This paper deals with the theory and calculation methods for compensation of the gradient in railway tunnels through theoretical analysis, numerical calculation, and statistic regression methods. On the basis of the p...This paper deals with the theory and calculation methods for compensation of the gradient in railway tunnels through theoretical analysis, numerical calculation, and statistic regression methods. On the basis of the principle that the resultant force is zero, the formula of the maximum calculated gradient was derived for the freight and passenger line and high-speed passenger special line. The formula of aerodynamic drag in tunnel is provided using the domestic and foreign relevant experimental investigations, and revised with modem train and engineering parameters. A calculation model of aerodynamic drag when the train goes through a single-tracked tunnel was built. Finally, the concept of maximum calculated gradient was adopted to revise the formula for compensation of the gradient in railway tunnels.展开更多
Magnetic interference represents the primary constraint on data accuracy in aeromagnetic gradient measurements.Focusing on superconducting quantum interference devices(SQUIDs),this study develops a magnetic gradient d...Magnetic interference represents the primary constraint on data accuracy in aeromagnetic gradient measurements.Focusing on superconducting quantum interference devices(SQUIDs),this study develops a magnetic gradient data compensation method utilizing single-channel signals from SQUID aeromagnetic gradiometers.The approach initiates with calculating the Earth's background reference magnetic field,its gradient field,and temporal variation rate within the flight platform's coordinate system,enabling compensation correction for three-component magnetometer data.These compensated fields subsequently facilitate single-channel gradiometer data compensation;the processed gradient data then undergoes low-pass filtering and quality evaluation.This systematic compensation framework achieves a root mean square(RMS)of 16 pT/m with an improvement ratio(IR)of 2.3×10^(3),effectively mitigating system and environmental noise across measurement platforms while significantly enhancing compensation accuracy and reliability for SQUID aeromagnetic gradiometers.展开更多
A high accuracy test of the weak equivalence principle(WEP) is of great scientific significance no matter whether its result is positive. We analyze the gravity gradient effect which is a main systematic error sourc...A high accuracy test of the weak equivalence principle(WEP) is of great scientific significance no matter whether its result is positive. We analyze the gravity gradient effect which is a main systematic error source in the test of WEP.The result shows that the uncompensated gravity gradient effect from the coupling term of the dominated gravity gradient multipole moment component q_(21) and the relative multipole field component Q_(21) contributes to an uncertainty of 1×10^(-11) on the E otv os parameter. We make a Q_(21) compensation to reduce the effect by about 20 times, and the limit of the test precision due to this coupling is improved to a level of a part in 10^(13).展开更多
文摘This paper deals with the theory and calculation methods for compensation of the gradient in railway tunnels through theoretical analysis, numerical calculation, and statistic regression methods. On the basis of the principle that the resultant force is zero, the formula of the maximum calculated gradient was derived for the freight and passenger line and high-speed passenger special line. The formula of aerodynamic drag in tunnel is provided using the domestic and foreign relevant experimental investigations, and revised with modem train and engineering parameters. A calculation model of aerodynamic drag when the train goes through a single-tracked tunnel was built. Finally, the concept of maximum calculated gradient was adopted to revise the formula for compensation of the gradient in railway tunnels.
基金supported by National Key Research and Development Program of China 2018YFC1406101。
文摘Magnetic interference represents the primary constraint on data accuracy in aeromagnetic gradient measurements.Focusing on superconducting quantum interference devices(SQUIDs),this study develops a magnetic gradient data compensation method utilizing single-channel signals from SQUID aeromagnetic gradiometers.The approach initiates with calculating the Earth's background reference magnetic field,its gradient field,and temporal variation rate within the flight platform's coordinate system,enabling compensation correction for three-component magnetometer data.These compensated fields subsequently facilitate single-channel gradiometer data compensation;the processed gradient data then undergoes low-pass filtering and quality evaluation.This systematic compensation framework achieves a root mean square(RMS)of 16 pT/m with an improvement ratio(IR)of 2.3×10^(3),effectively mitigating system and environmental noise across measurement platforms while significantly enhancing compensation accuracy and reliability for SQUID aeromagnetic gradiometers.
基金supported by the National Natural Science Foundation of China(Grant Nos.11575160 and 11605065)
文摘A high accuracy test of the weak equivalence principle(WEP) is of great scientific significance no matter whether its result is positive. We analyze the gravity gradient effect which is a main systematic error source in the test of WEP.The result shows that the uncompensated gravity gradient effect from the coupling term of the dominated gravity gradient multipole moment component q_(21) and the relative multipole field component Q_(21) contributes to an uncertainty of 1×10^(-11) on the E otv os parameter. We make a Q_(21) compensation to reduce the effect by about 20 times, and the limit of the test precision due to this coupling is improved to a level of a part in 10^(13).
