Spectrally controlled interferometry for high numerical aperture spherical cavity measurements

C. Salsbury, Donald A. Pearson, Artur Olszak
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Abstract

High numerical aperture optical elements are relied on for the most demanding applications in optical imaging but pose a significant challenge for conventional metrology techniques. Laser Fizeau interferometers provide a flexible measurement platform for measuring spherical optics by offering a common path configuration to test spherical optics against a convex reference surface. However, in this configuration, traditional piezoelectric transducer (PZT) based phase shifters produce non-uniform phase shifts which vary across the aperture as the spherical reference surface is translated along the optical axis. While these errors are negligible for low numerical aperture optics, the phase shift errors quickly become significant for high numerical aperture optics. The phase shift nonuniformity results in fringe print through and phase ripple artifacts which limit overall accuracy of phase shifted interferometry (PSI) measurements. Spectrally controlled interferometry (SCI) is a method which produces localized, high contrast interference fringes in non-zero optical path length cavities through tailored control of the sources spectral distribution. In addition to fringe location, fringe phase is also controlled through spectrum manipulation without mechanical motion or compensation. As a consequence, the SCI method produces uniform, full-aperture phase shifts with a high degree of linearity regardless of numerical aperture; thus, phase shift errors associated with traditional PZTs can be eliminated. Furthermore, because SCI is a source driven method, it can easily be integrated with any Fizeau interferometer. In this paper, we present the fundamental background for SCI and the advantages of the method as they apply to the measurement of high numerical aperture spherical optics. Additionally, we compare PSI measurements between a traditional laser Fizeau interferometer with PZT based phase shifters and an SCI Fizeau interferometer. Existing methods to this problem are discussed and compared with the presented SCI method, as well.
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高数值孔径球腔测量的光谱控制干涉测量
高数值孔径光学元件是光学成像中最苛刻的应用,但对传统的计量技术提出了重大挑战。激光菲索干涉仪提供了一个灵活的测量平台,通过提供一个共同的路径配置来测试球面光学对凸参考表面。然而,在这种配置中,传统的基于压电换能器(PZT)的移相器会产生不均匀的相移,当球面参考面沿着光轴平移时,相移会在孔径范围内变化。而这些误差是可以忽略不计的低数值孔径光学,相移误差迅速成为显著的高数值孔径光学。相移不均匀性导致条纹打印穿过和相纹伪影,限制了相移干涉测量(PSI)的整体精度。光谱控制干涉法是一种在非零光程长度的空腔中通过对光源光谱分布的定制控制而产生局部高对比度干涉条纹的方法。除了条纹位置外,还可以通过谱操作来控制条纹相位,而无需机械运动或补偿。因此,无论数值孔径如何,SCI方法都会产生均匀的全孔径相移,并且具有高度线性;因此,可以消除与传统压电陶瓷相关的相移误差。此外,由于SCI是一种源驱动方法,它可以很容易地与任何菲索干涉仪集成。本文介绍了SCI的基本背景,以及该方法应用于大数值孔径球面光学测量的优点。此外,我们比较了采用PZT移相器的传统激光菲索干涉仪和SCI菲索干涉仪之间的PSI测量结果。讨论了现有的方法,并与SCI方法进行了比较。
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