The analysis of inertial confinement fusion (ICF) plasma diagnostic pictures is crucial for fusion energy research. In this paper, a method based on the combination of deep reinforcement learning and computer vision techniques is proposed for the analysis of ICF plasma diagnostic pictures. The method first preprocesses the images using computer vision techniques and then uses deep reinforcement learning to classify and recognise them. The physical quantities are closer to the theoretical values using the new method, which is more instructive for the experiments. For example, at the radiation temperature, the obtained values are increased by 20-70 eV, and at the electron and plasma temperatures are close to the theoretical 5 KeV. at the same time the neutron yield is increased by a factor of 10. The experimental results show that the method has high accuracy and efficiency in the analysis of ICF plasma diagnostic pictures, and can effectively assist fusion research.
Nuclear fusion is a form of energy release that has received a lot of attention as it can free mankind from fossil fuels. However, the fusion process requires strict monitoring and measurement to ensure the reliability and safety of the reaction. Conventional fusion diagnostic devices suffer from problems such as low data credibility, data security and privacy protection, which may lead to inaccurate diagnostic results and thus threaten the stability and safety of the reaction. Therefore, how to solve these problems is an urgent issue at present. Blockchain technology is a distributed database technology, which has the characteristics of decentralisation, non-tampering and traceability. Blockchain technology has been widely used in finance, logistics, medical and other fields. In this paper, we will explore how to use blockchain technology to solve the problems of nuclear fusion diagnostic devices and improve the credibility and safety of nuclear fusion diagnosis. In this paper, a blockchain platform will be built to integrate mainly thermal imaging, mass spectrometer and neutron measurement data in fusion diagnostics. These data are stored on the blockchain using a consensus algorithm and establishing a multi-node mechanism. This prevents the data from being tampered with and can be traced at the same time. In terms of processing speed, due to the centralization and unification of the data and the nature of the consensus algorithm, the speed of processing data can be increased by several orders of magnitude through blockchain technology.
Metaverse is a virtual blockchain technology-based world that combines real-world data and digital assets with a virtual world. The emergence of Metaverse provides new methods and ideas for the physical design of fusion ignition. This paper focuses on the concept, characteristics, and application of meta-universe in the physical design of fusion ignition. This paper firstly introduces the basic principles and challenges of fusion ignition, then details the concepts and technical characteristics of meta-universe, and finally describes the application of meta-universe in Z-FFR (Z-pinch driven fusion-fission hybrid reactor) physical design, including data sharing, virtual simulation, intelligent contracts, and other aspects. In this study, the performance of the device was significantly improved by a meta-universe-driven design. The design cycle was dramatically shortened, the device durability was increased by a factor of 10, 000, and the delay jitter was reduced to 1-2 ns. At the same time, the neutron yield was increased by more than two orders of magnitude in terms of fusion physics. This paper argues that the emergence of meta-universe will further promote the physical design of fusion ignition and improve design efficiency and reliability.
Energy is a matter of economic security and national security. Research into fusion-fission hybrid reactors began in the 1950s with the original idea of using fusion neutrons to multiply fissionable nuclides (239 Pu, 233 U) from fissionable nuclides (238 U, 232 Th) and to amplify the fusion energy output in the process. The Z-FFR (Z-Pinch driven fusion fission hybrid reactor) contains two physical processes, fusion and fission, and is inherently complex in structure. The Z-FFR requires a larger number of disciplines and software platforms for its physical design. The original overall physical design was split between modules and confusing software choices, thus making it difficult to couple the Z-FFR in its overall design. The architecture design platform for multi-user massively parallel development conducts research on product integration and parallel development of architecture design software platforms to solve the integration of products from different software platforms and collaborative design of architecture design software. This will solve the coupling and linking between different physical processes and different design software in the design process of Z-FFR, and achieve the overall design optimal solution.
Thermonuclear fusion is the use of nuclear fusion reactions to produce energy. With higher energy density and less nuclear waste production than nuclear fission, thermonuclear fusion is considered to be a safer and more sustainable source of energy. However, the extreme conditions required to achieve thermonuclear fusion, such as high temperatures and densities, pose significant challenges to the design, construction and operation of fusion reactions. To overcome these challenges, iterative integrated design with training in thermonuclear fusion modelling and simulation has emerged as an important approach. With the continuous development of the crossover between artificial intelligence and physical design, combined with the powerful fitting capabilities of deep neural networks, deep learning was born, which utilises the highly anthropomorphic features of deep learning (DL) to learn itself through constant interaction and trial and error with the controlled object. Deep reinforcement learning has received great attention for its highly anthropomorphic features, pointto-point design ideas, and low a priori dependence. In this paper, deep learning is used to train and iterate on thermonuclear fusion models and their visualisation simulations to quickly obtain parameters for fusion reactions, significantly shortening the development cycle and providing more options and possibilities for the design and optimisation of fusion reactions, thus avoiding unnecessary costs and waste. The integrated design of thermonuclear fusion modelling and simulation training and iteration provides strong support for the research and application of thermonuclear fusion technology.
Inertial confinement fusion (ICF) is an approach to fusion that relies on the inertial of the fuel mass to provide confinement. Conditions under which inertial confinement is sufficient for efficient thermonuclear burn, a capsule (generally a spherical shell) containing different materials and thermonuclear fuel is compressed in an implosion process to conditions of high density and temperature. Another important process is the energy transport, in which the hohlraum coupling effect and hohlraum radiation uniform are the important physical parameters that can limit the energy transport. It is described the ignition condition by different physical parameters. Because the physical processes in fusion ignition are complex, and more physical quantities in the existence of multiple correlations and strong correlations, a single model often can not cope with fusion physics, this paper uses artificial intelligence, combined with complex physical processes, repeated model combination and iteration, to obtain the fusion materials model combination method, to provide an optimal parameter library for experimental physics. In this paper, we obtain the neutron yield of the main fuel DT can reach 1020, which indicates that the aim of achieving fusion can be achieved.
The Z-FFR (Z-Pinch driven Fusion Fission hybrid Reactor) contains two physical processes, nuclear fusion and nuclear fission, and has a complex structure itself. Using artificial intelligence and big data technology to construct the digital Z-FFR, a decision decomposition method for writing the source code of the digital Z-FFR (Z-Pinch driven fusion fission hybrid reactor) by an artificial intelligence programmer is also proposed, including the following steps: using big data to build a normalized description of the digital Z-FFR; based on the normalized description of the digital Z- FFR, a dimensional decomposition method is used to split the digital Z-FFR modeling, digital Z-FFR simulation and digital Z-FFR writing structure to obtain the decision splitting set of digital Z-FFR. The decision selection method is determined according to the digital Z-FFR decision splitting set and the digital Z-FFR source code writing is completed. The decision splitting method for writing digital Z-FFR source code with artificial intelligence and big data proposed in this paper decomposes the writing logic of digital Z-FFR and uses different artificial intelligence decision methods to complete the writing of digital Z-FFR source code according to different writing logics, which overcomes the disadvantages of long development cycle, repetitive development workload and high learning cost of various existing simulation systems.
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