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Revista mexicana de ciencias forestales

versión impresa ISSN 2007-1132

Rev. mex. de cienc. forestales vol.15 no.82 México mar./abr. 2024  Epub 26-Abr-2024

https://doi.org/10.29298/rmcf.v15i82.1431 

Scientific article

Diurnal Change of NDVI from UAV in trees of a temperate unavenged forest stand

Marín Pompa-García1  * 
http://orcid.org/0000-0001-7156-432X

José Ángel Sigala-Rodríguez2 
http://orcid.org/0000-0003-4292-8707

Eduardo Daniel Vivar-Vivar1 
http://orcid.org/0000-0002-2052-0404

Felipa de Jesús Rodríguez-Flores3 
http://orcid.org/0000-0001-8037-9361

Joel Rascón-Solano4 
http://orcid.org/0000-0002-2541-4176

1Laboratorio de Dendroecología, Facultad de Ciencias Forestales y Ambientales, Universidad Juárez del Estado de Durango. México.

2Campo Experimental Valle del Guadiana, INIFAP. México.

3Ingeniería en Tecnología Ambiental, Universidad Politécnica de Durango. México.

4Facultad de Ciencias Agrícolas y Forestales, Universidad Autónoma de Chihuahua. México.


Abstract

NDVI elucidates the ecophysiological mechanisms faced by vegetation. With the flexibility and versatility of unmanned aerial vehicles (UAVs), temporal, spatial and spectral resolutions have been useful in supporting decision-making. Here, we modeled diurnal change in the NDVI derived from UAV imagery for individual trees in a natural forest stand. Eight flights were conducted during daylight hours over one day to assess the dynamics of the NDVI of the genera Pinus, Juniperus, and Quercus. The results showed unstable NDVI values over time, with a parabolic quadratic trend in the model. The NDVI reached its maximum around 13:00 h and the values differed significantly according to genus: the highest value was found in Pinus with significant differences presented with Juniperus and Quercus, which showed similar values between them (p=0.533). As a validation strategy, we test the model generated using 124 trees independent of those that were sampled, which strengthened our results in terms of reliability. The similarities of statistical parameters confer a high variability of application of the results in models of simulation of similar forests ecosystems. We recommend to study more spectral indices of vegetation, including calibration of the sensor, particularly in longer-term seasonal studies. We conclude that the NDVI measured using UAV should consider image acquisition time to calibrate the records and thus improve the interpretation of results.

Key words Drones; index vegetation; individual trees; spectral indices; uneven aged; vigor

Resumen

El NDVI dilucida los mecanismos ecofisiológicos a los que se enfrenta la vegetación. Gracias a la flexibilidad y versatilidad de los vehículos aéreos no tripulados (VANT), las resoluciones temporales, espaciales y espectrales han sido útiles para apoyar la toma de decisiones. En este trabajo se modelizó el cambio diurno en el NDVI derivado de imágenes de VANT para árboles individuales en un rodal forestal natural incoetáneo. Se realizaron ocho vuelos durante las horas diurnas a lo largo de un día para evaluar la dinámica del NDVI de los géneros Pinus, Juniperus y Quercus. Los resultados mostraron valores de NDVI inestables en el tiempo, con una tendencia cuadrática parabólica en el modelo. El NDVI alcanzó su máximo alrededor de las 13:00 h y los valores difirieron significativamente según el género: el valor más alto se encontró en Pinus con diferencias significativas presentadas con Juniperus y Quercus, que mostraron valores similares entre ellos (p=0.533). Como estrategia de validación, probamos el modelo generado utilizando 124 árboles independientes de los muestreados, lo que reforzó nuestros resultados en términos de confiabilidad. Las similitudes de los parámetros estadísticos confieren una alta variabilidad de aplicación de los resultados en modelos de simulación de ecosistemas forestales similares. Recomendamos estudiar más índices espectrales de vegetación, incluyendo la calibración del sensor, particularmente en estudios estacionales de más largo plazo. Concluimos que el NDVI medido mediante VANT debe considerar el tiempo de adquisición de la imagen para calibrar los registros y así mejorar la interpretación de los resultados.

Palabras clave Drones; índice de vegetación; árboles individuales; índices espectrales; edad desigual; vigor

Introduction

The state of the art in the international agenda shows that UAV-derived information offers promising findings that elucidate novel ecological mechanisms (Dronova and Taddeo, 2022). For example, spectral indices of vegetation contain valuable information that is not normally perceived by the human eye at first glance. One of the vegetation indices most commonly used by the international scientific community is the Normalized Difference Vegetation Index (NDVI) (Huang et al., 2021), which ad-dresses the greenness index of vegetation. Its calculation is based on the ratio of infrared to near-infrared wavelengths. Likewise, the near-infrared depends on the amount of luminosity, which transforms into the differential reflectance of the received energy, and is influenced by shadows and mixed soil-plant pixel information (Huang et al., 2021; Buchhart and Schmidhalter, 2022). This implies that the amount of light received by the canopy overtime must be influenced by various factors, such as the time of image capture (Li et al., 2020), heterogeneity of the foliage, and canopy disposition (Fawcett et al., 2021), such that the NDVI could vary consequently. For this reason, its temporal variation in forests remains to be investigated to improve the interpretation of reflectance results (Beneduzzi et al., 2017).

These values have normally been available from satellite-mounted sensors, covering large areas at a regional level (e. g. too coarse (>10 m)) (Huang et al., 2021), but scarcely at the level of individual trees as ecological units (Gallardo-Salazar and Pompa-García, 2020). The most important studies on the use of UAV-derived NDVI recommend acquiring images at midday at least in the agricultural sector (Maresma et al., 2020; Hama et al., 2021), but quantitative data regarding their dynamics and comparative parameters in tree vegetation are limited. Knowledge of such metrics would therefore support the findings of the greenness indices and improve our interpretation of the results of forest management strategies. This understanding is crucial given the adverse climate variability currently faced by terrestrial ecosystems (Prăvălie et al., 2022).

The occurrence of mixed species in natural forest stands represents ideal laboratories in which to test the variability of NDVI at tree level. The diversity of species under management in these plots is ideal for conducting such studies. In addition, drones present great versatility for configuring missions according to users' interests. For example, when access to sites of interest or the weather conditions limit image acquisition at the desired time, the user can execute the missions when conditions permit, simply adjusting the model parameters to the respective time.

In northern Mexico, there are an uneven-aged forest experimental area with the presence of Pinus engelmannii Carrière, Quercus grisea Liebm., Arbutus bicolor S. González, M. González & P. D. Sørensen, and Juniperus deppeana Steud. species under management and of great ecological importance, which makes it ideal for conducting experiments to further our knowledge regarding the spatial and temporal dynamics of NDVI (Vivar-Vivar et al., 2022). This area also provides goods and services for the surrounding communities, most of which are indigenous, as well as a refuge for a range of faunal species.

The aim of this research is therefore to model the diurnal variation of reflectance values in a mixed forest stand in northern Mexico. We hypothesize an unstable reflectance value over time, with potential implication in image acquisition time to calibrate the records and thus improve the interpretation of NDVI values.

Materials and Methods

A 1 ha plot was used in the Sierra Madre Occidental Mountain range (27°80’57’’ N, 107°60’41’’ W; 2,400 masl), where species of the genus Pinus, Quercus, Juniperus, and Arbutus coexist (Table 1). The dominant species is P. engelmannii, followed by Q. grisea and J. deppeana, with a low presence of A. bicolor. Within the shrub stratum, individuals of Ceanothus buxifolius Willd. ex Schult. f. is prominent, while a great diversity of herbaceous plants is characterized by Bouvardia ternifolia (Cav.) Schltdl., Houstonia rubra Cav., Eryngium heterophyllum Engelm., Dysphania graveolens Mosyakin & Clemants, Bouteloua gracilis (Kunth) Lag. ex Griffiths, Cyperus esculentus L., among others (González-Elizondo et al., 2012). This area presents a gentle slope and sparse stoniness. The study site soils are Cambisol in type with thin layers of organic matter and the area is subjected to commercial forest management for timber (González-Elizondo et al., 2012). This region has a temperate climate, with an average annual temperature of 13.7 °C, the minimum temperature is -15 °C and there is highly variable rainfall ranging from 470 to 683 mm per year, with an average annual rainfall of 540.4 mm and an average of 75 days of rain per year (Gallardo-Salazar and Pompa-García, 2020).

Table 1 Descriptive statistics of the sampled trees in the study area. 

Statistic BD DBH CH TH
Pinus Juniperus Quercus Pinus Juniperus Quercus Pinus Juniperus Quercus Pinus Juniperus Quercus
+ * + * + * + * + * + * + * + * + * + * + * + *
Mean 34.9 15.1 18.4 10.4 45.2 16.6 28.6 11.2 13.3 7.2 35.9 11.5 6.6 2.9 2.1 1.8 3.1 1.9 13.9 6.7 5.2 3.6 12.2 6.5
Standard deviation 9.3 3.9 4.4 3.1 10.7 5.8 8.1 3.2 3.7 2.4 9.7 5.0 3.1 0.8 0.3 0.3 1.6 0.7 2.9 1.5 1.1 0.8 1.9 2.3
Range 45.6 17.3 18.8 10.7 41.8 18.6 40.4 13.5 14 8 41.6 18.8 10.1 5.1 1.4 1.2 8.5 3.1 13.8 74.8 4.9 3.4 8.6 8
Min 20.8 9.7 13.6 5.3 26.8 6.3 16 6.4 11 3.5 20.7 3.5 2.5 1.6 1.5 1.2 0.7 0.9 7.6 4.3 2.9 2.3 8.2 2.9
Max 66.4 27 32.4 16 68.6 24.9 56.4 19.9 25 11.5 62.3 22.3 12.5 6.7 2.8 2.4 9.2 4.1 21.4 12.1 7.8 5.7 16.8 10.9
Count 52 71 26 35 46 18 52 71 26 35 46 18 52 71 26 35 46 18 52 71 26 35 46 18

BD = Basal diameter (cm); DBH = Diameter at breast height (cm); CH = Commercial height (m); TH = Total height (m); + = Data used for generation model; * = Data used for validation model.

Data collection

Under clear sky conditions from 7:00 am to 7:00 pm on May 17th of 2022 (late spring), eight flights were conducted over this area in a north-south direction, covering the entire presence of the sun's luminosity. For this purpose, the respective missions were programmed into the model Phantom 4 Multispectral DJI® quadcopter. The P4M camera has one RGB sensor and five multispectral sensors (bands: blue=450±16 nm, green=560±16 nm, red=650±16 nm, red edge=730±16 nm, near infrared=840±26 nm), all with a 2 MP shooter. The flight recorded photographs in JPG format (24 bits, for images taken with the RGB sensor) and TIF format (16 bits, for those acquired with the multispectral sensors) at an altitude of 60 m, with the camera at an angle of 90° and an overlap of 80 %, and 75 % between the images and lines (Figure 1).

Figure 1 Flight parameters for the Phantom 4 Multispectral. 

For the purposes of the study, we assume here that the sensor reflectance correction provided by the manufacturer of DJI® is sufficient. However, it is known that no sensor is perfect, so specific radiometric corrections will be required in future studies (Mamaghani and Salvaggio, 2019), above all in those conducted over monthly or seasonal periods.

Image processing and statistical analysis

The images were processed by digital photogrammetry techniques using the open-source software OpenDroneMap (ODM, version 2.8.4; Cleveland Metroparks, Ohio, USA) (Vivar-Vivar et al., 2022) through the Structure from motion and Multi-View Stereo algorithm to produce a 3D point cloud. Geotagging of the images was not necessary because the drone has an integrated georeferencing system with vertical and horizontal accuracies of ±0.1 and ±0.3 m, respectively, according to the DJI® dealer.

We then generated the spectral orthomosaics (2.9 cm/pixel). Within the arbitrarily plot selected a total of 124 trees were recorder (Table 1), for which the NDVI was calculated at the individual tree level using the Q-Gis raster calculator (Gallardo-Salazar and Pompa-García, 2020) using the following expression:

NDVI= NIR-REDNIR+RED (1)

Where:

NDVI = Normalized Difference Vegetation Index

NIR = Near infrared band

RED = Red band

Variation of the NDVI as a function of time of day was fitted to a quadratic-type model using the following equation:

NDVI= Y0+ Y1t+ Y2t (2)

Where:

NDVI = Normalized Difference Vegetation Index

t = Time of the NDVI reading

Y 0 , Y 1 and Y 2 = Model fit parameters. Note that Y 2 is the parameter of the quadratic term

Model fitting was conducted with the lm function of the 'stats' package in R software version 4.1.1 (R Core Team, 2021) and regression assumptions were tested (Gujarati and Porter, 2009). Differences in the model parameters among tree genera were analyzed statistically by applying predefined orthogonal contrasts. Validation of the model fit was analyzed by graphical exploration between two sources of data.

As a validation strategy to evaluate the prediction performance of our model, we evaluate the prediction performance using new independent data set of 124 trees, (Table 1), then we plotted results.

Results

During each flight, a total of 141 RGB and 705 multispectral images were acquired with the UAV, which were used to create the multispectral orthomosaic.

The diurnal variation of the NDVI presented a quadratic behavior (Figure 2). The values start to increase from the first mission and reach a maximum at around 13:00 h, before decreasing over the rest of the day. Although all three genera showed quadratic behavior, the model parameters varied significantly depending on the genus (Table 2). In general, Pinus showed higher NDVI values throughout the day and with lower variation (from 0.41 to 0.54). On the other hand, Juniperus and Quercus showed similar behavior between them and higher diurnal variation of the NDVI, with values starting at 0.1 on average in the morning and reaching a maximum of around 0.45 (Figure 2).

The points represent the mean values observed at different times of the day. The dashed lines represent the values predicted by the fitted model, including genus as a source of variation. Bars denotes descriptive error bars.

Figure 2 Diurnal variation of the NDVI in three tree genera in the studied area. 

Table 2 Parameter estimates of the of the quadratic-type model fitted to the ratio of NDVI values as a function of time of day and tree genus. 

Parameter Estimate Std. Error t value Pr(>|t|)
γ0 Pinus L. -0.02819 0.06231 -0.452 0.651
Juniperus L. -1.05212 0.10783 -9.757 <2e-16
Quercus L. -0.98353 0.09088 -10.822 <2e-16
γ1 Pinus L. 2.10006 0.2573 8.162 1.01e-15
Juniperus L. 3.49121 0.44527 7.841 1.17e-14
Quercus L. 3.07798 0.3753 8.201 7.40e-16
γ2 Pinus L. -1.85688 0.24246 -7.659 4.50e-14
Juniperus L. -3.11087 0.41964 -7.413 2.66e-13
Quercus L. -2.78068 0.35368 -7.862 9.92e-15

Table 2 gives the estimated parameters and the corresponding goodness-of-fit statistics of the models developed, indicating that the estimated parameters are unbiased. For example, the model explained more than 60 % of the variance. The best fits were obtained for the genus Pinus, while the worst fits were obtained for Quercus, a finding that we attribute to sample size differentiation.

Overall, the models are similar around 13:00 h, suggesting that this time presents a maximum value for both data. This result highlights the importance of taking into account the time of measuring NDVI, and not simply flight the mission at any time, as is commonly practiced. Our study shows that the generated model is an advantageous tool for forest management studies that can be used to predict NDVI values according to time data acquisition.

Discussion

This pioneering study in Mexican mixed forests has shown that the diurnal timing of NDVI acquisition is unstable over the course of the day, making this a decisive factor in the interpretation of the greenness index for subsequent decision-making. Most of the scientifically documented studies undertaken during the fast-paced advent of drones have addressed applications in crops (Heinemann et al., 2022), while little attention has been paid to forests despite the promising perspective that drones offer for studying these ecosystems (Gallardo-Salazar and Pompa-García, 2020).

The findings of this study represent an opportunity to refine our knowledge of spectral reflectance variation at the individual tree level according to diurnal variation. The results show significant differences according to time of measurement, as well as among the genera studied. However, an in-depth analysis of the causes of the marginal differences between NDVI values is beyond the scope of the study (Vivar-Vivar et al., 2022).

The diurnal pattern of NDVI values follows a parabolic quadratic trend, reaching a maximum at 13:00 h for all of the vegetation studied (Figure 2). These values have been attributed to the better reception of light energy from the sun in the foliage. A consequent decrease in reflectance is evident at the beginning and end of the day, compared to when the sun is at its zenith, which is directly related to changes in the angle of the sun and the resulting shadows of the vegetation (Maresma et al., 2020; Hama et al., 2021). Interestingly, Beneduzzi et al. (2017) report that NDVI is affected by radiation, presenting opposite graph trends to our findings. We believe that sensor type, species phenology, and cloudiness are among the causes of these differences. Another possible cause is the NDVI-climate relationship, as has been seen in Ghebrezgabher et al. (2020).

The NDVI trend with the generated model produced results consistent with those derived from the validation since the parabolic trend is similar for all genera, with a maximum around 13:00 h. This indicates that our model has good predictive capabilities, although the causes of the marginal differences (e. g. canopy structure, individual physiological characteristics, etc.) remain to be determined. For example, some species have deciduous leaves throughout the seasons of the year. Also, our sensor has limitations as poor penetrating capacity of sunlight in overlapped canopies.

The results are important given that forest access conditions and sudden changes in the climate can often limit flight missions at specific times. In this way, our NDVI model makes it possible to make adjustments even after completion of the fieldwork, according to the time of sampling (Maresma et al., 2020). Likewise, in the forest, the complexity and magnitude of phenological changes also raise the need for analysis in future studies of greater temporality and seasonality (e. g. months) (Li et al., 2021).

However, thresholds of temporal heterogeneity of reflectance have been a reliable starting point and have made a contribution to the knowledge, which cannot always be achieved with satellite imagery. It has been demonstrated that UAVs calculate NDVI more accurately than the 10-m Sentinel-2, including as part of studies to monitor canopy phenology (Khaliq et al., 2019).

NDVI values should not be confused with photosynthetic activity per se (not studied here) since this variable requires thorough investigation, including actual field measurements beyond the leaf level. Moreover, the plant water status and leaf orientation during the day can contribute to diurnal differences in reflectance (Rischbeck et al., 2014). According to Buchhart and Schmidhalter (2022), measurements should be taken hourly, although the authors did make this recommendation for crops rather than for trees.

Although we documented that the diurnal greenness indices of canopies follow a heterogeneity pattern, the magnitude of photosynthetic variability in studied species remains a challenge that merits further analysis, including beyond the leaf level (Pompa-García et al., 2022). It is well known that the spectral reflectance captured by a UAV sensor can be associated with canopy geometry and foliage structure. Thus, a potential limitation could be the spurious spectral variation that can be confused with the potential photosynthesis (Vivar-Vivar et al., 2022).

The maximum NDVI values found at 13:00 h should therefore not necessarily be interpreted as the time of maximum "photosynthetic activity", but rather these metrics correspond to the reflectance of the energy captured by the sensor at that time (Vivar-Vivar et al., 2022), for which reason they must be treated with some caution, although the scientific community recommends this time of day unless adverse weather conditions prevent it.

This implies the need for further research to refine the estimates in these experimental studies. For example, flight duration must be considered to determine the spectral variation between the start and end of each mission, as well as radiance, temperature, and humidity data (Hama et al., 2021), as well as considering the vegetation characteristics (Jacquemoud et al., 2009) and the specific assessment of the foliage structure and arrangement (Li et al., 2020). It is well known that the quality of spectral information depends on the flight configuration parameters a paths and altitude, among others that configure the flight missions (Vivar-Vivar et al., 2022). Thus, flights should be configurated to obtain the best perspective of the variable of interest. However, it is necessary to balance the costs and benefits of management strategies that are developed in the field. Accurate NDVI information is essential to evaluate the efficiency of silvicultural practices in the field or to make adjustments to predictions since it is known that the NDVI can be a potential proxy of vigor and plant stress levels, among others (Huang et al., 2021).

We found heterogeneity in reflectance responses to time of image capture, within the different genus, which puts into perspective the need to configure specific actions towards sustainability, because these forests are subject to forest management. The causes can still be refined with more flight missions and a better knowledge on the true estimations of photosynthetic capacities. The heterogeneity of NDVI in responses to time data acquisition is crucial to design strategies of conservation and management in megadiverse ecosystems.

The strategy of using independent data for validation strengthened our results. Our methodology provides the use of a model that is statistically sound and functional. Acquisition of data from representative trees, such as those sampled here, guarantees that the results are reliable due to their relevance of direct application by the forest manager. Given these trees are under management, with fully developed crowns, they represent a valuable input data for subsequent research.

Conclusions

The NDVI does not remain fixed throughout the day, which is presumably attributed to the angle of the sun. The maximum values were found at 13:00 h for all genera and decreased as the solar zenith angle subsequently decreased.

Moreover, environmental parameters and equipment configurations must be evaluated, and this experiment should be replicated at seasonal time horizons and at higher vegetation resolutions (e. g. at the species level).

The uneven-aged forests and their exceptional tree diversity constituted an ideal setting to identify NDVI tree interactions. This gained knowledge has great implications to facilitate sustainable management in multi-species mountain forests, which are the most widely distributed in Mexican territory.

Analysis of NDVI should be integrated as a tool for forest management, but with-out replacing the use of data in situ that still provide essential information regarding the forest structure. In addition, more spectral indices of vegetation should be studied, as well as calibration of the sensor performed, particularly in longer-term seasonal studies.

Acknowledgments

We thank Conacyt for the support provided through project A1-S-21471 and DendroRed (http://dendrored.ujed.mx; accessed on October 26th, 2023). We also acknowledge the CIIDIR-Durango Herbarium, especially Dr. M. Socorro González-Elizondo for the taxonomic identification of the collected specimens. We appreciate the effort of Editor and three Referees for their time and providing valuables comments.

References

Beneduzzi, H. M., E. G. Souza, C. L. Bazzi and K. Schenatto. 2017. Temporal variability in active reflectance sensor-measured NDVI in soybean and wheat crops. Engenharia Agrícola 37(4):771-781. Doi: 10.1590/1809-4430-Eng.Agric.v37n4p771-781/2017. [ Links ]

Buchhart, C. and U. Schmidhalter. 2022. Daytime and seasonal reflectance of maize grown in varying compass directions. Frontiers in Plant Science 13:1029612. Doi: 10.3389/fpls.2022.1029612. [ Links ]

Dronova, I. and S. Taddeo. 2022. Remote sensing of phenology: Towards the comprehensive indicators of plant community dynamics from species to regional scales. Journal of Ecology 110(7):1460-1484. Doi: 10.1111/1365-2745.13897. [ Links ]

Fawcett, D., J. Bennie and K. Anderson. 2021. Monitoring spring phenology of individual tree crowns using drone-acquired NDVI data. Remote Sensing in Ecology and Conservation 7(2):227-244. Doi: 10.1002/rse2.184. [ Links ]

Gallardo-Salazar, J. L. and M. Pompa-García. 2020. Detecting individual tree attributes and multispectral indices using Unmanned Aerial Vehicles: Applications in a Pine clonal orchard. Remote Sensing 12(24):4144. Doi: 10.3390/rs12244144. [ Links ]

Ghebrezgabher, M. G., T. Yang, X. Yang and T. E. Sereke. 2020. Assessment of NDVI variations in responses to climate change in the Horn of Africa. The Egyptian Journal of Remote Sensing and Space Science 23(3):249-261. Doi: 10.1016/j.ejrs.2020.08.003. [ Links ]

González-Elizondo, M. S., M. González-Elizondo, J. A. Tena-Flores, L. Ruacho-González e I. L. López-Enríquez. 2012. Vegetación de la Sierra Madre Occidental, México: una síntesis. Acta Botánica Mexicana 100:351-403. Doi: 10.21829/abm100.2012.40. [ Links ]

Gujarati, D. N. and D. C. Porter. 2009. Basic Econometrics. McGraw-Hill. New York, NY, United States of America. 922 p. [ Links ]

Hama, A., K. Tanaka, B. Chen and A. Kondoh. 2021. Examination of appropriate observation time and correction of vegetation index for drone-based crop monitoring. Journal of Agricultural Meteorology 77(3):200-209. Doi: 10.2480/agrmet.D-20-00047. [ Links ]

Heinemann, P., S. Haug and U. Schmidhalter. 2022. Evaluating and defining agronomically relevant detection limits for spectral reflectance-based assessment of N uptake in wheat. European Journal of Agronomy 140:126609. Doi: 10.1016/j.eja.2022.126609. [ Links ]

Huang, S., L. Tang, J. P. Hupy, Y. Wang and G. Shao. 2021. A commentary review on the use of normalized difference vegetation index (NDVI) in the era of popular remote sensing. Journal of Forestry Research 32(1):1-6. Doi: 10.1007/s11676-020-01155-1. [ Links ]

Jacquemoud, S., W. Verhoef, F. Baret, C. Bacour, … and S. L. Ustin. 2009. PROSPECT+SAIL models: A review of use for vegetation characterization. Remote Sensing of Environment 113(S1):S56-S66. Doi: 10.1016/j.rse.2008.01.026. [ Links ]

Khaliq, A., L. Comba, A. Biglia, D. R. Aimonino, M. Chiaberge and P. Gay. 2019. Comparison of satellite and UAV-based multispectral imagery for vineyard variability assessment. Remote Sensing 11(4):436. Doi: 10.3390/rs11040436. [ Links ]

Li, D., J. M. Chen, X. Zhang, Y. Yan, … and W. Cao. 2020. Improved estimation of leaf chlorophyll content of row crops from canopy reflectance spectra through minimizing canopy structural effects and optimizing off-noon observation time. Remote Sensing of Environment 248:111985. Doi: 10.1016/j.rse.2020.111985. [ Links ]

Li, W., J. Jiang, M. Weiss, S. Madec, … and F. Baret. 2021. Impact of the reproductive organs on crop BRDF as observed from a UAV. Remote Sensing of Environment 259:112433. Doi: 10.1016/j.rse.2021.112433. [ Links ]

Mamaghani, B. and C. Salvaggio. 2019. Multispectral sensor calibration and characterization for sUAS Remote Sensing. Sensors 19(20):4453. Doi: 10.3390/s19204453. [ Links ]

Maresma, A., L. Chamberlain, A. Tagarakis, T. Kharel, … and Q. M. Ketterings. 2020. Accuracy of NDVI-derived corn yield predictions is impacted by time of sensing. Computers and Electronics in Agriculture 169:105236. Doi: 10.1016/j.compag.2020.105236. [ Links ]

Pompa-García, M., J. A. Martínez-Rivas, R. D. Valdez-Cepeda, C. A. Aguirre-Salado, … and D. J. Vega-Nieva. 2022. NDVI values suggest immediate responses to fire in an uneven-aged mixed forest stand. Forests 13(11):1901. Doi: 10.3390/f13111901. [ Links ]

Prăvălie, R., I. Sîrodoev, I.-A. Nita, C. Patriche, … and M.-V. Birsan. 2022. NDVI-based ecological dynamics of forest vegetation and its relationship to climate change in Romania during 1987-2018. Ecological Indicators 136:108629. Doi: 10.1016/j.ecolind.2022.108629. [ Links ]

R Core Team. 2021. R: A Language and Environment for Statistical Computing (version 4.1.1.). R Foundation for Statistical Computing. Vienna, W, Austria. https://www.R-project.org . (November 6th, 2023). [ Links ]

Rischbeck, P., P. Baresel, S. Elsayed, B. Mistele and U. Schmidhalter. 2014. Development of a diurnal dehydration index for spring barley phenotyping. Functional Plant Biology 41(12):1249-1260. Doi: 10.1071/FP14069. [ Links ]

Vivar-Vivar, E. D., M. Pompa-García, J. A. Martínez-Rivas and L. A. Mora-Tembre. 2022. UAV-Based characterization of tree-attributes and multispectral indices in an uneven-aged mixed conifer-broadleaf forest. Remote Sensing 14(12):2775. Doi: 10.3390/rs14122775. [ Links ]

Received: August 31, 2023; Accepted: January 10, 2024

*Corresponding author: e-mail: mpgarcia@ujed.mx

Conflicts of Interest

The authors declare no conflict of interest.

Contribution by author

Marín Pompa-García: conceptualization, data gathering, investigation, resources and writing-original draft preparation; José Ángel Sigala-Rodríguez: methodology, software, validation and editing; Eduardo Daniel Vivar-Vivar: methodology, experimental design, and formal analysis; Felipa de Jesús Rodríguez-Flores: methodology, experimental design, and resources; Joel Rascón-Solano: review, editing, and supervision. All authors have read and agreed to the published version of the manuscript.

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