1. Introduction
Fish products contribute a significant amount of protein to human nutrition- about 16% of the human diet worldwide. Also, its consumption has dramatically increased from approximately 36.82 million tons circa 1960 to 199.74 million tons by 2015 [1]. Likewise, the demand for aquaculture software, supplies, and equipment has increased-it was estimated to exceed US$ 80 billion in 2016 [1-3]. In Nigeria, catfish production has increased from 3 million tons per annum in 2001 to more than 30 million tons per annum in 2006 [4]. But Nigeria still imports approximately 900 000 tons of fish each year which costs about US$ 1 billion due to shortages in the production sector [5-7]. One of the problems faced by the production sector in the country is accurate counting as it is essential for accurate stocking of ponds, feeding planning, marketing and fast delivery of fish [8,9].
Most catfish counting in rural areas of Nigeria is performed manually, which involves counting and sorting the fish by hand [10]. However, the manual counting is prone to mistakes, occasional omissions, fatigue and may lead to stress and death of the fish. Another method of fish counting is the use of a container to estimate the number of catfish, which is also inaccurate [10]. Inaccurate estimation affects both the hatchery and the customer because it can lead to over- or under-feeding or payment. Even though several automatic counting systems have been devised, the cost of acquiring such commercial counting equipment is very high: US$ 75,000 and greater [3].
Various techniques have been proposed for fish counting such as mechanical, optical and digital image techniques (DIP). The techniques associated with DIP include pixels counting, video tracking, machine vision, etc. However, machine vision is mainly suitable for fishing or underwater counting [11]. Video tracking technique also increases the cost of counting, slows counting speed and is computationally intensive.
Despite some of the disadvantages of Fish counting using DIP, it is still a viable solution in catfish farms as it would reduce counting time, minimize fish stress, and facilitated proper financial planning [12]. Thus, to harness the benefit of DIP, one of the major issuesto improve in fish counting is accuracy, which is affected by factors such as noise, overlapped and other objects other than fish in the pond [13,14]. As the DIP basically employed pixel counting, there is a problem of object recognition to substantiate which area pixel is associated with fish as noise or variation in illumination or any other object in the image could erroneously be considered as fish. Besides, the flexibility of counting fish of any size is critical in attaining high accuracy in DIP.
Hence, this study is aimed at developing a catfish recognition and counting algorithm to improve pixel counting by recognizing the catfish before counting. It also addresses the issue of overlapping by formulating a new counting algorithm that is flexible to count fish of any size. Therefore, the main contributions of this paper that differ from other works is in at least one of the following points:
• The development of Catfish pre-processing, segmentation, and feature extraction techniques.
• Introduction of chaincode to improve catfish recognition accuracy using shallow neural networks with few trainable parameters.
• Formulation of new counting algorithm that is flexible to count fish of any size while addressing the problem of overlapping
The remainder of the paper is organized as follows: In Section 2, an overview of related works is presented. Section 3 provides the study methodology, Section 4 presents the results and discussion, and Section 5 provides the study conclusions.
2. Related Works
Newbury, Culverhouse, and Pilgrim used the top view of an artificial fish image to estimate fish count using neural networks [15]. High accuracy was achieved, but artificial fish were used and there was no background noise and no movement. Yada and Chen used a weighing technique to count seedling fry, but it was too slow, only a few milligrams were accurately weighed, and required a controlled environment [16]. Friedland et al. proposed a system that counted fish eggs using commercial software in which a dilution-erosion algorithm was employed to segment acquired images [17]. This work is particularly important because it attempted egg counting, which has issues with overlap as in catfish counting. Alver, Tennøy, Alfredsen, and Ø ie developed an autonomous rotifer sampling and counting system. However, accuracy figures were not presented [18]. A fully automated acoustic method for counting and sizing fish on fish farms using Dual-Frequency Identification Sonar (DIDSON) was proposed by Han, Honda, Asada, and Shibata [19]. The advantage of the proposed system is its ability to be applied in fish farms for counting and sizing, whereas DIDSON was initially designed for counting fish underwater. Toh et al. used blob detection to analyze the number of fish in a video by summing the fish in each frame and taking the average [20]. However, only five fish in overlap could be handled by this approach. Zheng and Zhang proposed a new method of counting fish using a digital image processing and a fuzzy artificial neural network (ANN) [21]. The method was capable of recognizing overlapped and differently sized fish. Loh, Raman, and Then developed Aquatic Tool Kits (ATK) for estimating the number of larval and juvenile fish using pixel counting [2]. However, the proposed method might not be flexible to count Fish of various size as the average area of a single larva is used to obtain the count
In another study, Labuguen et al. proposed an automated system using edge detection for fish fry counting and behavior analysis [13]. The method demonstrated an average accuracy of 95%. Luo, Li, Wang, Li, and Sun proposed a system for fish recognition and counting using a machine learning technique and statistical methods based on a set of six rules [22]. But a low accuracy of approximately 75% was recorded. Duan et al. proposed a non-invasive method of counting the live pelagic eggs of marine fish using an image analysis method [23]. The technique can be tried in ponds where contamination changes the watercolor. Raman et al. proposed a low-cost machine learning technique for efficient fish counting and growth studies using ANN [3]. However, the authors only stated that the boundary detection algorithm would be applied to count through the connected regions for overlaps case but there was no clear or robust explanation on how this would be performed.
More recently, Lumauag and Nava employed blob analysis and Euclidean filtering in DIP technique to estimate fish population [24]. The results of their experiment recorded an average counting and detection accuracy of 91% and 94%, respectively. Besides, Kaewchote et al. proposed an image recognition technique that utilized local binary pattern and RGB color feature extraction with an ensemble tree and random forest as classifiers for larvae counting [25]. However, a large root mean square error (MSE) of 14.43 was recorded mainly due to overlapping of shrimps. The study Lainez and Gonzales [26] proposed an automated fingerling counting algorithm using image processing method and convolution neural network (CNN). However, the CNN architecture requires a large trainable parameter. Garcial et al. [8] proposed an automatic fingerling counting algorithm which recorded an average error of 2.65% when compared with the manual counting. Meanwhile, a compressive review on image processing techniques for fisheries application was conducted by Awalludin et al. [9]. The authors observed that research publications with the application of image processing methods are still very limited.
Based on the reviewed literatures, issues such as counting other objects present in the water or counting noise caused by variations in illumination and flexible counting of fish of any size with high accuracy need to be addressed. Hence, this study aims to develop a catfish recognition and counting algorithm to improve pixel counting by recognizing the catfish before counting and the formulation of a new strategy for addressing overlapping in counting.
3. Catfish Counting Algorithm
The study methodology is comprised of five steps: image acquisition, image pre-processing, image segmentation, feature extraction, classification, and counting, as well as an evaluation of the accuracy and mean square error of the results. Fig. 1 shows the block diagram of the methodology in which an image is acquired, pre-processed, and segmented, features are then extracted for recognition and counting. Details of each unit in the block diagram are provided in the subsequent subsections.
Fig. 1. The proposed methodology for catfish counting
3.1 Image Acquisition
The image acquisition unit consisted of a camera that captured multiple images of a group of catfish in a container at an interval of approximately 3 s. The multiple image capture improved accuracy and reduced the issue of overlapping that occurred because of the catfish moving around in the water. The 8-megapixel camera was positioned vertically above the fish container.
3.2 Fish Image Pre-processing
Water contamination due to feed and other factors is a common problem in a fish pond. A preprocessing algorithm was implemented to successfully achieve a higher accuracy of counting in such an aquatic background, as shown in Fig. 2.
Fig. 2. Image pre-processing algorithm for noise removal and color conversion consisting of two operations: color conversion and gray morphological operation
After capture, the image was pre-processed to filter the fish and remove the noise from the image. The image was first converted from an RGB to a grayscale image using Equation (1).
\(I(x, y)=0.2989 \times R+0.5870 \times G+0.1140 \times B\) (1)
where R, G, and B are the red, green, and blue, respectively, colors of the RGB color space. Gray morphological operations were then performed using contrast enhacement and a media filer to enchance and remove noise from the image. Contrast enhancement mapped the intensity values in the grayscale level image, 𝐼(𝑥, 𝑦), to new values. The resulting values were saturated at low and high intensities of 1% of the data, which improved the contrast of the resulting image. The median filtering operation ranked neighboring pixels according to brightness (intensity), and the middle (median) value became the new value for the pixel under consideration. This filtering smoothed the noisy regions and preserved the boundary structures between the regions. The median was obtained using Equation (2):
\(\mathrm{I}_{m}(x, y)=\operatorname{median}_{(x, y) \epsilon S_{x y}}\{I(x, y)\}\) (2)
where 𝐼(𝑥, 𝑦) is the noisy gray image, and 𝑆𝑥𝑦 is a sub-image (region) of the image, 𝐼(𝑥, 𝑦). The image, 𝐼𝑚(𝑥, 𝑦), was then stored for the segmentation process
3.3 Image Segmentation Algorithm
In the segmentation algorithm, the image underwent three operations: thresholding, morphological operations, and edge segmentation. The process is illustrated in Fig. 3. The key operations in the algorithm are described as follows
Fig. 3. Image segmentation algorithm key operations: auto-thresholding, morphological operations, and edge detection operation
3.3.1 Auto-thresholding
Image binarization was performed using Otsu’s thresholding to correct the variations in the mean gray level that may arise due to factors such as unequal light exposure. Otsu’s thresholding method was employed to binarize the image, 𝐼𝑚(𝑥, 𝑦), into the foreground (catfish with pixels = 1) and background (= 0) by iterating through all the possible threshold values and calculating an optimal threshold to separate the two classes so that their intra-class variance was minimal while their inter-class variance was maximal. The exhaustive search for the threshold is the sum of the weighted variance of the two classes as obtained by Equation (3):
\(\sigma_{I_{m}(x, y)}^{2}(t)=\omega_{0}(t) \sigma_{0}^{2}(t)+\omega_{1}(t) \sigma_{1}^{2}(t)\) (3)
where 𝜔0 and 𝜔1 are the probabilities of the two classes, background and catfish, respectively, separated by a threshold, 𝑡, and the variances of these two classes are 𝜎02 and 𝜎12. The probabilities 𝜔0(𝑡) and 𝜔1(𝑡) were obtained using the histograms expressed by Equations (4) and (5), respectively:
\(\omega_{0}(t)=\sum_{i=0}^{t-1} p(i)\) (4)
\(\omega_{1}(t)=\sum_{i=t}^{L-1} p(i)\) (5)
where L is the grayscale layers of the image, 𝐼𝑚(𝑥, 𝑦). The resulting image, 𝐼𝑡 (𝑥, 𝑦), was stored for the next stage and is given as follows:
\(I_{t}(x, y)=\sigma_{I_{m}(x, y)}^{2}\) (6)
3.3.2 Morphological operations
After the initial binarization by thresholding, the fish objects’ holes and some minor noise still existed, and portions of the catfish were truncated. To correct these issues, firstly, a fill hole operation was executed using Equation (7):
\(I_{H}(x, y)=\left[R_{I_{t}(x, y)}(F)\right]^{t}\) (7)
where 𝑅𝐼𝑡 (𝑥,𝑦) is the reconstruction of the input image (mask), 𝐼𝑡 (𝑥, 𝑦), from 𝐹, and 𝐹 is the marker given as Equation (8):
\(F(x, y)=\left\{\begin{array}{c} 1-\mathrm{I}_{t}(x . y), \text { if }(x, y) \text { is on the border of } \mathrm{I}_{t}(x, y) \\ 0, \text { otherwise } \end{array}\right.\) (8)
An area opening operation was subsequently performed to remove small objects. In the opening operation, 𝑆 was eroded by 𝐼𝐻(𝑥, 𝑦), followed by a dilation of the result by 𝑆. The opening operation is given as Equation (9):
\(I_{H}(x, y) \circ S=\left(I_{H}(x, y) \ominus S\right) \oplus S\) (9)
where 𝑆 is the structuring element determined experimentally. In other words, the opening operation can be express as Equation (10):
\(I_{H}(x, y) \circ S=u\left\{(S)_{z} \subseteq I_{H}(x, y)\right\}\) (10)
where 𝑢 is the union of all sets. The erosion was executed to “shrink” or “thin” objects in the image to diminish the false connections that appear as overlap. The erosion of 𝐼𝐻(𝑥, 𝑦) by 𝑆 is given as Equation (11):
\(I_{H}(x, y) \ominus S=\left\{(S)_{z} \subseteq I_{H}(x, y)\right\}\) (11)
where 𝑆 ⊆ 𝐼𝐻(𝑥, 𝑦) indicates that 𝑆 is a subset of 𝐼𝐻(𝑥, 𝑦). Equation (11) indicates that the erosion of 𝐼𝐻(𝑥, 𝑦) by 𝑆 is the set of all points 𝑧 such that 𝑆, translated by 𝑧, is contained in 𝐼𝐻(𝑥, 𝑦). Consequently, the erosion can be expressed as follows:
\(I_{H}(x, y) \Theta S=\left\{(S)_{z} n I_{H}{ }^{c}=\emptyset\right\}\) (12)
Here, erosion is the set of all element origin locations where no part of 𝑆 overlaps the background, 𝐼𝐻(𝑥, 𝑦). The dilation in the opening operation “grows” and “thickens” objects in an image. The extent of the thickening is controlled by a shape referred to as a structuring element. The dilation is given as follows:
\(I_{H}(x, y) \oplus S=\left\{(\hat{S})_{z} n I_{H} \neq \emptyset\right\}\) (13)
where ∅ is the empty set and 𝑆̂ is the structuring element. Therefore, the resultant image, 𝐼𝑜 (𝑥, 𝑦), is given as Equation (14):
\(I_{o}(x, y)=x \circ y\) (14)
3.3.3 Edge detection operation
After the morphological operations, the shape boundary was obtained using edge detection. Based on the following criteria, the edge detection operation searched for places in the images where the intensity changed rapidly:
1. It found the places where the first derivative of the intensity was greater in magnitude than a specified threshold.
2. Then, it found the places where the second derivative of the intensity had a zero crossing. The first-order derivative is the gradient, (𝑔), of the 2D function 𝐼𝑂(𝑥, 𝑦), defined as follows:
\(v_{I_{o}(x, y)}=\left(\frac{g_{x}}{g_{y}}\right)=\left(\frac{\frac{\partial f}{\partial x}}{\frac{\partial f}{\partial y}}\right)\) (15)
The magnitude is given as follows:
\(\nabla I_{O}=\operatorname{mag}\left(\nabla I_{O}\right)=\left(g_{x}^{2}+g_{y}^{2}\right)^{\frac{1}{2}}\) (16)
and the angle at the maximum rate of change is
\(\alpha(x, y)=\left(\frac{g_{y}}{g_{x}}\right) .\) (17)
The second-order derivatives were computed using the Laplacian as shown below:
\(\nabla^{2} I_{O}(x, y)=\frac{\partial^{2} f I_{O}(x, y)}{\partial x^{2}}+\frac{\partial^{2} I_{O}(x, y)}{\partial y^{2}}\) (18)
The edge detected was then traced using a green outline, as presented in Section 4.2.
3.4 Feature Extraction Algorithm
After segmentation, the feature extraction algorithm was executed to obtain the shape descriptors of the fish. The algorithm extracted the shape features using a chain code representation and Fourier descriptors (CH-FD). The details of the CH-FD process are discussed in the subsequent section. Fig. 4 illustrates the feature extraction algorithm.
Fig. 4. Feature extraction algorithm using a chain code representation and Fourier descriptors (FDs)
The shape boundary pixel was obtained from the segmented catfish. The boundary pixels were then used to derive the chain code representation of the shape. The chain code was then processed using a discrete Fourier transform (DFT) implemented in the form of a fast Fourier transform (FFT). The results of these processes were termed as the Fourier descriptors (FDs).
3.4.1 Chain Code Representation.
The chain code boundary representation was based on eight connectivity segments. First, the boundary pixels were designated as segmented, as discussed in Section 3.3. The chain code of the boundary pixels was then generated. Fig. 5 shows the trace boundary of a catfish on a grid, from which the chain code was obtained.
Fig. 5. Catfish chain code representation
In this study, the new chain code generation function was developed based on a straightline gradient. Considering the figure on a line graph, the difference between two points (pixel boundary) on the y-axis (∆𝑦) was given by
\(\Delta y=y_{2}-y_{1}\) (19)
and the difference between two points on the x-axis (pixel boundary) was given as
\(\Delta x=x_{2}-x_{1}\) (20)
The gradient (𝛿) of any line segment in Fig. 5, can, therefore, be expressed as
\(\delta=\frac{\Delta y}{\Delta x}\) (21)
Using (19)– (21), the chain code (𝜂) can be expressed mathematically as (22)
\(=\left\{\begin{array}{ll} 0, & \delta==0 \text { and } \Delta y>0 \text { and } \Delta x==0 \\ 1, & \delta>0 \text { and } \Delta x>0 \\ 2, & \delta>0 \text { and } \Delta y>0 \\ 3, & \delta<0 \text { and } \Delta y>0 \text { and } \Delta x<0 \\ 4, & \delta==0 \text { and } \Delta y==0 \text { and } \Delta x<0 \\ 5, & \delta>0 \text { and } \Delta y<0 \text { and } \Delta x<0 \\ 6, & \delta<0 \text { and } \Delta y<0 \text { and } \Delta x==0 \\ 7, & \delta<0 \text { and } \Delta y<0 \end{array}\right.\) (22)
We applied a similar technique for optimal fish feeding strategy [27].
3.4.2 Fourier Descriptors (FDs)
The boundary chain code was further processed to obtain the FDs of the boundary. The chain code obtained is denoted as 𝜂 (k), where K is the sequence of the point. A DFT was implemented in the form of an FFT using
\(a(u)=\sum_{k=0}^{K-1} \eta(k) e^{-\frac{j 2 \pi u k}{K}}\) (23)
where 𝜂(𝑘) is the chain code and the complex coefficients, 𝑎(𝑢), are the FDs of the boundary. The value of 𝜂(𝑘) can be obtained using the inverse Fourier transform of these coefficients:
\(\eta(k)=\frac{1}{K} \sum_{k=0}^{K-1} a(u) e^{\frac{j 2 \pi u k}{K}}\) (24)
For 𝑘 = 0, 1, 2, 3. .𝐾 − 1, 𝑘 still ranges from 0 to 𝐾 − 1, i.e., the same number of points exists in the approximate boundary, but not as many terms are used in the reconstruction of each point.
3.4.3 Feature Selection
The FDs provide effective shape descriptors with efficient tradeoffs between the speed of recognition, accuracy, and the compactness of the representation. Additionally, few coefficients are sufficient to describe complex objects, which can be normalized to make them invariant to translation, scale, and rotation. In this study, ten FDs were applied to both the boundary pixels (BW-FD) and boundary chain code (CH-FD). Hence, the Fourier coefficients used only the first ten coefficients to compute the inverse as per Equation (25):
\(\eta(k)=\frac{1}{10} \sum_{u=0}^{9} a(u) e^{\frac{j 2 \pi u k}{10}}\) (25)
The FDs were then used as a dataset to train an ANN. The dataset contained catfish and noncat samples from which the FDs were extracted. Each sample consists of ten attributes described by the ten FDs.
3.5 Catfish Recognition using an ANN
The catfish recognition system was developed using a feedforward neural network (FFNN). The FFNN implemented in this study was based on a multilayer perceptron (MLP), which had the ten FDs as inputs, five hidden layers, and an output layer. The ANN parameters, i.e., the number of hidden neurons, the training cycle, and the training algorithm, were experimentally acquired to achieve optimal performance. Fig. 6 shows the designed ANN model.
Fig. 6. ANN recognition model consisting of an input layer, hidden layer, and output layer
Based on the design, the number of input parameters (k) is ten and the number of neurons in the hidden layer (j) is five. Thus, the input to output structure of the model is formulated as:
\(i_{j}=b_{1}+\sum_{i=1}^{k} w_{i j} \times F D_{i}\) (26)
where 𝑖𝑗 denotes the weighted sum of the j hidden neuron, 𝑏 denote the hidden neuron bias, 𝑤𝑖𝑗 is the synaptic weights of the neuron connection between the input and the hidden neuron, while 𝐹𝐷𝑖 is the input. The output of each hidden neuron is express as:
\(h_{j}=f\left(i_{j}\right)\) (27)
and the output layer neuron is given by:
\(O_{k}=b_{2}+\sum_{j=1}^{m} w_{j k} \times h_{j}\) (28)
where 𝑏2 is denote output neuron bias, 𝑤𝑗𝑘 is the synaptic weights of the neuron connection between 𝑚𝑡ℎ hidden neuron to the output neuron. The activation employed is tan sigmoid function, which limits the range of the output to 1 or 0, where 1 is the activator for catfish, and 0 is for non-catfish. The mathematical model of the function is given as:
\(f\left(O_{k}\right)=\frac{2}{1+e^{-2O_{k}}}-1\) (29)
where 𝑦 is the input and 𝑓(𝑂𝑘 ) is the output.
3.6 Catfish Counting Algorithm using Geometry
This study developed a new counting approach that is based on the geometry of the fish. This approach was used to estimate the possible number of fish in a cluster of connected or overlapped fish. Fig. 7 shows the counting algorithm.
Fig. 7. Fish counting algorithm flowchart
The first step in the counting method was to determine all of the areas of fish in the image, including the overlapped fish, by singly extracting them from the background. These obtained areas were used to form an array. The minimum area of the array was then estimated and used to determine the proportion by which each of the areas differed from the minimum area. Since the fish were of homogenous sizes, the difference in the area was assumed to be not more than 1.5 times the minimum area. Any area larger than 1.5 times the minimum area was considered an overlap. Further estimates were then performed on the overlapped fish to determine their possible number. Mathematically, this method can be expressed as follows:
The number of fish (𝜆) in an area is given by
\(\lambda\left\{\begin{array}{cl} 1 & \text { if } a<1.5(\min [A]) \\ 2 & \text { if } 1.5(\min [A])<a<2.5(\min [A]) \\ & \vdots & \vdots \\ & \quad: \quad: \\ k & \text { if }(k-0.5) \min [A]<a<(k+1.5) \min [A] \end{array}\right.\) (30)
where [A] is the array of the fish area, a is the area of fish in [A], and min[A] is the minimum area of fish in [A].
The total sum of fish (𝜑) is given as
\(\varphi=\sum_{i=1}^{N}\left(\lambda_{i}\right)\) (31)
where N is the number of elements in [A].
4. Performance Evaluation and Results
The performance of the recognition and counting algorithms was evaluated for sensitivity, specificity, and accuracy and then compared with the results obtained using the CH-FD and BD-FD approaches.
4.1 Image Pre-processing Performance Analysis
Fig. 8 shows the original image in RGB, which was first converted from RGB to gray level. The RGB was based on a coordinate system where each color appeared in its primary spectral components of red, green, and blue, represented by 24 bits. The gray level encodes the image using 8 bit/pixel data, which allows 256 different grey levels. A pixel value of 0 represents ‘black,’ while a pixel value of 255 represents white. Intermediate values between 0 and 255 represent the varying shades of gray. The simplicity provided by grayscale made it suitable for this study because the image processing used the concept of comparing region pixels [28]. Using grayscale data with real scalar algebraic operations was sufficient to detect the shapes required for this study. On the contrary, the use of RGB would require a more complex computation using an algebraic vector to differentiate colors.
Fig. 8. Original image in RGB
Fig. 9(a) shows the resulting image after conversion to the gray levels. The histogram of the gray level image in Fig. 9(b) revealed that most of the pixels were concentrated within the 100- to 200-pixel range. The contrast enhancement spread the pixel concentration from approximately 140 to the maximum 255, as shown in the histogram in Fig. 9(d). The contrast enhancement mapped the intensity values in the grayscale level image,𝐼 (𝑥, 𝑦), to new values, thus increasing the contrast of the output image, as shown in Fig. 9(c). This pre-processing step was utilized on more than one image and proved to be effective.
Fig. 9. Grayscale conversion and enhancement
4.1.1 Median Filter Performance Analysis
A median filter was further applied to smooth the noisy regions while preserving the structures of the boundaries of the fish image. At the edge boundary, the output pixel was computed such that a white pixel from a black region near the edge was not used in the computation. Likewise, a black pixel from an adjacent white region near the edge was not used in the computation of the output pixel because these alternating pixels found in the adjacent regions were noise.
Fig. 10(a) shows an unfiltered binary image with salt-and-pepper noise and blurred edges. Fig. 10(b) shows the effect of the median filter on the image; unlike smoothing using averaging, the median filter preserved the edge structures while simultaneously smoothing the uniform regions. The filter also removed the salt-and-pepper noise and most other small artifacts.
The complexity of the two operations, RGB to grey conversion and grey morphological operation, in the pre-processing are both linear and thus amount to O(2n), where n is the number of images. This means that the relationship between the input and the preprocessing operations done to complete its execution is linear. Thus, by ignoring the constant the final complexity is O(n)
Fig. 10. Effect of the median filter
4.2 Image Segmentation Algorithm Performance Analysis
The image segmentation processinvolved three steps: image binarization by Otsu thresholding, morphological operations, and contour detection. Segmentation was applied, as discussed in Section 3.0. Fig. 11(a) shows the binarization of the image, which resulted in the creation of holes, some minor noise, and cuts on the image that further thin the fish.
Fig. 11. Image segmentation
From the complement of the image in Fig. 11(b), the two fish at the top were joined with a thin line. Morphological operations were conducted to remove the thin line and holes and to fix the possible cuts, as shown in Fig. 12.
Fig. 12. Morphological operation on binary image.
The edge boundaries were successfully traced using contour detection and superimposed on the binary image, as shown in Fig. 13. The contour detection technique searched for boundary pixels with substantial intensity changes and operated based on the boundary consisting of a set of points that were connected and located on the outline of the object. The contour detector used the binary image as an input and computed the objects’ boundaries by hierarchically maintaining records of the holes inside the parent object. This information was extracted and traced onto each of the fish components, as shown in Fig. 13(a), (b), (c), and (d).
Fig. 13. Contour detection and tracing
The overall performance of the segmentation algorithm was determined using a supervised evaluation method. In supervised evaluation, a ground truth (GT) is generated, to which the segmented image (SI) is compared. In this study, the pixels of the GT—the image before segmentation—and the SI were extracted and compared. Fig. 14 shows a sample of the GT and SI.
Fig. 14. Sample GT and SI
The pixel in both the GT image and the SI was extracted, as shown in Table 1. The GT pixels in all samples were greater in number than those of the SI because the application of erosion during the segmentation process reduced the images’ pixels.
Table 1. Pixels of the detected GT and SI
Fig. 15 shows the segmentation performance against the GT. The red curve represents the GT, while the blue curve represents the segmented plot. This analysis revealed that the segmentation algorithm effectively segmented the image. The overall performance of the segmentation algorithm (ℇ) is the ratio of the pixel in the detected SI (𝜒) to the pixel in the GT (𝛶):
\(\varepsilon=\frac{\chi}{\gamma} \times 100\) (32)
Fig. 15. Segmentation algorithm performance
Hence, the performance of the segmentation algorithm using the detected pixels that matched the GT was 90.34 %, resulting from the morphological operation that was performed on the image to reduce the false connections between the fish.
Considering the complexity of the segmentation algorithm, the thresholding and morphological operations complexities are both O(n), while the edge segmentation has the complexity of O(n2). Therefore the overall complexity is O(n2)+O(2n). However, as the sample tends to infinity, the significance of O(2n) becomes negligible. Thus the segmentation algorithm complexity is O(n2)
4.3 ANN Fish Recognition Algorithm Performance Analysis
The ANN was trained with CH-FD and BD-FD. The dataset used contained 1368 images of Catfish and Non-catfish, as shown in Table 2. The training dataset was divided into 60% training, 20% validation, and 20% testing samples. These datasets for both the CH-FD and BD-FD were obtained from the image samples used previously.
Table 2. Datasets
The performance of the network classifier was measured in terms of accuracy, sensitivity, and specificity.
4.3.1 Performance analysis of the ANN recognition system using CH-FD
After training the network, the overall classification/recognition rate and accuracy of the network were evaluated. During the training, the network divided the input and the target data into three different sample types: training, validation, and testing. The training samples were used to train the network, and the weights were adjusted based on the output errors. The validation samples were used to measure the network generalization and halt training when the generalization stopped improving, while testing samples were used to independently measure the performance of the network after the training. The network was trained and tested using different threshold values, which varied from 0.1 to 1.0. For the training using CH-FD, the percentages of correctly classified catfish and non-catfish were 98.3% and 98.7%, respectively. Consequently, the optimal features for the training data yielded 98.6% accuracy, 98.7% sensitivity, and 98.3% specificity. For the CH-FD testing, the percentages of correctly classified catfish and non-catfish were both 100%. Thus, testing data yielded 100% for accuracy, sensitivity, and specificity. From the results of the experiments shown in Table 3, the highest accuracies were obtained at threshold 0.6 and 0.5. Even though 0.6 thresholds gave a better training result, but it takes about 13 epochs to generalize while 0.5 took about 7 epochs. Thus, 0.5 is adopted for the model and recorded 0.004088 MSE.
Table 3. CH-FD and BD-FD experimental results
4.3.2 Performance Analysis of the ANN using BD-FD
The BD-FD model optimal performance was attained at epoch 7 and 0.027086 MSE. The training results using the BD-FD data demonstrated that the optimal features yielded 97.5% accuracy, 95.0% sensitivity, and 100.0% specificity. The testing results show that the optimal features yielded 96.6% accuracy, 94.2% sensitivity, and 99.0% specificity. From the results of the experiments in Table 3, the highest testing accuracy of 96.6% was obtained at a threshold of 0.8.
Table 4 presents a comparison between the ANN performance using CH-FD and BD-FD. The CH-FD performed better in both training and testing with an accuracy of 98.5% and 100%, respectively. While the BD-FD recorded the performance of 97.5% and 96.6% for training and testing, respectively. Compacting the boundaries pixels using chain code improved the accuracy by normalizing and making the boundary pixel invariant to rotation, translation, and scaling. Conversely, the boundary pixels without the application of the shape representation scheme were not invariant to rotation, translation, and scaling and this affected the accuracy of the recognition. On the other hand, the training complexity of the ANN is estimated as O(n4 ) [29].
Table 4. ANN performance using CH-FD and BD-FD
4.4 Catfish Counting Algorithm Performance Analysis
The first step in the counting scheme was obtaining the pixel area of the fish in the image by extracting each area from the background, including the overlapped fish. Fig. 16 and 17 show the results of this step for two images. Fig. 16(b), (d), and (e) are the fish components of a single fish, while Fig. 16(c) contained overlap. Likewise, Fig. 17(c) and Fig. 17(d) each contained a single fish component, while Fig. 17(b) contained an overlapped component. These areas were stored in an array, and the set conditions from Section 3.0 were applied to obtain the catfish count.
Fig. 16. Counting Analysis
Fig. 17. Counting Analysis II
The areas of each extract were obtained and analyzed. Fig. 16 shows that the fish components A, B, C, and D had pixel area values of 4452, 3253, 8104, and 3975, respectively. The least pixels were in fish component B with a pixel area of 3253. Components A, D, and C were 1.37, 1.22, and 2.49 of component B and, hence, represented fish counts of one, one, and two, respectively. Resultingly, the total number of fish in sample 1, including the minimum area (component B), was five. Overlap only occurred with the two fish in component C.
Fig. 17 shows that the fish components A, B, and C had pixel area values of 7583, 1826, and 2351, respectively. The minimum pixels in the array was fish component B, with a pixel area of 1826. Components A and C were 4.15 and 1.28 of this minimum, and, therefore, represented fish counts of four overlapped fish and a fish, respectively. The total number of fish in sample 2, including the minimum area, component B, was therefore six. The overlap only occurred in component B with four fish.
Table 5 shows the overall result and performance of the counting algorithm. The counting demonstrated 100% accuracy for the two sample images because the fish in both images only overlapped side-by-side. The low water level in the container and the low number of fish contributed to the high accuracy
Table 5. Counting Algorithm Performance
Hence, the factors (𝜏) that affect accuracy can be summarized as the depth of water (ℎ) the population of fish in the container (𝑝) and the size of the container (𝑐). This can be expressed as follows:
\(\tau \alpha \frac{1}{p h c}\) (33)
The overall complexity of the proposed counting algorithm is estimated as O(4n). As the number of the n tends to infinity, the constant can be ignored, thus the complexity becomes O(n).
5. Conclusion
This study developed a catfish recognition and counting algorithm consisting of five steps: image acquisition, pre-processing, segmentation, feature extraction and recognition, and counting. The segmentation algorithm using detected pixels demonstrated 90.34% accuracy when compared to the GT, due to the morphological operation that was performed on the image to reduce the false connections between the fish. The boundary features from the SI were extracted using CH-FD and BD-FD and were then used as the dataset for training an ANN. The CH-FD method demonstrated 100% accuracy, while 96.6% accuracy was obtained by the BD-FD approach. These results show that compacting the boundary pixels using chain code improved the accuracy by normalizing and making the boundary pixels invariant to rotation, translation, and scaling. The boundary pixels without the application of this shape representation scheme were not invariant to rotation, translation, and scaling. The counting demonstrated 100% accuracy for the two sample images because the fish in both images only overlapped side-by-side. The low water level in the container and the low number of fish contributed to the high accuracy. Hence, the factors that affect accuracy can be summarized as the depth of water (ℎ), the population of fish in the container (𝑝), and the size of the container (𝑐). Despite the contribution of this paper, more experiments are needed to establish the optimal values regarding water depth, fish population and size of the container. Deep learning can also be explored to recognize overlap fish patterns from other possible objects or illumination that may affect recognition accuracy. As the developed counting algorithm requires at least a single fish that is not overlapped, further studies are required to eliminate the need for a single fish while maintaining high accuracy.
Acknowledgment
This work was supported in part by the TETFUND Institution-Based Research Intervention (IBRI) Fund of the Federal University of Technology, Minna, Nigeria. Reference No: TETFUND/FUTMINNA/2016-2017/6th BRP/01 and in part by Basic Science Research Program through the National Research Foundation of Korea(NRF) funded by the Ministry of Education (2017R1D1A1B03035988).
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