Proof of principle for direct reconstruction of qualitative depth information from turbid media by a single hyper spectral image

Hohmann M, Hecht D, Lengenfelder B, Späth M, Klämpfl F, Schmidt M (2021)


Publication Type: Journal article

Publication year: 2021

Journal

Book Volume: 21

Article Number: 2860

Journal Issue: 8

DOI: 10.3390/s21082860

Abstract

In medical applications, hyper-spectral imaging is becoming more and more common. It has been shown to be more effective for classification and segmentation than normal RGB imaging because narrower wavelength bands are used, providing a higher contrast. However, until now, the fact that hyper-spectral images also contain information about the three-dimensional structure of turbid media has been neglected. In this study, it is shown that it is possible to derive information about the depth of inclusions in turbid phantoms from a single hyper-spectral image. Here, the depth information is encoded by a combination of scattering and absorption within the phantom. Although scatter-dominated regions increase the backscattering for deep vessels, absorption has the opposite effect. With this argumentation, it makes sense to assume that, under certain conditions, a wavelength is not influenced by the depth of the inclusion and acts as an iso-point. This iso-point could be used to easily derive information about the depth of an inclusion. In this study, it is shown that the iso-point exists in some cases. Moreover, it is shown that the iso-point can be used to obtain precise depth information.

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APA:

Hohmann, M., Hecht, D., Lengenfelder, B., Späth, M., Klämpfl, F., & Schmidt, M. (2021). Proof of principle for direct reconstruction of qualitative depth information from turbid media by a single hyper spectral image. Sensors, 21(8). https://doi.org/10.3390/s21082860

MLA:

Hohmann, Martin, et al. "Proof of principle for direct reconstruction of qualitative depth information from turbid media by a single hyper spectral image." Sensors 21.8 (2021).

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