Hollow-beam geometry, in conjunction with mode-selective detection, is
of importance for the development of high-sensitivity devices for the
measurement of dynamic light scattering in living tissues. Its applic
ation to scattering methods in the eye makes it possible to increase d
iagnostic ability for some diseases that alter the scattering paramete
rs in the vitreous as well as in other transparent tissues of the eye.
We present a thorough theoretical analysis of the hollow-beam geometr
y proposed recently for dynamic light scattering measurements in the h
uman eye. The aims of the analysis are the determination of the excita
tion and the observation beam profiles at the focal plane and the eval
uation of the volume under test in the measurement, which allow predic
tion of the intensity of the measured signal. The above is carried out
with comparisons with the classical setup. From the theoretical point
of view, the most appealing feature of the hollow-beam geometry is hi
gh collection efficiency combined with high stability. In the analysis
performed, the concept of the characteristic length of a scattering s
ystem is introduced. With simple formalism, this parameter allows the
calculation of the collection efficiency for general beam shaping and
is extremely useful for the comparison of the performance of different
systems. (C) 1997 Optical Society of America.