Quantitative monitoring of leaf area index in wheat of different plant types by integrating NDVI and Beer-Lambert law

Tan, Changyin; Zhang, Pengpeng; Zhou, Xinxing; Wang, Zhixiang; Xu, Ziqiang; Mao, Wei; Li, Wenxi; ZhongYang, Huo; Guo, Wenshan; Fei, Yun

doi:10.1038/s41598-020-57750-z

Cited by 63 publications

(45 citation statements)

References 32 publications

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“…The k(θ) is generally obtained using the literature as ground observations are often not available and k(θ) is difficult to measure in the field [47]. Moreover, many studies use constant k(θ) over the growing period to simplify calculations [56]. A study calculating LAI for winter wheat using RapidEye multispectral satellite imagery was performed at the same study area in Selhausan, Germany [47].…”

Section: Deriving Gaimultispectralmentioning

confidence: 99%

“…The GAImultispectral method incorporated for UAS for this project may benefit from a linearity adjustment factor in the equations for better results or studies without in situ measurements. The PAILiDAR appears to be more stable over time and shows promise that fixing this parameter would introduce just minor uncertainty, so that it could be incorporated using values from the literature [47,56]. It is worth noting that none of the ground measurements were taken on the same day as flight campaigns, but within a maximum time span of nine days.…”

Section: Impacts Of the Extinction Coefficient K(θ)mentioning

confidence: 99%

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Estimating Canopy Density Parameters Time-Series for Winter Wheat Using UAS Mounted LiDAR

et al. 2021

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Monitoring of canopy density with related metrics such as leaf area index (LAI) makes a significant contribution to understanding and predicting processes in the soil–plant–atmosphere system and to indicating crop health and potential yield for farm management. Remote sensing methods using optical sensors that rely on spectral reflectance to calculate LAI have become more mainstream due to easy entry and availability. Methods with vegetation indices (VI) based on multispectral reflectance data essentially measure the green area index (GAI) or response to chlorophyll content of the canopy surface and not the entire aboveground biomass that may be present from non-green elements that are key to fully assessing the carbon budget. Methods with light detection and ranging (LiDAR) have started to emerge using gap fraction (GF) to estimate the plant area index (PAI) based on canopy density. These LiDAR methods have the main advantage of being sensitive to both green and non-green plant elements. They have primarily been applied to forest cover with manned airborne LiDAR systems (ALS) and have yet to be used extensively with crops such as winter wheat using LiDAR on unmanned aircraft systems (UAS). This study contributes to a better understanding of the potential of LiDAR as a tool to estimate canopy structure in precision farming. The LiDAR method proved to have a high to moderate correlation in spatial variation to the multispectral method. The LiDAR-derived PAI values closely resemble the SunScan Ceptometer GAI ground measurements taken early in the growing season before major stages of senescence. Later in the growing season, when the canopy density was at its highest, a possible overestimation may have occurred. This was most likely due to the chosen flight parameters not providing the best depictions of canopy density with consideration of the LiDAR’s perspective, as the ground-based destructive measurements provided lower values of PAI. Additionally, a distinction between total LiDAR-derived PAI, multispectral-derived GAI, and brown area index (BAI) is made to show how the active and passive optical sensor methods used in this study can complement each other throughout the growing season.

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Section: Deriving Gaimultispectralmentioning

confidence: 99%

Section: Impacts Of the Extinction Coefficient K(θ)mentioning

confidence: 99%

Estimating Canopy Density Parameters Time-Series for Winter Wheat Using UAS Mounted LiDAR

et al. 2021

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“…In agriculture and ecology, historically, the Leaf Area Index (LAI) concept is used for the estimation and evaluation of crop production and crop yield and the scheduling of irrigation and amendments during crop cultivation [1]. In order to assess growth and vegetation intensity across the globe, monitoring the distribution and change of LAI is significant.…”

Section: Introductionmentioning

confidence: 99%

“…However, many factors are important if the reflectivity of the crop canopy is to be assessed. These include the complexity of canopy design, improvements to the internal arrangement of leaves and background effects of the soil [1].…”

Section: Introductionmentioning

confidence: 99%

Estimating LAI of Rice Using NDVI Derived from MODIS Surface Reflectance

Kulkarni¹,

Honda²

2020

Adv. sci. technol. eng. syst. j.

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“…Readings from optical sensors can be associated with important indicators of agricultural crops, such as leaf area index [35], biomass production [18], and grain yield [9]. Thus, the proper use of optical sensors has been useful to improve the production and nutrient use efficiency [10].…”

Section: Introductionmentioning

confidence: 99%

Nitrogen fertilization for wheat following soybean and interfering factors on spectral reflectance readings

2020

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A field experiment examined the wheat response following soybean due to urea-N fertilization at sowing (0, 20, 40, and 60 kg N ha −1) and top dressing (0, 30, 60, and 90 kg N ha −1). Normalized difference vegetation index (NDVI) measurements using a GreenSeeker active sensor were taken at different growth stages, at various sensor heights above the canopy, and at different times of day. Both the shoot dry matter yield and the grain yield were not affected by N fertilization at sowing and increased with increasing N rates at top dressing. A maximum economic yield was obtained at 55 kg N ha −1 in top dressing, causing a 33% increase in grain yield and an economic return of US$ 189.50 ha −1. Differences in NDVI were found before and after top-dressing N fertilization, indicating that GreenSeeker was efficient in monitoring wheat N nutrition. NDVI varied depending on the measurement distance, stabilizing from 0.30 to 1.20 m above the canopy. Because of the influence of incident radiation, higher NDVI values were obtained at the beginning and end of the day. The results suggest that for the wheat cultivar Quartzo following soybean under minimum soil disturbance, while there is no need to apply N at sowing, an important increase in grain yield can be obtained with top-dressing N fertilization. In addition, to improve the accuracy in developing N fertilizer recommendation models using GreenSeeker, a consistent protocol for spectral reflectance readings, mainly regarding the time of day, is required.

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Quantitative monitoring of leaf area index in wheat of different plant types by integrating NDVI and Beer-Lambert law

Cited by 63 publications

References 32 publications

Estimating Canopy Density Parameters Time-Series for Winter Wheat Using UAS Mounted LiDAR

Estimating Canopy Density Parameters Time-Series for Winter Wheat Using UAS Mounted LiDAR

Estimating LAI of Rice Using NDVI Derived from MODIS Surface Reflectance

Nitrogen fertilization for wheat following soybean and interfering factors on spectral reflectance readings

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