Application of compressed sensing technology in laser inertial confinement fusion
-
摘要: 激光驱动惯性约束聚变(ICF)研究是当前国际前沿科学中一个具有挑战性的研究领域,它以高能激光作为驱动源,在极短的时间内将大量能量注入靶丸中使聚变材料达到高温高密度的状态从而在靶丸中心形成热斑并引燃整个燃料层,最终实现可控核聚变。由于内爆热斑直径为50~100 μm,其持续时间为100~200 ps,离子温度达到5 keV,压力可达4.0×1016 Pa。因此,发展极端瞬态条件下的诊断技术具有重要意义。介绍了两种基于压缩感知技术的诊断方法,第一种是基于数字微镜阵列(DMD)进行编码的反射式可见光压缩感知技术,这种技术将现有的一维任意反射面速度干涉仪(VISAR)与压缩超快成像(CUP)系统相结合,有望实现一种全新的具有高时间分辨的二维VISAR诊断技术,将诊断维度从一维扩展至二维,同时它克服了现有的二维VISAR单幅成像的缺点,有望实现对内爆压缩过程流体力学不稳定性演化过程的连续诊断。由于基于DMD进行编码的反射式可见光压缩感知技术只能用于可见光波段,无法用于紫外与X光波段,为此还发展了一种透射式压缩感知技术。这种透射式压缩感知技术采用一种新颖的透射式元件实现对待测信号的编码,可以实现对紫外和X光波段信号的二维超快探测,有望实现对内爆热斑超快时空演化过程进行精密诊断。此外,针对单通道CUP技术的高时间分辨的优势和低空间分辨的不足,还提出了多通道编码、分别扫描、解码、再合成的全新的高时空分辨诊断系统基本思路,有望实现高时间分辨的同时,实现高空间分辨的二维新型诊断技术。Abstract: Laser driven inertial confinement fusion is a challenging research field in the current international frontier science, which uses high-energy laser as the driving source. A large amount of energy is injected into the target pellet to make the fusion material reach the state of high temperature and high density in a very short time, thus forming a hot spot in the center of the target pellet and igniting the whole fuel layer, and finally achieving controlled nuclear fusion. As the diameter of the implosion hot spot is about 50−100 μm, and its duration is 100−200 ps, the ion temperature reaches 5 keV, and the pressure can reach 4.0×1016 Pa. Therefore, it is of great significance to develop diagnostic techniques under extreme transient conditions. In this paper we introduce two kinds of diagnosis method based on compressed sensing. The first one combines the one-dimensional line Velocity interferometer system for any reflectors (VISAR) with the Compressed Ultrafast Photography (CPU) system, which is expected to achieve a new 2D-VISAR diagnostic technique with high time resolution. At the same time, it overcomes the shortcomings of the existing two-dimensional VISAR that can only capture single image and is expected to realize continuous diagnosis of the evolution of hydrodynamic instability. Because the existing CUP technology encoded by digital micromirror device can only be used in the visible light band, and cannot be used in the ultraviolet and X-ray band, a transmission compressed sensing technology is also developed. The transmission compressed sensing technology uses a novel transmission element to encode the measured signal, which can realize the two-dimensional ultrafast detection of ultraviolet and X-ray signals, and is expected to realize the precise diagnosis of the ultra-fast space-time evolution process of the hot spots in the explosion. In addition, in view of the advantages of single-channel CUP technology with high time resolution and the shortcomings of low spatial resolution, a new high spatial resolution diagnosis system with multi-channel coding, separate scanning, decoding and re-synthesis is proposed, which is expected to achieve high time resolution and high spatial resolution of the two-dimensional new diagnostic technology.
-
图 3 实验中实测编码压缩图和解码重构结果
Figure 3. The measured result in experiment and the reconstruction result
图 7 静态编码图像
Figure 7. Static image of the encoding pattern with and without graphics mask of Li (a) without graphics mask (b) with graphics mask
-
[1] Hurricane O A, Callahan D A, Casey D T, et al. Inertially confined fusion plasmas dominated by alpha-particle self-heating[J]. Nature Physics, 2016, 12(8): 800-806. doi: 10.1038/nphys3720 [2] Meezan N B, Edwards M J, Hurricane O A, et al. Indirect drive ignition at the National Ignition Facility[J]. Plasma Physics and Controlled Fusion, 2017, 59: 014021. doi: 10.1088/0741-3335/59/1/014021 [3] Kline J L, Batha S H, Benedetti L R, et al. Progress of indirect drive inertial confinement fusion in the United States[J]. Nuclear Fusion, 2019, 59: 112018. doi: 10.1088/1741-4326/ab1ecf [4] Clark D S, Weber C R, Milovich J L, et al. Three-dimensional modeling and hydrodynamic scaling of National Ignition Facility implosions[J]. Physics of Plasmas, 2019, 26: 050601. doi: 10.1063/1.5091449 [5] 陈伯伦, 蒋炜, 景龙飞, 等. 再发射技术测量SGⅡ黑腔靶早期对称性[J]. 强激光与粒子束, 2013, 25(2):385-388. (Chen Bolun, Jiang Wei, Jing Longfei, et al. Re-emission technique for early time, hohlraum radiation symmetry measurements on SG Ⅱ facility[J]. High Power Laser and Particle Beams, 2013, 25(2): 385-388 doi: 10.3788/HPLPB20132502.0385 [6] 黎航, 蒲昱东, 景龙飞, 等. 间接驱动的内爆不对称性随腔长和时间变化的研究[J]. 物理学报, 2013, 62:225204. (Li Hang, Pu Yudong, Jing Longfei, et al. Variations of implosion asymmetry with hohlraum length and time in indirect-drive inertial confinement fusion[J]. Acta Physica Sinica, 2013, 62: 225204 doi: 10.7498/aps.62.225204 [7] 董建军, 曹柱荣, 杨正华, 等. 辐射驱动内爆流线实验测量[J]. 物理学报, 2012, 61:155208. (Dong Jianjun, Cao Zhurong, Yang Zhenghua, et al. Measurement of implosion trajectory for hohlraum-radiative-driven[J]. Acta Physica Sinica, 2012, 61: 155208 doi: 10.7498/aps.61.155208 [8] Li Yaran, Dong Jianjun, Xie Qing, et al. Development of a polar-view Kirkpatrick-Baez X-ray microscope for implosion asymmetry studies[J]. Optics Express, 2019, 27(6): 8348-8360. doi: 10.1364/OE.27.008348 [9] Nagel S R, Hilsabeck T J, Bell P M, et al. Investigating high speed phenomena in laser plasma interactions using dilation x-ray imager (invited)[J]. Review of Scientific Instruments, 2014, 85: 11E504. doi: 10.1063/1.4890396 [10] Hilsabeck T J, Nagel S R, Hares J D, et al. Picosecond imaging of inertial confinement fusion plasmas using electron pulse-dilation[C]//Proceedings of SPIE 10328, Selected Papers from the 31st International Congress on High-Speed Imaging and Photonics. Osaka: SPIE, 2017: 103280S. [11] Shiraga H. Review of concepts and applications of image sampling on high-speed streak cameras[C]//Proceedings of SPIE 10328, Selected Papers from the 31st International Congress on High-Speed Imaging and Photonics. Osaka: SPIE, 2017: 103280R. [12] Nagel S R, Bell P M, Bradley D K, et al. Fielding DIXI - a new x-ray framing camera for the NIF - at JLF[R]. LLNL-PRES-617852. [13] Engelhorn K, Hilsabeck T J, Kilkenny J, et al. Sub-nanosecond single line-of-sight (SLOS) x-ray imagers (invited)[J]. Review of Scientific Instruments, 2018, 89: 10G123. doi: 10.1063/1.5039648 [14] Theobald W, Sorce C, Bedzyk M, et al. The single-line-of-sight, time-resolved X-ray imager diagnostic on OMEGA[J]. Review of Scientific Instruments, 2018, 89: 10G117. doi: 10.1063/1.5036767 [15] Donoho D L. Compressed sensing[J]. IEEE Transactions on Information Theory, 2006, 52(4): 1289-1306. doi: 10.1109/TIT.2006.871582 [16] Gao Liang, Liang Jinyang, Li Chiye, et al. Single-shot compressed ultrafast photography at one hundred billion frames per second[J]. Nature, 2014, 516(7529): 74-77. doi: 10.1038/nature14005 [17] Lai Yingming, Xue Yujia, Côté C Y, et al. Single-shot ultraviolet compressed ultrafast photography[J]. Laser & Photonics Reviews, 2020, 14: 2000122. [18] Dong Chao, Loy C C, He Kaiming, et al. Image super-resolution using deep convolutional networks[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2016, 38(2): 295-307. doi: 10.1109/TPAMI.2015.2439281 [19] Conkey D B, Caravaca-Aguirre A M, Dove J D, et al. Super-resolution photoacoustic imaging through a scattering wall[J]. Nature Communications, 2015, 6: 7902. doi: 10.1038/ncomms8902 [20] Daubechies I, Defrise M, De Mol C. An iterative thresholding algorithm for linear inverse problems with a sparsity constraint[J]. Communications on Pure and Applied Mathematics, 2004, 57(11): 1413-1457. doi: 10.1002/cpa.20042 [21] Bioucas-Dias J M, Figueiredo M A T. A new twist: two-step iterative shrinkage/thresholding algorithms for image restoration[J]. IEEE Transactions on Image Processing, 2007, 16(12): 2992-3004. doi: 10.1109/TIP.2007.909319 -
下载:
点击查看大图
图(9)
计量
- 文章访问数: 1941
- HTML全文浏览量: 412
- PDF下载量: 113
- 被引次数: 0
