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Original Article 

Biosci. J., Uberlândia, v. 34, n. 6, p. 1706-1713, Nov./Dec. 2018 

COTTON VEGETATION INDICES UNDER DIFFENTENT CONTROL 

METHODS OF RAMULARIA LEAF SPOT  

 
INDICES DE VEGETAÇÃO NO ALGODOEIRO SOB DIFERENTES FUNGICIDAS 

DE CONTROLE DA MANCHA DA RAMULÁRIA 
 

Luiz Marcel MARTINS¹; Everton da Silva NEIRO¹; Alfredo Ricere DIAS²;  

Cassiano Garcia ROQUE¹; Fabio Henrique Rojo BAIO¹; Paulo Eduardo TEODORO¹ 
1. Universidade Federal de Mato Grosso do Sul (UFMS), Chapadão do Sul, Mato Grosso do Sul, Brasil; 2. Fundação Chapadão, 

Chapadão do Sul, Mato Grosso do Sul, Brasil. eduteodoro@hotmail.com 
 

ABSTRACT: This work aimed to correlate treatments using fungicides to different vegetation indices in 
response to effects caused by ramularia leaf spot (Ramularia areola). The experiment was carried out in the municipality 
of Chapadão do Sul, state of Mato Grosso do Sul, in the harvest 2016/2017, and consisted of a randomized blocks design, 
with 17 treatments and four replications. Data were obtained from the Sequoia 4.0 passive sensor and the Green Seeker LT 
200 active sensor. From the information recorded by the sensors, nine vegetation indices were generated and compared 
with the area under the curve of disease progression, plant height, yield, and agronomic efficiency, in 17 different 
treatments of fungicide products. Treatments responded differently to the product applied. The SAVI index (Soil Adjusted 
Vegetation Index), obtained from the band in the red spectral range, presented higher correlation to AACPD, agronomic 
efficiency, and yield. The NDVI index (Normalized Difference Vegetation Index) had a higher correlation to plant height 
and SR (simple ratio), both using the wavelength in the red spectral range. 

 
KEYWORDS: Gossypium hirsutum L. Cotton diseases. Remote sensing. Multispectral sensors.  

 
INTRODUCTION 

 
With the introduction of new technologies 

to agriculture, several questions have arisen 
regarding their use. Questions have been intensified 
with the improvement of these new technologies. 
For instance, vegetation indices have become 
increasingly more usual and accurate with the 
enhancement of image capture sensors. 

Vegetation Indices are mathematical models 
developed from wavelengths or spectral bands 
(ZARCO-TEJADA et al., 2005). These indices aim 
to understand the canopy variables and serve as the 
basis for several remote sensing applications for 
crop management since they are correlated to 
several critical biophysical properties (AHAMED et 
al., 2011). Change in plant canopies reflectance 
depends mainly on the number of leaves and canopy 
architecture (PONZONI et al., 2012). Therefore, any 
modification of these variables, such as foliar 
diseases that cause defoliation, will influence the 
reflectance and the vegetation indices (FRENCH et 
al., 2015). They may also be useful in the 
differentiation between diseased and healthy plants 
and diseases quantification. This fact is due to 
physiological stress that manifests in plants by 
changes in the pigment composition balance, such 
as carotenoid, chlorophyll, and xanthophyll 
(GONZÁLEZ-DUGO; MATEOS, 2008; 
DEVADAS et al., 2009). 

In cotton, due to the increase in its 
cultivated area in the Cerrado, new problems have 
emerged, particularly of phytosanitary nature 
(GALBIERI et al., 2015). Ramularia leaf spot 
(Ramularia areola), or white spot, is the primary 
cotton disease. This pathogen used to occur at the 
end of the crop cycle and was not a crucial 
phytosanitary problem. However, in recent years, it 
began to manifest earlier and cause premature 
defoliation, resulting in significant production losses 
(GIROTO et al., 2013). The high disease severity at 
the beginning of the reproductive plant cycle leads 
to premature plant defoliation and implies losses 
(SHIVANKAR; WANGIKAR, 1992). 

Ramularia leaf spot causes defoliation and 
vegetation indices can be a useful tool to capture 
this difference in defoliation. Thus, this study aimed 
to evaluate vegetation indices, captured by active 
and passive sensors, in response to effects caused by 
ramularia under different treatments with fungicide 
products for cotton crop in the region of Chapadões. 
 

MATERIAL AND METHODS 
 
The experiment was carried out in the area 

belonging to the Agricultural Research Support 
Foundation of Chapadão, located at Rodovia BR 
060, km 011, in the municipality of Chapadão do 
Sul, Mato Grosso do Sul (18°41’33”S; 52°40’45”W 
and 840 m asl). Sowing was carried out on 
December 20, 2016, with a spacing of 0.9 m 

Received: 23/09/17 
Accepted: 15/07/18 



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Biosci. J., Uberlândia, v. 34, n. 6, p. 1706-1713, Nov./Dec. 2018 

between rows and ten plants per meter. Seedling 
emergence occurred on December 27, 2016. The 
variety used was FM 975WS. 

The experiment consisted of a randomized 
blocks design with 17 treatments and four 
replications. Each plot comprised four 6m planting 
rows, totaling 21.6 m². The two central rows were 
considered as the useful area for data collection, and 
the two outer rows and one meter of the edges were 
considered as the border.  

Growth regulators were applied to the 
experimental area and pests were controlled based 
on the crop’s needs. Cotton plants were cultivated 
under no-tillage system with soybean (harvest 
15/16) and Urochloa ruziziensis (winter). Basic 
fertilization was applied with 400 kg ha-1 in the 
formula 11-52-00 (N-P-K) and 150 kg ha-1 of KCl at 

pre-sowing. Topdressing consisted of 130 kg ha-1 of 
urea, applied at 20, 35, and 50 days after emergence, 
always maintaining the equality in these 
requirements for the whole experimental area. No 
significant damage by pest attack or nutritional 
deficiency was observed over the crop cycle. 

Treatment 1 was considered as the control, 
without fungicide application. The remaining 16 
treatments received sequential applications (Table 
1), from two to 16 multisite action fungicides. Eight 
applications were performed with CO2, using a 
backpack sprayer XR11002 model, with six nozzles, 
spaced at 0.45 m, with three bar pressure and an 
application rate of 150 L ha-1. The first application 
occurred at the B1 phenological stage, on February 
09, 2017, from the second to the last spacing, with a 
14-day interval. 

 
Table 1. Treatments and rates used to control ramularia leaf spot (Ramularia areola) in cotton. 

Treatment Active Ingredient Concentration (g.i.a.kg-1)  Rate (g.pc.ha-1) (mL.pc.ha-1) 
1  - - - 
2 Fentin Hydroxide 400 500 
3 Chlorotalonil 720 1500 
4 Chlorotalonil 500 1500 
5 Copper Sulfate 610 750 
6 Fluazinam 500 1000 
7 Mancozebe 750 1500 
8 Copper Oxychloride + Mancozebe 300 + 440 1500 
9 Chlorotalonil 850 1500 
10 Chlorotalonil + Copper Oxychloride 250 + 504 1500 
11 Chlorotalonil 825 1500 
12 Fenpropimorph 750 600 
13 Mancozebe 800 1500 
14 Chlorotalonil + Thiophanate-Methyl 600 + 240 1250 
15 Copper Oxychloride 588 1000 
16 Copper Nitrate 440 200 
17 Piraclostrobin + Fluxapiroxade 333 + 167 300 + 500 

 
Four severity evaluations for ramularia leaf 

spot were performed over the crop cycle. The 
diagrammatic scale proposed by Aquino et al. 
(2008) was used in the following days and 
phenological stages, respectively: 03/28/2017, F9; 
04/11/2017, F19; 04/25/2017, F20; and 05/19/2017, 
C3. From these severity evaluations, data of the 
area under the disease progress curve (AUDPC) 
were taken, and afterward, the efficiency (EF) of 
each replication was calculated, adapting the 
formula proposed by Abbot (1925).  

The experimental area was overflown at the 
height of 120 m on 05/17/2017 by an unmanned 
aerial vehicle (UAV) eBee RTK model (senseFly 
Inc.) when the plant was at the C3 phenological 
stage. Images were captured with the Sequoia 4.0 
passive sensor with 1280 x 960 resolution, in the 

Green (550 nm), Red (660 nm), Red Edge (735 nm), 
and NIR (790 nm) bands. All images presented a 
spatial resolution of 0.23 m, orthorectified with the 
Pix4D Mapper software, and subject to radiometric 
corrections. On 05/19/2017, data were also collected 
from the NDVI (Normalized Difference Vegetation 
Index) by a GreenSeeker LT 200 active sensor 
(Trimble Inc.), which emits light at the red (660 nm) 
and near-infrared (770 nm) wavelengths, 
automatically measuring the light reflected by the 
plant and calculating the NDVI GS, at an average 
height of 0.8 m from the plant canopy. 

For the vegetation index data collection, ten 
plants were sampled within the useful area by the 
Green Seeker sensor and 10 pixels by the Sequoia 
sensor. The vegetation indices used in this study 
were:  



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Biosci. J., Uberlândia, v. 34, n. 6, p. 1706-1713, Nov./Dec. 2018 

NDVI S (Normalized Difference Vegetation Index) 
(QI et al. 1994):  

 

NDRE (Normalized Difference Red Edge index) (QI 
et al. 1994): 

 

SAVI-R (Soil Adjusted Vegetation Index) (HUETE, 
1988): 

 

SAVI-RE (Soil Adjusted Vegetation Index) using the 
Red Edge band (HUETE, 1988): 

 

 
For the L constant, the values of 0.25 

(SAVI-R 1 and SAVI-RE 1) (high vegetation 
densities) and 0.50 (SAVI-R 2 e SAVI-RE 2) 
(medium vegetation densities) were used. 
SR-R (Simple Ratio) (HUNSAKER et al., 2003):  

 

SR-RE (Simple Ratio) using the Red Edge band 
(HUNSAKER et al., 2003):  

 

 
Plant height (PH) was evaluated using ten 

plants per plot and yield (YIE) was assessed by 
collecting all cotton lint in 3.33 m in the two central 

rows inside the useful plot area, considering a final 
stand of 9 plants m-1. The values were converted 
into arrobas ha-1 of cotton seed. 

After the beginning of applications, the 
experimental area was monitored, and only on 
03/06/17, the first symptoms of ramularia leaf spot 
were observed when the crop was at the F1 stage. 

Data were subject to analysis of variance 
and means clustering by the Scott-Knott’s test at 5% 
probability. Subsequently, the Pearson’s correlation 
analysis was performed, and results were expressed 
by the correlation network. Variables with positive 
correlation are linked by a green trace, while 
variables with negative correlation are linked by a 
red trace. Trace thickness is proportional to the 
magnitude of the correlation modulus. All analyses 
were performed using the Rbio software 
(BHERING, 2017). 

 
RESULTS AND DISCUSSION 

 
Treatments presented a great difference 

when the crop was at the C3 phenological stage. At 
this stage, plants already presented great defoliation 
in some treatments (such as 1, 5, and 10), whereas 
other treatments had practically no defoliation (such 
as 2, 3, and 4) (Figure 1). The defoliation was 
caused by the disease, which was already at the 
advanced attack stage, presenting a significant 
amount of disease in some plots and resulting in 
high scores, based on the diagrammatic scale 
proposed by Aquino et al. (2008). Therefore, images 
and reflections were collected at this time. 

 

   
Treatment 1 Treatment 5  Treatment 10 

   
Treatment 2 Treatment 3 Treatment 4 

Figure 1. Images of the treatments with greater defoliation due to ramularia leaf spot at the C3 stage. 
 



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Table 2 shows a significant difference 
between the treatments used for the indices NDVI S, 
NDVI GS, SAVI-R 1, SAVI-R 2, and SR-R. 
Treatments  2, 3, 4, 6, 8, 9, 11, and 17 resulted in the 
highest means for NDVI S. Treatments 2, 3, 4, 6, 9, 
11, and 17  allowed the highest means for SAVI 1 
and SAVI 2. Finally, treatments 2, 3, 4, 6, 9, and 17 
provided the highest means for SR-R. 

Based on these data, the high values of the 
vegetation indices suggest that treatments with the 
highest amount of leaves per unit area might have 
undergone less disease attack, resulting in a higher 
yield. Dissimilarities between vegetation indices can 
be explained by the different way of calculating 
them or by the different way of collecting data, and 
the results of each vegetation index may be more 
usable depending on the purpose. 

 
Table 2. Summary of the analysis of variance for the variables NDVI S, NDVI GS, SAVI-R 1, SAVI-R 2, and 

SR-R evaluated in cotton under different fungicides for ramularia leaf spot control. 
Treatment NDVI S NDVI GS SAVI-R 1 SAVI-R2 SR R 

1 0.84 b 0.71 a 0.55 b 0.66 b 11.58 b 
2 0.88 a 0.75 a 0.61 a 0.73 a 15.77 a 
3 0.87 a 0.77 a 0.62 a 0.74 a 15.24 a 
4 0.88 a 0.78 a 0.62 a 0.74 a 15.49 a 
5 0.84 b 0.72 a 0.56 b 0.67 b 12.80 b 
6 0.87 a 0.76 a 0.61 a 0.73 a 15.02 a 
7 0.84 b 0.74 a 0.56 b 0.67 b 12.09 b 
8 0.86 a 0.76 a 0.58 b 0.69 b 13.68 b 
9 0.87 a 

0.78 a 
0.61 a 0.73 a 16.01 a 

10 0.83 b 0.72 a 0.55 b 0.66 b 11.35 b 
11 0.86 a 0.75 a 0.61 a 0.73 a 13.58 b 
12 0.84 b 0.75 a 0.56 b 0.68 b 11.92 b 
13 0.85 b 0.73 a 0.59 b 0.70 b 12.76 b 
14 0.85 b 0.73 a 0.57 b 0.68 b 12.23 b 
15 0.84 b 0.72 a 0.56 b 0.68 b 12.06 b 
16 0.84 b 0.76 a 0.56 b 0.67 b 11.59 b 
17 0.87 a 0.77 a 0.61 a 0.73 a 14.35 a 
Mean 0.85 0.75 0.58 0.70 13.38 
F-calculated 2.10* 1.52ns 2.93* 2.93* 3.16* 
CV (%) 2.65 4.81 5.04 5.04 13.71 
*: significant at 5% probability by the F test; CV: coefficient of variation. 

 
Table 2 shows that the coefficient of 

variation (CV%) was low for all the indices, with 
the highest values recorded for SR-R. This low CV 
value between the indices can explain its low 
expression in relation to ramularia leaf spot effects. 

Table 3 shows a significant difference 
between the treatments used for the variables 

NDRE, SAVI-RE 2, and SR-RE. Treatments 2, 3, 4, 
6, 9, 11, 13, 14, and 17 provided the highest means 
for NDRE. Treatments 2, 3, 4, 6, 9, 11, and 17 
showed the highest means for SAVI-RE 2. 
Treatments 2, 3, 4, 6, 9, and 17 had the highest 
means for SR-RE. 

 
Table 3. Summary of the analysis of variance for the variables NDRE, SAVI-RE 1, SAVI-RE 2, and SR-RE 

evaluated in cotton under different fungicides for ramularia leaf spot control. 
Treatment NDRE SAVI-RE 1 SAVI-RE 2 SR RE 
1 0.10 b 0.08 a 0.10 b 1.23 b 
2 0.13 a 0.11 a 0.13 a 1.30 a 
3 0.12 a 0.10 a 0.12 a 1.27 a 
4 0.13 a 0.11 a 0.13 a 1.30 a 
5 0.07 b 0.06 a 0.07 b 1.19 b 
6 0.12 a 0.10 a 0.12 a 1.27 a 
7 0.10 b 0.08 a 0.10 b 1.23 b 



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8 0.09 b 0.10 a 0.09 b 1.20 b 
9 0.12 a 0.11 a 0.12 a 1.27 a 
10 0.09 b 0.07 a 0.08 b 1.19 b 
11 0.10 a 0.09 a 0.11 a 1.24 b 
12 0.09 b 0.08 a 0.09 b 1.21 b 
13 0.10 a 0.08 a 0.10 b 1.22 b 
14 0.11 a 0.09 a 0.10 b 1.24 b 
15 0.09 b 0.07 a 0.09 b 1.20 b 
16 0.09 b 0.07 a 0.09 b 1.20 b 
17 0.11 a 0.10 a 0.12 a 1.26 a 
Mean 0.10 0.09 0.10 1.24 
F-calculated 2.16* 1.86ns 2.42* 2.17* 
CV (%) 20.23 24.91 21.77 3.97 
*: significant at 5% probability by the F test; CV: coefficient of variation. 
 

Table 3 indicates that the CV values for the 
indices calculated with the Red Edge band were 
higher than those calculated with the Red band. 
SAVI-RE 2 presented greater sensitivity in 
recording leaves infected with ramularia leaf spot. 

Meanwhile, Table 4 demonstrates a 
significant difference between the treatments used 
for all variables. Treatments 3, 4, 8, and 9 provided 
the highest means for PH. Treatments 3, 4, and 6 
had the highest means for YIE in arrobas ha-1 of 
cotton seed, whose values were also higher for all 
vegetation indices and EF. Treatment 1 provided 

the highest mean for AUDPC (control) and had the 
greatest amount of disease over the crop cycle. This 
result is for the treatment did not receive any 
fungicide. For those that received some fungicide, 
treatments 5, 7, 8, and 16 showed less disease 
control, i.e., they presented higher AUDPC means. 
This result proves that these treatments had the 
least disease control with eight sequential 
applications. For EF, treatments 2, 3, 4, 6, 9, 11, 
and 17 presented the highest means and provided 
the best performance for disease control. 

 
Table 4. Summary of analysis of variance for plant height (PH), seed cotton yield (YIE), area under the disease 

progress curve (AUDPC), and agronomic efficiency (EF) evaluated in cotton under different 
fungicides for ramularia leaf spot control. 

Treatment PH (m) YIE @/ha AUDPC EF 
1 0.99 b 332.75 d 1204.31 a 0.10 e 
2 0.99 b 363.75 c 14.38 e 0.99 a 
3 1.05 a 414.72 a 22.13 e 0.98 a 
4 1.05 a 393.19 a 84.88 e 0.94 a 
5 1.00 b 325.94 d 738.00 b 0.45 d 
6 1.00 b 401.25 a 101.13 e 0.92 a 
7 1.01 b 370.81 b 745.50 b 0.44 d 
8 1.05 a 375.00 b 753.50 b 0.44 d 
9 1.05 a 358.06 c 66.88 e 0.95 a 
10 0.92 b 351.33 c 505.25 c 0.62 c 
11 0.98 b 384.67 b 33.44 e 0.98 a 
12 0.92 b 338.06 d 293.75 d 0.78 b 
13 1.01 b 348.89 c 447.75 c 0.67 c 
14 0.96 b 333.33 d 361.75 d 0.73 b 
15 0.97 b 345.83 c 587.75 c 0.56 c 
16 0.98 b 332.31 d 826.63 b 0.38 d 
17 0.99 b 374.42 b 76.38 e 0.94 a 
Mean 0.99 361.43 403.73 0.70 
F-calculated 2.01* 9.63* 38.26* 38.24* 
CV (%) 5.78 4.72 28.89 12.46 
*: significant at 5% probability by the F test; CV: Coefficient of variation. 

 



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Over the crop development, treatments 2, 5, 
and 11 showed phytotoxicity symptoms 
(05/08/2017) at the C1 phenological stage after the 
last fungicide application (05/05/2017). Symptoms 
consisted of reddish color leaves, mostly on the 
adaxial side, near the edge. However, they probably 
did not affect the vegetation index, as the values of 

these plots were consistent with those of EF (Table 
2, 3, and 4). Conversely, a great variation was 
observed for yield, which was reduced in all the 
plots with phytotoxicity symptom, promoted by the 
abortion of the crowns in the upper third of the 
plants. 

The most relevant data may be revealed by 
comparing the treatments that had the highest values 
in practically all the vegetation indices shown in 
Tables 2 and 3, i.e., treatments 2, 3, 4, 6, 9, 11, and 
17. These treatments also presented the lowest 
AUDPC values, as shown in Table 4. The present 

result corroborates those for NDVI S, NDRE, 
SAVI-R 1, SAVI-R 2, and SAVI-RE 2, which are 
sensitive for detecting the treatments able to control 
the disease, where the most sensitive indices are the 
most correlated to AUDPC (Figure 2). 

 

 
Figure 2. Pearson’s correlation network between the evaluated variables. 
 

The values of the Pearson’s correlation 
network shown in Figure 2 ranged between 0 and 1 
for green trace and between -1 and 0 for red trace. 
The trace thickness corresponds to the magnitude of 
its correlation. All correlations of AUDPC showed 
red color traces, indicating that this variable 
presented values inversely proportional to those of 
the other variables, and the higher the AUDPC, the 
lower was the control action of the fungicide. 

Figure 2 shows a strong negative correlation 
between AUDPC and EF since the higher the 
efficiency value, the greater was the fungicide 
action and the lower was the disease severity 
(AUDPC). EF showed a positive relationship with 
yield and was not higher due to the phytotoxicity 
caused by some products. Conversely, AUDPC 
presented an inverse relationship with yield, as 
expected.  



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Bergamin Filho et al. (1995), when 
evaluating foliar diseases of common bean, 
observed no correlation between yield and AUDPC, 
whereas the present study revealed a strong 
correlation. This result proved the relevance of the 
study on ramularia leaf spot since the difference 
between the control and the most productive 
treatment is of 81.97 arrobas ha-1 of cotton seed. The 
products with higher disease control potential did 
not necessarily present the highest yields owing to 
their higher phytotoxicity. 

The vegetation indices SAVI-R 1 and 
SAVI-R 2 were the most correlated to EF and YIE 
and presented the highest negative correlation to 
AUDPC. Cao et al. (2013) obtained similar results 
and found a significant correlation between SAVI 
and wheat disease severity index. This result 
indicates that this vegetation index can detect 
disease in an area, but is still not very sensitive to 
show the disease severity. This fact is because low 
efficiency leads to non-significant differences in 
SAVI 1, even being lower. The vegetation indices 
SAVI-RE 1 and SAVI-RE 2 showed a weak positive 
correlation to YIE and EF, evidencing that the Red 

spectral range for this vegetation index is more 
sensitive than the Red Edge range. 

NDVI S and NDVI GS showed a strong 
positive correlation to PH, which did not present 
this same correlation to YIE and EF. NDRE had a 
low correlation to EF and YIE; however, it was 
higher than that of NDVIs. SR-R, SR-RE, and 
NDVIs had a higher correlation to PH than YIE. 
 
CONCLUSIONS 

 
The vegetation indices NDVI and SR R 

showed a higher correlation to plant height when 
compared with the other agronomic indices. 

SAVI, obtained with the wavelength in the 
Red spectral range, presented a higher correlation to 
efficiency and yield, being the most expressive 
index for ramularia leaf spot effects. 
 The vegetation indices that used the 
wavelength values in the Red spectral range showed 
a higher correlation to plant height, yield, and 
efficiency when compared with those that used 
values of wavelength in the Red Edge spectral 
range. 

 
 

RESUMO: Este trabalho objetivou correlacionar diferentes índices de vegetação em resposta aos efeitos 
causados pela mancha de ramulária (Ramularia areola) de vários tratamentos com produtos fungicidas. O experimento foi 
implantado no município de Chapadão do Sul, Estado de Mato Grosso do Sul, no ano agrícola 2016/2017. O delineamento 
experimental utilizado foi blocos casualizados com 17 tratamentos com quatro repetições. Foram obtidos dados a partir do 
sensor passivo Sequoia 4.0 e do sensor ativo Green Seeker LT 200. A partir das informações registradas pelos sensores, 
foram gerados nove índices de vegetação, que foram comparados com a área abaixo da curva de progresso da doença, 
altura de plantas, produtividade e eficiência agronômica em 17 diferentes tratamentos de produtos de ação fungicida. Os 
tratamentos responderam de forma distinta em relação ao produto neles aplicados, sendo que os índices SAVI (Soil 
Adjusted Vegetation Index), obtidos a partir da banda na faixa espectral do Red, apresentaram maior correlação com 
AACPD, eficiência e produtividade. Já o índice NDVI (Normalized Difference Vegetation Index) obteve maior correlação 
com a altura de plantas e SR (Simple Ratio), ambos utilizando o comprimento de onda na faixa espectral da banda Red. 
 

PALAVRAS-CHAVE: Gossypium hirsutum L. Doenças do algodoeiro. Sensoriamento remoto. Sensores 
multiespectrais. 
 
 
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