无拖曳控制是当前和未来若干空间任务中的一项关键技术.以重力梯度测量卫星为对象,对无拖曳控制回路进行深入剖析,包括对静电引力梯度仪、离子推力器和空间环境的模型与建模方法及无拖曳控制律设计方法的综述.借鉴GOCE卫星(gravity fiel...无拖曳控制是当前和未来若干空间任务中的一项关键技术.以重力梯度测量卫星为对象,对无拖曳控制回路进行深入剖析,包括对静电引力梯度仪、离子推力器和空间环境的模型与建模方法及无拖曳控制律设计方法的综述.借鉴GOCE卫星(gravity field and steady-state ocean circulation explorer)的成功经验并结合国内离子推力器和静电悬浮加速度计的研制现状,对未来发展我国重力梯度测量卫星无拖曳控制进行难点分析与展望.展开更多
In the standard model of particle physics, photons are massless particles with a particular dispersion relation. Tests of this claim at different scales are both interesting and important. Experiments in territory lab...In the standard model of particle physics, photons are massless particles with a particular dispersion relation. Tests of this claim at different scales are both interesting and important. Experiments in territory labs and several exterritorial tests have put some upper limits on photon mass, e.g., torsion balance experiment in the lab shows that photon mass should be smaller than 1.2 x 10-51g. In this work, this claim is tested at a cosmological scale by looking at strong gravitational lensing data available and an upper limit of 8.71 x 10-39g on photon mass is given. Observations of energy-dependent gravitational lensing with not yet available higher accuracy astrometry instruments may constrain photon mass better.展开更多
文摘无拖曳控制是当前和未来若干空间任务中的一项关键技术.以重力梯度测量卫星为对象,对无拖曳控制回路进行深入剖析,包括对静电引力梯度仪、离子推力器和空间环境的模型与建模方法及无拖曳控制律设计方法的综述.借鉴GOCE卫星(gravity field and steady-state ocean circulation explorer)的成功经验并结合国内离子推力器和静电悬浮加速度计的研制现状,对未来发展我国重力梯度测量卫星无拖曳控制进行难点分析与展望.
文摘In the standard model of particle physics, photons are massless particles with a particular dispersion relation. Tests of this claim at different scales are both interesting and important. Experiments in territory labs and several exterritorial tests have put some upper limits on photon mass, e.g., torsion balance experiment in the lab shows that photon mass should be smaller than 1.2 x 10-51g. In this work, this claim is tested at a cosmological scale by looking at strong gravitational lensing data available and an upper limit of 8.71 x 10-39g on photon mass is given. Observations of energy-dependent gravitational lensing with not yet available higher accuracy astrometry instruments may constrain photon mass better.
