , Ruby, Delphi, Flash, or other programming languages.
A number of software components are stored in the memory 712 and are executable by the processor 709. In this respect, the term "executable" means a program file that is in a form that can ultimately be run by the sor 709.
Examples of executable programs may be, for example, a compiled program that can be translated into e code in a format that can be loaded into a random access portion of the memory 712 and run by the processor 709, source code that may be expressed in proper format such as object code that is capable of being loaded into a random access portion of the memory 712 and executed by the processor 709, or source code that may be interpreted by another executable program to generate ctions in a random access portion of the memory 712 to be executed by the processor 709, etc. An executable program may be stored in any portion or ent of the memory 712 including, for example, random access memory (RAM), read—only memory (ROM), hard drive, solid-state drive, USB flash drive, memory card, optical disc such as compact disc (CD) or digital versatile disc (DVD), floppy disk, ic tape, or other memory components.
The memory 712 is d herein as including both volatile and nonvolatile memory and data storage components. Volatile components are those that do not retain data values upon loss of power. atile components are those that retain data upon a loss of power. Thus, the memory 712 may comprise, for example, random access memory (RAM), read-only memory (ROM), hard disk drives, solid-state drives, USB flash drives, memory cards accessed via a memory card reader, floppy disks accessed via an associated floppy disk drive, optical discs accessed via an optical disc drive, magnetic tapes ed via an appropriate tape drive, and/or other memory components, or a combination of any two or more of these memory components. In addition, the RAM may comprise, for e, static random access memory (SRAM), c random access memory (DRAM), or magnetic random access memory (MRAM) and other such devices. The ROM may comprise, for example, a programmable read-only memory (PROM), an erasable programmable read-only memory (EPROM), an electrically erasable programmable read—only memory (EEPROM), or other like memory device.
Also, the processor 709 may represent multiple processors 709 and the memory 712 may represent multiple memories 712 that operate in parallel processing circuits, respectively. In such a case, the local interface 715 may be an appropriate network that facilitates communication between any two ofthe le processors 709, between any processor 709 and any of the memories 712, or between any two of the memories 712, etc. The local interface 715 may comprise onal systems designed to coordinate this communication, including, for example, ming load ing. The processor 709 may be of electrical or of some other ble uction.
Although the soil monitoring and control application 718, and other various systems described herein, may be embodied in software or code executed by general purpose hardware as discussed above, as an alternative the same may also be embodied in dedicated hardware or a combination of software/general purpose hardware and dedicated hardware. If embodied in dedicated hardware, each can be implemented as a t or state machine that employs any one of or a combination of a number of logies. These technologies may include, but are not limited to, discrete logic circuits having logic gates for implementing various logic functions upon an application of one or more data signals, application specific integrated circuits having appropriate logic gates, or other components, etc. Such technologies are generally well known by those skilled in the art and, consequently, are not described in detail herein.
The flowcharts of FIGS. 3 and 6 show the onality and operation of an implementation of portions of a soil monitoring and control application 718. if embodied in software, each block may represent a module, segment, or portion of code that comprises program ctions to implement the ied logical function(s). The program instructions may be embodied in the form of source code that comprises human-readable ents written in a programming language or machine code that comprises numerical instructions recognizable by a suitable execution system such as a processor 709 in a computer system or other system.
The machine code may be converted from the source code, etc. If embodied in hardware, each block may ent a circuit or a number of interconnected circuits to implement the specified logical function(s).
Although the flowcharts of FIGS. 3 and 6 show a specific order of execution, it is understood that the order of execution may differ from that which is depicted. For example, the order of ion of two or more blocks may be led relative to the order shown. Also, two or more blocks shown in succession in FIGS. 3 and/or 6 may be executed concurrently or with partial concurrence. Further, in some embodiments, one or more of the blocks shown in FIGS. 3 and/or 6 may be skipped or omitted. In addition, any number of counters, state variables, warning semaphores, or messages might be added to the logical flow described herein, for es of enhanced utility, accounting, performance measurement, or providing troubleshooting aids, etc. It is tood that all such variations are within the scope of the present disclosure.
Also, any logic or application described herein, including soil monitoring and l application 718, that comprises software or code can be embodied in any non-transitory er-readable medium for use by or in connection with an instruction execution system such as, for example, a sor 709 in a computer system or other system. In this sense, the logic may comprise, for example, statements including instructions and declarations that can be d from the computer-readable medium and executed by the instruction execution system. In 2012/002718 the context of the t disclosure, a "computer-readable medium" can be any medium that can contain, store, or maintain the logic or application described herein for use by or in connection with the instruction execution system. The er- readable medium can comprise any one of many physical media such as, for e, electronic, magnetic, optical, electromagnetic, ed, or semiconductor media. More specific examples of a suitable computer-readable medium would include, but are not limited to, magnetic tapes, magnetic floppy diskettes, magnetic hard drives, memory cards, solid—state drives, USB flash drives, or optical discs.
Also, the computer-readable medium may be a random access memory (RAM) including, for example, static random access memory (SRAM) and dynamic random access memory (DRAM), or magnetic random access memory (MRAM). In addition, the computer-readable medium may be a read—only memory (ROM), a mmable read-only memory (PROM), an erasable programmable read-only memory (EPROM), an electrically erasable programmable read-only memory (EEPROM), or other type of memory device.
Briefly described, one embodiment, among others, comprises a method including obtaining s samples extracted from a plurality of suction probes positioned at multiple depths within a soil substrate including a root activity zone of a plant species in the soil substrate; analyzing the aqueous s to determine a chemical composition of the soil substrate; and determining amounts of an additive that is added to irrigation water supplied to the soil substrate to adjust the chemical composition of the soil substrate based at least in part upon the determined chemical composition and the plant species. At least one of the plurality of n probes may be positioned within the root activity zone. Determining the chemical composition of the soil substrate may comprise determining a al composition of the root ty zone.
The method may comprise ining amounts of a plurality of additives that are added to the irrigation water supplied to the soil substrate to adjust the chemical composition of the soil substrate based at least in part upon the determined chemical composition and the plant species. The additive may comprise water, residue water, fertilizer, or any combination thereof. The method may comprise obtaining a sample of a izer solution (FS) that has been supplied to the soil substrate and analyzing the FS sample to determine a composition of the FS, wherein the determined amount of additive is based at least in part upon the determined FS composition. The F8 may be supplied to the soil ate at least a predetermined time before extracting the aqueous samples from the plurality of n probes. The sample ofthe FS may be collected over an entire irrigation time during which the FS is supplied to the soil substrate.
The method may comprise extracting the aqueous samples from the plurality of suction probes. A vacuum may be drawn on each of the plurality of suction probes to induce hydraulic conduction of aqueous solutions from the soil substrate into each suction probe. The method may comprise obtaining a sample of the tion water and ing the irrigation water sample to determine a composition of the irrigation water, wherein the determined amount of additive is based at least in part upon the determined irrigation water composition. The method may comprise obtaining a tissue sample of the plant species in the root activity zone and analyzing the plant tissue sample to determine a nutritional condition of the plant. The method may comprise ing the determined amounts of additive that is added to the irrigation water to e a fertilizer solution (FS) that is supplied to the soil substrate. The method may comprise mixing the determined amounts of ve with the irrigation water to e the FS and applying the F8 to the soil substrate. The F8 may be applied through a drip line.
Another embodiment, among others, comprises a method including installing a n probe at a depth within a soil substrate; drawing a vacuum on the suction probe to induce hydraulic conduction of aqueous ons from the soil substrate into the suction probe; extracting an aqueous sample from the suction probe after applying the vacuum for a predetermined period of time; and analyzing the aqueous sample to determine a chemical composition at the depth of the soil substrate. The method may comprise installing a plurality of suction probes at multiple depths within the soil substrate; drawing a vacuum on each of the ity of n probes to induce hydraulic conduction of s solutions from the soil substrate into each suction probe; extracting aqueous samples from the plurality of suction probes after applying the vacuum for the predetermined period of time; and analyzing the aqueous samples to determine a chemical composition at the different depths of the soil substrate.
The aqueous samples may be ed to determine chemical composition at different depths of the soil substrate. At least one of the plurality of suction probes may be installed within a root activity zone of a plant species in the soil substrate. The aqueous samples may be analyzed to determine a chemical composition of the root activity zone. The method may comprise determining a corrective measure based at least in part upon the determined chemical composition of the root activity zone. The tive measure may be a g irrigation. The method may comprise obtaining a ity of soil samples at different depths of the root activity zone. The method may comprise determining a corrective measure based at least in part upon the determined chemical composition of the soil substrate.
Another ment, among others, comprises a method including obtaining, by a computing , a composition of a fertilizer solution (FS) that has been supplied to a soil substrate including a root activity zone of a plant species; obtaining, by the computing device, a chemical composition within the root activity zone, the chemical composition determined by analysis of an aqueous sample obtained from a suction probe positioned within the root activity zone after the FS is supplied to the soil substrate; determining, by the computing device, nutrient utilization by the plant species based at least in part upon the FS composition and the al composition of the root ty zone; and providing, by the computing , an amount of additive that is added to irrigation water to e a subsequent FS that is supplied to the soil substrate. The method may comprise obtaining the chemical composition at multiple depths within the root activity zone, the chemical composition determined by analysis of aqueous samples obtained from suction probes positioned at the multiple depths ofthe root activity zone after the FS is supplied to the soil substrate.
The method may comprise obtaining the chemical composition at multiple depths within the root activity zone, the chemical composition determined by is of s samples ed from suction probes positioned at the multiple depths ofthe root activity zone after the FS is supplied to the soil substrate. The method may comprise obtaining nutritional status of the plant species that is based upon is of a tissue sample of the plant species and determining the amounts of nutrients for the subsequent FS based at least in part upon the determined nt utilization and the nutritional status of the plant species. Determining nutrient 2012/002718 utilization may include evaluating marker ion concentrations determined by analysis ofthe aqueous sample. ining nutrient utilization may include determining a nitrogen utilization rate and/or a potassium utilization rate.
It should be emphasized that the above-described embodiments of the present disclosure are merely le examples of implementations set forth for a clear understanding of the principles of the disclosure. Many variations and modifications may be made to the above—described embodiment(s) without departing substantially from the spirit and principles of the disclosure. All such modifications and variations are intended to be ed herein within the scope of this disclosure and protected by the following claims.
It should be noted that ratios, concentrations, amounts, and other numerical data may be expressed herein in a range format. It is to be understood that such a range format is used for convenience and brevity, and thus, should be interpreted in a flexible manner to include not only the cal values explicitly recited as the limits of the range, but also to include all the individual numerical values or sub-ranges encompassed within that range as if each numerical value and nge is explicitly d. To illustrate, a concentration range of “about 0.1% to about 5%” should be interpreted to include not only the explicitly recited concentration of about 0.1 wt% to about 5 wt%, but also include individual concentrations (e.g., 1%, 2%, 3%, and 4%) and the sub-ranges (e.g., 0.5%, 1.1%, 2.2%, 3.3%, and 4.4%) within the ted range. The term “about” can include traditional rounding ing to significant figures of numerical values. In addition, the phrase “about‘x’ to I I" l n) y includes “about‘x’ to about y . 2012/002718 $2.333 _uu_Eu;u-_3_m>;a .3 .cozcmt‘: 9: BomELua we +0 3:9. 3:36 :9: :9; 9:. >tm_Eu;u E 95 ft: Una mcoiaEUmnO $1,558; .95 :om 5 uf cotuznofi 2255030 .mco;utn_ou.a _au_Eu;u._uu_m>;n_ we 55.5% E 33:53.3 :9; +0 mumauhun 9.69523 Bambi m_.om 3 3:63 nam_ :3 5236 < :25 uf mach u m co «cf 2.3 20.6.2. 323; xficmanf E uf.
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OVdem .x. “— e $3233: uEudoTx. x \ \ \ 0.93 : _. = +x 301.0N7vzv fluudxé .5183: V V '3 Av -2 E3338; .m.~ Appendix A ALLOCATION OF IRRIGATION FOR PEACH-NECTARINE TO START FROM 3rd GREEN ACCORDING TO THE PHENOLOGICAL CYCLE I Beginning of sprouting-formation of fruit Provision of irrigation gm3/ha1 Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop cient Kc = 0.5 Correction factors : A Based on values provided by pressure meter T30cm < 15 ab f(Ts): 0.7 T30cm 15 - 20 ch f(Ts): 1 B Based on the water coefficient Cl-40cm <1.5 er f(Ch): 1 CI-40cm >1.5 Cl—water f(Ch): 1.3 CI—40cm <2 Cl-water f(Ch): 1.3 Cl-40cm >2 Cl-water f(Ch): 1.5 CI-60cm >3 Cl—water f(Ch): 1.7 ECéOcm >4.0 mmhos/cm f(Ch): 2 ECéOcm >3 ECwater f(Ch): 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water Cl-waters <25 meq/L f(Cag): 1.2 E Based on the difference in values between samplings CI-40cm current sample >1.3 Cl-40cm previous sample f(t): 1.2 Cl-60cm t sample >1.3 Cl-60cm previous sample f(t): 1,2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 2.5 II Hardening of skin Provision of irrigation lm3/ha1 Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.6 Correction factors 2 A Based on values provided by pressure meter T30cm < 10 cb f(Ts): 0.7 T30cm 12 - 20 cb f(Ts): 1 T60cm <1.8 T30cm f(Ts): 1 T60cm >1.8 T30cm f(Ts): 1.3 B Based on the water coefficient Cl-40cm <1.5 er f(Ch): 1 Cl-40cm >1.5 Cl-water f(Ch): 1.3 Cl-40cm <2 er f(Ch): 1.3 CI—40cm >2 Cl-water f(Ch): 1.5 m >3 Cl-water f(Ch): 1.7 Appendix A ECéOcm >4.0 mmhos/cm f(Ch): 2 ECéOcm >3 ECwaTer f(Ch): 2 C Based on The acTiviTy Young planTing lsT green f(oc)= 0.4 2nd green f(oc)= 0.7 3rd green f(oc)= 1 AdulT planTing f(oc)= 1 D Based on The qualiTy of waTer Cl-waTers <2.5 meq/L f(Cag): 1.2 E Based on The difference in values beTween samplings Cl-40cm current sample >1.3 Cl-40cm previous sample f(T): 1.2 Cl-60cm currenT sample >1.3 Cl—60cm us sample f(T): 1.2 f(Ts) x f(Ch) x f(oc) x f(Cag) x f(T) < 2,0 Si (NH4+)60cm > 0.03 meq/L f(Ts) x f(Ch) x f(oc) x f(Cag) x f(T) < 1.5 III pmenT of The fruiT ion of irrigaTion (m3/ha): Dr = ETO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(T) Crop coefficienT Kc = 0.8 CorrecTion facTors : A Based on values ed by pressure meTer T30cm 10 - 18 cb f(Ts): 1 T30cm <10 cb f(Ts): 0.8 T60cm >1.8 T30cm f(Ts): 1.3 B Based on The waTer coefficienT Cl-40cm <1.5 Cl-waTer f(Ch): 1 Cl-40cm >1.5 Cl-waTer f(Ch): 1.3 Cl-40cm <2 Cl—waTer f(Ch): 1.3 Cl—40cm >2 Cl-waTer f(Ch): 1.5 Cl-60cm >3 Cl-waTer f(Ch): 1.7 ECbOcm >4.0 mmhos/cm f(Ch): 2 EC60cm >3 ECwaTer f(Ch): 2 C Based on The acTiviTy Young planTing lsT green f(oc)= 0.4 2nd green f(oc): 0.7 3rd green f(oc)= 1 AdulT ng f(oc)= 1 D Based on The qualiTy of waTer Cl—waTers <25 meq/L f(Cag): 1.2 E Based on The difference in values beTween samplings m currenT sample >1.3 Cl-40cm previous sample f(T): 1.2 Cl-60cm currenT sample >1.3 Cl—60cm previous sample f(T): 1.2 LimiTaTion f(Ts) x f(Ch) x f(oc) x f(Cag) x f(T) < 1.9 Appendix A Si (NH4+)60cm > 0.04 meq/L f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.5 IV Ripening of fruit-harvest ion of irrigation (m3/ha): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.7 Correction factors : A Based on values provided by pressure meter T30cm 10 - 18 Cb f(Ts)= 1 T30cm <10 cb f(Ts)= 0.8 T60cm >1.8 T30cm f(Ts)= 1.3 B Based on the water coefficient m <1.5 Cl-water f(Ch): 1 Cl-40cm >1.5 Cl—water f(Ch): 1.3 Cl-40cm <2 Cl-water f(Ch): 1.3 CI—40cm >2 Cl-water f(Ch): 1.5 Cl-60cm >3 Cl—water f(Ch): 1.7 ECGOcm >4.0 mmhos/cm f(Ch): 2 EC60cm >3 ECwater f(Ch): 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water Cl-waters <25 meq/L f(Cag): 1.2 E Based on the ence in values between samplings CI—40cm current sample >1.3 Cl-40cm previous sample f(t): 1.2 Cl-60cm current sample >1.3 Cl-60cm previous sample f(t): 1.2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.3 V Post-harvest I - up to 10 days after collection Provision of tion ): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.5 Correction factors : A Based on values provided by pressure meter T30cm 20 — 3O cb f(Ts): 1 T30cm <15 cb f(Ts)= 0.7 T60cm >2 T30cm f(Ts): 1.1 B Based on the water coefficient Cl-40cm <1.5 Cl-water f(Ch): 1 Cl-40cm >1.5 er f(Ch): 1.3 Cl-40cm <2 Cl-water f(Ch): 1.3 Cl-40cm >2 Cl-water f(Ch): 1.5 Cl-60cm >3 Cl—water f(Ch): L7 WO 28232 Appendix A ECéOcm >4.0 mmhos/cm f(Ch)= 2 ECéOcm >3 ECwater f(Ch)= 2 C Based on the activity Young ng lst green f(oc)= 0.4 2nd green f(oc)= 0.7 3rd green f(oc)= Adult planting f(oc)= 1 D Based on the quality of water Cl—waters <2.5 meq/L f(Cag): 1.2 E Based on the difference in values between samplings Cl—40cm current sample >1.3 CI—40cm previous sample f(t): 1.2 Cl-60cm current sample >1.3 Cl-60cm previous sample f(t): 1.2 Limitation ffl's) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.2 VI Post-harvest II - of 10 to 25 days after tion Provision of irrigation gm3/ha): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.4 Correction factors : A Based on values provided by pressure meter T30cm 20 - 30 ch f(Ts): 1 T30cm <15 cb f(Ts): 0.7 T60cm >2 T30cm f(Ts): 1.1 B Based on the water coefficient Cl-40cm <1.5 Cl-water f(Ch)= 1 Cl—40cm >1.5 er f(Ch)= 1.3 CI-40cm <2 Cl-water f(Ch)= 1.3 Cl-40cm >2 Cl-water f(Ch)= 1.5 Cl—60cm >3 Cl—water f(Ch)= 1.7 ECéOcm >4.0 mmhos/cm f(Ch): 2 ECéOcm >3 ECwater f(Ch)= 2 C Based on the activity Young planting lst green f(oc)= 0.4 2nd green f(oc): 0.7 3rd green f(oc)= 1 Adult planting f(oc)= 1 D Based on the quality of water CI-waters <2.5 meq/L f(Cag): 1.2 E Based on the difference in values between samplings Cl-40cm current sample >1.3 Cl-40cm previous sample f(t): 1.2 (El—60cm current sample >1.3 Cl—60cm previous sample f(t): 1.2 tion f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) ( 1_2 VII End of cycle ion of irrigation (m3/ha): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) ix A Crop coefficient Kc = 0.3 Correction factors : A Based on values provided by pressure meter T30cm 30 - 50 ab f(Ts): 1 T30cm <25 cb f(Ts): 0.7 B Based on the water coefficient CI-40cm <15 CI-water f(Ch): 1 Cl-40cm >1.5 er f(Ch): 1.3 CI-40cm <2 Cl-water f(Ch): 1.3 Cl—40cm >2 Cl-water f(Ch): 1.5 Cl-éOcm >3 Cl—water f(Ch): 1.7 ECéOcm >4.0 mmhos/cm f(Ch)= 2 ECbOcm >3 ECwater f(Ch): 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water CI-waters <25 meq/L f(Cag)= 1.2 E Based on the difference in values n samplings Cl-40cm current sample >1.3 Cl—40cm previous sample f(t): 1.2 CI-60cm current sample >1_3 Cl-60cm previous sample f(t): 1.2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1 ix A ALLOCATION OF IRRIGATION FOR PEACH—NECTARINE TO START FROM lst-an GREEN ACCORDING TO THE PHENOLOGICAL CYCLE I Beginning of sprouting-formation of fruit Provision of irrigation (m3/ha) Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.5 Correction factors : A Based on values provided by pressure meter T30cm < 15 cb f(Ts): 0.7 T30cm 15 - 20 ch f(Ts): 1 B Based on the water coefficient Cl-40cm <1.5 Cl—water f(Ch): 1 Cl—40cm >1.5 Cl-water f(Ch): 1.3 Cl-40cm <2 er f(Ch): 1.3 Cl-40cm >2 Cl—water f(Ch): 1.5 m >3 Cl-water f(Ch): 1.7 EC60cm >4.0 cm f(Ch): 2 ECéOcm >3 ECwater f(Ch): 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water ers <2.5 meq/L f(Cag): 1.2 E Based on the difference in values between samplings Cl-40cm current sample >1.3 Cl—40cm previous sample f(t): 1.2 Cl-60cm current sample >1.3 Cl-60cm previous sample f(t): 1.2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 2,5 II Hardening of skin Provision of irrigation (m3/hal Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) Crop coefficient Kc = 0.6 Correction factors : A Based on values provided by pressure meter T30cm < 10 ch f(Ts): 0.7 T30cm 12 - 20 cb f(Ts): 1 T60cm <1.8 T30cm f(Ts): 1 T60cm >1.8 T30cm f(Ts): 1.3 B Based on the water coefficient Cl-40cm <1.5 er f(Ch): 1 Cl-40cm >1.5 Cl-water f(Ch): 1.3 Cl-40cm <2 Cl-water f(Ch): 1.3 Cl-40cm >2 Cl—water f(Ch): 1.5 CI—éOcm >3 Cl—water f(Ch): 1.7 Appendix A ECéOcm >4.0 mmhos/cm f(Ch)= 2 ECéOcm >3 ECwater f(Ch)= 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the y of water Cl-waters <2.5 meq/L f(Cag): 1.2 E Based on the difference in values between samplings Cl-40cm current sample >1.3 Cl-40cm us sample f(t): 1.2 Cl-60cm current sample >1.3 Cl—60cm previous sample f(t): 1.2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 2,0 Si (NH4+)60cm > 0.03 meq/L f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.5 III Development of the fruit Provision of irrigation (MS/ha): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(tiempo) Crop coefficient Kc = 0.8 Correction factors : A Based on values provided by pressure meter T30cm 10 - 18 cb f(Ts): 1 T30cm <10 cb f(Ts): 0.8 T60cm >1.8 T30cm f(Ts): 1.3 B Based on the water coefficient (II—40cm <1.5 Cl-water f(Ch)= 1 Cl-40cm >1.5 Cl-water f(Ch)= 1.3 Cl-40cm <2 Cl—water‘ f(Ch)= 1.3 Cl—40cm >2 Cl—water f(Ch)= 1.5 Cl-60cm >3 Cl-water f(Ch)= 1.7 ECéOcm >4.0 mmhos/cm f(Ch): 2 EC60cm >3 ECwater f(Ch): 2 C Based on the ty Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water Cl—waters <25 meq/L f(Cag): 1.2 E Based on the difference in values between ngs Cl-40cm current sample >1.3 m previous sample f(t): 1.2 Cl-60cm current sample >1.3 Cl-60cm previous sample f(t): 1.2 f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.9 ix A Si (NH4+)60cm > 0.04 meq/L f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.5 V End of cycle Provision of irrigation (m3/ha): Dr = EtO x 10 x Kc x f(Ts) x f(Ch) x f(oc) x f(Cag) x f(tiempo) Crop coefficient Kc = 0.5 Correction factors : A Based on values provided by pressure meter T30cm 20 - 30 ab f(Ts): 1 T30cm <15 cb f(Ts): 0.7 T60cm >2 T30cm f(Ts): 1.1 B Based on the water coefficient m <15 Cl-water f(Ch): 1 Cl-40cm >1.5 Cl-water f(Ch): 1.3 Cl-40cm <2 Cl-water f(Ch): 1.3 Cl—40cm >2 Cl-water f(Ch): 1.5 Cl-60cm >3 Cl—water f(Ch): 1.7 ECéOcm >4.0 mmhos/cm f(Ch): 2 EC60cm >3 ECwater f(Ch): 2 C Based on the activity Young planting lst green f(oc): 0.4 2nd green f(oc): 0.7 3rd green f(oc): 1 Adult planting f(oc): 1 D Based on the quality of water ers <25 meq/L f(Cag): 1.2 E Based on the difference in values between samplings Cl-40cm t sample >1.3 Cl-40cm previous sample f(t): 1.2 Cl-éOcm current sample >1.3 Cl-60cm previous sample f(t): 1.2 Limitation f(Ts) x f(Ch) x f(oc) x f(Cag) x f(t) < 1.2 m. i fiéwfififiwmfimmmfiflwan: CO_H_.m3_m>m mmmmnfimv mEvtmEcucwm 3583qu E26 Hmwhmuc_ 52894 EEC 34"... .m «4%«ammfiwflmd; a} .8383. . mctBEoE mu_Emc>U U6 26m a $83 u cozmamfi EcoEbsz 3.803205 cemthEou mEvtmELucwm watercoEotEa : _m_3_:utm< .H 315028 53:28 650 _mco_umeE_ a“ mctotcoESEm Ema 3.?wv _...__=._ G .>oE<F mE_m_u / @2383 ‘ Qfiafi firm,@flwma m_ co_um:_m>m_ mEmeECwm QwEuom xficmaq< mm 1. 30395532388 Eh Euov Euom __ou_ mm mu_Emc>_o 35:55.22 ”.8th .2380 mmEEmm E a mcUom a“ U6 mctotcoE 39.03203. 3:25:8me 3 $53.; cozmémfi E85532 8E2; Stmqoi OH.mo.mN .mm IOI$U o~.~.o.mfi Eu ofi.mo.mm mucom mfi Eu mucom OHéOfiH a Ofi.mo.No Eu . 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Macaw WV fig EH; L , ZN g m: m: “53>“ @m m m_ “mam. xficmaa< new “mama 0.2530 uzuu Appendix C Date: Crop: Citrus Fruit Parcel: Variety: Mandarin Saline e Mid-EC of the fertilizer solution Elec. Cond. Slight salt stress in the root ty area Suitable salt wash Mid CI concentration within the feitiiiz'ei'soiution Chlorine High CI concentration in soil solution, possible toxicity risk Suitable salt wash Pértilizer solution containing high Na concentration High Na tration in soil, toxicity risk and clay dispersion Insufficient Na wash, unsuitable irrigation dose/ frequency‘ pH profile S.F.R. Low pH at the ESL Soil l soil pH. Conditions of high solubility of most nutrients The acidic pH of the soil makes sufficient the use of chelating agent EDT/537 Nutritional profile Medium Nitrogen content in the PSI.
Correct NO3—lCi— ratio in the F.S.l.
Nitrogen High uptake of the dose of en applied Low NO3—ICI— ratio in the soil solution due to excess of Cl Low Phosphorus content in the F.S.I.
Phosphorous High Phosphorus availability in the higher density of roots area Optimal Phosphorus solubility conditions Medium Potassium t in the F.S.l.
Potasium Medium uptake of the applied Potassium dose Very high Calcium content in the ESL Balanced Calcium concentration respect to the Sodium in the F.S.I.
Calcium Favourable Ca/Mg ratio in the F.S.I. for the Calcium absorption High Calcium concentration in the soil solution Low Ca/Na ratio in the soil on because of the low Calcium t.
High Magnesium content in. the F.S.I.
Magnesium urable Ca/Mg ratio in the F.S.I. for the Magnesium absorption due to high Ca content Fe Very high iron content in the F.S.I. and medium availability in the soil Micro Mn Very high Manganese content in the F.S.I. and Very high availability in the soil Elements Cu Very high Copper content in the F.S.I. and Very high availability in the soil Zn Very high Zinc content in the F.S.l. and Very high availability in the soil B Very high Boron content in the F.S.l. and Very high availability in the soil

Claims (6)

CLAIMS Therefore, at least the following is claimed:
1. A method, comprising: obtaining, by a computing device, a composition of a fertilizer solution (FS) that has been supplied to a soil substrate including a root activity zone of a plant species; obtaining, by the computing device, a chemical ition within the root activity zone, the chemical composition determined by analysis of an aqueous sample obtained from a suction probe positioned within the root activity zone after the FS is supplied to the soil substrate; determining, by the computing , nutrient utilization by the plant species based at least in part upon the FS composition and the chemical composition of the root activity zone; and providing, by the ing device, an amount of additive that is added to irrigation water to e a uent FS that is supplied to the soil substrate.
2. The method of claim 1, further comprising ing the chemical composition at multiple depths within the root ty zone, the chemical composition determined by analysis of aqueous samples obtained from suction probes positioned at the multiple depths of the root activity zone after the FS is supplied to the soil substrate.
3. The method of claim 1, further comprising: obtaining nutritional status of the plant species that is based upon analysis of a tissue sample of the plant species; and determining the amounts of nutrients for the subsequent FS based at least in part upon the determined nutrient utilization and the ional status of the plant species.
4. The method of claim 1, n determining nutrient utilization includes evaluating marker ion concentrations determined by analysis of the aqueous sample.
5. The method of claim 1, wherein determining nutrient ation includes determining a nitrogen utilization rate.
6. The method of claim 1, wherein determining nutrient utilization includes determining a potassium utilization rate.
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