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A split-window method to retrieving sea surface temperature from landsat 8 thermal infrared remote sensing data in offshore waters
Journal Pre-proof A split-window method to retrieving sea surface temperature from landsat 8 thermal infrared remote sensing data in offshore waters Jiaoqi Fu, Chao Chen, Biyun Guo, Yanli Chu, Hong Zheng PII:
S0272-7714(19)30934-5
DOI:
https://doi.org/10.1016/j.ecss.2020.106626
Reference:
YECSS 106626
To appear in:
Estuarine, Coastal and Shelf Science
Received Date: 2 October 2019 Revised Date:
17 January 2020
Accepted Date: 29 January 2020
Please cite this article as: Fu, J., Chen, C., Guo, B., Chu, Y., Zheng, H., A split-window method to retrieving sea surface temperature from landsat 8 thermal infrared remote sensing data in offshore waters, Estuarine, Coastal and Shelf Science (2020), doi: https://doi.org/10.1016/j.ecss.2020.106626. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier Ltd.
Conceptualization and methodology, Jiaoqi Fu and Chao Chen; Data curation, Jiaoqi Fu; Investigation and validation, Jiaoqi Fu, Chao Chen and Yanli Chu; Supervision, Chao Chen; Writing - original draft, Jiaoqi Fu; Writing - review & editing, Chao Chen, Yanli Chu and Hong Zheng; Revising, Jiaoqi Fu, Biyun Guo and Chao Chen.
1 2
A split-window method to retrieving sea surface temperature from
3
Landsat 8 thermal infrared remote sensing data in offshore waters
4 Jiaoqi Fua, Chao Chena,*, Biyun Guoa, Yanli Chub, Hong Zhengc
5 6 7 8 9 10 11 12
a
Marine Science and Technology College, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China b
School of Economics and Management, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China c
National Engineering Research Center of Marine Facilities Aquaculture, Zhejiang Ocean University, Zhoushan, 316000, China *
Correspondence: ([email protected])
13
Abstract: Sea surface temperature (SST) is an important parameter used to describe the air-sea
14
interaction and the state of marine structures. Atmospheric water vapor has a significant attenuation
15
effect on thermal infrared information, which will reduce the accuracy of SST inversion. However,
16
the effect of atmospheric water vapor on the inversion accuracy is not considered carefully in the
17
existing SST inversion algorithm. In this study, a new method is proposed for retrieving SST from
18
Landsat 8 Thermal Infrared Remote Sensing (TIRS) data based on the variation of atmospheric water
19
vapor content (wvc). First, simulating atmospheric conditions by using moderate resolution
20
atmospheric transmission (MODTRAN) based on atmospheric profiles data (air temperature and
21
pressure). Second, calculating the bright temperature based on the radiation transfer equation and
22
Planck’s law. Then, constructing the SST retrieval model of thermal infrared remote sensing based on
23
wvc. Finally, evaluating the accuracy of the proposed model by using simulation data. The root mean
24
square errors (RMSEs) are within 0.5 K, indicating that the accuracy of the model is good in theory.
25
In addition, taking the Zhoushan sea area as the research area, SST is retrieved by Landsat 8 TIRS
26
data. The accuracy of inversion results is evaluated by advanced very high-resolution radiometer
27
(AVHRR) SST products. The bias and RMSE based on the AVHRR SST products are within 1 K and
28
2 K, respectively. The results show that the accurate SST with high spatial resolution was
29
successfully obtained by using the method. The study is of great significance to the acquisition of
30
marine structural parameters, the exploitation of marine resources, and the monitoring of marine
31
disasters.
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Keywords: Sea surface temperature; Landsat 8; thermal infrared remote sensing data; MODTRAN
33 34
1. Introduction
1
35
Sea surface temperature (SST) is the result of the interaction of ocean dynamic and thermodynamic
36
processes with ocean and atmosphere, which is located at the junction of ocean and atmosphere
37
(Noori et al., 2017; Wynsberge et al., 2017). It is a very important variable in the earth's climate
38
system. It plays an important role in marine monitoring, numerical prediction, seasonal forecasting of
39
marine and atmospheric system, and climate change monitoring (Leonardo et al., 2017; Kawai and
40
Wada, 2007). Extreme weather events such as El Niño and La Niña have highly correlated
41
relationship with the variation of SST (Liu et al., 2017). In addition, the ocean is a major component
42
of the earth, covering 71% of the surface of the earth. Due to the large heat capacity of seawater, a
43
small variation in ocean temperature will impact the local or even global weather and change the
44
environment (Varelaa et al., 2018). Therefore, studying the SST is not only of great scientific value
45
but also of great significance to human activities and the social economy.
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The traditional methods of SST measurement are mainly observation by in-suit ships and buoys (Li
47
and He, 2014; Zhu et al., 2019). From those methods, it is difficult to obtain large-scale and
48
synchronous SST data, especially in extreme weather conditions such as typhoons. In recent years,
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with the rapid growth of sensor technology and big data processing techniques, ocean satellite remote
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sensing has achieved remarkable development. Satellite remote sensing technology can effectively
51
overcome various limitations by the unique characteristics of high time efficiency, wide range, and
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high dynamics. It is increasingly being used in ocean observation and has become an important
53
technology in ocean monitoring (Luo et al., 2019). Satellite remote sensing includes thermal infrared
54
remote sensing and microwave remote sensing (Schmitt and Zhu, 2016). A microwave radiometer is
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often used in meteorological satellites. It cannot accurately obtain observations in coastal waters
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because it can be greatly affected by land (Liu et al., 2017; Othman et al., 2002). Thermal infrared
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remote sensing has high spatial resolution and can effectively reduce the effect of land on offshore
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SST retrieval (Wang et al., 2013; Li et al., 2013; Mathieu et al., 2017). According to relevant
59
research, thermal infrared remote sensing has the capability to invert SST in land-sea interaction areas
60
and offshore areas (Jimenez-Munoz et al., 2009; Mo et al., 2018).
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Many domestic and foreign scholars have studied the algorithm of SST inversion using thermal
62
infrared remote sensing. The most common algorithm is the split-through algorithm (Minnett et al.,
63
2019). In 1975, MC Millin first proposed the split-window algorithm based on the radiation transfer
64
equation (Mcmillin, 1975; Loncan et al. 2015), and achieved good results in the inversion of SST. In
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2006, Liu et al. proposed a multi-channel split window algorithm to retrieve the SST in the Yellow
66
Sea and the East China Sea, which reflected the distribution of the SST in the Yellow Sea and the East
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China Sea (Liu and Zhou, 2006). In 2011, Kotaro Hosoda et al. tested the atmospheric correction
68
model of MODIS data, and the results showed that the split window algorithm had the highest
69
accuracy (Hosoda, 2011). In 2019, Bo Ai et al. proposed a new SST inversion model based on split
70
window algorithm. The results of SST inversion in Bohai Sea were compared with MODIS SST
71
products to verify the credibility of the model (Ai et al., 2019). At present, the technology of
2
72
retrieving SST from satellite thermal infrared remote sensing data is becoming more and more
73
mature. However, the research on SST in China and abroad is mostly focused on the ocean, but less
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on lakes, rivers, and offshore areas, mainly due to the constraints of remote sensing data sources and
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satellite sensors.
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In this study, a method is proposed to retrieve SST in coastal waters with thermal infrared remote
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sensing dataset collected from the Landsat 8 Thermal Infrared Sensor (TIRS). It is of great
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significance to the acquisition of marine structural parameters, the exploitation of marine resources,
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and the monitoring of marine disasters. In addition, atmospheric water vapor has a significant
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attenuation effect on thermal infrared information, which will reduce the accuracy of SST inversion
81
(Jimenez-Munoz et al., 2010; CristAbal et al., 2009). Therefore, the effect of atmospheric water vapor
82
content (wvc) on SST is also considered in this study.
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2. Establishment of the offshore SST retrieval model
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2.1. Data for model construction
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The atmospheric profiles data provided by the National Centers for Environmental Prediction
86
(NCEP) were used in this study. The NCEP freely provides 17-layer global atmospheric parameter
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profiles at 00:00, 06:00, 12:00, and 18:00 every day since 1948. The spatial resolution is 2.5° × 2.5°.
88
The atmospheric pressures of 17-layer are 1000, 925, 850, 700, 600, 500, 400, 300, 250, 200, 150,
89
100, 70, 50, 30, 20, and 10 hPa.
90
The emissivity data used in this study are from Moderate Resolution Imaging Spectrometer
91
(MODIS) University of California, Santa Barbara (UCSB) Emissivity Library. The library collects
92
emissivity measurements of natural and manmade materials that can be divided into four categories:
93
water, ice, and snow; soils and minerals; vegetation; and manmade materials. It can be used as a
94
source of spectral emissivity at the component level in the TIR BRDF models to calculate the scene
95
emissivity in the split-window channels to be used in the land surface temperature (LST) algorithms.
96
2.2. Model construction
97
In our study, a new method is proposed for the retrieval of SST based on the characteristics of the
98
Landsat 8 thermal infrared sensor. The detailed research plan is shown in Fig. 1 and described as
99
follows:
100
1.
Simulating atmospheric conditions and atmospheric wvc by using moderate resolution
101
atmospheric transmission (MODTRAN) based on NCEP atmospheric profiles data (air
102
temperature and relative humidity).
103
2.
Calculating the bright temperature based on the radiation transfer equation and Planck’s law.
104
3.
Constructing the SST retrieval model of thermal infrared remote sensing based on wvc by using
105 106
the principle of the split-window algorithm. 4.
Evaluating the accuracy of the proposed model by using simulation data.
3
107 108 109
Fig. 1. Technical flowchart. 2.2.1. Atmospheric conditions simulated by MODTRAN
110
The radiation signal received by thermal infrared remote sensors consists of three parts: sea surface
111
radiation after atmospheric attenuation, upward atmospheric radiation, and downward atmospheric
112
radiation reflected by the sea surface. The expression is described as follows (Guillevic et al., 2003): ↑ ↓ Bi (Ti ) = ε i B( TS )τ i + Ratmi + (1 - ε i ) Ratmi τi
113
(1)
114
where Bi is the Planck function, Ti is the bright temperature observed at the top of atmosphere in
115
channel i, TS is the sea surface temperature, ε i is the offshore seawater emissivity, τ i is the
116
↑ ↓ atmospheric transmittance, Ratmi and Ratmi are the upward atmospheric radiation and downward
117
atmospheric radiation, respectively.
118
In order to retrieve the SST accurately, the effect of atmosphere on spectral radiation has to be
119
eliminated (Xing et al., 2007; Passang and Peter, 2018; Yi et al., 2018). In this study, the NCEP
120
atmospheric profiles at 12:00 in the period from January 1, 2013, to December 31, 2018, in the
121
Zhoushan Sea area was extracted, totaling 2,191. Fig. 2 shows the atmospheric wvc and the bottom
122
layer (1000 hpa) air temperature for these atmospheric profiles. The atmospheric wvc was mainly
123
distributed between 1 g/cm2 and 5.5 g/cm2, among which the most was between 1.5 g/cm2 and 3.5
124
g/cm2. The bottom layer air temperature was mainly between 285 K and 301 K and was concentrated
125
between 290 K and 299 K.
4
126 127
Fig. 2. The distribution of water vapor content (wvc) and bottom layer air temperature of the National
128
Centers for Environmental Prediction atmospheric profiles.
129
In our study, the bottom layer air temperature is regarded as the SST. The upward atmospheric
130
↓ ↑ radiation Ratmi , downward atmospheric radiation Ratmi , and atmospheric transmittance τ i are
131
simulated by the atmospheric radiation transfer software MODTRAN with the atmospheric profiles
132
mentioned above (Berk et al., 2003). The results are shown in Fig. 3. In general, the main components
133
of atmosphere are concentrated in the lower atmosphere (Li et al., 1994; Vitor et al., 2018; Wieke et
134
al., 2017). This situation will result in upward radiation less than downward radiation. In addition, the
135
atmospheric radiation of channel 11 is mostly larger than that of channel 10, and the transmittance of
136
channel 11 is less than that of channel 10.
137 138
Fig. 3. Two thermal infrared channels simulated by moderate resolution atmospheric transmission:
139
(a) the upward atmospheric radiation, (b) downward atmospheric radiation, and (c) atmospheric
140
transmittance. Channel 10 is shown in black; and channel 11 is shown in red.
5
141
2.2.2. Bright temperature calculated by Planck’s law
142
Planck imported quantum theory to blackbody radiation sources. Planck’s law shows that, in
143
theory, the distribution function of blackbody radiation energy varies with wavelength. The
144
expression is described as follows (Jimenez-Munoz et al., 2014): B ( λ,T ) =
145
hc 2πhc 2 kλT e − 1 5 λ
−1
(2)
146
where the units of B ( λ, T ) are W/(m2·µm), c represents light speed, h = 6.6262×10-34 J·S is the
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Planck constant, k = 1.3806×10-23 J/K and is the Boltzmann constant, and the units of wavelength λ
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and temperature T are µm and K, respectively.
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According to the bottom layer air temperature T0 of each profile, the SST was set to eight levels,
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Ts=T0 + [-10, -5, 0, 5, 10, 15, 20, 25] K. In addition, three seawater emissivity curves: seawater01,
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seawater02, and seawater03 were selected from the UCSB Emissivity Library for simulation, as
152
shown in Figure 4. The data of seawater01 and seawatre02 are the emissivity averaged over 18 sets
153
from Goleta, CA, USA. The data of seawater03 are the emissivity averaged over 10 sets. Based on the
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eight SST levels, three emissivity samples and the upward atmospheric radiation, downward
155
atmospheric radiation, and atmospheric transmittance of the two channels, the radiance in 52,584
156
cases was simulated by using the radiation transfer equation (Equation 1). Then, the bright
157
temperature observed at the top of atmosphere can be calculated by Planck’s law (Equation 2).
158 159 160
Fig. 4. The three seawater emissivity curves. 2.2.3. The split-window algorithm based on wvc
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Atmospheric water vapor has a clear attenuation effect on thermal infrared information, which will
162
reduce the inversion accuracy of the SST. Therefore, atmospheric wvc is added as a variable into the
163
algorithm. Based on the principle of the split-window algorithm, a new model is constructed to
164
retrieve the SST from the infrared channels (Jimenez-Munoz et al., 2014; Hulley et al., 2011; Wang et
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al., 2015; Tang, 2018):
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SST = a0 + a1 ⋅ Ti1 + a2 ⋅ Ti 2 + a3 ⋅ ( Ti1 − Ti 2 ) + a4 ⋅ wvc + a5 ⋅ wvc 2 2
(3)
6
167
where a k (k = 0,1…5) are coefficients, Ti1 and Ti2 are the brightness temperature in two thermal
168
infrared channels, SST is the sea surface temperature, and wvc is the water vapor content obtained by
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the NCEP atmospheric profiles data. Based on the brightness temperature data of the two channels,
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the SST and the wvc, the coefficients a k were obtained by regression analysis according to equation
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(3). The results are shown in Table 1.
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Table 1. Coefficients of the split-window algorithm with wvc.
a0 -0.992
173
a1 3.970
a2 -2.963
a3 0.044
a4 -0.328
a5 0.091
2.2.4. Model validation
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Accuracy evaluation is indispensable in temperature retrieval. It is not only a standard for
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evaluating the quality of the method and the influence on the subsequent application but also an
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important basis for evaluating the performance of the method, adjusting model parameters, and
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optimizing the extraction process (Li et al., 2019; Li et al., 2018). In order to study the influence of
178
water vapor on the accuracy of SST inversion, the study proposed an SST inversion method without
179
considering the variation of atmospheric wvc:
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SST = a0 + a1 ⋅ Ti1 + a2 ⋅ Ti 2 + a3 ⋅ (Ti1 − Ti 2 )
181
Similarly, the coefficients of each water vapor interval are obtained by regression analysis. The
182
results are shown in Table 2.
183
2
(4)
Table 2. Coefficients of the split-window algorithm without wvc.
a0 3.228
a1 4.072
a2 -3.081
a3 0.048
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In this study, the parameters that were obtained during modeling are substituted into the SST
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retrieval model to calculate the SST. The accuracy of the proposed algorithm is verified by comparing
186
the initial SST with the inversion SST (Hu et al., 2015). The root means square error (RMSE) is used
187
to measure the deviation between the initial SST and the inversion SST:
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RMSE =
1 N 2 ∑ ( SSTi − TSi ) N i =1
(5)
189
where SSTi is the inverted SST, TSi is the initial SST, and N=52,584 is the number of SSTs. The
190
results are shown in Fig. 5. The RMSE of the derived results is within 0.5 K. The accuracy of the
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algorithm is good in theory. However, the RMSE of the algorithm with wvc is 0.3961K, which is
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smaller than the RMSE of the algorithm without wvc. It shows that the method proposed in the paper
193
is effective. This paper has improved the method of split-window algorithm to retrieve SST.
7
194 195
Fig. 5. Scatterplots of the initial SST ( TSi ) and the inversion SST ( SSTi ): (a) the algorithm with wvc,
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and (b) the algorithm without wvc.
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3. Experiments and results
198
3.1. Research area
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In this study, the Zhoushan sea area was chosen as a representative location at which to study the
200
inversion of offshore SST. The Zhoushan sea area is located in northeastern Zhejiang province, near
201
the East China Sea and Hangzhou Bay, as shown in Fig. 6. It is an open seaport and passageway for
202
the Yangtze River Basin and the Yangtze River Delta (Fu et al., 2019).
203 204
Fig. 6. A sketch map of the research area.
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3.2. Data
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In our study, Landsat 8 TIRS data are used to retrieve the offshore SST, with a spatial resolution of
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30 m, 15° viewing angle, and 16-day revisit period. Landsat 8 was launched by NASA on February
208
11th, 2018 (Braga et al., 2017). It is mainly equipped with an Operational Land Imager and a TIRS.
209
Compared with Landsat 5/TM and Landsat 7/ETM+, Landsat 8 TIRS have been greatly adjusted. It
210
has two thermal infrared channels with a 10–12 micron wavelength. Therefore, the Landsat 8 satellite
8
211
is more advantageous than the previous series of satellites in SST retrieval (Wang et al., 2019; Fu et
212
al., 2018).
213
3.3. Results
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In this study, the Landsat 8 remote sensing images of Zhoushan Sea on March 12, 2015, August 3,
215
2015, and April 2, 2017, were selected for inversion of SST. According to the transit time of the
216
satellite, the atmospheric wvc corresponding to the three remote sensing images was estimated to be
217
4.171 g/cm2 (Figure 7 (a1)), 2.154 g/cm2 (Figure 7 (a2)), and 1.774 g/cm2 (Figure 7 (a3)).
218
Generally, the Landsat 8 remote sensing images acquired by users are gray values without physical
219
meaning. Thus, it is necessary to perform radiometric calibration, which converts gray value into
220
radiance with physical significance, on the images according to the parameters of the file. The
221
brightness temperature is calculated based on the radiance of the thermal infrared bands. The SST is
222
obtained by the new SST retrieval model based on the wvc. The results of the inversion are shown in
223
Fig. 7. On March 12, 2015, the inversion results showed that the lowest SST was 281.64 K, the
224
highest SST was 296.81 K, the average SST was 285.43 K, and the SST was mainly between 280 K
225
and 290 K. On August 3, 2015, the inversion results showed the maximum temperature difference,
226
with the lowest SST being 296.75 K, the highest SST being 316.66 K, and the average SST being
227
302.55 K. The SST was mainly between 298 K and 305 K. The lowest SST of the inversion results on
228
April 2, 2017, was 285.11 K, the highest SST was 300.01 K, the average SST was 287.91 K, and the
229
SST was concentrated between 285 K and 290 K.
230 231
(a1)
(b1)
(c1)
232 233
(a2)
(b2)
(c2)
9
234 235
(a3)
(b3)
(c3)
236
Fig. 7. The Landsat8 images of the Zhoushan sea area, China: (a) true color images, (b) thermal
237
infrared images, and (c) SST inversion results.
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3.4. Accuracy evaluation
239
The observation data are usually used for accuracy evaluation. However, in the absence of
240
observation data, the accuracy of the derived results is evaluated from the Advanced Very
241
High-Resolution Radiometer (AVHRR) SST products (Ai et al., 2019; Brewin et al., 2017; Carroll et
242
al., 2012; Tyagi et al., 2017) in order to verify the validity and applicability of the SST retrieval model
243
in coastal waters. AVHRR SST products were used to analyze the accuracy of the derived results.
244
Although AVHRR SST products cannot fully represent SST, they can be used as an indirect indicator
245
for the accuracy of the inversion results.
246
AVHRR is a scanning radiometer with five spectral channels, which was launched and is
247
maintained by the National Oceanic and Atmospheric Administration (NOAA). The AVHRR SST
248
dataset is obtained by the NOAA National Centers for Environmental Information. The SST
249
algorithm is based on the NOAA/National Environmental Satellite Data and Information Service
250
nonlinear SST operational algorithm (NLSST). This dataset provides twice-daily (day and night)
251
global SST Level 3 data with a 0.0417º × 0.0417º rectangular grid. It provides a high-quality Climate
252
Data Record (CDR) of SST. It is available to the public for a wide variety of uses including scientific
253
research and analysis. The spatial resolution of AVHRR SST products is different from that of
254
Landsat 8 thermal infrared data. According to the longitude and latitude of AVHRR SST products,
255
the corresponding pixel is found in Landsat 8 inversion results. And it is regarded as the center pixel.
256
The SST of the center pixel is averaged by the 133 × 133 window for the Landsat 8 inversion results
257
(Nguyen and Katsuaki, 2018). After expanding with a 133 * 133 window, the spatial range of Landsat
258
8 inversion results is roughly the same as AVHRR SST products. Then, it is compared to the SST of
259
the corresponding pixel to the AVHRR SST product.
260
In this study, the average bias, RMSE, and Pearson correlation coefficient were used to evaluate the
261
inversion accuracy of the SST (Meng et al., 2018). Bias is the inversion SST minus the AVHRR SST
262
product. Pearson’s correlation coefficient, usually denoted as R, was used to measure the linear
263
relationship between two variables,
10
∑ ( SST − SST )(T N
R=
264
i
Si
− TS
i=1
∑ ( SST − SST ) * ∑ (T N
i =1
2
i
N
i =1
Si
)
− TS
)
(6) 2
265
where SSTi is the inversion SST, SST is the average of inversion SST, TSi is the initial SST, TS is
266
the average of the initial SST, and N is the number of SSTs. Figure 8 shows the comparison between
267
the AVHRR SST and the inversion SST. The Pearson correlation coefficients of the three cases were
268
0.8211, 0.8842, and 0.8408. The larger the R, the better the correlation between the inversion SST and
269
AVHRR SST. Overall, the biases were within 1 K, and the RMSEs are within 2 K. The minimum bias
270
of the inversion result on March 12, 2015, was 0.0019 K, the maximum bias was 4.9930 K, the
271
average bias was 0.6666 K, and the RMSE was 1.8252 K. On August 3, 2015, the derived result had a
272
minimum bias of 0.0002 K, maximum bias of -4.8765 K, average bias of 0.0037 K, and RMSE of
273
1.5979 K. On April 2, 2017, the minimum bias of the inversion result was 0.0062 K, the maximum
274
bias was 4.8806 K, the average bias was 0.7943 K, and the RMSE was 1.7643 K. The error is within
275
the acceptable range. The algorithm can be used to retrieve the SST.
276 277 278
Fig. 8. Scatterplots of the AVHRR SST and the inversion SST ( SSTi ). 4. Discussion
279
Based on the variation of atmospheric wvc, the SST inversion model was constructed. The
280
influence of atmospheric wvc on SST inversion was revealed. Atmospheric wvc is an important input
281
parameter for SST inversion. The accuracy of the model depends on the accuracy of wvc. Inaccurate
282
wvc will reduce the accuracy of SST inversion model. However, the wvc used in this paper is derived
283
from NCEP atmospheric profiles data, which may have errors. In addition, the spatial resolution of
284
NCEP atmospheric profiles data is low. There is only one point of atmospheric profiles data in the
285
entire Zhoushan sea area, which cannot fully represent the atmospheric conditions in the Zhoushan
286
sea area. The low spatial resolution of the data may affect the accuracy of SST inversion model.
287
Atmospheric profile data can be obtained from more sources to solve the problem of accuracy of
288
wvc and improve the accuracy of inversion. We also can obtain wvc by acquiring mature water vapor
289
products or improving existing water vapor algorithms. Using the atmospheric profiles data from
290
multiple sources to build the model to improve the inversion accuracy. In addition, it is likely that the
11
291
low spatial resolution of the atmospheric profiles data can be solved by data interpolation. We can
292
interpolate the original atmospheric profiles data to obtain higher resolution data to improve the
293
inversion accuracy.
294
5. Conclusions
295
SST is a basic and important parameter for understanding and studying the ocean. It can be used as
296
a reference for oceanographic research such as water mass, circulation, ocean front, seawater mixing
297
and upwelling. The change of SST not only determines the living environment of marine organisms,
298
but also affects human life, production, economic and social development. This study proposed a new
299
split-window algorithm that takes into account the variation of atmospheric wvc based on Landsat 8
300
TIRS. The SST inversion and verification were carried out with the Zhoushan sea area as the research
301
area. First, the SST retrieval model was established by wvc based on atmospheric correction with
302
MODTRAN. Then, the accuracy of the algorithm was evaluated using simulation data. The RMSEs
303
were within 0.5 K, indicating that the error of the algorithm was small. Landsat 8 remote sensing
304
images were used to retrieve SST. Finally, AVHRR SST products were used to evaluate the inverted
305
SST. The biases were within 1 K, and the RMSEs are within 2 K. The error of the algorithm was
306
within an acceptable range. It was shown that the algorithm can be used to retrieve SST. The study is
307
not only of great scientific value but also of great significance to human activities and the social
308
economy.
309
Although some achievements have been made, the following deficiencies still exist in this study.
310
First, in this study, we did not find the observation data of the Zhoushan sea area for model validation.
311
The results of the accuracy evaluation were not accurate enough to comprehensively analyze the
312
accuracy of the inversion results. Therefore, the observation data and more satellite SST products can
313
be selected to verify the accuracy of the algorithm in the follow-up research works of this study. In
314
addition, combined with the effect of suspended sediment on emissivity, the inversion of the offshore
315
SST requires further study.
316
Acknowledgement
317
We would like to thank the anonymous reviewers for their constructive comments and suggestions.
318
We thank LetPub (www.letpub.com) for its linguistic assistance during the preparation of this
319 320
manuscript. This research was funded by National Natural Science Foundation of China (41701447) and the
321
Training Program of Excellent Master Thesis of Zhejiang Ocean University.
322
Data Availability Statement
323
The input data for this research are all publicly available. The Landsat8 data can be obtained from
324
the website of United States Geological Survey (https://earthexplorer.usgs.gov/), the emissivity data
325
of seawater samples can be obtained from the website of MODIS (Moderate Resolution Imaging
12
326
Spectrometer) UCSB Emissivity Library (https://icess.eri.ucsb.edu/modis/EMIS/html/em.html), the
327
AVHRR (Advanced Very High Resolution Radiometer) data can be obtained from the website of
328
gridded
329
(https://coastwatch.pfeg.noaa.gov/erddap/griddap/index.html?page=1&itemsPerPage=1000),
330
atmospheric profile data for atmospheric modeling can be obtained from the website of NOAA
331
ESRL
332
(https://www.esrl.noaa.gov/psd/data/gridded/data.ncep.reanalysis.pressure.html). The data explicitly
333
generated in this research (atmospheric conditions data simulated by using MODTRAN based on
334
atmospheric profile data, sea surface temperature retrieved from Landsat8 TIRS data) will be
335
available on Mendeley Data (http://data.mendeley.com).
336
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(1) A split-window method is proposed for retrieving SST from Landsat 8 TIRS data based on the variation of atmospheric water vapor content (wvc). (2) The coefficients of model with atmospheric water vapor content (wvc) are fitted. (3) The root mean square errors (RMSEs) of the model are within 0.5 K, indicating that the accuracy of the model is good in theory. (4) Compared with the AVHRR SST products, the bias and RMSE of the retrieving result in the Zhoushan sea area, China are within 1 K and 2 K, respectively. (5) Accurate SST with the high spatial resolution is successfully obtained by using the proposed method in offshore waters.
The authors declare no conflict of interest.
S0272-7714(19)30934-5
DOI:
https://doi.org/10.1016/j.ecss.2020.106626
Reference:
YECSS 106626
To appear in:
Estuarine, Coastal and Shelf Science
Received Date: 2 October 2019 Revised Date:
17 January 2020
Accepted Date: 29 January 2020
Please cite this article as: Fu, J., Chen, C., Guo, B., Chu, Y., Zheng, H., A split-window method to retrieving sea surface temperature from landsat 8 thermal infrared remote sensing data in offshore waters, Estuarine, Coastal and Shelf Science (2020), doi: https://doi.org/10.1016/j.ecss.2020.106626. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier Ltd.
Conceptualization and methodology, Jiaoqi Fu and Chao Chen; Data curation, Jiaoqi Fu; Investigation and validation, Jiaoqi Fu, Chao Chen and Yanli Chu; Supervision, Chao Chen; Writing - original draft, Jiaoqi Fu; Writing - review & editing, Chao Chen, Yanli Chu and Hong Zheng; Revising, Jiaoqi Fu, Biyun Guo and Chao Chen.
1 2
A split-window method to retrieving sea surface temperature from
3
Landsat 8 thermal infrared remote sensing data in offshore waters
4 Jiaoqi Fua, Chao Chena,*, Biyun Guoa, Yanli Chub, Hong Zhengc
5 6 7 8 9 10 11 12
a
Marine Science and Technology College, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China b
School of Economics and Management, Zhejiang Ocean University, Zhoushan, Zhejiang 316022, China c
National Engineering Research Center of Marine Facilities Aquaculture, Zhejiang Ocean University, Zhoushan, 316000, China *
Correspondence: ([email protected])
13
Abstract: Sea surface temperature (SST) is an important parameter used to describe the air-sea
14
interaction and the state of marine structures. Atmospheric water vapor has a significant attenuation
15
effect on thermal infrared information, which will reduce the accuracy of SST inversion. However,
16
the effect of atmospheric water vapor on the inversion accuracy is not considered carefully in the
17
existing SST inversion algorithm. In this study, a new method is proposed for retrieving SST from
18
Landsat 8 Thermal Infrared Remote Sensing (TIRS) data based on the variation of atmospheric water
19
vapor content (wvc). First, simulating atmospheric conditions by using moderate resolution
20
atmospheric transmission (MODTRAN) based on atmospheric profiles data (air temperature and
21
pressure). Second, calculating the bright temperature based on the radiation transfer equation and
22
Planck’s law. Then, constructing the SST retrieval model of thermal infrared remote sensing based on
23
wvc. Finally, evaluating the accuracy of the proposed model by using simulation data. The root mean
24
square errors (RMSEs) are within 0.5 K, indicating that the accuracy of the model is good in theory.
25
In addition, taking the Zhoushan sea area as the research area, SST is retrieved by Landsat 8 TIRS
26
data. The accuracy of inversion results is evaluated by advanced very high-resolution radiometer
27
(AVHRR) SST products. The bias and RMSE based on the AVHRR SST products are within 1 K and
28
2 K, respectively. The results show that the accurate SST with high spatial resolution was
29
successfully obtained by using the method. The study is of great significance to the acquisition of
30
marine structural parameters, the exploitation of marine resources, and the monitoring of marine
31
disasters.
32
Keywords: Sea surface temperature; Landsat 8; thermal infrared remote sensing data; MODTRAN
33 34
1. Introduction
1
35
Sea surface temperature (SST) is the result of the interaction of ocean dynamic and thermodynamic
36
processes with ocean and atmosphere, which is located at the junction of ocean and atmosphere
37
(Noori et al., 2017; Wynsberge et al., 2017). It is a very important variable in the earth's climate
38
system. It plays an important role in marine monitoring, numerical prediction, seasonal forecasting of
39
marine and atmospheric system, and climate change monitoring (Leonardo et al., 2017; Kawai and
40
Wada, 2007). Extreme weather events such as El Niño and La Niña have highly correlated
41
relationship with the variation of SST (Liu et al., 2017). In addition, the ocean is a major component
42
of the earth, covering 71% of the surface of the earth. Due to the large heat capacity of seawater, a
43
small variation in ocean temperature will impact the local or even global weather and change the
44
environment (Varelaa et al., 2018). Therefore, studying the SST is not only of great scientific value
45
but also of great significance to human activities and the social economy.
46
The traditional methods of SST measurement are mainly observation by in-suit ships and buoys (Li
47
and He, 2014; Zhu et al., 2019). From those methods, it is difficult to obtain large-scale and
48
synchronous SST data, especially in extreme weather conditions such as typhoons. In recent years,
49
with the rapid growth of sensor technology and big data processing techniques, ocean satellite remote
50
sensing has achieved remarkable development. Satellite remote sensing technology can effectively
51
overcome various limitations by the unique characteristics of high time efficiency, wide range, and
52
high dynamics. It is increasingly being used in ocean observation and has become an important
53
technology in ocean monitoring (Luo et al., 2019). Satellite remote sensing includes thermal infrared
54
remote sensing and microwave remote sensing (Schmitt and Zhu, 2016). A microwave radiometer is
55
often used in meteorological satellites. It cannot accurately obtain observations in coastal waters
56
because it can be greatly affected by land (Liu et al., 2017; Othman et al., 2002). Thermal infrared
57
remote sensing has high spatial resolution and can effectively reduce the effect of land on offshore
58
SST retrieval (Wang et al., 2013; Li et al., 2013; Mathieu et al., 2017). According to relevant
59
research, thermal infrared remote sensing has the capability to invert SST in land-sea interaction areas
60
and offshore areas (Jimenez-Munoz et al., 2009; Mo et al., 2018).
61
Many domestic and foreign scholars have studied the algorithm of SST inversion using thermal
62
infrared remote sensing. The most common algorithm is the split-through algorithm (Minnett et al.,
63
2019). In 1975, MC Millin first proposed the split-window algorithm based on the radiation transfer
64
equation (Mcmillin, 1975; Loncan et al. 2015), and achieved good results in the inversion of SST. In
65
2006, Liu et al. proposed a multi-channel split window algorithm to retrieve the SST in the Yellow
66
Sea and the East China Sea, which reflected the distribution of the SST in the Yellow Sea and the East
67
China Sea (Liu and Zhou, 2006). In 2011, Kotaro Hosoda et al. tested the atmospheric correction
68
model of MODIS data, and the results showed that the split window algorithm had the highest
69
accuracy (Hosoda, 2011). In 2019, Bo Ai et al. proposed a new SST inversion model based on split
70
window algorithm. The results of SST inversion in Bohai Sea were compared with MODIS SST
71
products to verify the credibility of the model (Ai et al., 2019). At present, the technology of
2
72
retrieving SST from satellite thermal infrared remote sensing data is becoming more and more
73
mature. However, the research on SST in China and abroad is mostly focused on the ocean, but less
74
on lakes, rivers, and offshore areas, mainly due to the constraints of remote sensing data sources and
75
satellite sensors.
76
In this study, a method is proposed to retrieve SST in coastal waters with thermal infrared remote
77
sensing dataset collected from the Landsat 8 Thermal Infrared Sensor (TIRS). It is of great
78
significance to the acquisition of marine structural parameters, the exploitation of marine resources,
79
and the monitoring of marine disasters. In addition, atmospheric water vapor has a significant
80
attenuation effect on thermal infrared information, which will reduce the accuracy of SST inversion
81
(Jimenez-Munoz et al., 2010; CristAbal et al., 2009). Therefore, the effect of atmospheric water vapor
82
content (wvc) on SST is also considered in this study.
83
2. Establishment of the offshore SST retrieval model
84
2.1. Data for model construction
85
The atmospheric profiles data provided by the National Centers for Environmental Prediction
86
(NCEP) were used in this study. The NCEP freely provides 17-layer global atmospheric parameter
87
profiles at 00:00, 06:00, 12:00, and 18:00 every day since 1948. The spatial resolution is 2.5° × 2.5°.
88
The atmospheric pressures of 17-layer are 1000, 925, 850, 700, 600, 500, 400, 300, 250, 200, 150,
89
100, 70, 50, 30, 20, and 10 hPa.
90
The emissivity data used in this study are from Moderate Resolution Imaging Spectrometer
91
(MODIS) University of California, Santa Barbara (UCSB) Emissivity Library. The library collects
92
emissivity measurements of natural and manmade materials that can be divided into four categories:
93
water, ice, and snow; soils and minerals; vegetation; and manmade materials. It can be used as a
94
source of spectral emissivity at the component level in the TIR BRDF models to calculate the scene
95
emissivity in the split-window channels to be used in the land surface temperature (LST) algorithms.
96
2.2. Model construction
97
In our study, a new method is proposed for the retrieval of SST based on the characteristics of the
98
Landsat 8 thermal infrared sensor. The detailed research plan is shown in Fig. 1 and described as
99
follows:
100
1.
Simulating atmospheric conditions and atmospheric wvc by using moderate resolution
101
atmospheric transmission (MODTRAN) based on NCEP atmospheric profiles data (air
102
temperature and relative humidity).
103
2.
Calculating the bright temperature based on the radiation transfer equation and Planck’s law.
104
3.
Constructing the SST retrieval model of thermal infrared remote sensing based on wvc by using
105 106
the principle of the split-window algorithm. 4.
Evaluating the accuracy of the proposed model by using simulation data.
3
107 108 109
Fig. 1. Technical flowchart. 2.2.1. Atmospheric conditions simulated by MODTRAN
110
The radiation signal received by thermal infrared remote sensors consists of three parts: sea surface
111
radiation after atmospheric attenuation, upward atmospheric radiation, and downward atmospheric
112
radiation reflected by the sea surface. The expression is described as follows (Guillevic et al., 2003): ↑ ↓ Bi (Ti ) = ε i B( TS )τ i + Ratmi + (1 - ε i ) Ratmi τi
113
(1)
114
where Bi is the Planck function, Ti is the bright temperature observed at the top of atmosphere in
115
channel i, TS is the sea surface temperature, ε i is the offshore seawater emissivity, τ i is the
116
↑ ↓ atmospheric transmittance, Ratmi and Ratmi are the upward atmospheric radiation and downward
117
atmospheric radiation, respectively.
118
In order to retrieve the SST accurately, the effect of atmosphere on spectral radiation has to be
119
eliminated (Xing et al., 2007; Passang and Peter, 2018; Yi et al., 2018). In this study, the NCEP
120
atmospheric profiles at 12:00 in the period from January 1, 2013, to December 31, 2018, in the
121
Zhoushan Sea area was extracted, totaling 2,191. Fig. 2 shows the atmospheric wvc and the bottom
122
layer (1000 hpa) air temperature for these atmospheric profiles. The atmospheric wvc was mainly
123
distributed between 1 g/cm2 and 5.5 g/cm2, among which the most was between 1.5 g/cm2 and 3.5
124
g/cm2. The bottom layer air temperature was mainly between 285 K and 301 K and was concentrated
125
between 290 K and 299 K.
4
126 127
Fig. 2. The distribution of water vapor content (wvc) and bottom layer air temperature of the National
128
Centers for Environmental Prediction atmospheric profiles.
129
In our study, the bottom layer air temperature is regarded as the SST. The upward atmospheric
130
↓ ↑ radiation Ratmi , downward atmospheric radiation Ratmi , and atmospheric transmittance τ i are
131
simulated by the atmospheric radiation transfer software MODTRAN with the atmospheric profiles
132
mentioned above (Berk et al., 2003). The results are shown in Fig. 3. In general, the main components
133
of atmosphere are concentrated in the lower atmosphere (Li et al., 1994; Vitor et al., 2018; Wieke et
134
al., 2017). This situation will result in upward radiation less than downward radiation. In addition, the
135
atmospheric radiation of channel 11 is mostly larger than that of channel 10, and the transmittance of
136
channel 11 is less than that of channel 10.
137 138
Fig. 3. Two thermal infrared channels simulated by moderate resolution atmospheric transmission:
139
(a) the upward atmospheric radiation, (b) downward atmospheric radiation, and (c) atmospheric
140
transmittance. Channel 10 is shown in black; and channel 11 is shown in red.
5
141
2.2.2. Bright temperature calculated by Planck’s law
142
Planck imported quantum theory to blackbody radiation sources. Planck’s law shows that, in
143
theory, the distribution function of blackbody radiation energy varies with wavelength. The
144
expression is described as follows (Jimenez-Munoz et al., 2014): B ( λ,T ) =
145
hc 2πhc 2 kλT e − 1 5 λ
−1
(2)
146
where the units of B ( λ, T ) are W/(m2·µm), c represents light speed, h = 6.6262×10-34 J·S is the
147
Planck constant, k = 1.3806×10-23 J/K and is the Boltzmann constant, and the units of wavelength λ
148
and temperature T are µm and K, respectively.
149
According to the bottom layer air temperature T0 of each profile, the SST was set to eight levels,
150
Ts=T0 + [-10, -5, 0, 5, 10, 15, 20, 25] K. In addition, three seawater emissivity curves: seawater01,
151
seawater02, and seawater03 were selected from the UCSB Emissivity Library for simulation, as
152
shown in Figure 4. The data of seawater01 and seawatre02 are the emissivity averaged over 18 sets
153
from Goleta, CA, USA. The data of seawater03 are the emissivity averaged over 10 sets. Based on the
154
eight SST levels, three emissivity samples and the upward atmospheric radiation, downward
155
atmospheric radiation, and atmospheric transmittance of the two channels, the radiance in 52,584
156
cases was simulated by using the radiation transfer equation (Equation 1). Then, the bright
157
temperature observed at the top of atmosphere can be calculated by Planck’s law (Equation 2).
158 159 160
Fig. 4. The three seawater emissivity curves. 2.2.3. The split-window algorithm based on wvc
161
Atmospheric water vapor has a clear attenuation effect on thermal infrared information, which will
162
reduce the inversion accuracy of the SST. Therefore, atmospheric wvc is added as a variable into the
163
algorithm. Based on the principle of the split-window algorithm, a new model is constructed to
164
retrieve the SST from the infrared channels (Jimenez-Munoz et al., 2014; Hulley et al., 2011; Wang et
165
al., 2015; Tang, 2018):
166
SST = a0 + a1 ⋅ Ti1 + a2 ⋅ Ti 2 + a3 ⋅ ( Ti1 − Ti 2 ) + a4 ⋅ wvc + a5 ⋅ wvc 2 2
(3)
6
167
where a k (k = 0,1…5) are coefficients, Ti1 and Ti2 are the brightness temperature in two thermal
168
infrared channels, SST is the sea surface temperature, and wvc is the water vapor content obtained by
169
the NCEP atmospheric profiles data. Based on the brightness temperature data of the two channels,
170
the SST and the wvc, the coefficients a k were obtained by regression analysis according to equation
171
(3). The results are shown in Table 1.
172
Table 1. Coefficients of the split-window algorithm with wvc.
a0 -0.992
173
a1 3.970
a2 -2.963
a3 0.044
a4 -0.328
a5 0.091
2.2.4. Model validation
174
Accuracy evaluation is indispensable in temperature retrieval. It is not only a standard for
175
evaluating the quality of the method and the influence on the subsequent application but also an
176
important basis for evaluating the performance of the method, adjusting model parameters, and
177
optimizing the extraction process (Li et al., 2019; Li et al., 2018). In order to study the influence of
178
water vapor on the accuracy of SST inversion, the study proposed an SST inversion method without
179
considering the variation of atmospheric wvc:
180
SST = a0 + a1 ⋅ Ti1 + a2 ⋅ Ti 2 + a3 ⋅ (Ti1 − Ti 2 )
181
Similarly, the coefficients of each water vapor interval are obtained by regression analysis. The
182
results are shown in Table 2.
183
2
(4)
Table 2. Coefficients of the split-window algorithm without wvc.
a0 3.228
a1 4.072
a2 -3.081
a3 0.048
184
In this study, the parameters that were obtained during modeling are substituted into the SST
185
retrieval model to calculate the SST. The accuracy of the proposed algorithm is verified by comparing
186
the initial SST with the inversion SST (Hu et al., 2015). The root means square error (RMSE) is used
187
to measure the deviation between the initial SST and the inversion SST:
188
RMSE =
1 N 2 ∑ ( SSTi − TSi ) N i =1
(5)
189
where SSTi is the inverted SST, TSi is the initial SST, and N=52,584 is the number of SSTs. The
190
results are shown in Fig. 5. The RMSE of the derived results is within 0.5 K. The accuracy of the
191
algorithm is good in theory. However, the RMSE of the algorithm with wvc is 0.3961K, which is
192
smaller than the RMSE of the algorithm without wvc. It shows that the method proposed in the paper
193
is effective. This paper has improved the method of split-window algorithm to retrieve SST.
7
194 195
Fig. 5. Scatterplots of the initial SST ( TSi ) and the inversion SST ( SSTi ): (a) the algorithm with wvc,
196
and (b) the algorithm without wvc.
197
3. Experiments and results
198
3.1. Research area
199
In this study, the Zhoushan sea area was chosen as a representative location at which to study the
200
inversion of offshore SST. The Zhoushan sea area is located in northeastern Zhejiang province, near
201
the East China Sea and Hangzhou Bay, as shown in Fig. 6. It is an open seaport and passageway for
202
the Yangtze River Basin and the Yangtze River Delta (Fu et al., 2019).
203 204
Fig. 6. A sketch map of the research area.
205
3.2. Data
206
In our study, Landsat 8 TIRS data are used to retrieve the offshore SST, with a spatial resolution of
207
30 m, 15° viewing angle, and 16-day revisit period. Landsat 8 was launched by NASA on February
208
11th, 2018 (Braga et al., 2017). It is mainly equipped with an Operational Land Imager and a TIRS.
209
Compared with Landsat 5/TM and Landsat 7/ETM+, Landsat 8 TIRS have been greatly adjusted. It
210
has two thermal infrared channels with a 10–12 micron wavelength. Therefore, the Landsat 8 satellite
8
211
is more advantageous than the previous series of satellites in SST retrieval (Wang et al., 2019; Fu et
212
al., 2018).
213
3.3. Results
214
In this study, the Landsat 8 remote sensing images of Zhoushan Sea on March 12, 2015, August 3,
215
2015, and April 2, 2017, were selected for inversion of SST. According to the transit time of the
216
satellite, the atmospheric wvc corresponding to the three remote sensing images was estimated to be
217
4.171 g/cm2 (Figure 7 (a1)), 2.154 g/cm2 (Figure 7 (a2)), and 1.774 g/cm2 (Figure 7 (a3)).
218
Generally, the Landsat 8 remote sensing images acquired by users are gray values without physical
219
meaning. Thus, it is necessary to perform radiometric calibration, which converts gray value into
220
radiance with physical significance, on the images according to the parameters of the file. The
221
brightness temperature is calculated based on the radiance of the thermal infrared bands. The SST is
222
obtained by the new SST retrieval model based on the wvc. The results of the inversion are shown in
223
Fig. 7. On March 12, 2015, the inversion results showed that the lowest SST was 281.64 K, the
224
highest SST was 296.81 K, the average SST was 285.43 K, and the SST was mainly between 280 K
225
and 290 K. On August 3, 2015, the inversion results showed the maximum temperature difference,
226
with the lowest SST being 296.75 K, the highest SST being 316.66 K, and the average SST being
227
302.55 K. The SST was mainly between 298 K and 305 K. The lowest SST of the inversion results on
228
April 2, 2017, was 285.11 K, the highest SST was 300.01 K, the average SST was 287.91 K, and the
229
SST was concentrated between 285 K and 290 K.
230 231
(a1)
(b1)
(c1)
232 233
(a2)
(b2)
(c2)
9
234 235
(a3)
(b3)
(c3)
236
Fig. 7. The Landsat8 images of the Zhoushan sea area, China: (a) true color images, (b) thermal
237
infrared images, and (c) SST inversion results.
238
3.4. Accuracy evaluation
239
The observation data are usually used for accuracy evaluation. However, in the absence of
240
observation data, the accuracy of the derived results is evaluated from the Advanced Very
241
High-Resolution Radiometer (AVHRR) SST products (Ai et al., 2019; Brewin et al., 2017; Carroll et
242
al., 2012; Tyagi et al., 2017) in order to verify the validity and applicability of the SST retrieval model
243
in coastal waters. AVHRR SST products were used to analyze the accuracy of the derived results.
244
Although AVHRR SST products cannot fully represent SST, they can be used as an indirect indicator
245
for the accuracy of the inversion results.
246
AVHRR is a scanning radiometer with five spectral channels, which was launched and is
247
maintained by the National Oceanic and Atmospheric Administration (NOAA). The AVHRR SST
248
dataset is obtained by the NOAA National Centers for Environmental Information. The SST
249
algorithm is based on the NOAA/National Environmental Satellite Data and Information Service
250
nonlinear SST operational algorithm (NLSST). This dataset provides twice-daily (day and night)
251
global SST Level 3 data with a 0.0417º × 0.0417º rectangular grid. It provides a high-quality Climate
252
Data Record (CDR) of SST. It is available to the public for a wide variety of uses including scientific
253
research and analysis. The spatial resolution of AVHRR SST products is different from that of
254
Landsat 8 thermal infrared data. According to the longitude and latitude of AVHRR SST products,
255
the corresponding pixel is found in Landsat 8 inversion results. And it is regarded as the center pixel.
256
The SST of the center pixel is averaged by the 133 × 133 window for the Landsat 8 inversion results
257
(Nguyen and Katsuaki, 2018). After expanding with a 133 * 133 window, the spatial range of Landsat
258
8 inversion results is roughly the same as AVHRR SST products. Then, it is compared to the SST of
259
the corresponding pixel to the AVHRR SST product.
260
In this study, the average bias, RMSE, and Pearson correlation coefficient were used to evaluate the
261
inversion accuracy of the SST (Meng et al., 2018). Bias is the inversion SST minus the AVHRR SST
262
product. Pearson’s correlation coefficient, usually denoted as R, was used to measure the linear
263
relationship between two variables,
10
∑ ( SST − SST )(T N
R=
264
i
Si
− TS
i=1
∑ ( SST − SST ) * ∑ (T N
i =1
2
i
N
i =1
Si
)
− TS
)
(6) 2
265
where SSTi is the inversion SST, SST is the average of inversion SST, TSi is the initial SST, TS is
266
the average of the initial SST, and N is the number of SSTs. Figure 8 shows the comparison between
267
the AVHRR SST and the inversion SST. The Pearson correlation coefficients of the three cases were
268
0.8211, 0.8842, and 0.8408. The larger the R, the better the correlation between the inversion SST and
269
AVHRR SST. Overall, the biases were within 1 K, and the RMSEs are within 2 K. The minimum bias
270
of the inversion result on March 12, 2015, was 0.0019 K, the maximum bias was 4.9930 K, the
271
average bias was 0.6666 K, and the RMSE was 1.8252 K. On August 3, 2015, the derived result had a
272
minimum bias of 0.0002 K, maximum bias of -4.8765 K, average bias of 0.0037 K, and RMSE of
273
1.5979 K. On April 2, 2017, the minimum bias of the inversion result was 0.0062 K, the maximum
274
bias was 4.8806 K, the average bias was 0.7943 K, and the RMSE was 1.7643 K. The error is within
275
the acceptable range. The algorithm can be used to retrieve the SST.
276 277 278
Fig. 8. Scatterplots of the AVHRR SST and the inversion SST ( SSTi ). 4. Discussion
279
Based on the variation of atmospheric wvc, the SST inversion model was constructed. The
280
influence of atmospheric wvc on SST inversion was revealed. Atmospheric wvc is an important input
281
parameter for SST inversion. The accuracy of the model depends on the accuracy of wvc. Inaccurate
282
wvc will reduce the accuracy of SST inversion model. However, the wvc used in this paper is derived
283
from NCEP atmospheric profiles data, which may have errors. In addition, the spatial resolution of
284
NCEP atmospheric profiles data is low. There is only one point of atmospheric profiles data in the
285
entire Zhoushan sea area, which cannot fully represent the atmospheric conditions in the Zhoushan
286
sea area. The low spatial resolution of the data may affect the accuracy of SST inversion model.
287
Atmospheric profile data can be obtained from more sources to solve the problem of accuracy of
288
wvc and improve the accuracy of inversion. We also can obtain wvc by acquiring mature water vapor
289
products or improving existing water vapor algorithms. Using the atmospheric profiles data from
290
multiple sources to build the model to improve the inversion accuracy. In addition, it is likely that the
11
291
low spatial resolution of the atmospheric profiles data can be solved by data interpolation. We can
292
interpolate the original atmospheric profiles data to obtain higher resolution data to improve the
293
inversion accuracy.
294
5. Conclusions
295
SST is a basic and important parameter for understanding and studying the ocean. It can be used as
296
a reference for oceanographic research such as water mass, circulation, ocean front, seawater mixing
297
and upwelling. The change of SST not only determines the living environment of marine organisms,
298
but also affects human life, production, economic and social development. This study proposed a new
299
split-window algorithm that takes into account the variation of atmospheric wvc based on Landsat 8
300
TIRS. The SST inversion and verification were carried out with the Zhoushan sea area as the research
301
area. First, the SST retrieval model was established by wvc based on atmospheric correction with
302
MODTRAN. Then, the accuracy of the algorithm was evaluated using simulation data. The RMSEs
303
were within 0.5 K, indicating that the error of the algorithm was small. Landsat 8 remote sensing
304
images were used to retrieve SST. Finally, AVHRR SST products were used to evaluate the inverted
305
SST. The biases were within 1 K, and the RMSEs are within 2 K. The error of the algorithm was
306
within an acceptable range. It was shown that the algorithm can be used to retrieve SST. The study is
307
not only of great scientific value but also of great significance to human activities and the social
308
economy.
309
Although some achievements have been made, the following deficiencies still exist in this study.
310
First, in this study, we did not find the observation data of the Zhoushan sea area for model validation.
311
The results of the accuracy evaluation were not accurate enough to comprehensively analyze the
312
accuracy of the inversion results. Therefore, the observation data and more satellite SST products can
313
be selected to verify the accuracy of the algorithm in the follow-up research works of this study. In
314
addition, combined with the effect of suspended sediment on emissivity, the inversion of the offshore
315
SST requires further study.
316
Acknowledgement
317
We would like to thank the anonymous reviewers for their constructive comments and suggestions.
318
We thank LetPub (www.letpub.com) for its linguistic assistance during the preparation of this
319 320
manuscript. This research was funded by National Natural Science Foundation of China (41701447) and the
321
Training Program of Excellent Master Thesis of Zhejiang Ocean University.
322
Data Availability Statement
323
The input data for this research are all publicly available. The Landsat8 data can be obtained from
324
the website of United States Geological Survey (https://earthexplorer.usgs.gov/), the emissivity data
325
of seawater samples can be obtained from the website of MODIS (Moderate Resolution Imaging
12
326
Spectrometer) UCSB Emissivity Library (https://icess.eri.ucsb.edu/modis/EMIS/html/em.html), the
327
AVHRR (Advanced Very High Resolution Radiometer) data can be obtained from the website of
328
gridded
329
(https://coastwatch.pfeg.noaa.gov/erddap/griddap/index.html?page=1&itemsPerPage=1000),
330
atmospheric profile data for atmospheric modeling can be obtained from the website of NOAA
331
ESRL
332
(https://www.esrl.noaa.gov/psd/data/gridded/data.ncep.reanalysis.pressure.html). The data explicitly
333
generated in this research (atmospheric conditions data simulated by using MODTRAN based on
334
atmospheric profile data, sea surface temperature retrieved from Landsat8 TIRS data) will be
335
available on Mendeley Data (http://data.mendeley.com).
336
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(1) A split-window method is proposed for retrieving SST from Landsat 8 TIRS data based on the variation of atmospheric water vapor content (wvc). (2) The coefficients of model with atmospheric water vapor content (wvc) are fitted. (3) The root mean square errors (RMSEs) of the model are within 0.5 K, indicating that the accuracy of the model is good in theory. (4) Compared with the AVHRR SST products, the bias and RMSE of the retrieving result in the Zhoushan sea area, China are within 1 K and 2 K, respectively. (5) Accurate SST with the high spatial resolution is successfully obtained by using the proposed method in offshore waters.
The authors declare no conflict of interest.