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S1018 Irrigation Management for Humid and SubHumid Areas

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... GA exploring remote sensing crop condition with various imaging systems mounted ... Observations of physiological growth stages, maturity, yield components ... – PowerPoint PPT presentation

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Title: S1018 Irrigation Management for Humid and SubHumid Areas


1
S1018 Irrigation Management for Humid and
Sub-Humid Areas
2
Objective 2
  • Improve irrigation scheduling methods and the
    knowledge application database associated with
  • crop coefficients,
  • reference ET predictions,
  • precipitation forecasting, and
  • field-based sensor systems
  • as they relate to plant water use.

3
Approach a)
  • Development of reference ET crop coefficients
  • Weighing lysimeters,
  • Remote sensing for spectral response,
  • Doppler rainfall information,
  • Modeling to estimate effective rainfall,
  • ET determination water balance calculations
  • Cotton, soybean, peanut

4
Approach a) Development of reference ET crop
coefficients
  • Weighing lysimeters
  • MS, LA, FL, SC using weighing lysimeters for
    reference ET and crop coefficients
  • Improve ET determination under humid conditions
  • Improve models from checkbook to more complex
    physiological models

5
Approach a) Development of reference ET crop
coefficients
  • Remote sensing for spectral response
  • ARS in MS, GA, SC, and GA exploring remote
    sensing crop condition with various imaging
    systems mounted on airplanes, balloons, unmanned
    airplanes, as well as closer to ground units on
    tractor mounts, extension poles and irrigation
    equipment.
  • Frequency and timeliness of imaging in a region
    of unpredictable rainfall make add challenges
  • Canopy temperature normalized difference
    vegetative index (NDVI) most commonly evaluated
  • Examination of effects of background bare soil,
    crop residues
  • Cotton and Peanut

6
Approach b)
  • Field-based approaches to irrigation scheduling
  • Water content sensors - Sentec, TDR
  • Water pressure sensors - Watermark
  • Evaporation scheduling Easy Pan, checkbook
  • Temperature-based Arkansas scheduler,
    IrrigatorPro
  • Yield responses, economic returns
  • Deficit irrigation limited water supplies
  • Cotton, corn, soybean, peanut, rice

7
Approach b) Field-based approaches to irrigation
scheduling
  • Scheduling models using ET estimates, sometimes
    with sensors
  • AR, MO Arkansas Irrigation Scheduler applied to
    rice improved with weather data for better ET
  • LA evaluating Arkansas Irrigation Scheduler for
    soybean cotton
  • Scheduling of drainage of rice fields based on
    whc of soil
  • GA IrrigatorPro models improved for corn, cotton,
    peanut using sensor-based inputs for corn
    cotton continued use of soil temperature for
    protecting peanut quality yield
  • FL developed scheduling guidelines for citrus
    that use reduced applications and earlier cutoff
    to meet Fl demands for reduced irrigation.

8
Approach b) Field-based approaches to irrigation
scheduling
  • Sensor-based scheduling
  • Nearly all states exploring and testing soil
    water sensors for scheduling.
  • Soil water content sensors
  • Capacitance probes Sentec TDR, TDT
  • Dual-frequency capacitance probes - Triscan
  • Soil water pressure sensors
  • Electrical resistance Irrometer Watermark,
    tensiometers
  • Many involve continuous logging devices in field
  • Some of those use radio, cell, satellite
    communications with irrigation controllers (like
    turf applications), base stations, internet
    hosted data.
  • GA, ARS in MS developing low-cost sensing
    logging systems

9
Approach b) Field-based approaches to irrigation
scheduling
  • Sensor-based scheduling
  • Nearly all states exploring and testing soil
    water sensors for scheduling.
  • Some of those use radio, cell, satellite
    communications with irrigation controllers (like
    turf applications), base stations, internet
    hosted data.
  • GA, ARS in MS developing low-cost sensing
    logging systems
  • As VRI options improve we need systems for
    site-specific scheduling tools
  • GA, SC sensor placement in varying
    soil/application

10
Approach b) Field-based approaches to irrigation
scheduling
  • Sensor-based scheduling
  • Nearly all states exploring and testing soil
    water sensors for scheduling.
  • So you know the water content or pressure
  • What trigger water content/pressure?
  • Should that change through the season?
  • How do you deal with changing zones of water
    extraction as roots develop?
  • Sensors have advantage of confirming that an
    irrigation applied water deeply enough or whether
    an excess was applied
  • How many sensor locations needed to manage an
    irrigation system in various sized fields?
  • How do you use sensors if you have to schedule
    water deliveries or withdrawals?

11
Approach b) Field-based approaches to irrigation
scheduling
  • Easy Pan-based scheduling
  • Easy-Pan scheduling
  • GA, LA, ARS-MS peanut, cotton, (corn), pecans
  • Atmometer based ET
  • NC calibrating atmometers with ref-ET and ET
    equations

12
Approach c)
  • Crop physiological response to water
  • Stress levels
  • Irrigation methods
  • Tillage regimes
  • Observations of physiological growth stages,
    maturity, yield components
  • Accurate crop water use functions with
    characterization based on irrigation and soil
    type

13
Approach c) Crop physiological response to water
  • Crop response and irrigation affected by tillage
  • ARS in MS GA, GA comparing water availability
    in conservation vs conventional tillage
  • Corn, cotton, peanut

14
Approach c) Crop physiological response to water
  • Crop response and irrigation affected by
    irrigation method
  • AL, DE, GA, FL examined scheduling in drip
    irrigation, including SDI
  • Type and placement of sensors, dual measurements
    salts fertilizers
  • Vegetables, citrus, corn, cotton, peanut
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