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SYMPOSIUM PHOTO INTERPRETATION, DELFT 1962
monly designated “Muskeg” in Canada, peatland in Great Britain and by
other expressions in Scandinavia, U.S.S.R., Latin America, etc.
In Canada, Organic Terrain covers well over 500,000 square miles of sur
face. To know what this terrain is, how it varies, and how it can be assessed
for any or all purposes, has become nationally expedient. The task is not easy
for various reasons. An important one is that overland access involving such
a vast expanse is not only difficult, or sometimes almost impossible, but is also
expensive.
Recent research [8] has encouraged a view that this difficulty can be sub
stantially circumvented if adequate evaluation of the terrain properties can
be achieved either by direct observation from the air or by inspection of air-
photos, or both. There are two basic assumptions that obtain for this possibil
ity. One is that objective aerial inspection will reveal the presence of patterns
which symbolize inherent characteristics of the terrain; the other is that such
patterns, if they exist, can be interpreted in engineering terms.
The writer and his associates have shown that in organic terrain, the fossil
ized component, peat, reveals botanical trends that culminate in production
of specified living cover, the contemporary component of the terrain [2, 4, 6].
Where fossil trends differ, vegetal cover differs accordingly. By reference to
differentials in cover, therefore, one affords indirect reference to sub-surface
botanical trends in historical retrospect and to differentials in these trends.
Now these trends being botanical are subject to characteristic constitutional
limitation and this is manifested in peat structure. Structural difference, or
ganized as to constitutional differentials, is therefore observable in peat.
Phenomena under cosmic influence are classifiable if they recur as do specific
differences in peat. Once recognized by interpretive procedure, they may be
interpreted elsewhere. By reason of the relationship between cover and peat,
it follows that vegetal cover is the significant key to detection of either sub
surface structural condition or structural differentials.
It is perhaps not surprising in view of the argument presented that vegetal
cover of a given type will show distributional delineation. Thus surficial pat
terns arise which characterize organic sub-surface. Such patterns are observ
able, of course, from the air, and they recur. Thus the sub-surface botanical
and structural constitution can be interpreted directly or indirectly from the
air.
The most frequently recurring patterns observable at an altitude of 30,000 ft
are known [3] and have been named as shown in the legends to the photo
graphs which represent them, figs. 1, 2, 3, 4, 5.
Though structural composition in the peat and the resulting air-form pattern
are functions of botanical trend, there are factors other than biotic that contri
bute to pattern. These may arise through the influence of the mineral sub
layer, ice, the accumulative effect of organic deposition, or water [7]. They
are secondarily imposed after biotic relations are established and the peat
formation has commenced. The aspects of relationship between the primary
(botanical) and secondary (extra-biotic) factors have not been examined and
