Evaluation of Key Methodology for Digital Image Analysis of Turfgrass Color Using Open‐Source Software

Zhang, Chenxi; Pinnix, Garland D.; Zhang, Zheng; Miller, Grady L.; Rufty, Thomas W.

doi:10.2135/cropsci2016.04.0285

Cited by 10 publications

(12 citation statements)

References 14 publications

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“…Thus, experiments with digital image analysis are efficient to estimate the nutritional status of the lawn (Zhang et al, 2017), especially with regard to nitrogen, and corroborate the studies that correlate this analysis with nitrogen doses by Backes et al (2010), Lima et al (2012), Agati et al (2015) and Gazola et al (2016).…”

Section: Resultssupporting

confidence: 73%

Sewage sludge composted in the coloring and development of Bermuda grass

et al. 2020

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‘Barazur’ or DiscoveryTM (Cynodon dactylon) is a new variety of Bermuda grass that has slow vertical growth and a bluish-green colour, and the use of sewage sludge in implantation of this species may be an alternative for its sustainable cultivation, without need for chemical fertilizers. Thus, the objective was to evaluate the influence of sewage sludge compound on colour and development of Bermuda grass DiscoveryTM. The experiment was conducted in the field with sod implanted in black plastic containers (volume 8.46 L) filled with soil + sand (1:1) and added different dosages of sludge compost, being: 0 g L -1 (control), 30 g L-1, 60 g L-1 and 120 g L-1. Digital image analysis, fresh and dry leaf mass, Nitrogen leaf and Nitrogen leaf accumulation were evaluated. It was observed that the sewage sludge influenced on turfgrass colouring and development, where 30 g L-1 showed excellent results for colouring with less mass production and N accumulation than the highest dose, showing that this treatment is sufficient for lawn development, without the need of using higher concentrations of compound. It is concluded that the use of composted sewage sludge at a dose of 30 g L-1 is recommended for use in implantation of Bermuda grass DiscoveryTM.

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Section: Resultssupporting

confidence: 73%

Sewage sludge composted in the coloring and development of Bermuda grass

et al. 2020

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“…Zhang et al. (2017) reported that θ generally outperformed saturation or brightness when used to identify turfgrass color variations among genotypes or due to fertility levels. However, the current research suggests concurrent analysis of saturation and brightness (or analogous components) along with θ may be required to obtain a more complete picture of color.…”

Section: Resultsmentioning

confidence: 99%

“…The same is true for DGCI. While DGCI was effective in assessing turf colors (Zhang et al., 2017) and does include aspects of saturation and brightness, it may not be suitable for examining colors other than green, which may preclude follow‐up assessment of shoots treated with herbicides or growth regulators or other chemicals or cultural practices known to elicit phytotoxicity reducing green color.…”

Section: Resultsmentioning

confidence: 99%

“…Specifying color in digital images of turfgrass is straightforward (Berndt, Riger, & Riger, 2018a; Karcher & Richardson, 2013; Zhang, Pinnix, Zhang, Miller, & Rufty, 2017) but reporting of resulting color space data may be improved by differentiating colors in photographs more accurately. Having the ability to accurately differentiate colors is important because color differentiation has implications for many facets of turfgrass research involving pesticides, fertilizers, colorants, cultivars or species, and/or other areas.…”

Section: Introductionmentioning

confidence: 99%

“…Having the ability to accurately differentiate colors is important because color differentiation has implications for many facets of turfgrass research involving pesticides, fertilizers, colorants, cultivars or species, and/or other areas. Statistical analysis of hue angle (θ) and a hue, saturation, brightness (HSB) color space derivative, termed dark green color index (DGCI), have been a basis for identifying and reporting color differences in turfgrass research (Karcher & Richardson, 2013; Zhang et al., 2017).…”

Section: Introductionmentioning

confidence: 99%

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Color‐distance modeling improves differentiation of colors in digital images of hybrid bermudagrass

Berndt¹,

Karcher

Richardson

2020

Crop Science

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Identifying and reporting color differences is important in turfgrass experimentation. Finding ways to improve color differentiation may be desirable. Research was conducted to determine if color‐distance modeling (∆E*ab) improves differentiation of color in images of hybrid bermudagrass [Cynodon dactylon (L.) Pers. × Cynodon transvaalensis Burtt‐Davy]. Colors differ perceptibly if ∆E*ab >1.0; magnitude of difference increases as ∆E*ab increases. Hue angle (θ) and dark green color index (DGCI) of untreated shoots; shoots treated with petroleum hydrocarbons; and turf treated with N, herbicides, or a growth regulator were determined by digital image analysis. Hue and DGCI means were separated using orthogonal contrasts; ∆E*ab was computed for each contrast. Delta E*ab was a good predictor of color difference magnitude. Association between p‐values for contrasts of θ or DGCI and ∆E*ab were strong; smaller p‐values corresponded to larger ∆E*ab. When log10 p‐values for θ contrasts for ‘Tifway’ turf treated with N, herbicides, and a growth regulator were regressed on ∆E*ab, r2 = .9657 (y = − 0.602 − 0.9512x); for DGCI, r2 = .8743 (y = − 1.6097 − 0.8743x). Computing ∆E*ab helped avoid making false conclusions. Neither θ nor DGCI differed for Tifway treated with mesotrione or glyphosate (p = .2049, .6195) but ∆E*ab was 3.8 due to differences in saturation (p = .0137) and brightness (p = .0067). Computing ∆E*ab improved differentiation of turfgrass color by enhancing the accuracy of difference detection. Improving the ability to differentiate colors and avoidance of making false conclusions has advanced reporting of turfgrass color data.

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Predicting Munsell color for turfgrass leaves

Berndt¹,

Gaussoin

2023

Crop Science

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Linking turfgrass color to hue, value, chroma (H V/C) in the Munsell Plant Tissue Color Book is a visual comparison process for specifying and communicating plant color. If subjectivity of visual comparison can be mitigated, then the accuracy of color matching may be improved. Research was conducted to develop an algorithm predicting H V/C from CIE-xyY color (xyY) in digital images of leaves of four turfgrasses. First, value-chroma (V/C) arrays for Munsell hue groups 5Y, 2.5GY, 5GY, 7.5GY, 10GY, and 2.5G were converted to xyY. Next, chromaticity (xy) plots from each array were fitted with 95% prediction bands. Then, xy points for leaves (N = 60) for each turfgrass were plotted versus prediction bands. The prediction interval containing the most leaf xy points specified leaf H. Pairing each V from each hue group (N = 98) with its corresponding Y regressing log 10 V on log 10 Y predicted leaf V from leaf Y (log 10 V = 0.0715 + 0.5303logY -0.0332logY 2 ). Pairing each C (N = 98) with its corresponding xy predicted leaf C from leaf xy (C = −11.6021 − 11.2908x + 48.0880y). Predicted H V/C for "Champion" and "TifEagle" hybrid bermudagrass [Cynodon dactylon (L.) Pers. var. dactylon × Cynodon transvaalensis Burtt-Davy] was 10GY 8/4 and 7.5GY 8/4 mirroring H V/C predicted from xyY using open-source algorithms in R and Python. The experimental algorithm predicted H V/C accurately, and objectively advancing the way turfgrass color is specified and communicated. Specifying turfgrass color in situ could be possible by interfacing the algorithm with smartphone technology.

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Evaluation of Key Methodology for Digital Image Analysis of Turfgrass Color Using Open‐Source Software

Cited by 10 publications

References 14 publications

Sewage sludge composted in the coloring and development of Bermuda grass

Sewage sludge composted in the coloring and development of Bermuda grass

Color‐distance modeling improves differentiation of colors in digital images of hybrid bermudagrass

Predicting Munsell color for turfgrass leaves

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