Best hyperspectral indices for assessing leaf chlorophyll content in a degraded temperate vegetation

Peng, Yu; Min, Fan; Wang, Qinghui; Lan, Wenjuan; Long, Yating

doi:10.1002/ece3.4229

Cited by 16 publications

(10 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Different degradation intensities demonstrated obvious variability in correlation coefficients. As reported in Peng et al 39 , under light degradation, the values of Viopt, FD525-570, MSS-DVI, SDb, and SDr were significantly negatively correlated with measured contents. However, in severe degradation, the relations are significantly positive.…”

Section: Assessment Of Empirical Hyperspectral Indices Forty-three Esupporting

confidence: 77%

“…However, for leaf N estimation in wheat, wavelengths of 384, 492, 695, 1339, and 508 nm and 681, 722, 960, 1264, and 1369 nm were found to perform best 17 . Among these bands, chlorophyll and carotenoids in green plants often strongly absorb the visible range 384, 492, and 508 nm; 681, 695, and 722 nm in the red range and can serves as sensitive N indicators; and the shortwave infrared range 960, 1264, 1339, and 1369 nm bands are indicators of proteins (where N is a main component) 39 . In our study, the sensitive bands for leaf N content from temperate degraded vegetation were found to be 468, 623, 624, 633, 652, 657, 668, 818, 821, 842, 937, and 938 nm, in the red and NIR regions.…”

Section: Discussionmentioning

confidence: 99%

“…We used stepwise linear regression to distinguish the optimal combination among the 22 sensitive bands selected earlier to identify the best combinations for estimating leaf nutrition for all indices. Following this, previously established methods were applied to devise high accuracy regression equations for leaf N, P, and K content 39 . The most sensitive bands finally selected for leaf N content were 468, 623, 624, 633, 652, 657, 668, 818, 821, 842, 937, and 938 nm (Table 1), which mostly lie in the red and NIR regions of the spectrum.…”

Section: Development Of New Hyperspectral Indicesmentioning

confidence: 99%

See 2 more Smart Citations

Estimation of leaf nutrition status in degraded vegetation based on field survey and hyperspectral data

Peng

Zhang

et al. 2020

Sci Rep

Self Cite

View full text Add to dashboard Cite

Timely monitoring of global plant biogeochemical processes demands fast and highly accurate estimation of plant nutrition status, which is often estimated based on hyperspectral data. However, few such studies have been conducted on degraded vegetation. In this study, complete combinations of either original reflectance or first-order derivative spectra have been developed to quantify leaf nitrogen (N), phosphorus (P), and potassium (K) contents of tree, shrub, and grass species using hyperspectral datasets from light, moderate, and severely degraded vegetation sites in Helin County, China. Leaf N, P, and K contents were correlated to identify suitable combinations. The most effective combinations were those of reflectance difference (Dij), normalized differences (ND), first-order derivative (FD), and first-order derivative difference (FD(D)). Linear regression analysis was used to further optimize sensitive band-based combinations, which were compared with 43 frequently used empirical spectral indices. The proposed hyperspectral indices were shown to effectively quantify leaf N, P, and K content (R2 > 0.5, p < 0.05), confirming that hyperspectral data can be potentially used for fine scale monitoring of degraded vegetation.employed in biomes such as grasslands and savannas 1,18-20 , crops 21 , and trees 22 . A study of maize leaf P content found that 540, 720, 740, and 850 nm are the most sensitive bands for detection of P in both the vegetation production stage and the flowering stage 21 .The spectral region which most closely relates to leaf P content has been found to overlay the spectral region which demonstrates water absorbing traits (1000-2500 nm) 19 . Bands which are indicative of leaf P also lie in the region of 580-710 nm, although this varies among different case studies. The confusion between water absorption and sensitivity to sampling sites makes it difficult to identify the most suitable bands for leaf P estimation. In this study, we aimed to select several sensitive bands from the 500 available and develop a complete combination of reflectance and its first-order derivative (FD) from tree, shrub, and grass species in various degraded vegetation sites, with the objective of developing more general hyperspectral indices for the estimation of leaf P content.Finally, potassium (K) is also a key plant requirement, present mostly as K + ions in vacuoles. K provides regulatory control over processes such as transpiration, starch synthesis, sucrose translocation, respiration, and lipid synthesis 23 . Plants deficient in K exhibit limited growth, metabolism, and stress defense 24 , leading to lower overall biomass and coverage and changes to leaf color. If a K deficiency occurs at the vegetation level, this can accelerate the degradation process. Soils in many broad-acre semiarid areas have become deficient in K, resulting in a decrease of K in the canopy and stem 25,26 .Remote sensing of leaf N, P, or K contents is a challenging task due to the lack of direct absorption features that can be observed in t...

show abstract

Section: Assessment Of Empirical Hyperspectral Indices Forty-three Esupporting

confidence: 77%

Section: Discussionmentioning

confidence: 99%

Section: Development Of New Hyperspectral Indicesmentioning

confidence: 99%

See 1 more Smart Citation

Estimation of leaf nutrition status in degraded vegetation based on field survey and hyperspectral data

Peng

Zhang

et al. 2020

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…For this reason, the diodes mainly peak in the red, far-red, and blue part of the spectrum. These narrow bands of the spectrum boost the growth of the plants, as they satisfy the chlorophyll a (Chl a) and chlorophyll b (Chl b) requirements [5].…”

Section: Introductionmentioning

confidence: 99%

Optimization of Photoperiod and Quality Assessment of Basil Plants Grown in a Small-Scale Indoor Cultivation System for Reduction of Energy Demand

Avgoustaki

2019

Energies

View full text Add to dashboard Cite

Vertical farming is a novel type of food production in indoor environments with artificial lighting and controlled cultivation conditions. In this context, sustainability in small-scale indoor cultivation systems is crucial. Sustainability can be achieved by optimizing all the cultivation factors involved in the production process. The effects of different photoperiod conditions under different timing during plant development—from sowing to germination and maturity—have been studied in a small-scale indoor cultivation area. The main objective of this research was to investigate the possibilities of an optimized photoperiod for basil plants to reduce the energy demand cost of the cultivation unit. Three different photoperiod treatments (P8D16L, P10D14L, and P11D13L) were applied to basil plants with stable light intensity. Furthermore, the photoperiod was shortened to test the reaction of the biomass from the plants in a reduced energy demand system. The dry biomass produced was measured along with the energy consumed in each treatment. The basil quality was assessed by measuring different physiological indices, such as chlorophyll a (Chl a), chlorophyll b (Chl b), total chlorophyll (Chl tot), the fraction of photosynthetically active irradiance absorbed by the leaf, and leaf temperature. The results of the study showed that a shorter photoperiod did not negatively affect the quantity and quality of the basil plants. Continuously, the evaluation of the energy demand variation under the different photoperiod treatments can provide a significant positive impact on the energetic, ecological, and economic aspects of small-scale food production.

show abstract

“…Therefore, traditional wet chemistry destructive method is obviously undesirable for assessing chlorophyll content in navel oranges. For this reason, hyperspectral remote-sensing technology can be applied to estimate the spatio-temporal variations in the physical and chemical parameters of vegetation, including the chlorophyll content, at a relatively low cost compared to field measurements (MUTANGA et al, 2004;ZHANG et al, 2008;HE, 2013;PU et al, 2014;PENG et al, 2018;HOEPPNER et al, 2020;JI et al, 2020;LI et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Retrieval of leaf chlorophyll content in Gannan navel orange based on fusing hyperspectral vegetation indices using machine learning algorithms

et al. 2023

View full text Add to dashboard Cite

Estimating leaf chlorophyll contents through leaf reflectance spectra is efficient and nondestructive. The literature base regarding optical indices (particularly chlorophyll indices) is wide ranging and extensive. However, it is without much consensus regarding robust indices for Gannan navel orange. To address this problem, this study investigated the performance of 19 published indices using RDS (raw data spectrum), FDS (first derivative data spectrum) and SDS (second derivative data spectrum) for the estimation of chlorophyll content in navel orange leaves. The single spectral index and combination of multiple spectral indices were compared for their accuracy in predicting chlorophyll a content (Chla), chlorophyll b content (Chlb) and total chlorophyll content (Chltot) content in navel orange leaves by using partial least square regression (PLSR), adaboost regression (AR), random forest regression (RFR), decision tree regression (DTR) and support vector machine regression (SVMR) models. Through the comparison of the above data in three datasets, the optimal modeling data set is RDS data, followed by FDS data, and the worst is SDS data. In modeling with multiple spectral indices, good results were obtained for Chla (NDVI750, NDVI800), Chlb (Datt, DD, Gitelson 2) and Chltot (Datt, DD, Gitelson2) by corresponding index combinations. Overall, we can find that the AR is also the best regression method judging by prediction performance from the results of single spectral index models and multiple spectral indices models. In comparison, result of multiple spectral indices models is better than single spectral index models in predicting Chla and Chltot content using FDS data and SDS data, respectively.

show abstract

Best hyperspectral indices for assessing leaf chlorophyll content in a degraded temperate vegetation

Cited by 16 publications

References 29 publications

Estimation of leaf nutrition status in degraded vegetation based on field survey and hyperspectral data

Estimation of leaf nutrition status in degraded vegetation based on field survey and hyperspectral data

Optimization of Photoperiod and Quality Assessment of Basil Plants Grown in a Small-Scale Indoor Cultivation System for Reduction of Energy Demand

Retrieval of leaf chlorophyll content in Gannan navel orange based on fusing hyperspectral vegetation indices using machine learning algorithms

Contact Info

Product

Resources

About