2. Experimental apparatus

2.2. Two-directional simultaneous photography system

Figure 1 shows a schematic of the TDSP system (Islam et al. Reference Islam, Nakashima, Kobayashi, Nishino, Nakano, Hosoi, Ichimura, Islam, Shimizu, Fukui, Ohuchi, Terakado, Yoshikawa, Kohagura, Hirata, Ikezoe, Wang, Ichimura, Sakamoto and Imai2016; Yoshikawa et al. Reference Yoshikawa, Nakashima, Kohagura, Shima, Nakanishi, Takeda, Kobayashi, Minami, Ezumi and Sakamoto2022) and sub-millimetre hydrogen pellet injection system (Kawamori et al. Reference Kawamori, Tamano, Nakashima, Yoshikawa, Kobayashi, Cho, Ishii, Mase and Yatsu2000; Kubota et al. Reference Kubota, Yoshikawa, Nakashima, Kobayashi, Higashizono, Matama, Noto and Cho2007; Yoshikawa et al. Reference Yoshikawa, Nakashima, Kohagura, Shima, Nakanishi, Takeda, Kobayashi, Minami, Ezumi and Sakamoto2022) installed in the central cell. The TDSP system consists of wide-angle lenses, dual branch optical fibre bundles, a TV lens and a high-speed camera (MEMRECAM GX-1, NAC Inc.). The x-direction (vertical) and y-direction (horizontal) images were observed through the horizontal side port at z = 0 m and on the upper side port at z = −0.10 m, respectively. The frame rate, imaging size and bit depth of the high-speed camera were 20 000 fps, 320 × 240 pixels and 8 bits, respectively. Images in the vertical and horizontal directions were obtained in the same frame of the camera system. The pixel resolution was 6.5 × 10⁻³ m pixel⁻¹.

Figure 1. Schematic of the TDSP system, sub-millimetre hydrogen pellet injection system and multichannel microwave interferometer system in the central cell.

3. Tomography method for pellet ablation cloud

We used the ART for the tomography of the TDSP data of the pellet ablation cloud. ART is an iterative reconstruction technique (Guan & Gordon Reference Guan and Gordon1996; Zhang et al. Reference Zhang, Zhang, Gong, Ghasemlizadeh, Wang and Cao2014). It reconstructs an image from a series of angular projections, meaning that the projection of image intensities along a line extends radially in the direction of a specified angle (similar to a sinogram). One advantage of the ART is that a calculation program can be constructed relatively easily with a short calculation time. For two-dimensional (2-D) iterative methods, the reconstruction problem can be formulated as a linear algebraic problem:

(3.1)\begin{equation}\boldsymbol{WF} = \boldsymbol{P},\end{equation}

where F represents unknown image vector (N × 1) of N = n × n pixels, P represents projection vector (M × 1) of M rays and W represents system matrix (M × N) whose element w_ij denotes the weight coefficient representing the contribution of the jth pixel to the ith ray integral. The ART is an iterative procedure for solving (3.1). The reconstructed image elements of the jth pixel, f_j, are as follows:

(3.2)\begin{equation}f_j^{(k + 1)} = f_j^{(k)} + \lambda \frac{{{p_i} - \sum\limits_{j = 1}^N {f_j^{(k)}{w_{ij}}} }}{{\sum\limits_{j = 1}^N {w_{ij}^2} }}{w_{ij}},\quad k = 0,1,2,3, \ldots ,\end{equation}

where p _i represents the projection intensity of the ith ray, i represents k (mod M) + 1, k denotes the number of iterations and λ denotes the relaxation parameter. In the ART method, only one sample value p_i of the projection data is used for each iteration of the image update. ART can be considered an iterative solver of a system of linear equations, where a small choice of λ results in a long iteration time but can improve the signal-to-noise ratio of the output.

3.1. Checking the ART method

We validated the ART method by computing image reconstructions of images that simulated pellet ablation cloud images. Figures 2(a) and 2(b) show the mean squared error (MSE) against λ with iteration k = 100 and iteration number k with λ = 2.0, respectively. Figures 3(a) and 3(b) show the original image of the Gaussian profile and image reconstruction using the ART method with λ = 2.0 and iteration n = 30. The MSE of the reconstructed image relative to that of the original image was <0.1 %.

Figure 2. MSE against (a) λ and (b) iteration number k.

Figure 3. (a) Original image and (b) reconstructed image using the ART method.

3.2. 3-D image reconstruction

We calculated the 2-D reconstruction images of the pellet ablation cloud in the x–y planes at each z. This implied that they were pellet ablation cloud-sliced images along the z-direction. We then obtained the pellet ablation cloud in a 3-D form by presenting the same surface images. The 3-D images reconstructed from the two-directional images are shown in figure 4. The Gaussian profiles of the two-directional images showed a spherical shape in the surface intensity at 50 % of the maximum intensity of the image.

Figure 4. Reconstructed 3-D image.

4. Pellet injection experiments

The hydrogen plasma was produced and heated by the ion cyclotron range of the frequency wave from t = 51 to 440 ms and additional hydrogen gas puffing for the radiator gas in the D-module from t = 50 to 450 ms with a pressure of 750 mbar for the detached plasma experiment. The sub-millimetre pellet was injected into the central cell plasma at approximately t = 200 ms. The time evolutions of the diamagnetism and line density in the central cell are shown in figure 5, indicating the pellet injection time. Evidently, the electron line density drastically increased and diamagnetism decreased with pellet injection. Figure 6 shows the time-dependent radial profile of the electron density measured using a multichannel microwave interferometer system.

Figure 5. Time evolutions of diamagnetism and line density.

Figure 6. Time dependent radial profile of the electron density.

The electron density reached 7 × 10¹² cm⁻³ at t = 200.9 ms and the plasma density peak moved from approximately y = −2 cm at t = 200.5 ms to the positive side (approximately y = 5 cm) at t = 201.2 ms.

Figure 7 shows the pellet ablation cloud images observed by the TDSP system from t = (a) 200.75 ms to (l) 201.30 ms in intervals of 0.05 ms. As shown in figure 7, the vertical (left side) and horizontal (right side) wide-angle images were obtained in the same frames. The magnetic field directions and x-, y- and z-axes are shown in figure 7(a). As shown in the left-side images in figure 7, the pellet ablation clouds moved to the upper side frame-by-frame. As shown in the images on the right side, the pellet ablation clouds moved slightly from the centre of the plasma to the upper side. This result was comparable to that obtained using the multichannel interferometer system.

Figure 7. Pellet ablation cloud images measured by the TDSP from t = (a) 200.75 ms to (l) 201.30 ms.

Figure 8 presents the 3-D reconstructed images of the pellet ablation cloud surfaces of 60 % and 55 % of maximum intensity of the images at t = 200.80 ms in panel (b) to 201.25 ms in panel (k), and except at t = 201.00 ms in panel ( f), respectively. At t = 200.75 ms in panel (a) and 201.30 ms in panel (l), the ablation emission intensities were extremely small to show a surface intensity at 31 % and 24 %, respectively. The ablation cloud images of the surfaces used a higher intensity region in the reconstruction. This was because the image reconstructed using the ART method contained errors in the low-intensity region, such as diamond-shaped errors. This effect was eliminated from the low-intensity region.

Figure 8. 3-D reconstructed images of pellet ablation clouds from t = (a) 200.75 ms to (l) 201.25 ms.