Abstract
Phase shifting interferometric (PSI) techniques are among the most sensitive phase measurement methods. Owing to its high sensitivity, any minute phase change caused due to environmental instability results into, inaccurate phase measurement. Consequently, a well calibrated piezo electric transducer (PZT) and highly-stable environment is mandatory for measuring accurate phase map using PSI implementation. Here, we present an inverse approach, which can retrieve phase maps of the samples with negligible errors under environmental fluctuations. The method is implemented by recording a video of continuous temporally phase shifted interferograms and phase shifts were calculated between all the data frames using Fourier transform algorithm with a high accuracy ≤ 5.5 × 10-4 π rad. To demonstrate the robustness of the proposed method, a manual translation of the stage was employed to introduce continuous temporal phase shift between data frames. The developed algorithm is first verified by performing quantitative phase imaging of optical waveguide and red blood cells using uncalibrated PZT under the influence of vibrations/air turbulence and compared with the well calibrated PZT results. Furthermore, we demonstrated the potential of the proposed approach by acquiring the quantitative phase imaging of an optical waveguide with a rib height of only 2 nm and liver sinusoidal endothelial cells (LSECs). By using 12-bit CMOS camera the height of shallow rib waveguide is measured with a height sensitivity of 4 Å without using PZT and in presence of environmental fluctuations.vn.
Highlights
Digital holographic microscopy (DHM) is a quantitative phase imaging (QPI) technique that has the capability to record the complex wavefront of the light field interrogated with the specimen [ 1–3]
The strip waveguide is placed under the white light phase shifting interference microscopy (WL-PSIM) having 620 nm central wavelength bandpass filter into the white light beam path to record a time lapsed movie of of the five phase shifted interferograms using uncalibrated piezo electric transducer (PZT)
The interferometric movie of the waveguide is recorded without vibration isolation table under environmental fluctuation to capture phase shifted interferograms
Summary
Digital holographic microscopy (DHM) is a quantitative phase imaging (QPI) technique that has the capability to record the complex wavefront (amplitude as well as phase) of the light field interrogated with the specimen [ 1–3]. An off-axis digital interference microscopy can recover information related to specimen from a single interferogram, which makes it suitable to study dynamical behavior of biological cells or tissues [3,6,8] It utilizes maximum one-fourth of the detector’s bandwidth for the noise (DC and twin image) free phase recovery. Resolution of the reconstructed object field i s l imited i rrespective o f t he d etector’s c apability, w hich records diffraction limited information about the specimen To overcome this limitation, on-axis digital interference microscopy attracted strong attention of many researchers, which can utilize full resolving power of CCD/CMOS cameras [9]. It needs multiple phase shifted interferograms for noise (DC and twin image) free phase recovery of biological specimens at full detector resolution [9]
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