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Abstract Resumen
Since there are no mathematical models that can calculate the Laguna
Ante la inexistencia de modelos matemáticos que calculan el
de Bustillos’ water storage levels, water balance requires this data to almacenamiento de agua de Laguna de Bustillos, el balance hídrico
understand the connectivity between this water body and the
requiere este dato para comprender la conectividad entre este cuerpo
Cuauhtemoc aquifer. This article presents a new three-dimensional de agua y el acuífero Cuauhtémoc. Este artículo presenta una nueva
reconstruction technique based on a time series of multispectral
técnica de reconstrucción tridimensional basada en series de tiempo
remote sensing images, bathymetry, a topographic survey with high
de imágenes de sensores remotos multiespectrales, batimetría,
precision GPS, and regional contours. With the images of Landsat
levantamiento topográfico con GPS de alta precisión y curvas de nivel
ETM+/OLI and Sentinel 2A from 2012 to 2013, 2016, and 2017, the regionales. Con las imágenes de Landsat ETM +/OLI y Sentinel 2A de
contours of the water surface were extracted using the MNDWI and 2012 a 2013, 2016 y 2017, se extrajeron los contornos de la superficie
were associated with an elevation received from GPS. An Autonomous del agua utilizando el MNDWI y se asociaron con una elevación obtenida
Surface Vehicle was also used to obtain the bathymetry of the lake. A a través del GPS. Se utilizó un Vehículo Autónomo de Superficie para
topographic survey was carried out using GPS in populated areas, and obtener la batimetría del lago. Se realizó un levantamiento topográfico
the contour lines extracted from the INEGI Continuous Elevations
usando GPS en áreas pobladas y se usaron las curvas de nivel extraídas
Model 3.0. A DEM was constructed using ArcGIS 10.5.1, and surfaces del Modelo 3.0 de Elevaciones Continuas del INEGI. Se construun
and volumes were calculated at different elevations and compared with MDE, las superficies y volúmenes se calcularon a diferentes elevaciones
16 Landsat TM/ETM+/OLI multispectral images from 1999 to 2018.
y se compararon con 16 imágenes multiespectrales Landsat TM/
The results showed that the mean of the average intersection area
ETM+/OLI de 1999 al 2018. Los resultados mostraron que la media del
between the test images and the area extracted from the 3D model is área promedio de intersección del modelo y las imágenes tiene una
above 90.9% according to the confidence interval, kappa overall
eficiencia superior al 90,9% de acuerdo con el IC, precisión general
accuracy 95.299.7%, and a coefficient 89.999.3%. This model
kappa 95.2-99.7% y un coeficiente 89.9-99.3%. Este modelo demostró
proved to be very accurate on a regional scale when the water level ser muy preciso en escala regional, sobre todo cuando el espejo del
exceeded 1971.32 meters above mean sea level and useful to evaluate agua supera los 1971.32 metros sobre el nivel medio del mar, y a la vez
and administer water resources. útil para la evaluación y administración de los recursos hídricos.
Palabras clave:
DEM, storage, lake, MNDWI, RTK, sound.
Keywords:
MDE, almacenamiento, lago, MNDWI, RTK, sonar.
Topobathymetric 3D model reconstruction
of shallow water bodies through remote
sensing, GPS, and bathymetry
Reconstrucción de modelo 3D topobatimétrico de cuerpos de agua
someros mediante teledetección, GPS y batimetría
H
UGO
L
UIS
R
OJAS
-V
ILLALOBOS
1,6
, L
UIS
C
ARLOS
A
LATORRE
-C
EJUDO
2
, B
LAIR
S
TRINGAM
3
,
ZOHRAB SAMANI4 AND CHRISTOPHER BROWN5
Recibido: Enero 6, 2018 Aceptado: Noviembre 11, 2018
_________________________________
1 NEW MEXICO STATE UNIVERSITY. Water Science and Management Program. Department of Geography, 1525 Stewart St. Breland Hall, Las
Cruces, NM. USA. 88003. Tel. (+1 575) 646-5755.
2 UNIVERSIDAD AUTÓNOMA DE CIUDAD JUÁREZ, Sede Cuauhtémoc. Programa de Geoinformática, Departamento de Arquitectura. Carretera
Anáhuac S/N, Cd. Cuauhtemoc, Chih, México. 31600. (+52 625) 128-1700.
3 NEW MEXICO STATE UNIVERSITY. Plant and Environmental Sciences. College of Agriculture, Consumer and Environmental Sciences, 945
College Drive. Skeen Hall, Las Cruces, NM. USA. 88003. (+1 575) 646-7665
4 NEW MEXICO STATE UNIVERSITY. Department of Civil Engineering, 3035 S. Espina St. Hernandez Hall, Las Cruces, NM. USA. 88003.
(+1 575) 646-2904
5 NEW MEXICO STATE UNIVERSITY. Department of Geography, 1525 Stewart St. Breland Hall, Las Cruces, NM. USA. 88003. Tel (+1 575)
646-1892.
6 Dirección electrónica del autor de correspondencia: hlrojas@nmsu.edu
Ingeniería y Tecnología Artículo arbitrado
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Vol. XII, Núm. 1 Enero-Abril 2018
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
T
Introduction
he Laguna de Bustillos is in a region that has a high demand for groundwater for the
agricultural industry, making the Cuauhtemoc aquifer the largest over-exploited aquifer
in northwest Mexico (Comisión Nacional del Agua, 2016). It is necessary to provide updated
data to the water balance of the basin to improve water management in the region.
Because there are no known mathematical
models that calculate water storage, it is imperative
to develop a new technique or method that allows us
to estimate the water volume contained in water
bodies. The calculation of water storage of shallow
water bodies requires the construction of 3D models
of the terrain including the surrounding areas.
Integrating techniques based on sound, spectral
analysis of satellite imagery, and GPS allow
researchers to increase the accuracy of the existing
3D models and expand them from the reservoir
representation to a topobathymetric integrated model.
Topobathymetry is a geospatial concept that
integrates bathymetric and topographic data from
different spatial scales, time, and sensors. The terrain
model is applied to monitor coastal erosion, sea level
rise, flood impact reduction programs, and coral
barrier studies (Gesch et al., 2016). Digital terrain
models, topography, bathymetry, and the use of water
body contours are essential sources for integrating
this model. Some research tried to get 3D models, but
only one or two data sources were used in comparison
with those applied in this research. The delimitation
of water bodies is an indirect way of getting contour
lines through differentiating the spectral response
between the green band (G) and the bands near infra-
red (NIR) or the infra-red short-wave band (SWIR).
The Normalized Difference Water Index (NDWI)
(McFeeters, 1996) and the Modification of Normalized
Difference Water Index (MNDWI) (Xu, 2006) have
been used to monitor (Lu et al., 2013) changes in the
extent of the lakes (Ma et al., 2007), and the location
of water bodies (Rana and Neeru, 2017). Sonar is a
technique that uses sound waves to calculate water
depth (Knott and Hersey, 1957) and has advantages
such as high accuracy 0.1 m), low cost, and the
device can be mounted on any boat. Several types of
research have used sound for mapping water bodies
(McPherson et al., 2011; Popielarczyk and Templin,
2014; Giordano et al., 2015). Leon and Cohen (2012)
modeled the volume of Lake Eyre in Australia using
bathymetry and remote sensing. The authors used
surveys realized in 1974 and 1976 with the precision
of ± 0.3 m in the vertical component and up to ± 500
m in the horizontal component, which proved to be a
very limited and inaccurate method.
Water storage has two components: groundwater
and surface water (lakes, ponds, or reservoirs) (Brooks
et al., 2012). Some variations in water storage in the
reservoirs are due to an underground hydraulic
connection between aquifers and water bodies (Isiorho
et al., 1996; Winter, 1999). These variations in the
volume of water can be so drastic that large reservoirs
dry up in a short time like Laguna de Bustillos had in
years 2002 to 2006 and 2013 (NASA, 2017). Although
there is a geohydrological study that supports recharge
deficit in the aquifer, there is no information about the
storage capacity of Laguna de Bustillos. The lack of
information encourages the main objective of this
research to generate a new technique to generate a 3D
topobathymetric model that contributes to the
generation of updated data, which allows the deduction
of variables, such as underground infiltration from the
catchment area of Laguna de Bustillos. Despite these
models of volumetric estimation of water bodies, the
combination of more than two different topobathy-
metric measurement techniques had not been explored.
This document proposes a unpublish new method
integrating three methodologies to generate a more
robust and accurate three-dimensional model.
Materials and methods
This study was conducted between 2016 and the
first semester of 2018 in the Spatial Applications and
Research Center at the New Mexico State University.
The study area of Laguna de Bustillos is in the quadrant
between the coordinates 28° 38' 51'’ N 228' 27'’ N
and 106° 57' 3'’ W 10 38' 50' W in the municipality
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Figure 1. The study area of Laguna de Bustillos, Chihuahua. Source: LandsatLook Viewer (USGS, 2017a).
of Cuauhtemoc, in the state of Chihuahua (Figure 1).
This regions climate is warm and semi-arid since it is
in a transition zone between the semi-humid climate
of the mountains and the Chihuahua desert (Kottek et
al., 2006). The average annual temperature ranges
from 6.9 to 21°C, with an average annual rainfall of
about 528 mm per year (Servicio Meteorológico
Nacional, 2017).
The authors designed a new four-stage method
to develop a 3-D topobathymetric model for the
purpose of determining water storage: i) extract
contour lines through a time series of remote sensing;
ii) determine bathymetry; iii) perform a topographic
survey (GPS-RTK); and iv) extract contours from the
regional terrain digital model. Also, it was included a
regression analysis in determining the two equations
that provide the volume and surface area using water
height. The flowchart below (Figure 2) shows the
modeling process.
Bathymetry
The New Mexico Water Resources Research
Institute (WRRI) funded a project to build an
Autonomous Surface Vehicle (ASV) to generate
bathymetric data for shallow water bodies. A PVC
center frame was attached to a two-hulled catamaran
boat, propelled by two motors, and equipped with a
GPS on the top to receive signals via satellite to provide
the direction and location. An Ardupilot® system
automated the catamaran navigation through an
Arduino® MEGA 2560 board to receive the GPS signal
while the sonar data bus decoded and recorded the
information on an SD card. Subsequently, the recorded
points were downloaded to a computer for
processing. The transducer was a Garmin® Intelliducer
Thru-Hull NMEA-0183, which does not require the
previous calibration and can measure from 60 cm to
200 m with a 0.1 m accuracy (Rojas-Villalobos, 2016).
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Figure 2. Schematic of the workflow to generate the 3D model.
Figure 3. Components to calculate the height of the lake bottom above sea level.
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
To construct a 3D model of the region including
the bottom of the lake, the bathymetry data (depth)
was transformed into topographic data (height).
Figure 3 shows the schematic of the surveying
process to transform to the correct topographic
points.
The following equation ( 1 ) was developed to
calculate the altitude above sea level for each
bathymetric point:
(1)
Here, ABP is the height of the bathymetric point,
ASNM is the altitude above sea level of the reference
level, PS is the depth of the sonar, and PR is the
recorded depth. The bathymetry consisted of 5
trajectories, and the data were adjusted through the
above equation using the reference levels of the
survey days. A GPS-RTK was used to establish the
fixed reference point corresponding to the height of
the lake contour and was linked to the bathymetry
obtained that day.
Contour extraction from remote sensors
Since the spatial resolution of remote sensing is
the most important factor for delineating the
contours of water bodies, Landsat ETM +, Landsat
OLI (Operational Land and Imager), and Sentinel 2A
(Table 1) were chosen to build the MNDWI.
These images are available for free on the
LandsatLook Viewer websites of the United States
Geological Survey (USGS, 2017a) and the Copernicus
Open Access Hub of the European Space Agency (ESA,
2017). Seven images were selected with the lowest
possible cloudiness over the study area during the time
the lake had gradually dried (March 2012 August
2013). Also, six recent images were downloaded to
establish the maximum lagoon extent and baseline
curves for the bathymetry data (June 2016
September 2017). Using the Semiautomatic
Classification extension (Congedo, 2013) in QGIS®,
atmospheric correction was applied to the images
using the method of Subtraction of Dark Objects 1
(Chavez, 1996). Then, a fusion of images was
performed with the panchromatic band (ETM + and
OLI) using the Brovey transformation (Johnson et
al., 2012) to increase the spatial resolution to 15 m
before the MNDWI construction.
The Normalized Difference Water Index (NDWI)
was created to identify Landsat water bodies. The
high relative reflectance of green (G) in the electro-
magnetic spectrum contrasts with the high absorption
of the NIR in clear water (McFeeters, 1996). Excessive
suspended matter in the water increases reflectance
measurements in the NIR band (Ruddick et al., 2006),
thus dramatically reducing the difference between
the G-NIR bands, which makes it difficult to
distinguish between water and non-water surfaces.
Table 1. Collection of remote sensing data used in this article.
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Therefore, the NDWI method is not fit for Laguna de
Bustillos due to the turbidity of water. The MNDWI
suppresses this problem by replacing the NIR band
with an infrared shortwave band (SWIR) because the
water absorbs energy and the reflectance is low. The
equation that determines the MNDWI (Xu, 2006) is:
(2)
Where G is the green band of the electromagnetic
spectrum and SWIR is the short-wave band of the
infrared spectrum. The possible MNDWI values are
from -1 to 1.
In ArcGIS®, the raster calculator was used to
apply the MNDWI equation to Landsat and Sentinel
images. According to the MNDWI method, positive
values represent water and negative values the
surface without water. Therefore, the resulting raster
was reclassified by assigning 1 to those values greater
than 0 and 0 to values less than or equal to 0. From
the reclassified images, the contours were extracted
and examined through visual interpretation. This
procedure ensures that the extracted contours
correspond to the edge of the lake using false infrared
color composite images and avoids errors due to the
influence of the vegetation.
A failure of the SLC (Scan Line Corrector)
introduced strips with missing data in the Landsat
ETM+ images captured on May 31st, 2003 (USGS,
2017b). Due to this error in the sensor, only segments
were vectorized corresponding to the edge of the
water surface.
An orthometric height was assigned to the
contours using the closest ABP to the contour line (<
0.5 meters). When there were no bathymetry points
near the line, points were selected in a buffer of 1 to 2
m on each side of each contour. The contour took the
mean height following the Classic Central Limit
Theorem (Erdös and nyi, 1959; Dowdy et al., 2011).
According to this theorem, when the sample size
increases, the average sample will approximate a
normal distribution. This procedure reduces the
uncertainty and variability of bathymetric data due to
boat sway and sonar accuracy (Krause and Menard,
1965; Eltert and Molyneux, 1972; Schmitt et al., 2008).
Topography
The GPS points were measured using two
SOKKIA GRX2 GNSS devices with a horizontal
accuracy of 5 mm and 10 mm on the vertical axis. A
GPS was established as base at the coordinate 28° 27'
25.1532" N and 106° 47' 24.9432" O at the height of
2069.08 on the WGS ellipsoid of 1984. 1006
topographic points were collected and transformed
to the Mexican Gravimetric Geoid 2010 (GGM10) to
generate altitude above the mean sea level (INEGI,
2015).
Digital elevation model
A contour was extracted at every meter from the
Mexican Elevation Continuation 3.0 (CEM 3.0) of the
National Institute of Statistics and Geography (INEGI,
2016). On September 5th, 2017, the water level of
the lake was 1975.56 m above sea level (masl). For
this reason, contour lines below 1976 m were
eliminated from the regional DEM.
Topobathymetric 3D model and volume estimation
An MDE with a spatial resolution of 2 m was
created using the four sources of elevation data using
the Topo-to-Raster tool contained in the 3D analysis
module of ArcGIS. This tool allows the creation of
hydrologically correct lifting meshes based on the
ANUDEM program (Hutchinson et al., 2011). Since
the triangulated irregular network (TIN) generates
more accurate volumetric calculations (Mi et al., 2007;
Hanjianga et al., 2008), the DEM was converted into
a TIN. The volume and water surface were calculated
from 1970.50 m to 1978.9 masl every 1 mm using
the ArcGIS Polygon Volume tool.
Statistical Evaluation
Since there is no previous model to evaluate the
lake storage, 16 areas of water coverage of different
scenes were extracted through remote sensing (RS)
when the lake was drying (real area) (Table 2).
The area of each scene was used to extract the
corresponding contour line from the 3D model and
generate the area. Using ArcGIS, the intersection of
the two layers was the area of a coincidence that was
statistically evaluated (Figure 4).
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Table 2. List of multispectral images used to compare 3D model
contours.
Figure 4. Demonstration of matching areas between water
surface extracted from a multispectral satellite image and the
3D model at the same reference level.
Some Landsat ETM + and OLI images were
replaced with recent Sentinel 2 images (early 2018)
to distribute the extracted contours along the height
through the 3D model (Table 3). This procedure is
used to evaluate the model accuracy (reality vs. model).
Table 3. List of multispectral images used to compare areas
between reality and 3D model. Added images are identified with *.
Because of the surface area changes according to
the elevation of the water surface, it is not possible to
evaluate the efficiency of the model directly. For this
reason, the relationship between the coincidence surface
and the reference area of the satellite image were used.
The maximum possible relation between both
areas is 100% because the level curves obtained from
the 3D model are directly related to the waterbody
contours. The water/non-water coverage maps of
the model and the satellite images of each year (Table
3) were analyzed using the Kappa statistic (K-hat)
through QGIS (QGIS, 2018) and Semi-Automated
Classification Plugin (Congedo, 2013). The Kappa
coefficient and overall accuracy allows us to know
the degree of agreement between the 3D model and
the water body surface (Card, 1982; Jensen, 2007;
Congalton and Green, 2008; Lillesand et al., 2014) .
Also, the t-statistical distribution was applied to find
the lower limit of the 95% Confidence Interval and
estimated the range of acceptable match surface
values (from Table 2) according to the sample mean
(Dowdy et al., 2011) ( 3 ).
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
(3)
Where is the mean of the sample, is the level
of significance, v is the degrees of freedom (n -1), s is
the standard deviation, and n is the sample size.
Finally, two equations were generated repre-
senting the area of the water surface and the volume
contained in the lake according to the elevation of
the water surface.
Results and discussion
Figure 5 shows the sources of data used for the
reconstruction of the topobathymetric model: 13
contours from remote sensors, 29,715 bathymetry
points, 1,006 GPS points, and INEGI contours.
Figure 5. Map showing bathymetry, GPS points, derived curves
from multispectral RS, and regional contours (INEGI).
Figure 6. Triangulated Irregular Network is representing the topobathymetric 3D model of Laguna de Bustillos.
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
As a result of the reconstruction data process,
Figures 6 and 7 show the 3D topobathymetric model
and a 3D perspective of the Laguna de Bustillos. The
results show that the deepest point of the lake is
at 1970.215 masl, the maximum depth is 3.785 m
when the water level reaches the 1974 masl, the
water storage is 324.4 Mm3, and the average depth
is 1.37 m.
Figure 7. 3D perspective of Laguna de Bustillos (5 times height
exaggeration for better visualization).
Since the Kappa statistic shows the difference
between classified values of the satellite image
(reference data) and the surface of water body
generated by the 3D model, the coincidence is
expected to be high. Typically, Kappa values greater
than 0.80 represent a strong match between the
compared data. The result of the comparison shows
an overall accuracy higher than 95.21% and the K-
hat coefficients above 0.899. Table 4 shows the
increase of the values of overall accuracy and the
Kappa coefficient when the water level is higher.
It is observed that the values of elevation that
are between 1971.168 and 1971.284 have a value of
K-hat less than 0.9289 and are associated with water
coverage less than 80 km2. When the water level rises
above 1971.284 m, the Kappa indicator increases its
value above 0.93, reaching levels of 0.99. Also, low K-
hat values (0.8993 0.9289) are associated with low
depth averages (<0.41 m) in contrast to those K-hat
values above 0.96 that are in depth averages greater
than 0.71 m.
Table 4. Kappa coefficient values and overall accuracy between imagery (reality) and simulation (3d model).
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Conversely, with a confidence level of 95%, the
mean of the percentage of matching areas between
the satellite images and the 3D model is greater than
90.9% (Table 5).
Table 5. Confidence Interval analysis for the percentage of the
matching area between the three-dimensional model and
the sample images.
Below the contour 1971.325 m, four of the six
comparisons are below the lower limit of the
confidence interval (Figure 8).
Figure 8. Graph showing the behavior of the intersection
percentage between the surfaces of the 3D model and the
areas of RS images along elevation.
The mean area intersected below the reference level
is only 88.91%, while in the upper range, it is 97.01%.
Two equations were generated that estimated the
area of water coverage according to the depth of the
lake. The first equation calculated the volume below
the 1971.325 masl and the second equation calculated
the remaining volume above it. Similarly, two other
equations were generated estimating the amount of
water in the lake. The determination coefficients (R2)
for the estimated equations are greater than 0.9882;
this indicates that the equations obtained are suitable
for the topobathymetric model within the extent limits
of the lake (Figure 9).
Figure 9. Graphs of the surface and volume equations adjusted
to the 3D model.
Conclusions
Four different techniques, such as bathymetry,
GPS-RTK points, and contour lines extracted from the
remote sensors, were decisive in creating this new
three-dimensional modeling methodology for water
bodies. Its efficiency is demonstrated after the statistical
analysis applied. According to the results obtained in
the Kappa analysis and the confidence interval, the 3D
model is a robust and precise model (Kappa>0.80).
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
Three processes were important in the cons-
truction of the model:
· The use of high precision GPS helped in fixing
the reference height points of the contours of the most
recent satellite images (2015 2018) with great
precision and accuracy.
· The bathymetric points linked to the current
height of the water level of the lake were instrumental
in establishing the height above sea level at the
bottom of the lagoon.
· The related height between the bathymetric
points and the levels closest to the bottom of the lake
was extracted from the satellite images (1999 2002).
Additionally, it was observed that the segments
of the contours extracted from the Landsat ETM+
images with an error in the SLC (USGS, 2017b)
influenced the relative low efficiency (0.8993 < Kappa
<0.9079) of the model below 1971.325 masl. On the
other hand, effectiveness in the top height ranges
from 1971.5 to 1974 masl was as a result of the spatial
resolution of the satellite images of Landsat OLI (15
m panchromatic) and Sentinel 2 (10 m) (Figure 10).
Although this 3D hydrological model is very
robust to be used in the administration of water in
the basin, special care must be taken in forecasting
floods in rural-urban areas. The model simulates much
of the flooded areas of Mennonite farmers, but the
3D model should not be used to prevent flood risks
due to the topographic complexity with dams and
ditches.
In future work, researchers should continue the
bathymetric survey with greater data density using a
sonar with increased accuracy to further the model’s
efficiency. The acquisition of more bathymetric data
will allow replacing contours extracted from the oldest
images such as Landsat ET and ETM +. Additionally,
the photogrammetric triangulation could be of great
benefit in urban and agricultural zones to delineate
more accurate topography. This development is the
first step to estimate the volume of water in the
Laguna de Bustillos as this work produces estimates
that approximate the actual values and such research
is relevant to water management in the region.
Figure 10. RS time series contours. The dark contour delimits the outer areas with greater 3D model performance and the internal
area with less accuracy.
HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
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Vol. XII, Núm. 1 Enero-Abril 2018
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HUGO LUIS ROJAS-VILLALOBOS, LUIS CARLOS ALATORRE-CEJUDO, BLAIR STRINGAM, ZOHRAB SAMANI, CHRISTOPHER BROWN: Topobathymetric 3D
model reconstruction of shallow water bodies through remote sensing, GPS, and bathymetry
54
Vol. XII, Núm. 1 Enero-Abril 2018
Este artículo es citado así:
Rojas-Villalobos, H. L., L. C. Alatorre-Cejudo, B. Stringam, Z. Samani, C. Brown. 2018. Topobathymetric 3D model reconstruction of
shallow water bodies through remote sensing, GPS, and bathymetry. TECNOCIENCIA Chihuahua 12(1):42-54.
DOI: https://doi.org/10.54167/tch.v12i1.129