Presentation is loading. Please wait.

Presentation is loading. Please wait.

Precision Agriculture an Overview. Precision Agriculture? Human need Environment –Hypoxia –$750,000,000 (excess N flowing down the Mississippi river/yr)

Published byChristine Sanders Modified over 8 years ago

Similar presentations

Presentation on theme: "Precision Agriculture an Overview. Precision Agriculture? Human need Environment –Hypoxia –$750,000,000 (excess N flowing down the Mississippi river/yr)"— Presentation transcript:

1 Precision Agriculture an Overview

2 Precision Agriculture? Human need Environment –Hypoxia –$750,000,000 (excess N flowing down the Mississippi river/yr) Developed vs Developing Countries High vs Low yielding environments

3 Many research & development practices are not designed to foster site-specific management Continued success in wheat germplasm and technology dissemination worldwide depends on the free and uninhibited flow of genetic materials and information. Restrictions imposed on such movement due to intellectual property protection could have serious consequences on the ability of developing countries to sustain wheat productivity growth. …. further gains would have to come from specifically targeting breeding efforts to the unique characteristics of marginal environments

4 What is Precision Agriculture? Treating small areas of a field as separate management units for the purpose of optimizing crop production based on in-field variability

5 Site Specific Management The application of an input to a specific area based on the evaluation of variability of the need for that input. Richardson, 1996. Recognition of site-specific differences within fields and tailoring management accordingly, instead of managing an entire field based on some hypothetical average. Emmert, 1995.

6 Definitions of Precision Agriculture Using information to better manage farms at the field level or finer resolution. Optimizing inputs to produce the largest net income. Combine yield monitors, GPS, Grid Soil Sampling.

7 What is Precision Farming? Management by the Field Management by the foot Global Positioning Systems Yield Monitors Sensor Based Weed Control Grid Sampling Variable Rate Fertilizer Application

8 Oklahoma State University’s Definition of Precision Agriculture Variable rate application of fertilizers, pesticides or other materials based on the sensed needs of the crop within the following constraints: –Available Technology –Agronomic –Economic

9 Large Scale (Macro) Variability Within a Field

10 Intermediate Scale Variability Within a Field IKONI Imagery 4 m Resolution

11 Small Scale (Micro) Variability Within a Field

12 Variability in Weed Populations

13 Variability in Grain Yield

14 Map Based - Precision Farming Map Based - Precision Farming

15 On-the- Go Sensing of Plant Needs and Variable Rate Treatment

16 Map Based vs. Real Time Map Based: 1.Treat next season’s crop 2.Historic information 2. Slowly changing variables e.g. pH 3. Coarse resolution 4. Can directly measure variables e.g. pH Transition: Aerial/Satellite Imagery 1.Sense and treat current crop 2.Near real-time 3.Variables that change rapidly, e.g. N 4.Resolution limited by ability to accurately and precisely locate position Real-Time: 1.Sense and treat current crop 2.Real-Time, sense and treat on-the-go 3.Variables that change rapidly, e.g. N 4.High resolution, 1 m 5.Indirect measurement

17 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1991

18 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1993 1992 First discussion between the Departments of Plant and Soil Sciences and Biosystems and Agricultural Engineering concerning the possibility of sensing biomass in wheat and bermudagrass. Biomass was to be used as an indicator of nutrient need (based on removal).

19 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1994

20 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1995

21 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1996

22 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 1998 www.dasnr.okstate.edu/nitrogen_use 1997

23 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 2000 1999 TEAM-VRT entered into discussions with John Mayfield, Patchen, Inc., concerning the potential commercialization of a sensor-based N fertilizer applicator for cereal crops. 2001

24 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 2002 TreatmentPre- Trt. N, lb/ac Trt. N, lb/ac Total N, lb/ac Yield, lb/ac Net Rtn, $/ac N-Rich Strip 940 44.6110 Var. Rate56237939.8100 Fixed Rate A 56359137.391 Fixed Rate B 58248235.485 Field Rate73209234.682 SED3.19.5 Treated March 20 to April 10, 2002 Net Revenue = grain yield * $3.00 / bu – N Fertilizer * $0.25 / lb SED = Standard Error of the Difference

25 History Oklahoma State University Optical Sensor Based Nitrogen Fertilizer Application 2003

Download ppt "Precision Agriculture an Overview. Precision Agriculture? Human need Environment –Hypoxia –$750,000,000 (excess N flowing down the Mississippi river/yr)"

Similar presentations

What is Precision Agriculture? John K. Schueller.

What is Precision Agriculture? John K. Schueller.
SPONSOR of 4R Nutrient Stewardship Program. The Nature Conservancy Teaming with the Florida agriculture industry to increase farmer profitability and.

SPONSOR of 4R Nutrient Stewardship Program. The Nature Conservancy Teaming with the Florida agriculture industry to increase farmer profitability and.
Crop Science 6 Fall 2004. Crop Science 6 Fall 2004 What is Precision Agriculture?? The practice of managing specific field areas based on variability.

Crop Science 6 Fall Crop Science 6 Fall 2004 What is Precision Agriculture?? The practice of managing specific field areas based on variability.
G OVERNMENT’S R OLE IN P RECISION A GRICULTURE ============================================================= Daniel E. Edmonds ============================================

G OVERNMENT’S R OLE IN P RECISION A GRICULTURE ============================================================= Daniel E. Edmonds ============================================
Use of remote sensing on turfgrass Soil 4213 course presentation Xi Xiong April 18, 2003.

Use of remote sensing on turfgrass Soil 4213 course presentation Xi Xiong April 18, 2003.
INTEGRATED FARMING SYSTEMS November, 2012 1 COMPANY CONFIDENTIAL.

INTEGRATED FARMING SYSTEMS November, COMPANY CONFIDENTIAL.
 Errors or differences in Soil samples ◦ Collection method > laboratory ◦ Environment > laboratory  Field Variability ◦ Composite sample no matter area.

 Errors or differences in Soil samples ◦ Collection method > laboratory ◦ Environment > laboratory  Field Variability ◦ Composite sample no matter area.
Precision Agriculture in Europe Olga S. Walsh BIOEN/SOIL 4213 Spring 2007.

Precision Agriculture in Europe Olga S. Walsh BIOEN/SOIL 4213 Spring 2007.
GreenSeekerTM Variable Rate Applicator Equipment and Applications

GreenSeekerTM Variable Rate Applicator Equipment and Applications
Overview Importance of using GIS Software, GPS Hardware, and Site Specific Data Management for farm management Past and Present / Future Levels of crop.

Overview Importance of using GIS Software, GPS Hardware, and Site Specific Data Management for farm management Past and Present / Future Levels of crop.
Site-Specific Management Factors influencing plant growth Water Light Temperature Soil Compaction Drainage.

Site-Specific Management Factors influencing plant growth Water Light Temperature Soil Compaction Drainage.
Using Yield Data to Make Decisions. Reasons for Collecting Yield Data Document yields Conduct field experiments Bottom-line Considerations Variable Rate.

Using Yield Data to Make Decisions. Reasons for Collecting Yield Data Document yields Conduct field experiments Bottom-line Considerations Variable Rate.
Making the Most of Spatial Technologies: from an Ag Retailer and Service Provider’s Perspective Clint Jayroe Director of Operations – OptiGro Jimmy Sanders,

Making the Most of Spatial Technologies: from an Ag Retailer and Service Provider’s Perspective Clint Jayroe Director of Operations – OptiGro Jimmy Sanders,
A comparison of remotely sensed imagery with site-specific crop management data A comparison of remotely sensed imagery with site-specific crop management.

A comparison of remotely sensed imagery with site-specific crop management data A comparison of remotely sensed imagery with site-specific crop management.
2014 Agronomy Seedsmanship Conference Precision Farming Technologies Overview Dr. Brian Arnall Oklahoma State University.

2014 Agronomy Seedsmanship Conference Precision Farming Technologies Overview Dr. Brian Arnall Oklahoma State University.
Agronomic Spatial Variability and Resolution What is it? How do we describe it? What does it imply for precision management?

Agronomic Spatial Variability and Resolution What is it? How do we describe it? What does it imply for precision management?
What is Precision Agriculture?

What is Precision Agriculture?
Economics of Precision Agriculture, What Technologies are Being Adopted and Why Danny Dallas Soil 4213.

Economics of Precision Agriculture, What Technologies are Being Adopted and Why Danny Dallas Soil 4213.
New Technology and Strategies for Nitrogen Management.

New Technology and Strategies for Nitrogen Management.
Agronomic Spatial Variability and Resolution What is it? How do we describe it? What does it imply for precision management?

Agronomic Spatial Variability and Resolution What is it? How do we describe it? What does it imply for precision management?

Similar presentations

Ads by Google