Relationships between Normalized Difference Vegetation Index and Visual Quality in Turfgrasses: Effects of Mowing Height

Lee, Hyeonju; Bremer, Dale J.; Su, Kemin; Keeley, Steven J.

doi:10.2135/cropsci2010.05.0296

Cited by 41 publications

(50 citation statements)

References 26 publications

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“…X C. transvaalensis Burtt Davy, 'Midiron']. In other studies, vegetation indices calculated from reflectance data were also strongly correlated with visual quality in a number of turfgrass species and under different cultural practices (Bell et al, 2002;Fitz-Rodriguez and Choi, 2002;Keskin et al, 2008;Lee et al, 2011).…”

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confidence: 89%

“…In fact. Lee et al (2011) compared models between two turfgrass species over 2 yr and reported that the models were different between species and between years within each species.…”

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confidence: 99%

“…Therefore, in this 3-yr study our objectives were to statistically compare models of relationships between normalized difference vegetation index (NDVI) and visual quality ratings among four turfgrasses using the same method as Lee et al (2011), who, in research investigating the effects of mowing height on NDVI, only evaluated two grasses over 2 yr. We evaluated relationships between NDVI and visual quality in Kentucky bluegrass, two hybrid bluegrasses, and tall fescue, which are all cool-season turfgrasses.…”

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confidence: 99%

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Relationships between Normalized Difference Vegetation Index and Visual Quality in Cool‐Season Turfgrass: I. Variation among Species and Cultivars

Bremer

Lee

et al. 2011

Crop Science

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Canopy spectrai reflectance may provide an objective means to evaluate visual quality of turfgrass, but evaluations of visual quality may be confounded by differences in reflectance among species or cultivars. In this 3-yr study near Manhattan, KS, we examined effects of species and cultivars on relationships between normalized difference vegetation index (NDVI) and visual quality ratings in Kentucky bluegrass {Poa pratensis L., 'Apollo'), two Kentucky bluegrass x Texas biuegrass {Poa arachnifera Ton.) hybrids (Thermal Blue' and 'Reveille'), and tall fescue {Festuca arundinacea Schreb., 'Dynasty'). A broad range of visual quality was imposed on all four grasses through deficit irrigation and NDVI was measured using broadband spectral radiometry across this range for each grass. Distinct linear regression models of visual quality were found for each grass, and models were also distinct among years in each grass. Relationships between NDVI and visual quality were stronger in the bluegrasses (r^ = 0.41 to 0.83) because they had a greater range in quality under deficit irrigation than tall fescue. The 95% confidence intervals surrounding predictions of visual quality from NDVI ranged from ± 1.25 to 2.10 (on a 1 to 9 scale). Results indicated that the requirement to develop separate models for each grass and in each year, combined with relatively wide confidence intervals, represents a practical limitation to predicting visual quality with NDVI.

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confidence: 89%

“…In fact. Lee et al (2011) compared models between two turfgrass species over 2 yr and reported that the models were different between species and between years within each species.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

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Relationships between Normalized Difference Vegetation Index and Visual Quality in Cool‐Season Turfgrass: I. Variation among Species and Cultivars

Bremer

Lee

et al. 2011

Crop Science

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“…30-0.40. ) Most vegetation indices in turfgrasses have been developed using multispectral, or broadband, radiometry (Trenholm, Carrow, and Duncan 1999;Jiang and Carrow 2007;Bremer et al 2011aBremer et al , 2011bLee et al 2011), including in the study described above by Lee (2008). Multispectral radiometry measures the spectral reflectance of plant canopies in a few bands (e.g.…”

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confidence: 99%

“…The variations in model strength and viability may be related to changes in the density of Kentucky bluegrass during the growing season. For example, in the study area the green biomass of Kentucky bluegrass typically increases during early spring but may decrease during middle to late summer when it is under heat stress (Bremer et al 2006;Lee et al 2011). There may be additional, poorly understood factors of the turfgrass canopy that change over the course of the growing season (e.g.…”

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Using hyperspectral radiometry to predict the green leaf area index of turfgrass

Goldsby

Price

et al. 2015

International Journal of Remote Sensing

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The green leaf area index (LAI) is an important indicator of the photosynthetic capacity of turfgrass canopies. The measurement of LAI is typically destructive and requires large plots to allow for multiple sampling dates. Hyperspectral radiometry may provide a rapid, non-destructive means for estimating LAI. Our objectives were to: (1) evaluate the utility of hyperspectral radiometry to predict the LAI of Kentucky bluegrass (Poa Pratensis L.); and (2) determine regions of the spectrum that provide the best LAI predictions. An empirical prediction model of spectral data for LAI was conducted with partial least squares regression (PLSR). The PLSR method created viable, first-iteration models for five of 11 sampling dates (the coefficient of determination (R 2 ) is 0.52-0.85). Each model had its own set of factors that were analysed to determine their 'weights', or specific regions of the spectrum by which they were most strongly influenced. Second iterations of each model were then created using only those regions most strongly influenced, centred on 600, 690, 761, 960, 1330, and 1420 nm (±10 nm). Four of the five second-iteration models had LAI estimation capabilities greater than or similar to the first-iteration models (R 2 = 0.72-0.86), indicating that the information contained in all other wavelengths was redundant or irrelevant in regard to predictions of LAI. The robustness of prediction models varied over the growing season, possibly related to changes in canopy properties with environmental conditions. Results suggest hyperspectral radiometry has a significant potential to predict LAI in turfgrass, although different models may be required throughout the growing season.

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Reduced creeping bentgrass fairway reflectance following synthetic colorant application

Leiby

Schlossberg

2022

Agricultural & Env Letters

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Repeated measures using multispectral radiometry resolutely quantify canopy attributes of identical turfgrass cultivars under similar management. Concern regarding multispectral radiometric characterization of turfgrass canopies <24 h following synthetic phthalocyanine colorant application has been affirmed and is accordingly now avoided; yet explicit guidance on subsequent employ, at time(s) > 24-h postapplication, is lacking. Our objective assessed how petroleum-derived spray oil (PDSO) and synthetic Cu II phthalocyanine colorant (CPC) combination product influences creeping bentgrass (Agrostis stolonifera L.) reflectance up to 10 d following application. A maintained fairway received semimonthly 9.76 kg ha -1 soluble N treatments alone or in combination with 27 L PDSO+CPC ha -1 . Treatment by PDSO+CPC increased mean shoot growth (kg ha -1 ) and dark green color index (DGCI) calculated by visible waveband reflectance. Yet reduced far red and near infrared reflectance from PDSO+CPC treated plots artificially deflated mean normalized differential vegetative indices. Cautious interpretation of vegetative indices relying on 710-to-810nm canopy reflectance is encouraged when evaluating fairways treated by PDSO and Cu II phthalocyanine combination product(s).

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Relationships between Normalized Difference Vegetation Index and Visual Quality in Turfgrasses: Effects of Mowing Height

Cited by 41 publications

References 26 publications

Relationships between Normalized Difference Vegetation Index and Visual Quality in Cool‐Season Turfgrass: I. Variation among Species and Cultivars

Relationships between Normalized Difference Vegetation Index and Visual Quality in Cool‐Season Turfgrass: I. Variation among Species and Cultivars

Using hyperspectral radiometry to predict the green leaf area index of turfgrass

Reduced creeping bentgrass fairway reflectance following synthetic colorant application

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