3 /^ m3
sim] PROFILE G | se
Ic? x=28 LIA — IN x=23
10° M 10° \
L10* L 10^
103 210?
- 4l
gt uo no im A gio 0 Li
PROFILE IN
-
rj
ig. 2. Fourier-spectra from profiles in Greenland and Norway.
The relationship between ag, be, £ and L can be studied by means of the
power spectrum S. In order to compensate for the influence of the varying
length L of the profile, the spectrum can be written as function of the
absolute frequency F = £/L
S(F) = s (5) = 1 "rial + pi) (2)
= ; - L 1
or as a function of the wavelength A = Te T
The representation of the terrain in the frequency domain greatly simplifies
the separation of various surface forms.
The following model proved to be valid for a large domain of F:
S(F) 2E -F (3)
where a and E are characteristic parameters for the terrain (Jacobi, 1980).
The relationship is experimentally verified for our two terrain examples
. 1) and the result is shown in Fig. 2. The average spectrum was com-
d for a large number of profiles in both areas. Relationship (3) proves
valid for wavelengths l/F ranging from 50 to 10.000 meters. On a double
logaritmic scale log S is linearly related to log F. The slope a of this
i
line is significantly larger for the Greenland terrain than for Norway
(2.8 versus 2.3). In general, if the slope à CE the spectrum is larger
than 2.5, the landscape is smooth due to the absence of high amplitudes
at high frequencies. On the other hand, a slope less than 2.0 indicates
a rough surface with relatively large variations of high frequencies.
Relationship (3) implies that the surface characteristics are independent
Of the scale of Observation. In particular, for à « 2 the landscape looks
the same independent cf the scale at which it is observed, the amplitudes
and wavelengths of the surface details are on the average directly propor-
tional,
Based on this model, the suitability of different LIRE POLE ENS methods
an ed a C f interpol on S depe in the
