We present a method to obtain quantitatively accurate images of small obstacles or inhomogeneities situated near the surface of a strongly scattering medium. The method uses time-resolved measurements of backscattered light to form the images. Using the asymptotic solution of the radiative transfer equation for this problem, we determine that the key information content in measurements is modeled by a diffusion approximation that is valid for small source-detector distances, and shallow penetration depths. We simplify this model further by linearizing the effect of the inhomogeneities about the known background optical properties using the Born approximation. The resulting model is used in a two-stage imaging algorithm. First, the spatial l...
Using only surface reflection data and first-arrival infor-mation, we generate up- and down-going wa...
AbstractWe show that an obstacle inside a known inhomogeneous medium can be determined from measurem...
Scattering media act in many situations as backgrounds in target recognition and remote sensing and ...
We present a method to obtain quantitatively accurate images of small obstacles or inhomogeneities s...
We present a method to obtain quantitatively accurate images of small obstacles or inhomogeneities s...
The reconstruction of the location and optical properties of objects in turbid media requires the so...
Using only surface reflection data and first-arrival information, we generate the incoming and outgo...
Virtually all structured light methods assume that the scene and the sources are immersed in pure ai...
We present an image-based technique to efficiently acquire spatially varying subsurface reflectance ...
Light in heavily scattering media such as tissue can be modeled with a diffusion equation. A diffusi...
Conventional imaging algorithms assume single scattering and therefore cannot image multiply scatter...
In this paper, a subsurface imaging problem is addressed. In particular, the focus here is to determ...
In this paper a new formulation of the Linear Sampling Method, called the no\u2013Sampling Linear Sa...
We study by means of experiments and Monte Carlo simulations, the scattering of light in random medi...
Abstract. We consider imaging in a scattering medium where the illumination goes through this medium...
Using only surface reflection data and first-arrival infor-mation, we generate up- and down-going wa...
AbstractWe show that an obstacle inside a known inhomogeneous medium can be determined from measurem...
Scattering media act in many situations as backgrounds in target recognition and remote sensing and ...
We present a method to obtain quantitatively accurate images of small obstacles or inhomogeneities s...
We present a method to obtain quantitatively accurate images of small obstacles or inhomogeneities s...
The reconstruction of the location and optical properties of objects in turbid media requires the so...
Using only surface reflection data and first-arrival information, we generate the incoming and outgo...
Virtually all structured light methods assume that the scene and the sources are immersed in pure ai...
We present an image-based technique to efficiently acquire spatially varying subsurface reflectance ...
Light in heavily scattering media such as tissue can be modeled with a diffusion equation. A diffusi...
Conventional imaging algorithms assume single scattering and therefore cannot image multiply scatter...
In this paper, a subsurface imaging problem is addressed. In particular, the focus here is to determ...
In this paper a new formulation of the Linear Sampling Method, called the no\u2013Sampling Linear Sa...
We study by means of experiments and Monte Carlo simulations, the scattering of light in random medi...
Abstract. We consider imaging in a scattering medium where the illumination goes through this medium...
Using only surface reflection data and first-arrival infor-mation, we generate up- and down-going wa...
AbstractWe show that an obstacle inside a known inhomogeneous medium can be determined from measurem...
Scattering media act in many situations as backgrounds in target recognition and remote sensing and ...