James L. Wright’s research while affiliated with University of Idaho and other places

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Publications (27)


Figure 1. Locations of National Weather Service (NWS) air temperature stations (diamonds) and automated weather stations (AgriMet, PN/INL, and RAWS) used for wind and dewpoint estimation at NWS (stars).
Figure 2. Locations of NWS air temperature stations (squares) for Nevada used to calculate ET and net irrigation water requirements and select stations (squares with circles) used to assign HUC 8 subbasin (black outlines) average net irrigation water requirements.
Figure 7. Spatially interpolated Ko (dewpoint depression) over Nevada averaged over annual periods and representing reference ET conditions (from Huntington and Allen, 2009).
Figure 8. (a) Simulated greenup (GU) dates for alfalfa for nine locations in Nevada using a CGDD value of 300 °C-days from 1 January versus reported or typical dates, and (b) simulated cutting dates for alfalfa using a CGDD value of 880 °C-days from GU to the first cutting and 740 °C-days for later cutting versus reported or typical dates (from Huntington and Allen, 2009).
Figure 9. Kcb curves of Wright (1982) converted to normalized cumulative growing degree day basis (NCGDD) for application with standardized ASCE PM method for alfalfa reference (from ASCE, 2016).

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Applying the FAO-56 Dual Kc Method for Irrigation Water Requirements over Large Areas of the Western U.S.
  • Article
  • Full-text available

January 2020

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419 Reads

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12 Citations

Transactions of the ASABE (American Society of Agricultural and Biological Engineers)

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Highlights The FAO-56 dual crop coefficient procedure was applied over the entire agricultural areas of Idaho and Nevada to determine evapotranspiration (ET) and net irrigation water requirements (IWR). Basal crop coefficients were expressed as functions of normalized cumulative growing degree days. ET during dormant seasons was included in the estimates. The procedure was applied to a U.S. West-wide study of climate change effects on ET and IWR. Abstract . The FAO-56 dual crop coefficient procedure was used to determine evapotranspiration (ET) and net irrigation water requirements for all agricultural areas of the states of Idaho and Nevada and in a western U.S. study on effects of climate change on future irrigation water requirements. The products of the applications are for use by state governments for water rights management, irrigation system planning and design, wastewater application system design and review, hydrologic water balances, and groundwater modeling. The products have been used by the U.S. federal government for assessing impacts of current and future climate change on irrigation water demands. The procedure was applied to data from more than 200 weather station locations across the state of Idaho, 200 weather station locations across the state of Nevada, and eight major river basins in the western U.S. for available periods of weather records. Estimates were made over daily, monthly, and annual time intervals. Methods from FAO-56 were employed for calculating reference ET and crop coefficients (Kc), with ET calculations performed for all times of the calendar year including winter. Expressing Kc as a function of thermal-time units allowed application across a wide range of local climates and elevations. The ET estimates covered a wide range of agricultural crops grown in the western U.S. plus a number of native plant systems, including wetlands, rangeland, and riparian trees. Evaporation was estimated for three types of open-water surfaces ranging from deep reservoirs to small farm ponds. Keywords: Consumptive use, Dual crop coefficient, Evapotranspiration, FAO-56, Irrigation water requirements.

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Estimation of Evaporation and Evapotranspiration during Nongrowing Seasons Using a Dual Crop Coefficient

May 2009

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48 Reads

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4 Citations

Evapotranspiration and net irrigation water requirement estimates were updated in 2007 by Allen and Robison (2007; Allen et al., 2007) for agricultural areas in Idaho. ET calculation procedures were employed that use an updated procedure to calculate crop coefficients that considers the impact of surface wetting by irrigation and precipitation on total evapotranspiration. ET was calculated for daily, monthly and annual timesteps for 123 weather station locations across Idaho for complete, available periods of record. ET estimates were made for all times during the calendar year including winter to provide design and operation information for managing land application of agriculture, food processing and other waste streams and to provide full-calendar year estimates of E and ET for hydrologic studies and to estimate beginning of growing season soil water content.


Satellite-Based Energy Balance for Mapping Evapotranspiration With Internalized Calibration (METRIC) – Applications

August 2007

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3,823 Reads

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827 Citations

Journal of Irrigation and Drainage Engineering

Recent satellite image processing developments have provided the means to calculate evapotranspiration ET as a residual of the surface energy balance to produce ET "maps." These ET maps i.e., images provide the means to quantify ET on a field by field basis in terms of both the rate and spatial distribution. The ET images show a progression of ET during the year or growing season as well as its spatial distribution. The mapping evapotranspiration at high resolution with internalized calibration METRIC is a satellite-based image-processing procedure for calculating ET. METRIC has been applied with high resolution Landsat images in southern Idaho, southern California, and New Mexico to quantify monthly and seasonal ET for water rights accounting, operation of ground water models, and determination of crop coefficient populations and mean curves for common crops. Comparisons between ET by METRIC, ET measured by lysimeter, and ET predicted using traditional methods have been made on a daily and monthly basis for a variety of crop types and land uses. Error in estimated growing season ET was 4% for irrigated meadow in the Bear River basin of Idaho and 1% for an irrigated sugar beet crop near Kimberly, Id. Standard deviation of error for time periods represented by each satellite image averaged about 13 to 20% in both applications. The results indicate that METRIC and similar methods such as SEBAL hold substantial promise as efficient, accurate, and inexpensive procedures to estimate actual evaporation fluxes from irrigated lands throughout growing seasons.


Fig. 1 Water potential at soil depths of 23, 46, and 92 cm before and after each of four irrigations for two dry bean landraces and four cultivars evaluated under an intermittently drought-stressed environment at Kimberly, Idaho in  
Water use efficiency among dry bean landraces and cultivars in drought-stressed and non-stressed environments

April 2007

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782 Reads

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81 Citations

Euphytica

The agricultural use of water is higher than 85% in the western USA, resulting in an increasing water deficit in the region; this situation is commonly encountered throughout the world where irrigated and irrigation-assisted production systems are operational. The objective of this study was to examine differences among dry bean (Phaseolus vulgaris L.) landraces and cultivars in terms of water use efficiency (WUE), subsequently identifying those with a high water use efficiency. Six medium-seeded (25-40 g 100 seed wt-1) landraces and cultivars of pinto and red market classes were evaluated in intermittent drought-stressed (DS) and non-stressed (NS) environments at Kimberly, Idaho, USA in 2003 and 2004. Each market class comprised one each of a landrace and old and new cultivars. Mean evapotranspiration (ET) in the NS environment was 384 mm in 2003 and 432 mm in 2004; the respective ET values in the DS environment were 309 and 268 mm. Mean seed yield was higher in the DS (2678 kg ha-1) and NS (3779 kg ha-1) environments in 2004 than in 2003 (688 and 1800 kg ha -1, respectively). Under severe drought stress in 2003, WUE in the pinto bean ranged from 1.5 for the Common Pinto landrace to 4.4 kg ha -1 mm-1 water for cv. Othello. The Common Red Mexican landrace had the highest WUE (3.7), followed by cvs. NW 63 (2.8) and UI 259 (1.4) in the red market class. Under favorable milder climatic conditions in 2004, the mean WUE value was 10 kg ha-1 mm-1 water in the DS environment and 8.7 kg ha-1 mm-1 water in the NS environment. We conclude that dry bean landraces and cultivars with high WUE should be used to reduce dependence on irrigation water and to develop drought-resistant cultivars to maximize yield and WUE.


Development and validation of canopy reflectance-based crop coefficient for potato

February 2007

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82 Reads

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98 Citations

Agricultural Water Management

The present paper describes the development and validation of canopy reflectance-based crop coefficients for potato using canopy reflectance (measured using hand-held radiometers and high resolution multispectral digital imagery), and extensive crop biophysical sampling in selected potato growing fields in and around Kimberly, Idaho, during 1998 and 1999 seasons. Daily crop evapotranspiration was estimated using basal and canopy reflectance-based crop coefficients, and a hydrologic water balance was conducted in the plant root zone. Independent measurements of actual soil moisture measurements were made by neutron probe and gravimetric methods, and used to validate the simulated results. The results validate the reflectance-based crop coefficient method. High resolution multispectral aerial imagery was used to highlight the spatial variability of actual crop water demand in the study fields.



Selection for Drought Resistance in Dry Bean Landraces and Cultivars

September 2006

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723 Reads

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177 Citations

Drought is a worldwide constraint to dry bean (Phaseolus vulgaris L.) production. The objective of this research was to determine the response of three dry bean landraces and 13 cultivars evaluated under non-stressed (NS) and intermittent drought-stressed (DS) environments at Kimberly, Idaho in 2003 and 2004. The NS received seven irrigations in 2003 and five in 2004, and DS only four in 2003 and two in 2004. Most water use occurred within the top 0.5 m soil in both the NS and DS. Drought reduced biomass and seed yield, harvest index, and seed weight. Maturity was delayed in severe drought, but was similar or shortened by 1 to 6 d under moderate drought. Mean seed yield was reduced by 62% in 2003 and by 27% in 2004. Common Red Mexican and CO 46348 had high seed yield in both NS and DS environments, whereas 'Matterhorn' and 'Othello' yielded comparatively high under DS but moderately in NS environment. Drought resistance was inadvertently reduced from Common Red Mexican landrace to intermediate levels in 'NW-63' and 'UI 239' released in 1979 and 1993, respectively, and more recently released 'LeBaron' (1999) and 'UI 259' (1996) were susceptible. Conversely, drought resistance was increased in newer pinto (Othello 1986; CO 46348) and great northern (Matterhorn 1998) releases compared to the landraces and older cultivars tested for those market classes. Seed yield in NS and DS was positively correlated. Seed yield was also correlated with harvest index in DS and NS. All early maturing cultivars except Othello (e.g., UI 59, US 1140, Common Pinto, Topaz, UI 320, and LeBaron) were susceptible. Common Red Mexican did not have any reduction in seed weight due to drought stress. Drought resistant genotypes should be used for determining irrigation frequency, amount of water to be applied, and mechanisms of resistance and for identifying, mapping, and pyramiding favorable genes for dryland and irrigation-assisted sustainable production systems.


A recommendation on standardized surface resistance for hourly calculation of reference ETO by the FAO56 Penman-Monteith method

March 2006

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1,023 Reads

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711 Citations

Agricultural Water Management

Continued development of networks of electronic weather stations worldwide has increased the availability of weather data for calculating ETo on an hourly basis. There has been question and debate as well as studies on the appropriate expression and parameterization for the surface resistance (rs) parameter of the Penman-Monteith (PM) equation and the associated coefficient for the reduced form FAO-PM equation when applied hourly. This paper reviews the performance of the FAO-PM method using rs = 70 s m−1 for hourly periods and using a lower rs = 50 s m−1 value during daytime and rs = 200 s m−1 during nighttime. Variability in hour to hour trends in rs among locations and dates makes it difficult, if not impossible, to establish a consistent algorithm for rs. However, the relatively good and consistent accuracy in ETo when using a constant rs = 50 s m−1 during daytime gives good reason to recommend this value as a standardized parameter and coefficient for calculating ETo. Based on a national study in the U.S. and studies by European and American researchers, the authors recommend that the FAO-PM ETo method from FAO56, when applied on an hourly or shorter basis, use rs = 50 s m−1 for daytime and rs = 200 s m−1 for nighttime periods. This use will provide, on average, good agreement with computations made on a 24-h time step basis. No changes are suggested for the FAO-PM method for daily (24-h) time steps, where use of rs = 70 s m−1 should continue.


Fig. 1(a)
Figure 5 . Comparison of simulated aggregated water demand using reflectance based crop coefficients with the actual water deliveries in the Smithfield canal command area, Utah. Though no measurements of application efficiency were conducted in the mostly sprinkler irrigated fields, the results compared well with the demand (Q) plus 20% values shown in the 
Irrigation water management using high resolution airborne remote sensing

November 2005

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509 Reads

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79 Citations

Irrigation and Drainage Systems

This paper offers a historical retrospective on the remote sensing of crop coefficients for obtaining actual crop evapotranspiration. We present the canopy reflectance-based approach of crop coefficients and show the usefulness of high-resolution airborne imagery as a tool for monitoring the actual crop growth changes and characterizing in-field variability in an objective manner.


Operational Aspects of Satellite-Based Energy Balance Models for Irrigated Crops in the Semi-Arid U.S

November 2005

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823 Reads

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177 Citations

Irrigation and Drainage Systems

SEBAL and METRIC remote sensing energy-balance based evapotranspiration (ET) models have been applied in the western United States. ET predicted by the models was compared to lysimeter-measured ET in agricultural settings. The ET comparison studies showed that the ET estimated by the remote sensing models corresponded well with lysimeter-measured ET for agricultural crops in the semi-arid climates. Sensitivity analyses on impacts of atmospheric correction for surface temperature and albedo showed that the internal calibration procedures incorporated in the models helped compensate for errors in temperature and albedo estimation. A repeatability test by two totally independent model applications using different images, operators and weather datasets showed that seasonal estimations by the models have high repeatability (i.e. stable results over ranges in satellite image timing, operator preferences and weather datasets). These results imply that the SEBAL/METRIC remote sensing models have a high potential for successful ET estimation in the semi-arid United States.


Citations (21)


... fields with larger slopes), it is regionally a small component of the water balance and is unlikely to explain systematic patterns of model errors observed across our study area (Deines et al., 2021). The consistent positive precipitation deficit for rainfed corn (Fig. 9) further suggests that effective precipitation is being underestimated by our approach, and calculating effective precipitation using a field-specific soil water balance model approach such as ETDemands (Allen et al., 2020) could help to improve overall agreement. Issues with ET data may also be greater during wet conditions, as we would expect greater errors in calculated ET, and therefore irrigation, for periods or regions with increased cloud cover that affect the optical and thermal bands of satellites used by ET models. ...

Reference:

Estimating irrigation water use from remotely sensed evapotranspiration data: Accuracy and uncertainties at field, water right, and regional scales
Applying the FAO-56 Dual Kc Method for Irrigation Water Requirements over Large Areas of the Western U.S.

Transactions of the ASABE (American Society of Agricultural and Biological Engineers)

... (ii) Physical and water holding characteristics for each soil layer (Table 2), initial values for the thickness of the soil evaporation layer (Z e , m) and the readily and total evaporable water (REW and TEW, mm); and the soil moisture at sowing (expressed as % of TAW). (iii) Initial values for the parameters of algorithms used to estimate runoff, with CN from Allen et al. (2007), and deep percolation a DP and b DP following Liu et al. (2006). ...

Chapter 8. Water Requirements

... where σ is the Stefan-Boltzman constant (4.895 × 10-9 −2 −1 −4 ), T is the average air temperature, f is a factor to adjust for cloud cover, and ε is the atmospheric emissivity. Wright and Jensen et al., [27] proposed the following equation for f: f = a + (14) and Brunt [28] developed an empirical equation for atmospheric emissivity ε: ...

Peak Water Requirements of Crops in Southern Idaho
  • Citing Article
  • June 1972

Journal of the Irrigation and Drainage Division

... Generally, G represents 5-20% of Rn during daylight hours . Since G cannot be directly measured remotely, several models have been proposed to estimate G based on the G/Rn ration as a function of soil and vegetation characteristics Burba et al., 1999;Ma et al., 2002;Payero et al., 2001;Tasumi, 2003). ...

Estimating Diurnal Variation of Soil Heat Flux for Alfalfa and Grass
  • Citing Conference Paper
  • January 2001

... Various empirical equations (Romanenko 1961;Ahooghalandari et al. 2016), including the FAO-24 Blaney-Criddle method (Doorenbos and Pruitt 1975), directly use the value of RH for estimating evapotranspiration. Also, RH values are required for the modification of crop coefficient values according to a given climate (Allen et al. 2005;Allen and Wright 2009). Crop coefficient values are used to estimate the values of the actual crop evapotranspiration of a given site. ...

Estimation of Evaporation and Evapotranspiration during Nongrowing Seasons Using a Dual Crop Coefficient
  • Citing Conference Paper
  • May 2009

... Crop coefficient K c (t) is used in calculating evapotranpirtion as shown in equation 2. Several studies (ElGhandour et al., 2019;Jayanthi et al., 2001;Irmak et al., 2011) show that remote sensing based techniques can be used to measure crop coefficient. Crop coefficient K c (t) and normalized difference vegetation index (NDVI(t)) have a linear relationship (Trout and Johnson, 2007;D'Urso, 2010) ...

Seasonal evapotranspiration estimation using canopy reflectance: A case study involving pink beans

... Daily gridded data (25 km²) for the hindcast period was obtained from the Joint Research Centre's (JRC) Agri4Cast database (version 2.0) for the variables daily minimum, average and maximum surface air temperature, precipitation, 10-m wind speed, global radiation, and actual vapour pressure at 25 km spatial resolution for Europe covering the EU-27 countries plus UK, Croatia, Serbia, Bosnia and Herzegovina, Montenegro, Albania, North Macedonia, Norway, Liechtenstein and Switzerland. Wind speed was converted to an estimate at 2 m height following Allen & Wright (1997). ...

Translating Wind Measurements from Weather Stations to Agricultural Crops

Journal of Hydrologic Engineering

... The reference crop in the PM-ET0 method is considered a standard crop that represents ideal conditions for evapotranspiration calculations. It has a fixed height of 12 cm, a surface resistance of 70 sm −1 , and an albedo (reflectivity) of 0.23, which approximates the evapotranspiration rate of a crop that is free of disease infection and is of uniform and vigorous growth, has complete coverage of the soil surface, adequate water and nutrient supply, and an expansive surface for the crop evapotranspiration process [33]. The specific formula is as follows: ...

Development and Evaluation of Evapotranspiration Muueis for Irrigation Scheduling

Transactions of the ASAE. American Society of Agricultural Engineers

... Although higher accuracy reference methods are always desirable, the 42 mm diameter cores were near the maximum size that was feasible in these soils with the available coring equipment. In future studies, use of larger diameter cores should be considered, perhaps along with an assessment of BD measurement accuracy similar to that described by Allen et al. (1993). Penetrometer and SSPS data were collected at S3 in October 2005 as part of a project to compare SSPS performance with another on-the-go soil strength sensor (Adamchuk, Ingram, Sudduth, & Chung, 2008). ...

Error analysis of bulk density measurements for neutron moisture gauge calibration

... Detection of contamination entrance to distribution networks is done by monitoring stations. In this regard and in order to increase the reliability of the network, the installation of quality sensors can be considered as a high-efficiency strategy for contamination crisis managing of water distribution networks [2,3]. ...

Weather Station Siting and Consumptive Use Estimates

Journal of Water Resources Planning and Management