When using a laser guide star (LGS) adaptive optics (AO) system, quasi-static aberrations are observed between the measured wavefronts from the LGS wavefront sensor (WFS) and the natural guide star (NGS) WFS. These LGS aberrations, which can be as much as 1200 nm RMS on the Keck II LGS AO system, arise due to the finite height and structure of the sodium layer. The LGS aberrations vary significantly between nights due to the difference in sodium structure. In this paper, we successfully model these LGS aberrations for the Keck II LGS AO system. We use this model to characterize the LGS aberrations as a function of pupil angle, elevation, sodium structure, uplink tip/tilt error, detector field of view, the number of detector pixels, and seeing. We also employ the model to estimate the LGS aberrations for the Palomar LGS AO system, the planned Keck I and the Thirty Meter Telescope (TMT) LGS AO systems. The LGS aberrations increase with increasing telescope diameter, but are reduced by central projection of the laser compared to side projection.
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机译:当使用激光导星(LGS)自适应光学(AO)系统时,在LGS波前传感器(WFS)和自然导星(NGS)WFS的测量波前之间会观察到准静态像差。这些LGS像差在Keck II LGS AO系统上可能高达1200 nm RMS,是由于钠层的高度和结构有限而引起的。由于钠结构的差异,夜间之间的LGS像差差异很大。在本文中,我们成功地为Keck II LGS AO系统建模了这些LGS像差。我们使用此模型将LGS像差表征为瞳孔角,仰角,钠结构,上行链路尖端/倾斜误差,探测器视场,探测器像素数和视线的函数。我们还使用该模型来估算Palomar LGS AO系统,计划中的Keck I和30米望远镜(TMT)LGS AO系统的LGS像差。 LGS像差随望远镜直径的增加而增加,但与侧面投影相比,由于激光的中央投影而降低。
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