Quantitative multi-height phase retrieval via a coded image sensor

Multi-height phase retrieval introduces different object-to-detector distances for obtaining phase diversity measurements. In the acquisition process, the slow-varying phase information, however, cannot be converted to intensity variations for detection. Therefore, the low-frequency contents of the phase profile are lost during acquisition and cannot be properly restored via phase retrieval. Here, we demonstrate the use of a coded image sensor for addressing this challenge in multi-height phase retrieval. In our scheme, we add a coded layer on top of the image sensor for encoding the slow-varying complex wavefronts into intensity variations of the modulated patterns. Inspired by the concept of blind ptychography, we report a reconstruction scheme to jointly recover the complex object and the unknown coded layer using multi-height measurements. With both simulation and experimental results, we show that the recovered phase is quantitative and the slow-varying phase profiles can be properly restored using lensless multi-height measurements. We also show that the image quality using the coded sensor is better than that of a regular image sensor. For demonstrations, we validate the reported scheme with various biospecimens and compare the results to those of regular lensless multi-height phase retrieval. The use of a coded image sensor may enable true quantitative phase imaging for the lensless multi-height, multi-wavelength, and transport-of-intensity equation approaches.