Frequency-modulated atomic force microscopy (FM-AFM; also called non-contact atomic force microscopy) is the prevailing operation mode in (sub-)atomic resolution vacuum applications. A major obstacle that prohibits a wider application range is the low frame capture rate. The speed of FM-AFM is limited by the low bandwidth of the automatic gain control (AGC) and frequency demodulation loops. In this work we describe a novel algorithm that can be used to overcome these weaknesses. We analysed the settling times of the proposed loops and that of the complete system, and we found that an approximately 70-fold improvement can be achieved over the existing real and virtual atomic force microscopes. We show that proportional - integral - differential controllers perform better in the frequency demodulation loop than conventional proportional - integral controllers. We demonstrate that the signal to noise ratio of the proposed system is 5.7 x 10~(-5), which agrees with that of the conventional systems; thus, the new algorithm would improve the performance of FM-AFMs without compromising the resolution.
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机译:调频原子力显微镜(FM-AFM;也称为非接触原子力显微镜)是(亚)原子分辨率真空应用中的主要操作模式。禁止广泛应用的主要障碍是帧捕获率低。 FM-AFM的速度受自动增益控制(AGC)和频率解调环路的低带宽限制。在这项工作中,我们描述了可以用来克服这些弱点的新颖算法。我们分析了提出的回路和整个系统的建立时间,发现与现有的真实和虚拟原子力显微镜相比,可以实现约70倍的改进。我们表明,比例-积分-差分控制器在频率解调环路中的性能要优于传统的比例-积分控制器。我们证明了该系统的信噪比为5.7 x 10〜(-5),与常规系统的信噪比一致。因此,新算法将在不损害分辨率的情况下提高FM-AFM的性能。
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