High-resolution single-pixel imaging based on a probe of single-mode fiber and hybrid multimode fiber

Abstract

In single-pixel imaging, the combination of random speckles generated by the multimode fiber (MMF) as projection patterns and the compressed sensing theory is beneficial for improving imaging performance and expanding application scenarios. However, the image reconstruction quality using the MMF is usually unsatisfactory, which is helpless for retrieving objects with detailed information or multi-resolution objects. The reason lies in the limited number and compromised spatial resolution of low-correlated speckle patterns provided by the MMF in practical circumstances like long operating time or bending disturbances. Here, we propose a novel concept of hybrid multimode fibers (HMMF) for single-pixel imaging resolution enhancement. Based on the bending insensitivity property of single-mode fiber (SMF) and the compatibility property of small bending radius and high mode density of HMMF, the wavelength-modulated SMF-HMMF probe is designed to significantly improve the number and spatial resolution of speckle patterns while ensuring the robustness of the imaging system. The experimental results demonstrate that the spatial resolution of the speckle patterns has been improved by approximately 3 times (from 20.35 pixels to 7.24 pixels) compared to the non-HMMF probe. The correlation of the speckle patterns holds as low as about 0.1, even when the tuning wavelength interval is reduced to 5 pm. The maximum deviation of the repeatability of the speckle pattern was 0.044 for the 120-min interval tested, and the consistent output of the speckle pattern under various bending configurations demonstrates the strong robustness of the imaging system. High-quality imaging of multi-resolution target objects has been achieved even at a remarkably low sampling rate (SR) of 5 %. This study has the potential to expand the application of single-pixel imaging systems in flexible and long-distance detection imaging scenarios.