Quantitative evaluation of light microscopes based on image processing techniques

Bioimaging Pub Date : 2001-05-11 DOI:10.1002/1361-6374(199809)6:3<138::AID-BIO4>3.0.CO;2-8

L R van den Doel, A D Klein, S L Ellenberger, H Netten, F R Boddeke, L J van Vliet, I T Young

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引用次数: 20

Abstract

In this note we will present methods based on image processing techniques to evaluate the performance of light microscopes. These procedures are applied to three different ‘high-end’ light microscopes. Tests are carried out to measure the homogeneity of the illumination system. From these tests it follows that Köhler illuminated images can have an exceedingly high amount of shading. Another result found from the illumination calibration is that traditional lamp housings are not designed to make fine-tuning easy. Next, the (automated) stage is considered. Several tests are performed to measure the stage motion in the xy-plane and in the axial direction to address accuracy, precision, and hysteresis effects. Finally, the entire electro-optical system is characterized by measuring the optical transfer function (OTF) at wavelengths 400 nm, 500 nm, 600 nm, and 700 nm. The results of these experiments show that there is a consistent deviation from the theoretical OTF at wavelengths around 400 nm. The final conclusion is that modern light microscopes perform better than their five-to-ten-year-old predecessors.

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基于图像处理技术的光学显微镜定量评价

在这篇文章中，我们将介绍基于图像处理技术的方法来评估光学显微镜的性能。这些程序适用于三种不同的“高端”光学显微镜。进行了测试以测量照明系统的均匀性。从这些测试可以得出Köhler照明图像可以有非常高的阴影量。从照明校准中发现的另一个结果是，传统的灯具外壳设计不容易进行微调。接下来，考虑(自动化)阶段。为了解决精度、精度和迟滞效应，在x平面和轴向上进行了几个测试来测量舞台运动。最后，通过测量400 nm、500 nm、600 nm和700 nm波长处的光学传递函数(OTF)对整个电光系统进行了表征。实验结果表明，在400 nm左右的波长处与理论OTF存在一致的偏差。最后的结论是，现代光学显微镜比5到10年前的前辈表现得更好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bioimaging

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