An analytical model for optimization of frequency-domain system

Author

Tu, Tao ; Chen, Yu ; Chance, Britton

Author_Institution

Dept. of Biochem. & Biophys., Pennsylvania Univ., Philadelphia, PA, USA

fYear

2002

fDate

2002

Firstpage

79

Lastpage

80

Abstract

Frequency-domain NIR techniques have been widely used to study the physiological state of biological tissues non-invasively. This paper presents a theoretical model to predict and optimize the performance of frequency-domain system. Experimental data are demonstrated to validate this method. This model can be used to design and optimize frequency-domain system for various applications

Keywords

bio-optics; biological tissues; biomedical imaging; frequency response; infrared imaging; infrared spectroscopy; intensity modulation; optical noise; optical tomography; photon transport theory; shot noise; thermal noise; turbidity; biological tissues; frequency responses; frequency-domain NIR system; highly scattering media; human skull; intensity modulated light diffusion; near-infrared tomography; optimization model; photon migration; physiological state; relative intensity noise current density; shot noise current density; thermal noise current density; tissue spectroscopy; transmission model; turbid medium; Analytical models; Band pass filters; Frequency domain analysis; Instruments; Intensity modulation; Noise figure; Optical modulation; Optical noise; Optical scattering; Optical sensors;

fLanguage

English

Publisher

ieee

Conference_Titel

Bioengineering Conference, 2002. Proceedings of the IEEE 28th Annual Northeast

Conference_Location

Philadelphia, PA

Print_ISBN

0-7803-7419-3

Type

conf

DOI

10.1109/NEBC.2002.999474

Filename

999474