Interactive zoom display in smartphone-based digital holographic microscope for 3D imaging

TL;DR

This paper presents a low-cost, smartphone-based digital holographic microscopy system capable of real-time 3D imaging with interactive zoom, suitable for biological and remote diagnostics.

Contribution

It introduces a compact, inexpensive DHM system integrating 3D printing, smartphone reconstruction, and real-time zoom functionality, advancing portable 3D holographic imaging technology.

Findings

Successfully reconstructed amplitude and phase information in real time.

Enabled interactive zoom using touchscreen gestures.

Demonstrated potential for biological and remote diagnostics.

Abstract

Digital holography has applications in bio-imaging because it can simultaneously obtain the amplitude and phase information of a microscopic sample in a single shot, thus facilitating non-contact, noninvasive observation of the 3D shape of transparent objects (phase objects, which can be mapped with the phase information,) and moving objects. The combination of digital holography and microscopy is called digital holographic microscopy (DHM). In this study, we propose a smartphone-based DHM system for 3D imaging that is compact, inexpensive, and capable of observing objects in real time; this system includes an optical system comprising a 3D printer using commercially available image sensors and semiconductor lasers; further, an Android-based application is used to reconstruct the holograms acquired by this optical system, thus outlining the amplitude and phase information of the observed object. Also, by utilizing scalable diffraction calculation methods and touchscreen interaction, we implemented zoom functionality through pinch-in gestures. The study results showed that the DHM system successfully obtained the amplitude and phase information of the observed object via the acquired holograms in an almost real time manner. Thus, this study showed that it is possible to construct a low cost and compact DHM system that includes a 3D printer to construct the optical system and a smartphone application to reconstruct the holograms. Furthermore, this smartphone-based DHM system's ability to capture, reconstruct, and display holograms in real time demonstrates its superiority and novelty over existing systems. This system is also expected to contribute to biology fieldwork and pathological diagnosis in remote areas.