To assess the anisotropy degree of the sample from the shear wave velocity the generalized
anisotropy factor [B.sub.S] was calculated by the formula:
The ellipsoid is characterized with two parameters: the
anisotropy factor for the irregularities equaling to the ratio of ellipsoid axes [chi] = [l.sub.[parallel]]/[l.sub.[perpendicular to]] (ratio of longitudinal and transverse sizes of plasma irregularities with respect to the external magnetic field) and orientation characterizes by the inclination angle [[gamma].sub.0] of the prolate irregularities with respect to the lines of forces of an external magnetic field (sometimes with respect to horizon).
The absorption coefficient and
anisotropy factor of the second layers were chosen as minimum values given in [13] for 500-550 nm wavelengths, 0.6 ([cm.sup.-1]), and 0.87, respectively.
This function is characterized by
anisotropy factor of irregularities X = [l.sub.[parallel]]/[l.sub.[perpendicular to]](ratio of longitudinal and transverse linear scales of plasma irregularities with respect to the external magnetic field) and the inclination angle of prolate irregularities with respect to the external magnetic field [[gamma].sub.0].
a = [square root of [[lambda].sub.[parallel]]/[[lambda].sub.[perpendicular to]]]] = thermal conductivity
anisotropy factorThe degree of orientation, or
anisotropy factor (AF), is defined as the difference between the principal values of (uu):
Beside paper--dye interaction (mainly, cross-section profile of raster element) our interest will also be focused on investigation of influence of
anisotropy factor in our model which could be important for optimization of paper components initial mixture.
The optical parameters absorption coefficient ([[micro].sub.a]), reduced scattering coefficient ([[micro].sub.s.sup.[]]) and
anisotropy factor (g) of tissues and phantoms were determined by Monte Carlo simulation technique.
Determination of
Anisotropy Factor. Firstly, brain tissue phantoms were made for comparative pictures of photon distribution.
8, the
anisotropy factor ranges from 0 for an isotropic distribution of orientation to 1 for the case of perfect domain alignment in the x-y plane.
The calculations of the [V.sub.P] range of changes within the depths of 5-25 km (5.82-6.60 km/s) with the average of 6.27-6.40 km/s allow the
anisotropy factor variations to be estimated from 4 % to 9 %, Table 5.
The
anisotropy factor, that means the ratio of in-plane conductivity and conductivity in the direction perpendicular to the pellet plane, was 328 (PANI/MMT pellet) and 6.7 (pure PANI pellet), respectively.