Existing techniques for measuring and characterising anisotropy are discuss
ed. The advantages are suggested in treating anisotropic surfaces as self-a
ffine fractals, characterised by two parameters, the fractal dimension and
the topothesy. These parameters are conveniently determined experimentally
by measuring the slope and intercept of a logarithmic plot of the structure
function. A 3D version of the structure function is presented, any section
for which is equivalent to an ensemble average of profile structure functi
ons. The angular variation of topothesy and fractal dimension obtained from
such sections describes the anisotropy of the parent surface. Also, a bifr
actal structure function, typical of surfaces with stratified textures, may
be split into its component straight Lines by fitting with a hyperbola. Th
e intersection of the asymptotes then defines the so-called "corner frequen
cy" between the two fractals. The 3D height measurements were made on a gri
t-blasted, a ground and a plateau-honed surface with a scanning white-light
interferometer and a stylus instrument. On the isotropic grit-blasted surf
ace, fractal parameters did not. vary with direction. On the strongly aniso
tropic ground surface, the fractal dimension varied only parallel to the la
y, as predicted, but the topothesy varied by some orders of magnitude. On t
he stratified plateau-honed surface, the only true bifractal, fractal param
eters were found to be sensitive to the direction of homing scratches. (C)
1999 Published by Elsevier Science S.A. All rights reserved.