M. Villiger (US) Harvard Medical School, Wellman Center for Photomedicine
Harvard Medical School Wellman Center for PhotomedicineAuthor Of 2 Presentations
TuA1.2 - POLARIZATION-SENSITIVE OPTICAL COHERENCE TOMOGRAPHY WITH A SINGLE INPUT POLARIZATION STATE
- M. Villiger (US) Harvard Medical School, Wellman Center for Photomedicine
- Q. Xiong (SG) Nanyang Technological University
- N. Wang (SG) Nanyang Technological University
- X. Liu (SG) Nanyang Technological University
- L. Liu (SG) Nanyang Technological University
- B. Bouma (US) Wellman Center for Photomedicine
Abstract
Abstract
Measuring depth-resolved birefringence traditionally requires at least two distinct input polarization states. We identified a constraint on the evolution of the polarization state as a function of the round-trip path-length into birefringent tissue that enables to recover comparable results using only a single input state.
TuA2.3 - CONFOCAL IMAGING THROUGH A MULTIMODE FIBER WITHOUT ACTIVE WAVE-CONTROL
Abstract
Abstract
We demonstrate a method to reconstruct confocally gated reflection images acquired through a multimode fiber. It requires a series of distinct illumination patterns obtained by varying the proximal coupling of the illumination and enables fast volumetric imaging without physically focusing the light into the sample.
Presenter Of 1 Presentation
TuA1.2 - POLARIZATION-SENSITIVE OPTICAL COHERENCE TOMOGRAPHY WITH A SINGLE INPUT POLARIZATION STATE
- M. Villiger (US) Harvard Medical School, Wellman Center for Photomedicine
- Q. Xiong (SG) Nanyang Technological University
- N. Wang (SG) Nanyang Technological University
- X. Liu (SG) Nanyang Technological University
- L. Liu (SG) Nanyang Technological University
- B. Bouma (US) Wellman Center for Photomedicine
Abstract
Abstract
Measuring depth-resolved birefringence traditionally requires at least two distinct input polarization states. We identified a constraint on the evolution of the polarization state as a function of the round-trip path-length into birefringent tissue that enables to recover comparable results using only a single input state.