Evaluation of a Penman–Monteith approach to provide “reference” and crop canopy leaf wetness duration estimates
Leaf wetness duration (LWD) is a key parameter for plant disease-warning systems since the risk of outbreaks of many plant diseases is directly proportional to this environmental variable. However, LWD is not widely measured so several methods have been developed to estimate it from weather data. Me...
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Published in | Agricultural and forest meteorology Vol. 141; no. 2; pp. 105 - 117 |
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Main Authors | , , , , , |
Format | Journal Article |
Language | English |
Published |
Amsterdam
Elsevier B.V
20.12.2006
Oxford Elsevier New York, NY |
Subjects | |
Online Access | Get full text |
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Summary: | Leaf wetness duration (LWD) is a key parameter for plant disease-warning systems since the risk of outbreaks of many plant diseases is directly proportional to this environmental variable. However, LWD is not widely measured so several methods have been developed to estimate it from weather data. Methods based on the physical principles of dew deposition and dew or rain evaporation have shown good portability and sufficiently accurate results for operational use. A Penman–Monteith approach to modeling LWD on a “reference” wetness sensor located at a weather station was investigated as well as the use of an empirical wetness coefficient (
W) to convert “reference” LWD into crop LWD. This study was undertaken because recent observations revealed that an LWD sensor located about 30
cm above a turfgrass surface provided useful estimates of LWD in various nearby crops, suggesting that modeling such a sensor and location may be a simpler “reference” alternative to modeling LWD in a crop canopy. LWD was measured over mowed turfgrass at different heights (30, 110, and 190
cm above the ground) and at the top of the canopy of eight crops – apple, coffee, cotton, maize, muskmelon, grape, soybean, and tomato – using painted flat-plate sensors. At the same times and places, automatic weather stations measured air temperature, relative humidity, wind speed, and net radiation over turfgrass. A Penman–Monteith approach estimated sensor LWD over turfgrass with very good accuracy and precision, using an additional aerodynamic resistance based on wind speed to estimate LWD at 110 and 30
cm. The model overestimated LWD by 3.3% at 190
cm (
R
2
=
0.92), 1.5% at 110
cm (
R
2
=
0.87), and 5.7% at 30
cm (
R
2
=
0.89). When modeled LWD for a 30-cm height over turfgrass was correlated with LWD measured at the top of crop canopies, strong agreement was observed, with an average overestimation of 6.3% and a coefficient of determination of 0.92 for five crops combined. The use of both general and specific
W coefficients reduced the average overestimation and the mean absolute error in LWD to less than 1
h/day. When independent data from four crops were use to evaluate crop LWD estimates by this two-step Penman–Monteith approach, mean absolute error was <1.6
h when both general and specific
W coefficients were used. We concluded that a Penman–Monteith model for a fixed sensor size, albedo and exposure over turfgrass may be a very useful “reference” index to estimate crop LWD for use in plant disease management schemes. |
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Bibliography: | http://dx.doi.org/10.1016/j.agrformet.2006.09.010 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 |
ISSN: | 0168-1923 1873-2240 |
DOI: | 10.1016/j.agrformet.2006.09.010 |