3.1. Mathematical morphology

Mathematical morphology is a tool for extracting image components that are useful for representation and description (Haralick, Sternberg, & Zhuang Reference Haralick, Sternberg and Zhuang1987). The basic idea is by means of the structure of a certain morphology to measure and extract the corresponding shape of an image. Compared with the differential operator to extract edges, this method has following advantages: it is not so sensitive to noise as differential operator, meanwhile the recognised edges are smooth, continuous, and have less breakpoints.

The two basic morphological set transformations are erosion and dilation. These transformations involve the interaction between an image I (the object of interest) and a structuring set B, called the SE. A lot of other morphological operations are derived from them. In the following, erosion, dilation, closing, opening, and Bot-hat transformation will be introduced.

1. (1) Erosion

   To obtain the minimum grey value of the original image I minus the one of the block B, erosion operation is defined as follows:

   $$\begin{equation*} I\ominus B\! =\! \min \lbrace I(x+x^{\prime },y+y^{\prime })\, {-}\, B(x^{\prime },y^{\prime })|(x^{\prime },y^{\prime })\in D_b\rbrace . \end{equation*}$$

   Here, D_b is the neighbourhood block.

2. (2) Dilation

   Dilation is to obtain the maximum grey value of the original image plus the one of block. It is defined as follows:

   $$\begin{equation*} I\oplus B\! =\! \max \lbrace I(x-x^{\prime },y-y^{\prime })\, {+}\, B(x^{\prime },y^{\prime })|(x^{\prime },y^{\prime })\in D_b\rbrace . \end{equation*}$$

   Here, D_b mean the same as in (1).

3. (3) Closing

   Closing operation is a process of dilation followed by erosion. It is defined as follows:

   $$\begin{equation*} I\bullet B = (I\oplus B)\ominus B. \end{equation*}$$

   It is employed to fill small holes, with objects connect the adjacent objects and smooth the boundaries of the images.

4. (4) Opening

   Opening generally smooths a contour in an image, breaking narrow isthmuses and eliminating thin protrusions. It is defined as follows:

   $$\begin{equation*} I\circ B = (I\ominus B)\oplus B. \end{equation*}$$

5. (5) Bot-hat transformation

   Bot-hat transformation is a subtraction of the original image and the closing image, it is defined as follows:

   $$\begin{equation*} T = I - (I\oplus B)\ominus B. \end{equation*}$$

   T shows a grey valley in the original image, and highlights the boundaries between connected objects. It is able to extract dark pixels from a bright background.

3.2. Otsu algorithm

Otsu algorithm is a way to search an adaptive threshold, proposed by Otsu (Reference Otsu1979), whose idea is to divide an image into two parts: background and objective with a sharp discrepancy. The more different the two parts are, the sharper the discrepancy is. Part of the objectives wrongly divided into the background will make the discrepancy smaller. Therefore, the sharpest discrepancy means minimum probability of erroneous division. The calculation principle is as follows.

Now suppose that we dichotomise the pixels of the image I(x, y) into two classes (objects and background) by a threshold T, the objects and background pixels numbers are N ₁ and N ₂, respectively. The image size is indicated by M × N, the percentage of the objects pixel number is ω₁, the percentage of the background ones is ω₂, then we can easily verify the following relation:

(1) $$\begin{equation} \omega _1 = \frac{N_1}{M\times N} \end{equation}$$\\

(2) $$\begin{equation} \omega _2 = \frac{N_2}{M\times N} \end{equation}$$\\

(3) $$\begin{equation} N_1 + N_2 = M\times N \end{equation}$$\\

(4) $$\begin{equation} \omega _1 + \omega _2 = 1. \end{equation}$$

ω₁ and ω₂ are the objects and background area probabilities, respectively (Sezgin et al. Reference Sezgin2004).

The objects and the background average grey values are shown by μ₁ and μ₂, respectively. The image average grey value is then by μ

(5) $$\begin{equation} \mu = \mu _1 \times \omega _1 + \mu _2 \times \omega _2. \end{equation}$$

It is the total mean level of the original picture.

g is given by

(6) $$\begin{equation} g = \omega _1\times (\mu - \mu _1)^2 + \omega _2\times (\mu - \mu _2)^2. \end{equation}$$

It represents the variances between objects and background. Substituting Equation (5) into (6) gives

(7) $$\begin{equation} g = \omega _1 \times \omega _2 \times (\mu _1 - \mu _2)^2. \end{equation}$$

Iterating all possible pixel values at the threshold T, the value which makes g the biggest will be the result.

4.1. Extraction of solar limb

To calculate sunspot positions and areas on the solar disk, we must determine the solar centre and radius. This is achieved by extracting the solar limb. A procedure based on a morphological method and Otsu algorithm is designed. The steps are as follows (Figure 1):

1. (1) The first step is to remove sunspots and noises on the solar disk to get a clean solar disk. This is achieved by applying a closing operation (first dilation then erosion) with a structuring element (SE) to the original image in Figure 1(a). When this SE is larger than sunspots and noises, the closing operation will be able to remove them. The biggest sunspot in hundreds of images is chosen, and its radius calculated to be 30 pixels, so the SE radius is set to be 30. Then a clean solar disk is gotten in Figure 1(b).

2. (2) The second step is to shrink the solar disk in Figure 1(b). To do this, an erosion operation is employed by using an SE. This SE radius is set to be 1 pixel so as to make the radius of the solar disk 1 pixel smaller, then a shrunk solar disk is shown in Figure 1(c).

3. (3) To get the solar limb, Figure 1(c) is subtracted from Figure 1(b) and 1(d) is gotten.

4. (4) The following step is to get the pixel position of the solar limb. Otsu algorithm is applied to segment Figure 1(d), and a binary image is gotten in Figure 1(e), on which the white pixels are the position of the solar limb.

5. (5) In Figure 1(e), some CCD noises often exist near image border. In order to separate them from the solar limb, a criterion is made, that is as follows:

   Figure 1(e) is set to I, and its size is M × N, a pixel in the image is set to I(x, y), if $(\frac{N}{2} - y)^2 + (\frac{M}{2} - x)^2 > M^2$ , then I(x, y) = 0.

   Then CCD noises will be removed from Figure 1(e).

6. (6) In the final step, the white pixel positions in Figure 1(e) are extracted and saved for X and Y arrays, then least square fitting method is used to arrays X and Y to create a circle which is considered to be the solar limb. It is labelled with red colour and overlapped on the original image shown in Figure 1(f.)

Figure 1. A sample of the solar limb extraction in HSOS full-disk photospheric images: (a) the original image; (b) the clean image; (c) the image shrunk of the solar disk, the radius is 1 pixel smaller than that in (b); (d) the solar limb shown in grey image; (e) the solar limb shown in the binary image; (f) the solar limb labelled in red and overlapped on (a).

4.2. Recognition of sunspots

Once the solar limb is extracted, we can recognise the sunspots in its interior. Due to the limited resolution of data, the sunspot umbra and penumbra could not be separated in HSOS images, so they will be treated as a whole in the processing. The recognition of sunspots is achieved by the following steps (Figure 2):

1. (1) Pre-processing: the method in Wang, Su, & Zhang (Reference Wang, Su and Zhang2008) is employed to pre-process the original image and Figure 2(a) is gotten.

2. (2) The second step is to get the gradient of the boundaries of sunspots and noises on Figure 2(a). First, a closing operation with the SE radius of 30 pixels is applied in Figure 2(a), which is larger than the radiuses of sunspots and noises so as to remove them, the definition of this SE is the same with the method in the first step of Section 4.1, and a clean solar image in Figure 2(b) is available. Then Figure 2(a) is subtracted from Figure 2(b), the gradient is shown in the resulting image of Figure 2(c).

3. (3) The third step is to separate the gradient of sunspots from noises in Figure 2(c). Here, the definition of threshold is the key, it depends on the darkness of Figure 2(c). By tests and statistics, the suitable value is 20% of the intensity range of Figure 2(c). But due to solar limb darkening, the sunspots gradient is lower at the solar limb, we make this threshold smaller to be 15% on the region of 0.8R of the solar disk (R represents the solar radius). Then sunspots candidate regions are gotten in Figure 2(d).

4. (4) The final stage is to acquire sunspots from candidates in Figure 2(d). We consider the candidates as verified sunspots in which the difference between the max grey value of a pixel and the min one is bigger than 5, and other regions are discarded.

5. (5) The sunspots are labelled in red and superimposed on the original image. The result is shown in Figure 2(e).

Figure 2. The procedure of sunspot recognition in HSOS full-disk photosphere images: (a) the original image; (b) the clean image; (c) the gradient on the image; (d) the binary image showing sunspots candidates; (e) recognised and superimposed sunspots on the original image.

4.3. Sunspots recognition in images with instrument noises

As mentioned in the first paragraph, the instrument noises which appear in HSOS images make the previous methods not work well. So this procedure is used to test the effect of the recognisation of the sunspots. The result is shown in Figure 3, in which we can see the procedure performs well for these images.

Figure 3. (a) The original image disturbed by instrument noises; (b) the clean image without sunspots; (c) the gradient on the image; (d) the binary image showing sunspots candidates; (e) recognised and superimposed sunspots on the original image.