A Survey of Target Detection and Recognition Methods in Underwater Turbid Areas PDF

Summary

This research article surveys methods for detecting and recognizing targets in underwater turbid areas. It analyzes image degradation caused by turbidity and various target recognition techniques. The review covers deep learning, image restoration, and polarization-based imaging for improved underwater image clarity.

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applied
sciences
Review
A Survey of Target Detection and Recognition Methods in
Underwater Turbid Areas
Xin Yuan , Linxu Guo , Citong Luo, Xiaoteng Zhou and Changli Yu *

School of Ocean Engineering, Harbin Institute of Technology, Weihai 264209, China; [email protected] (X.Y.);
[email protected] (L.G.); [email protected] (C.L.); [email protected] (X.Z.)
* Correspondence: [email protected]; Tel.: +86-138-6310-6670

Abstract: Based on analysis of state-of-the-art research investigating target detection and recognition
in turbid waters, and aiming to solve the problems encountered during target detection and the
unique influences of turbidity areas, in this review, the main problem is divided into two areas: image
degradation caused by the unique conditions of turbid water, and target recognition. Existing target
recognition methods are divided into three modules: target detection based on deep learning methods,
underwater image restoration and enhancement approaches, and underwater image processing
methods based on polarization imaging technology and scattering. The relevant research results
are analyzed in detail, and methods regarding image processing, target detection, and recognition
in turbid water, and relevant datasets are summarized. The main scenarios in which underwater
target detection and recognition technology are applied are listed, and the key problems that exist
in the current technology are identified. Solutions and development directions are discussed. This
work provides a reference for engineering tasks in underwater turbid areas and an outlook on the
development of underwater intelligent sensing technology in the future.

Keywords: turbid water; underwater operation; image processing; target detection and recognition;
intelligent sensing

Citation: Yuan, X.; Guo, L.; Luo, C.;
Zhou, X.; Yu, C. A Survey of Target
Detection and Recognition Methods
in Underwater Turbid Areas. Appl.
1. Introduction
Sci. 2022, 12, 4898. https://doi.org/ Nowadays, underwater intelligent sensing technology is widely used in seabed re-
10.3390/app12104898 source exploration, fishery monitoring, underwater archaeology, underwater warfare,
pipeline maintenance, and other fields. It also benefits the economy, military, culture, and
Academic Editor: Andrea Prati
other aspects. The future in this field is immeasurable, and the demand for large-scale
Received: 12 April 2022 and long-term monitoring of the internal water body is increasing. Due to the unique
Accepted: 10 May 2022 underwater operation environment, it has significant benefits but is also accompanied
Published: 12 May 2022 by some challenges. Turbidity is often encountered in underwater development as the
Publisher’s Note: MDPI stays neutral
required targets always exist in complex water environments, and water contains a variety
with regard to jurisdictional claims in of organic and inorganic suspended particles. Thus, the direction of light transmission
published maps and institutional affil- is changed by the scattering or absorption of water and particles, which results in sig-
iations. nificant interference in the reflected light received by the imaging system, resulting in a
significant reduction in the clarity of underwater images. Compared with turbid water,
intuitively, the quality and visibility of clear water is good. For example, in a small clean
pond, the target characteristics obtained via visual sensing are easily recognized due to
Copyright: © 2022 by the authors. the small amount of biological impurities and sediment in the water. Shallow water has
Licensee MDPI, Basel, Switzerland. the advantage of good light transmittance. However, target detection in turbid water is
This article is an open access article a significantly challenging task. Turbid water can be divided into shallow turbid water
distributed under the terms and
and two kinds of deep turbid water. Shallow turbid water, such as turbid fish farms, has
conditions of the Creative Commons
a significant impact on the transmission of light information due to the high density of
Attribution (CC BY) license (https://
aquatic organisms and suspended matters, such as fishes and sediments, in the water.
creativecommons.org/licenses/by/
This leads to significant image distortion, such as blurred target features, severe distortion,
4.0/).

Appl. Sci. 2022, 12, 4898. https://doi.org/10.3390/app12104898 https://www.mdpi.com/journal/applsci
Appl. Sci. 2022, 12, 4898 2 of 21

and color changes, which pose a significant challenge regarding visual technology and
target recognition. Deep turbid water, such as some deep water areas, is challenged by
the same problems as shallow turbid water and has low light conditions, resulting in
the instrument receiving limited effective target light information. Due to these factors,
traditional target detection and recognition methods cannot meet instruments’ technical
requirements. Therefore, the investigation of object detection and recognition in turbid
areas is necessary. Currently, research on underwater vision is mainly focusing on scenarios
with good water conditions, such as experimental pools, lakes, inland rivers, etc. Due
to the complexity of underwater environments, significant differences between various
types of water exist. As large-scale engineering operations are often carried out at sea,
most research methods do not contain adequate robustness to overcome the significant
difficulties encountered in practical engineering applications. Focusing on the common
applications scenes of turbid areas, this paper systematically collates the relevant research
methods and the latest achievements, analyzes key technical problems, and summarizes
future development directions.
Since target detection in turbid water is more unique than that in clean water, this
paper presents three perspectives: the first perspective is target feature extraction and
detection based on deep learning methods, the second perspective is underwater image
restoration and enhancement, and the last perspective is image processing based on the po-
larization imaging approach. The contents of this paper are summarized as follows: (1) the
application of ConvNet and a typical network, such as Faster RCNN and YOLOv3 ,
and a comparison of the Canny edge detection algorithm and a track prediction algo-
rithm combined with practical engineering are introduced, and the disadvantages of deep
learning methods and their corresponding solutions are analyzed. (2) Some methods, in-
cluding the migrating defogging algorithm and addition of the haze reduction module, for
restoring and enhancing underwater images are summarized. (3) The polarization-based
imaging technology and scattering-based image processing methods are summarized
and compared. (4) Some minor research methods (such as the use of an electric field) are
introduced. (5) The commonly used visual research datasets in visual research carried out
in turbid underwater environments are summarized to provide a reference for future study.

2. Research Field Analysis
In recent years, the emergence of deep learning has provided a new direction for
target detection and recognition in turbid waters. The combination of this field with image
processing, polarization imaging technology, and other areas has also obtained excellent
experimental results as presented in the latest papers. However, little scientific research
has been conducted on this aspect at present. In this field, scholars engaged in underwater
vision have presented some research attempting to improve the scattering and enhancement
of image contrast. In the exploration of new methods, researchers who were inspired by
biology, such as marine organisms , have used electronic communication and sonar to
broaden their understanding of solutions and promote the development of target detection
and recognition in turbid waters.
Based on the Web of Science database and the keyword turbid zone target recogni-
tion, the fields involved in research results presented over the last five years were identified.
It was found that the application fields of these studies are very comprehensive, with
strong generality and crossover. According to the identified applications of target detection
and recognition in turbid waters, it can be concluded that this research field covers a
wide range of disciplines. Moreover, it can be applied in, but not limited to, engineering,
optics, instruments instrumentation, communication, computer science, oceanography,
telecommunications, physics, chemistry and environmental ecology, chemical analysis, and
biomedical engineering, such as the detection of targets in turbid solution samples. Figure 1
shows the general statistical results of the application of this study in various areas.
 Appl. Sci. 2022, 12, x FOR PEER REVIEW 3 of 22

Appl. Sci. 2022, 12, x FOR PEER REVIEW 3 of 22

samples. Figure 1 shows the general statistical results of the application of this study in
Appl. Sci. 2022, 12, 4898 various areas.
samples. Figure 1 shows the general statistical results of the application of this study3 of
in21
various areas.

Figure 1. Percentages of different application areas.

Figure
Figure1.1.Percentages
Percentagesofofdifferent
differentapplication
applicationareas.
areas.
Due to the unique environmental impacts of turbid waters, research on target detec-
tion in
Dueclear waters hasenvironmental
progressed more significantly than target detection in turbid wa-
Due totothe
the unique
unique impacts
environmental impacts of
of turbid
turbid waters,
waters,research
researchon ontarget
targetdetection
detec-
ters. At
in clear present,
waters most
hashas advanced
progressed target
more detection
significantly and recognition
than target approaches
detection inin in water
turbid use
waters.
tion in clear waters progressed more significantly than target detection turbid wa-
deep learning,
At present, most polarization
advanced imaging,
target and
detection other
andand techniques,
recognition and researchers
approaches in water have used
use use
deep
ters. At present, most advanced target detection recognition approaches in water
these methods
learning, in turbidimaging,
polarization water to and develop
othernew improvedand
techniques, methods, whichhave
researchers is significant
used for
these
deep learning, polarization imaging, and other techniques, and researchers have used
promoting
methods in the development
turbid water to of underwater
develop new target
improved detection technology.
methods, which is significant for
these methods in turbid water to develop new improved methods, which is significant for
promoting the development of underwater target
promoting the development of underwater target detection technology. detection technology.
3. Problems in Turbid Areas
3. Problems in Turbid Areas turbidity areas include aquaculture farms, shallow coastal
In engineering,
3. Problems in Turbidcommon
Areas
areas,Indeep
engineering,
sea areas, common turbidity
etc. Aquatic areas include
aquaculture farmsaquaculture
often resultfarms,
in severeshallow coastal
blurring of
In engineering, common turbidity areas include aquaculture farms, shallow coastal
areas, bodies
water deep sea dueareas,
to theetc. Aquatic
density aquaculture
of aquatic organismsfarms andoften result inlight
insufficient severe blurring of
transmittance
areas,
water deep seadue areas, etc. Aquatic aquaculture farmsand often result in severe blurring ofin
in the bodies
water body. to Most
the density
shallow of aquatic organisms
water receives abundant insufficient
light, butlight
the transmittance
turbidity of the
water bodies
the water due
body. to the
Mostdue density
shallow of aquatic
water sediment,organisms
receives abundant and insufficient light transmittance
water body is high to coastal aquatic light, but theand
organisms, turbidity
human of activities.
the water
inbody
the water
is high body.
due Most
to shallow
coastal sediment,water receives
aquatic abundant
organisms, andlight, but activities.
human the turbidity Deepofsea
theis
Deep sea is characterized by weak light but clear water quality. Underwater images of
water body is high
characterized duelight
to coastal sediment, aquaticUnderwater
organisms, images
and human activities.
specific turbidby weak
waters but clear
are demonstrated water quality.
in Figure 2. of specific turbid
Deep
watersseaareis demonstrated
characterized by weak light
in Figure 2. but clear water quality. Underwater images of
specific turbid waters are demonstrated in Figure 2.

(a) (b) (c)
Figure
Figure 2.
2. Underwater
(a)
Underwater images
imagesofofturbid
turbidwater.
(b)(a)(a)
water. AnAnunderwater
underwaterphoto of (c)
photo aoffish farm.
a fish (b) An
farm. (b) un-
An
derwater
underwater image
imageof shallow
of water.
shallow (c)
water. An
(c) underwater
An underwaterimage of
image deep
of sea.
deep sea.
Figure 2. Underwater images of turbid water. (a) An underwater photo of a fish farm. (b) An un-
derwater image of shallow water. (c) An underwater image of deep sea.
In general,
general, turbid
turbidwater
watercannot
cannotbebepurified,
purified,soso
thethe density
density of suspended
of suspended particles
particles in
in tur-
bid water
turbid results
water in low
results contrast,
in low with
contrast, no no
with inherent
inherentcharacteristics, blurring,
characteristics, andand
blurring, distortion.
distor-
In general, turbid water cannot be purified, so the density of suspended particles in
The most
tion. difficult
The most problem
difficult encountered
problem during
encountered the use
during theofuse
some detection
of some approaches
detection is the
approaches
turbid water results in low contrast, with no inherent characteristics, blurring, and distor-
scattering
is effect of
the scattering water
effect on the on
of water light
thewave.
light Therefore, strong strong
wave. Therefore, backscattered light, which
backscattered light,
tion. The most difficult problem encountered during the use of some detection approaches
carries impurity information, obscures the target data, and reduces the image contrast.
is the scattering effect of water on the light wave. Therefore, strong backscattered light,
Although typical optical image methods, such as the use of underwater cameras, offer
an inherently high resolution capability, the unknown imaging conditions, including the
optical water type, scene location, illumination , and absorption and scattering character-
istics of the marine medium, severely limit the image performance. For example, the visible
range in the Singapore coastline area is only 2–3 m. Due to the attenuation of reflected
 which carries impurity information, obscures the target data, and reduces the image con-
trast. Although typical optical image methods, such as the use of underwater cameras,
offer an inherently high resolution capability, the unknown imaging conditions, including
the optical water type, scene location, illumination , and absorption and scattering char-
Appl. Sci. 2022, 12, 4898 acteristics of the marine medium, severely limit the image performance. For example,4 of 21
the
visible range in the Singapore coastline area is only 2–3 m. Due to the attenuation of
reflected light, blurring caused by tiny impurities, and abnormal changes in color, the ac-
curacy of targetcaused
light, blurring recognition is reduced.
by tiny impurities, and abnormal changes in color, the accuracy of
Considering
target recognitionthe objective limitations of optical sensors in underwater scenes, most
is reduced.
common detectionthe
Considering methods in turbid
objective areasof
limitations areoptical
based sensors
on computer vision theory
in underwater andmost
scenes, uti-
common
lize detection
non-optical methods
sensors, such inas turbid areas etc.
lidar, sonar, are However,
based on computer
as a result vision theory and
of the complexity
utilize
and non-optical
significant sensors, such
interference as lidar,
in turbid sonar,
waters, etc. methods
these However,cannot
as a result of the
provide complexity
satisfying re-
and significant interference in turbid waters, these methods cannot provide
sults. Thus, the investigation of new approaches based on these methodologies is difficult. satisfying
results.
This work Thus, the investigation
focuses of new methods
on target detection approaches based
based onon these
deep methodologies
learning, is difficult.
some underwater
This work
image focuses on
restoration target detection
enhancement methods
methods, andbased on deepimage
underwater learning, some underwater
processing methods
image on
based restoration enhancement
polarization imaging,methods,
which haveanddemonstrated
underwater image processing
the most advancedmethods based
target de-
on polarization
tection imaging,
performances and which
meet the have demonstrated
requirements the most advanced
of underwater target
intelligent detection
sensing tech-
performances
nology. and meet the
The underwater requirements
image processing ofeffect
underwater intelligent
is depicted sensing
in Figure 3. technology. The
underwater image processing effect is depicted in Figure 3.

(a) (b)
Figure
Figure 3.
3. Comparison
Comparison of images before
before and
andafter
afterunderwater
underwaterimage
imageprocessing.
processing.(a)(a)Before
Before analysis
analysis of
of the image. (b) After analysis of the image.
the image. (b) After analysis of the image.

4. Research
4. Research on
on Target
Target Detection and Recognition in Turbid
Turbid Waters
Waters
4.1. Target Detection Based on Deep Learning Methods
4.1. Target Detection Based on Deep Learning Methods
In recent
In recent years,
years, deep
deep learning
learning technology
technology hashas been
been widely
widely used
used inin underwater
underwater image
image
defogging and target identification. Methods based on deep learning
defogging and target identification. Methods based on deep learning investigate image investigate image
sets by
sets by training
training the
the neural
neural network
network andand seek
seek to
to establish
establish aa logical
logical relationship
relationship to
to improve
improve
the image clarity or extract target features for intelligent recognition. In turbid waters,
the image clarity or extract target features for intelligent recognition. In turbid waters,
such as typical fish farms, monitoring of fish in real-time is required. Therefore, accurate
such as typical fish farms, monitoring of fish in real-time is required. Therefore, accurate
identification of targets and prediction of motion trajectories in turbid waters is important.
identification of targets and prediction of motion trajectories in turbid waters is important.
Due to the typical problems, such as low contrast, a lack of inherent features, blurring,
Due to the typical problems, such as low contrast, a lack of inherent features, blurring,
and distortion, caused by the turbidity of water or the presence of suspended particles in
and distortion, caused by the turbidity of water or the presence of suspended particles in
water in aquaculture farms, target detection of fish is difficult. This section discusses the
water in aquaculture farms, target detection of fish is difficult. This section discusses the
applicability of deep learning networks for target recognition in turbid waters and methods
applicability of deep learning networks for target recognition in turbid waters and meth-
to improve the deep learning defects.
ods to improve the deep learning defects.
Traditional target detection methods manually extract the features of target areas,
Traditional target detection methods manually extract the features of target areas,
which is time consuming and has poor robustness. With the appearance of the deep learning
which is time consuming and has poor robustness. With the appearance of the deep learn-
convolution neural network, the target detection algorithm entered a new stage. Existing
ing convolution
target detection neural network,
algorithms the target
are mainly detection
divided algorithmalgorithms
into two-stage entered a new and stage. Ex-
one-stage
isting target detection algorithms are mainly divided into two-stage
algorithms. Two-stage algorithms mainly include the RCNN series algorithms (RCNN , algorithms and one-
stage algorithms.
Fast RCNN Two-stage
, Faster RCNN algorithms mainly include
). These algorithms the RCNN
first generate series
regional algorithms
proposals, and
(RCNN , Fast RCNN , Faster RCNN ). These algorithms first generate
then perform classification and regression tasks on the regional proposals. Thus, detection regional
proposals,
is improved, andbut
thentheperform
processingclassification and regression
time is increased tasks on
accordingly. Suchthealgorithms
regional proposals.
are more
Thus,
suitable for the detection of static underwater objects, such as seafloor rocks,Such
detection is improved, but the processing time is increased accordingly. algo-
corals, etc.
rithms are more suitable for the detection of static underwater objects,
Single-stage algorithms mainly include the SSD algorithm and YOLO series algorithms such as seafloor
(YOLO , YOLOv2 , YOLOv3 ). These algorithms improve the detection speed
and maintain the detection effect as much as possible and use the direct regression method
to forecast the category and location of targets. Therefore, such an algorithm is suitable for
when the target detection required is frequent due to frequent aquatic activities, such as
those of fish.
Effective target feature detectors and classifiers provide deep learning methods with
an advantage in turbid water environments, which is why it is important for computers
Appl. Sci. 2022, 12, 4898 5 of 21

to adapt the fuzzy characteristic of turbid water and precisely identify target features.
Lakshmi and Santhanam proposed two types of classifiers: one is a two-classification
convolution neural network for distinguishing between the target and background while
the other is a multi-classification convolution neural network for predicting the background
or one type of target, such as shoes and ropes. They trained a convolution neural network
(CNN) to classify 64 × 64 inputs. The images were classified, and the classifier was used as
the target feature detector. The accuracy rate of the 2-class convolution neural network was
93.9%, and the target detection accuracy rate of the multi-class convolution neural network
was 90.1%, which is higher than existing multi-class detectors (88%).
Phooi et al. focused on the selection and improvement of the basic network
architecture in Faster RCNN. They preprocessed the acquired images and tested the basic
network performance under different network architectures in Faster RCNN to select the
best basic network for image training in turbid media. The experimental results showed
that the accuracy of MobileNetV2 on the basic network was 87.52%, which is better
than other architectures. A comparison of the experimental results is shown in Table 1.

Table 1. Comparison of the experimental results of different basic networks. The networks were
pretrained by the ImageNet.

Number of Number of Trainable Training Model
Type Accuracy (%)
Parameters Parameters Storage
ResNet50 34,386,842 34,356,164 137.8 MB 78.28%
MobileNet 8,280,256 8,255,236 33.3 MB 82.19%
MobileNetV2 6,743,096 6,701,188 27.2 MB 84.57%
DenseNet 42,726,388 42,672,772 171.4 MB 83.98%

To extract features from turbid areas with significant interference, Wei et al.
focused on a one-stage algorithm and proposed a target detection algorithm YOLOv3-
brackish based on an improved scale and attention mechanism. In this algorithm, the
extrusion excitation module is added behind the deep convolution layer, which enhances
the feature extraction ability of the YOLOv3 model. To solve the problem of multiple
small targets, the identification of which is difficult, shallow features with greater location
information were combined with deep features to improve the detection performance of
the small target model. The experimental results showed that the improved YOLOv3-
Appl. Sci. 2022, 12, x FOR PEER REVIEW
brackish model performed better than SSD, Faster CNN, and YOLOv3, and the effect 6 of 22
is
demonstrated in Figure 4.

Figure 4. Comparison
Figure 4. Comparison of target detection
of target detection results.
results. (a) Original picture.
(a) Original picture. (b)
(b) Correct
Correct annotation.
annotation. The
The
target detection result of (c) SSD, (d) Faster RCNN, (e) YOLOv3, and (f) YOLOv3-brackish.
target detection result of (c) SSD, (d) Faster RCNN, (e) YOLOv3, and (f) YOLOv3-brackish.

Liu et al. combined image processing with deep learning to realize species iden-
tification and density calculation of marine organisms to monitor the invasion of marine
organisms in real-time. An underwater camera was used to capture image data in real-
time within the monitoring range and deep learning was used to achieve end-to-end
Appl. Sci. 2022, 12, 4898 6 of 21

Liu et al. combined image processing with deep learning to realize species iden-
tification and density calculation of marine organisms to monitor the invasion of marine
organisms in real-time. An underwater camera was used to capture image data in real-time
within the monitoring range and deep learning was used to achieve end-to-end recognition
of jellyfish. First, the convolution neural network was designed and improved, and a
convolution neural network composed of two convolution layers, two pooling layers, and
a full connection layer was obtained. After training, the convolution neural network was
predicted using test sample images. Under the non-uniform light field, the characteristics
of the biological images taken in turbid water were investigated using image sharpening,
edge detection, edge closure, hole filling, etc. A binary image separate from the target and
background was obtained, demonstrating real-time estimation of the marine biological
density. The results showed that this method can be effectively applied to calculate the
marine biological density and detect marine biological species. This study provides a
reference for the early warning of biological invasion in offshore waters.
Ahmed et al. focused on the comparison of various existing edge detection
methods, including Laplace, SobelX, SobelY, Combined Sobel, and the Canny detector. The
results of these methods were obtained and analyzed, as shown in Table 2.

Table 2. Results of edge detection algorithms.

Type Accuracy Accuracy Evaluation
Laplacian 68.9% Normal
Sobel X 79.26% High
Sobel Y 79% High
Combined Sobel 88.9% Very high
Canny 89.13% Very high

When the Laplace method was used, the accuracy was 68%. The accuracy of SobelX
was similar to that of SobelY. Canny showed higher accuracy than the other methods and
has been widely used in edge detection. Therefore, the Canny edge detection method is the
best algorithm for detecting the edge of the target contour in a turbid area.
In practical engineering applications, an algorithm that can identify the underwater
bios trajectory of fisheries to enable easier localization and capture has also been inves-
tigated. As an optimization tool, the genetic algorithm has been widely used in various
fields, but it has not been fully studied in terms of the trajectory prediction of moving
targets. However, in a recent study, the concept of the dynamic traveler problem based on
the genetic algorithm and Newton equation of motion was used to obtain excellent results
in predicting the minimum distance traveled by a moving fishing boat in the future. Since
use of the genetic algorithm (GA) in this field has not been fully realized, Palconit et al.
further discussed its application potential in fish tracking based on GA. On the other
hand, the deep learning algorithms recurrent neural network (RNN) and long short-term
memory (LSTM) have been used in several visual track prediction methods to predict
targets, including pedestrians, vehicles, mobile robots, fish, etc. The results from these
methods were shown to be better than most tracking methods, and thereby underwater
video fish tracking research has been carried out based on RNN-LSTM. The results showed
that trajectory prediction using LSTM is more accurate than the use of a genetic algorithm,
but both showed an acceptable accuracy and the average absolute percentage errors of GA
and LSTM were 2.8~30.5% and 3.33~17.74%, respectively. LSTM has been widely used in
trajectory prediction in many fields while the genetic algorithm has seldom been used as a
trajectory prediction method. The results of GA can be improved through the use of addi-
tional variables or fitness functions, such as Newton’s equation of motion and quadratic
regression. Three-dimensional coordinates have been shown to provide more accurate
prediction results for GA and LSTM, so it can be further extended for two-dimensional and
three-dimensional path prediction in the future, such as the use of GA and LSTM in fish
tracking and marking or investigation of its combination with other tracking algorithms.
Appl. Sci. 2022, 12, 4898 7 of 21

Intelligent target recognition and positioning using deep learning methods is powerful.
However, the accuracy of underwater target recognition is affected by the image clarity,
and deep learning methods are only applicable in waters that are similar to the training
set image, so this method has some limitations. Therefore, the combination of good image
restoration methods and deep learning methods can make target detection and recognition
in turbid waters more effective.

4.2. Underwater Image Restoration and Enhancement Methods
Deep learning has been widely used in underwater image restoration and enhance-
ment to improve the quality of underwater images to a certain extent. Methods based
on deep learning can be used to study the relationship between the features of an image
set by training the neural network, and reduce the error caused by prior invalidity. Some
characteristics of turbid water are similar to those of foggy weather, including problems
regarding the attenuation of reflected light, blur caused by tiny impurities, and abnormal
changes in color. These factors result in severe color distortion and low visibility in the
captured image, so suitable light models and algorithms need to be developed to eliminate
any negative impacts. Because underwater image processing and defogging have certain
similarities, various defogging algorithms have been gradually improved for application to
the enhancement of underwater images.
Thomas et al. developed a fully connected convolution neural network for un-
derwater image defogging. The integration of low-level and high-level features through
the depth frame of the encoder-decoder helped to restore blurred images, showing better
results than existing methods, such as the structural similarity index (SSIM) , peak
signal to noise ratio (PSNR), and mean square error (MSE). It was also able to retain details
during the removal of fog. Dudhane et al. proposed an end-to-end trainable image
defogging network called LIGHT-Net, which includes a color constancy module and a
haze reduction module. The color constancy module was used to remove color differences
in the image caused by the weather conditions, and the haze reduction module used an
initial residual module to reduce the haze effect. Feature sharing was also proposed in this
module, which means the features learned at the initial level are effectively shared through
the network. The experimental results of this method are promising. Yin and Ma
proposed a migration learning method for several types of naturally degraded image
enhancement, including underwater image enhancement. They used transfer learning for
each specific natural degradation. By repeatedly applying the general enhancement model,
they overcame existing problems regarding the shortage of training datasets for in-depth
learning methods and the computational burden of the training process. The enhanced
model was finetuned, and its performance surpassed several of the most advanced methods
designed for specific tasks, such as uwcnn and funie-gan.
Martin et al. proposed a combination of image enhancement, image recovery, and
the convolution neural network, resulting in a method for target detection of recovered
images. Due to the maximum number of green pixels in underwater images, under
dark channel prior method (UDCP)-based energy transmission restoration (UD-ETR) was
proposed to process green channel images and obtain the recovered images. The image
processing results are displayed in Table 3.
On this basis, a method for fish detection in restored images using CNN was proposed,
and a PC-based automatic target detection recognition visual system was developed. The
training results of CNN were also shown to be significantly better than that of the traditional
model, which solves the problem of inaccurate target detection caused by blurred images.
Appl. Sci. 2022, 12, 4898 8 of 21

Table 3. Comparison of the parameters from transmission map estimation and UD-ETR.

Existing Approach (Transmission Proposed Approach
Parameters
Map Estimation) (UD-ETR-Based Restoration)
Contract luminance 39 89
UCIQE 12 26
Saturation 0.1 0.5
Chroma 2.5 5.5
PSNR 5 14
RMSE 140 50
MSE 1.7 0.3

Cecilia et al. proposed an effective edge perception restoration and enhancement
model for severely blurred shallow coastal images with low contrast. Restoration methods,
which are based on the dark channel and rolling guidance filter, were used to restore and
denoise such images, resulting in clearer edge perception. This method introduced a rolling
guidance filter in dark channel prior (DCP) restoration, which effectively restored images
and decreased the noise in the images. This experiment showed that the rolling filter based
on the recovery model has better denoising effects.
Regarding the enhancement of the quality of underwater images taken in different
water body types, the image forming model used in earlier methods is imprecise and
its restoration effect is poor. Zhou et al. developed a defogging method using a
modified model. They first designed an underwater image depth estimation method to
create depth maps and estimate backscattering based on the depth values of each pixel,
and then removed backscattering based on a more accurate underwater imaging model.
To address the color distortion characteristics of the turbid area, they proposed a color
correction method to automatically adjust the global color distribution of an image. This
method used a single underwater image as the input, eliminating the effects of light wave
absorption and scattering. Experiments have demonstrated that this approach has better
applicability compared with previous research methods.
Considering that scattering attenuation and color correction of high-turbidity underwa-
ter images affects the classification results of target recognition based on machine learning
(ML), Li et al. proposed a contrast-enhanced method to remove scattering. This enhance-
ment method considers the illumination and camera spectral characteristics, eliminates
scattering, and correctly restores the scene color. They also used different ML approaches
for classification in their research to confirm that this method can be applied to classification
and recognition architecture preprocessing based on deep learning, which showed a better
image classification effect. However, for practical applications, use of the scattering removal
algorithm does not provide the accuracy required by practical engineering.
Yang proposed an underwater polarized imaging target enhancement technique
based on non-polarized illumination to overcome the disadvantages of the current un-
derwater polarized scattering algorithm, such as its low accuracy and limited application
range. The use of unpolarized light ensures that any polarization difference between the
target reflected light and stray light can be detected. At the same time, the characteristic
parameter of the polarization angle ensures accurate estimation of the stray light inten-
sity. Compared with current underwater polarized imaging technology based on linear
polarized light illumination, it has a wider application range and higher image restoration
accuracy. The results showed that the visibility of underwater restored images is improved
effectively, and the contrast is improved by at least 100%. Meanwhile, this technique can be
applied to water environments with various material targets, imaging distances, diverse
impurities, and turbidity levels, and has potential application value in many underwater
imaging fields.
Drews-Jr et al. proposed a new underwater restoration method based on monocu-
lar image sequences, which utilizes the time relationship and geometric and environmental
information to improve the quality of visual features in underwater images. It can also
Appl. Sci. 2022, 12, 4898 9 of 21

robustly estimate the depth map and attenuation coefficient. The attenuation coefficient is
used to evaluate the loss of light in the medium, so the accuracy of its estimation affects
image restoration. Depth estimation is realized using adaptive optical flow and struc-
ture motion technology, and the attenuation coefficient is estimated by introducing an
underwater optical attenuation model into the RANSAC frame. Meanwhile, a depth
map is estimated from the combination of motion structure technology and model-based
restoration. The simulation and real image test results showed that the method restores the
image, thus improving the ability of target recognition and feature matching.
Cheng et al. proposed a method for image fusion based on the Mueller matrix to
enhance the quality of underwater degradation images. Each Mueller matrix element image
is given a weight and fused to generate a new image. The optimal weights are obtained
by searching for values that maximize the image quality. The validity of this method was
proved by comparison with the Mueller matrix image and the latest method using objective
and subjective analysis. Moreover, the image was enhanced using analog weights. Due
to the nature of the Mueller matrix, this method improves the underwater observation
distance and image quality, and provides the enhanced images with information that is
unavailable when conventional methods are used.
Due to the absorption and scattering of light in water, color projection and poor
contrast are often present in underwater images. Zhou et al. proposed an underwater
image restoration method based on a priori underwater features. They first established a
powerful model to estimate the background light based on the characteristics of flatness,
hue, and brightness, thus effectively mitigating color distortion. The red channel of the
color-corrected image was then compensated to correct its transmission map. The rough
transmission diagram was refined by combining it with a structure-guided filter.

4.3. Underwater Image Processing Based on Polarization Imaging and Scattering
The most difficult problem encountered during optical detection in turbid areas is the
scattering effect of water on the light wave, which mainly results in low image contrast, a
reduction in resolution, and image blurring. Scattering includes forward and backward
scattering processes. When forward scattering occurs, light deviates from the original trans-
mission path, resulting in a reduced image resolution and blurred image. Backscattered
light, which carries suspended particulate information, produces a ‘curtain effect’ on the
target image and reduces the image contrast. Therefore, it is necessary to overcome the
scattering and reflection problems in underwater imaging to improve the imaging distance
and quality.
Polarized imaging technology has obvious advantages in removing background scat-
tered light and achieving clear underwater images by deeply mining the uniqueness and
differences in polarization information in a scattered light field. Currently, accurate es-
timation of the polarization characteristics and relationship between target information
light and background scattered light, inverting the intensity distribution of target informa-
tion light and background scattered light, are key research areas of underwater imaging
technology. Research has shown that the polarization characteristics of incident polarized
light can be used to separate these two kinds of light in a scene, effectively restoring a
clear scene, improving the contrast and clarity of imaging results, and aiding underwater
target detection and recognition. Because underwater search and rescue operations often
face target detection problems in high-turbidity water, exploration of polarization imaging
technology that is suitable for turbid water is necessary. An overview of this method is
depicted in Figure 5.
With a long research history and significant basic experience, polarization imaging
technology is suitable for more in-depth research in this direction. Currently, polarization
imaging methods are being developed for the unique environment of turbid waters.
 ing technology. Research has shown that the polarization characteristics of incident po-
larized light can be used to separate these two kinds of light in a scene, effectively restor-
ing a clear scene, improving the contrast and clarity of imaging results, and aiding under-
water target detection and recognition. Because underwater search and rescue operations
often face target detection problems in high-turbidity water, exploration of polarization
Appl. Sci. 2022, 12, 4898 10 of 21
imaging technology that is suitable for turbid water is necessary. An overview of this
method is depicted in Figure 5.

Figure 5. An overview of underwater data processing methods based on polarization imaging.
Figure 5. An overview of underwater data processing methods based on polarization imaging.

With a long research
Underwater models for history and significant
studying turbidity and basic experience,have
illumination polarization imaging
been established,
technology
which is suitable
is helpful for more
for optical in-depth
research research
of target in this and
detection direction. Currently,
recognition polarization
in turbid waters.
imaging
Bailey et methods are beinga developed
al. proposed model based foron thethe
unique
spatial environment
variation inofunderwater
turbid waters. environ-
ments and coherent
Underwater light and
models used it forturbidity
for studying low-contrastand target detection
illumination havein turbid water. This
been established,
model
which is was used for
helpful to theoretically
optical research studyof the effects
target of turbidity,
detection projection in
and recognition space-frequency
turbid waters.
variation,
Bailey et al. and three-dimensional
proposed a model target shapes
based on theonspatial
unstructured scattered
variation light components
in underwater environ-
and the target structured return signal. The results showed that the
ments and coherent light and used it for low-contrast target detection in turbid water. This model’s accuracy is
adequate
model wasfor theto
used modeling of noise
theoretically study reduction
the effects technology.
of turbidity, This result indicates
projection that the
space-frequency
received
variation,three-dimensional
and three-dimensional target target
imageshapes
can be onmodeled with backscattering
unstructured scattered light and struc-
compo-
tured illumination,
nents and the targetand noise reduction
structured and target
return signal. identification
The results showed can thatbetheachieved
model’sin the
accu-
model environment. Based on the image degradation model, Han
racy is adequate for the modeling of noise reduction technology. This result indicates that considered image
degradation
the received due to the joint effects
three-dimensional of forward
target image can andbebackward
modeled scattered light, estimated
with backscattering and
the
structured illumination, and noise reduction and target identification can be and
degradation function of forward scattered light using the edge method, further
achieved in
restored
the model clear scene images.
environment. Based Heonconstructed a turbid water
the image degradation polarization
model, Han imaging
considered model,
im-
and then obtained
age degradation duethetopolarization degree
the joint effects of of target and
forward information
backward light and background
scattered light, esti-
scattered light using the optical correlation principle to restore
mated the degradation function of forward scattered light using the edge method, and the clear scene.
furtherOnrestored
the premise clearofscene
establishing
images.an Heoptical model,aHan
constructed water
turbid proposed an active
polarization under-
imaging
water polarization imaging method, which is based on the imaging
model, and then obtained the polarization degree of target information light and back- noise analysis model,
and
groundstudied the effect
scattered lightofusing
noisethethatoptical
is introduced during
correlation the polarization
principle to restoreimaging
the clearprocess
scene. on
the final imaging quality. This method resulted in the best polarization
On the premise of establishing an optical model, Han proposed an active under- azimuth image for
active underwater polarization imaging, and the relationship
water polarization imaging method, which is based on the imaging noise analysis model,between different polarizer
images and the final imaging quality was established. This method can effectively realize
and studied the effect of noise that is introduced during the polarization imaging process
the imaging distance in a high-turbidity water body, improve the imaging quality and
on the final imaging quality. This method resulted in the best polarization azimuth image
detection effect, and providing support for underwater search and rescue work in rivers
for active underwater polarization imaging, and the relationship between different polar-
and offshore areas.
izer images and the final imaging quality was established. This method can effectively
Huang proposed a polarization image restoration algorithm and a new curve
realize the imaging distance in a high-turbidity water body, improve the imaging quality
fitting-based method to estimate the target signal of polarization difference images. Based
and detection effect, and providing support for underwater search and rescue work in
on the polarization effect of reflected light in underwater imaging, the former was used
rivers and offshore areas.
to restore underwater blurred images with polarization imaging, and study the imaging
model of underwater active illumination imaging systems and the transmission behavior
of polarization information in an underwater turbid medium. The latter considers the
polarization effect of the reflected light from the object in the scene to derive the true trans-
mission coefficient image and underwater restored image. Both can overcome the invalid
detection problem in the area corresponding to objects with a low degree of deflection and
effectively enhance the underwater imaging quality.
As backscattered light occurs due to the presence of high concentrations of impurities
in turbid water, the reflected light from an object is easily confused, which makes it difficult
to distinguish the object from the environment. Therefore, the division of reflected light
from interfering light, such as backscattered light, which reflects the characteristic of the
object, is a core issue for underwater image processing using polarized imaging. At present,
several methods, such as optical sensing technology, the polarization filter method, and
the backscattering interference suppression method, that can separate coherent light from
incoherent light exist. Cochenour et al. proposed new optical sensing technology
Appl. Sci. 2022, 12, 4898 11 of 21

based on the orbital angular momentum (OAM). The target is illuminated by a Gauss
beam. By setting a diffraction spiral phase plate at the receiving end, the reflected and
backscattered light of the object passes through the phase plate to form vortex light, thus
spatial separation of coherent and incoherent light is achieved. Experiments have shown
that the echo of a ballistic target can achieve detection that is two to three orders of
magnitude the level of backscattered clutter. The detection of this coherent element is
realized using a complex optical heterodyne scheme. In addition, the detection of this
small coherent signal is completed without the use of any complex optical heterodyne
scheme, which indicates that the unique characteristics of OAM can be used to distinguish
between objects and the environment. Amer et al. used a polarized imaging optical
system to reduce the influence of underwater beam diffusion on image acquisition and
optimized the DCP method. They used a low-pass polarization Gauss filter to calculate
the illumination from the input image and enhance underwater optical imaging, which