As the plasma current power in tokamak devices increases,a significant number of stray magnetic fields are generated around the equipment.These stray magnetic fields can disrupt the operation of electronic power devic...As the plasma current power in tokamak devices increases,a significant number of stray magnetic fields are generated around the equipment.These stray magnetic fields can disrupt the operation of electronic power devices,particularly transformers in switched-mode power supplies.Testing flyback converters with transformers under strong background magnetic fields highlights electromagnetic compatibility(EMC)issues for such switched-mode power supplies.This study utilizes finite element analysis software to simulate the electromagnetic environment of switched-mode power supply transformers and investigates the impact of variations in different magnetic field parameters on the performance of switched-mode power supplies under strong stray magnetic fields.The findings indicate that EMC issues are associated with transformer core saturation and can be alleviated through appropriate configurations of the core size,air gap,fillet radius,and installation direction.This study offers novel solutions for addressing EMC issues in high magnetic field environments.展开更多
The scanning interference field exposure technique is an effective method to fabricate holographic diffraction grating with meter-level size and nano-level precision.The main problems of fabricating large-aperture and...The scanning interference field exposure technique is an effective method to fabricate holographic diffraction grating with meter-level size and nano-level precision.The main problems of fabricating large-aperture and high-precision grating by this technique are the high-precision displacement measurement of the stage,the high-precision control of the interference fringe and the real time compensation of the grating phase error.In this paper,the influence of grating groove error on the wavefront aberration is analyzed.In order to improve the precision of the stage with displacement range more than one meter,an integrated displacement measurement combining grating sensing and laser interferometry is proposed,which suppresses the influence of environment on measurement precision under long displacement range.An interference fringe measurement method is proposed,which combines the diffraction characteristics of the measuring grating with the phase-shifting algorithm.By controlling the direction,period and phase nonlinear errors of the interference fringe,high quality interference fringe can be obtained.Further,a dynamic phase-locking model is established by using heterodyne interferometry to compensate grating phase error caused by stage motion error in real time.A grating with the aperture of 1500mm×420mm is fabricated.The wavefront aberration reaches 0.327λ@632.8 nm and the wavefront gradient reaches 16.444 nm/cm.This research presents a novel technique for the fabrication of meter-level size and nano-level precision holographic grating,which would further promote the development of chirped pulse amplification systems,high-energy laser and ultra-high precision displacement measurement.展开更多
We do theoretical research on using high-speed rail(HSR)as an active source to perform reverse time migration(RTM)and analyze the influence of the interferometric field on the seismic imaging results.When a train runs...We do theoretical research on using high-speed rail(HSR)as an active source to perform reverse time migration(RTM)and analyze the influence of the interferometric field on the seismic imaging results.When a train runs on a rail viaduct,the evenly spaced piers of the viaduct generate a nearly spherical interferometric wavefield with radically travelling waves in frequency-determined directions.We find that the directions span stationary areas of the interference phases,of which cross-talks deteriorating HSR seismic imaging can be well suppressed by stacking.Accordingly,we propose a method for performing RTM by employing HSR data.Numerical tests primarily verify the proposed method by use of 2 D and 3 D acoustic wave equations.Subsequently,we execute least square RTM to suppress crosstalk artifacts,further improving the imaging quality.At last,we stack images derived from trains with different velocities,which extends the frequency band,effectively overcoming the limit from the discrete spectrum of the source wavelet.展开更多
基金supported by the Natural Science Foundation of Anhui Province(No.228085ME142)the Comprehensive Research Facility for the Fusion Technology Program of China(No.20180000527301001228)the Open Fund of the Magnetic Confinement Fusion Laboratory of Anhui Province(No.2024AMF04003)。
文摘As the plasma current power in tokamak devices increases,a significant number of stray magnetic fields are generated around the equipment.These stray magnetic fields can disrupt the operation of electronic power devices,particularly transformers in switched-mode power supplies.Testing flyback converters with transformers under strong background magnetic fields highlights electromagnetic compatibility(EMC)issues for such switched-mode power supplies.This study utilizes finite element analysis software to simulate the electromagnetic environment of switched-mode power supply transformers and investigates the impact of variations in different magnetic field parameters on the performance of switched-mode power supplies under strong stray magnetic fields.The findings indicate that EMC issues are associated with transformer core saturation and can be alleviated through appropriate configurations of the core size,air gap,fillet radius,and installation direction.This study offers novel solutions for addressing EMC issues in high magnetic field environments.
基金supported by National Key R&D Program of China(2022YFB3606100)the National Natural Science Foundation of(62435019,52275554,U21A20509,61227901)+1 种基金CAS Project for Young Scientists in Basic Research(YSBR-103)Chinese Academy of Sciences Youth Innovation Promotion Association grant(2021220).
文摘The scanning interference field exposure technique is an effective method to fabricate holographic diffraction grating with meter-level size and nano-level precision.The main problems of fabricating large-aperture and high-precision grating by this technique are the high-precision displacement measurement of the stage,the high-precision control of the interference fringe and the real time compensation of the grating phase error.In this paper,the influence of grating groove error on the wavefront aberration is analyzed.In order to improve the precision of the stage with displacement range more than one meter,an integrated displacement measurement combining grating sensing and laser interferometry is proposed,which suppresses the influence of environment on measurement precision under long displacement range.An interference fringe measurement method is proposed,which combines the diffraction characteristics of the measuring grating with the phase-shifting algorithm.By controlling the direction,period and phase nonlinear errors of the interference fringe,high quality interference fringe can be obtained.Further,a dynamic phase-locking model is established by using heterodyne interferometry to compensate grating phase error caused by stage motion error in real time.A grating with the aperture of 1500mm×420mm is fabricated.The wavefront aberration reaches 0.327λ@632.8 nm and the wavefront gradient reaches 16.444 nm/cm.This research presents a novel technique for the fabrication of meter-level size and nano-level precision holographic grating,which would further promote the development of chirped pulse amplification systems,high-energy laser and ultra-high precision displacement measurement.
基金supported by the public High Preference Computer of Peking Universitysupported by the Program of Hebei Earthquake Science and Technology Spark Plan (Grant No. DZ20200827054)
文摘We do theoretical research on using high-speed rail(HSR)as an active source to perform reverse time migration(RTM)and analyze the influence of the interferometric field on the seismic imaging results.When a train runs on a rail viaduct,the evenly spaced piers of the viaduct generate a nearly spherical interferometric wavefield with radically travelling waves in frequency-determined directions.We find that the directions span stationary areas of the interference phases,of which cross-talks deteriorating HSR seismic imaging can be well suppressed by stacking.Accordingly,we propose a method for performing RTM by employing HSR data.Numerical tests primarily verify the proposed method by use of 2 D and 3 D acoustic wave equations.Subsequently,we execute least square RTM to suppress crosstalk artifacts,further improving the imaging quality.At last,we stack images derived from trains with different velocities,which extends the frequency band,effectively overcoming the limit from the discrete spectrum of the source wavelet.
