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Laboratory Testing and Calibration of Vertically Oriented
TDR Soil Moisture Sensors
By: Phillip McFarland
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Project Recap:
•Soil Moisture – agricultural, hydro-geological modeling and corrections to groundwater gravity measurements.
•TDR – time domain reflectometry
•VWC – volumetric water content
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θ =VwVt= VwVs +Vp
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Principles of TDR
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c = 1εoμo
→ εo =1c 2μo
v p =1ε 'μ '
→ ε'= 1v p2μ '
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εra ≡ε 'εo= c
2μov p2μ '
assume :μo = μ '
εra =cv p
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εra =ctL
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t =L εrac
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v p =Lt
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θ =0.115 εra −0.176
Maxwell: Explanation of “Relative Permittivity”:
Applications of Relative Permittivity:
Ledieu Equation for VWC:
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TDR Waveforms
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Waveform Interpretation
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Horizontally Oriented Soil Moisture Sensor Probes
•Proven technology
•Very accurate VWC measurement
•Little or no calibration required
•Destructive to soil
•In situ TDR device required
•Costly
•Limited sample volume per probe
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Development of a Vertically Oriented TDR Probe System
Challenges:•Calibration of probe connectors•Larger sample volume•Average VWC over several layers v. local measurement at each layer•Unknown soil constituents may deflect probe installation (i.e. buried stones)•Best material for waveguidesPossible Advantages:•Easy installation•Cost effective•Fewer TDR devices required to survey a large land area. Especially when less frequent measurements are needed.
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First Attempt!!
Results:•38% error!!•Interesting variations in pulse reflection from connectors
•Probe calibration needed•Probe connector offset constant needed
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Theory of Connector Calibration
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twater = to +(Le εrawater (T))
c
tair = to +(Le εraair
c
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to water = twater − t'watertoair = tair − t'air
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t'=Le εrac
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Calibration Method
•20 probe pairs used
•4 pairs @ lengths: 28, 24, 20, 16 and 8 in.
•TDR measurements made in air and DI water
•2 measurements made with each pair of waveguides in each medium with each connector
•160 TDR measurements total made
•Relative permittivity of water and air known
•Measurements compared with theoretical values
•Probe constant isolated empirically
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Results of Calibration
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c = Le 't
Leo '= cto
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Avg.%error ≈ 6%
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Leo '= 0.071m
•Electrical path length constant of waveguide connectors was used to correct previous data collected
•Average % error decreased by nearly 32%
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What’s Next•Develop a field ready model
•Further test existing and new probes and connectors in a wider variety of conditions
•Implement a comprehensive soil moisture system around gravity measurement sites
•Use reliable soil moisture information to correct gravity ground water measurements