Application of Combinatorial Optimization in Shock Temperature
Inversion
ZHANG Ning-chao1, YE Xin1, LI Duo1, XIE Meng-qi1, WANG Peng1, LIU Fu-sheng2, CHAO Hong-xiao3*
1. College of Electronics and Information Engineering, Xi'an Technological University,Xi'an 710021, China
2. Institute of High Temperature and High Pressure Physics, Southwest Jiaotong University, Chengdu 610031, China
3. Northwest Institute of Mechanical & Electrical Engineering,Xianyang 712099,China
Abstract:The physical temperature of shock is an important parameter for weapon ammunition performance testing and the characterization of material states in extreme environments. Accurate acquisition of temperature has vital significance in the fields of national defence and industrial manufacturing. The shock process has characteristics of short duration, difficulty in contact-based measurements, and a wide temperature range, which can cause the failure of conventional temperature measurement methods. This paper proposes a temperature measurement method based on multi-spectral radiometry, which obtain the values of material radiation intensity. The inversion model based on Planck's radiation law can obtain the shock physical temperature value. In practice, the randomness of different target emissivity can cause large errors using the temperature inversion model. The emissivity model of the material during the shock process is more difficult to obtain. Meanwhile, the material's structure under shock may change in phase, which leads to a change in the emissivity model. Therefore, it is difficult to accurately obtain the shock physical temperature value by directly assuming the emissivity model. In this paper, the temperature calculation in multi-spectral temperature measurement experiments turned into a constrained optimization problem based on the constrained optimization theory. The temperature value obtained for each channel should be the same, limiting the object emissivity to a specific range. The constraint optimization algorithm calculates the target temperature and emissivity, which can overcome unknown emissivity for a shock physical temperature solution. At the same time, the combination of Equilibrium Optimizer and Sequential Quadratic Programming is applied to the solution of the temperature model, which avoids the shortcomings of poor stability and slow speed of a single algorithm. It improves the efficiency and accuracy of temperature inversion. The emissivity data of four common emissivity models at 3 000 K are simulated and verified. The results show that the temperature inversion error is less than 1%, and an inversion time is within 3 seconds. Finally, the temperature inversion of copper under shock compression is carried out using this algorithm. Compared with the Least Squares Method and Interior Point Penalty Function Method, the results indicate that the method proposed in this paper obtains the impact physical temperature value of copper more closely to the theoretical calculation. Therefore, this method provides an effective inversion approach for obtaining the physical temperature of other targets with unknown emissivity models.
张宁超,叶 鑫,李 多,解孟其,王 鹏,刘福生,钞红晓. 组合优化算法在冲击温度反演中的应用[J]. 光谱学与光谱分析, 2023, 43(12): 3666-3673.
ZHANG Ning-chao, YE Xin, LI Duo, XIE Meng-qi, WANG Peng, LIU Fu-sheng, CHAO Hong-xiao. Application of Combinatorial Optimization in Shock Temperature
Inversion. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3666-3673.
[1] Burrage K C, Perreault C S, Moss E K. High Pressure Research, 2019, 39(3): 489.
[2] Clayton J D. Contemporary Physics, 2019, 60(1): 97.
[3] Hamilton V E, Christensen P R, Kaplan H H, et al. Astronomy & Astrophysics, 2021, 650: A120.
[4] Ren H, Nie J, Dong J, et al. Earth and Space Science, 2021, 8(1): e2020EA001436.
[5] TANG En-ling, LI Zhen-bo, HAN Ya-fei, et al(唐恩凌, 李振波, 韩雅菲,等). Chinese Journal of Luminescence(发光学报), 2017, 38(7): 944.
[6] Flower W L. Combustion Science and Technology, 1983, 33(1-4): 17.
[7] YANG Yong-jun, WANG Zhong-yu, ZHANG Shu-kun, et al(杨永军, 王中宇, 张术坤, 等). Journal of Beijing University of Aeronautics and Astronautics(北京航空航天大学学报), 2014, 40(8): 1022.
[8] SUN Hong-sheng, LIANG Xin-gang, MA Wei-gang, et al(孙红胜, 梁新刚, 马维刚, 等). Infrared and Laser Engineering(红外与激光工程), 2022, 51(4): 20210985.
[9] SUN Xiao-gang, DAI Jing-min, CONG Da-cheng, et al(孙晓刚, 戴景民, 丛大成, 等). Journal of Infrared and Millimeter Waves(红外与毫米波学报), 2001,(2): 151.
[10] DAI Jing-min, SONG Yang, WANG Zong-wei(戴景民, 宋 扬, 王宗伟). Infrared and Laser Engineering(红外与激光工程), 2009, 38(4): 710.
[11] XING Jian, LIU Zhi-jun, HAN Bing, et al(邢 键,刘志军,韩 冰, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2023, 43(6): 1936.
[12] ZHANG Fu-cai, SUN Bo-jun, SUN Xiao-gang(张福才, 孙博君, 孙晓刚). Acta Optica Sinica(光学学报), 2019, 39(2): 0212008.
[13] Wen C D, Mudawar I. International Journal of Heat and Mass Transfer, 2005, 48(7): 1316.
[14] Daniel K, Feng C, Gao S. Measurement, 2016, 92: 218.
