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> the 
monly 
referred to as lineaments in remotely sensed images. 
They are a source of natural cyclicity in spectrally 
analyzed images. Alternating stratigraphic lithologies in 
folded mountainous terrains with colluvial sluff would be 
expected to contribute a natural periodicity, and, 
furthermore, vegetation establishment and patterns are in 
part controlled by slope, aspect, micro-climate and 
elevation as well as chemistry and moisture associated 
with rock strata and soil type. The orientation of stream 
pattern development in low order streams can be 
influenced by the direction of systematic jointing in rock. 
Without better understanding of the contribution of natural 
biotic and geologic frequencies, a full evaluation of images 
periodicities and spatial frequencies is not likely to be 
attained. The comparative feature extraction and 
evaluation techniques developed are expandable to other 
mountainous regions of the world. 
Data-requirement for Simulated Multistage Spatial and 
Spectral Bands in a Near Temporal Time Frame 
Simulated multi spectral sensor data derived from digitized 
1993 and 1995 CIR Photography ranging from 550 nm, to 
850 nm band with 0.1 m and 11.0 m IFOV resolution are 
employed. The CIR 1:12000, 1993 and 1:6000, 1995 
photography was optically scanned with a Nikon AX-1200 
flat bed scanner with Scantouch and ADOBE Photoshop 
software at 2400 , 1400, 650, 150, and 50 dpi with digital 
output of 1400, 550, 200, 120, 60 and 30 dpi respectively. 
Also using differing filters for red, green, and blue with f 
stop settings at normal or increased to 0.75 f stop 
increase for scanning for separate bands corresponding to 
0.5-0.6nm, 0.6-0.7nm, 0.7-0.85nm of the CIR respectively 
was achieved with this system. These data are then 
compared with ground control data collected and GPS 
registered in July and October of 1995. These data, along 
with elevation, are incorporated in a geobiophysical 
modeling system software for performing the various 
digital multi-variate mergers analyses . 
Analysis 
The data sets are subjected to principal components 
analysis, supervised sampling procedures for the same 
aerial extent for each site with close geographic position 
maintained for signature analysis in feature separability, 
histogram analysis of the samples and a comparative 
analysis of each sample variance for category separability 
and cluster based feature extraction techniques for 
spatial evaluation(Yuill, et al, 1991; Bloemer, et al, 1994; 
Oberly and Brumfield, 1991). The features and sample 
areas represented are: maple beech (6096/4096) 
association; maple beech (4096-6096) association; maple 
spruce (6096/4096) association; red pine spruce (8096/20) 
association; red pine spruce (8096/1096) association; 
spruce yellow birch (8096/2096) associations; field meadow 
shrub rock (50%/20%/20%) association; field meadow rock 
soil (40%/30%/20%) association; road/limestone meadow 
(90%/10%) association; open canopy maple beech 
(30%/40%/30%) association. These features are then 
compared to the GPS registered ground control field data 
in a geobiophysical modeling system for spatial, statistical 
and mathematical analysis for evaluation. Computer 
61 
graphic displays are utilized for comparative evaluation of 
sample data sets. 
RESULTS AND CONCLUSIONS 
The differing IFOV's ranging from 0.1-11m with 
comparative analysis as stated in technique as given in 
the example frequency histograms for infra red, red and 
green respectively of figures 1, 1.6m and 2 , 0.2m, 
demonstrate that larger IFOV than about 1.0 m results in 
a more fragmented spectral frequency sample set than a 
set less than one meter. The characteristics of the spatial 
distribution of the vegetation assemblages, compared to 
field mapping of the vegetation, suggest an intermittent 
discontinuity of spectral frequency that has resulted from 
integration of the spectral energies apparent at higher 
resolutions (IFOV). In fact, histogram display of 2.6m 
IFOV resulting from groupings of frequencies comparable 
to ground cover distribution provided a classification 
similar to higher frequency (IFOV) cluster classification 
(Figures 3 and 4). These results are particularly 
noticeable for sample features that are spatially and 
spectrally similar (Figures 1 and 2). However, it should be 
noted that at higher IFOV, the frequency of the data 
numbers increases while the apparent variance 
decreases; the separability of the spectral types increase 
for the mean of the type in each spectral band (Figures 
5 & 6). This suggests that increased separability of 
spectral features that are spectrally similar, figure 7 & 8, 
may be further separated by higher spatial frequencies 
that provide more of a spectral continuum which may be 
spatially associated. For a fixed number and width of 
Multi spectral bands, with decreasing IFOV, the data 
become more continuous and the individual data 
frequency variance decreases in a constant sample area 
of fixed size within a particular vegetation category. This 
provides better opportunities for characterization of the 
sample within its population and the variance of the 
population. 
The next generation of air and space borne sensor 
platforms need significantly higher spatial and spectral 
resolution if foresters, earth scientists and planners are to 
monitor, inventory and evaluate the resource conditions 
and rejuvenation capacity that mountain forest 
ecosystems provide. Factors, which contribute to the 
degeneration of the mountainous regions of the world, 
must be investigated, to mitigate the degradation of the 
intricate cycles that support forest ecosystems. These 
results demonstrate the validity that higher spatial 
resolutions are necessary to monitor and evaluate the 
higher frequency variability of mountainous terrain in a 
timely fashion for longer term forest ecological processes 
interaction in global change. 
REFERENCES 
Adams H S., Stephenson J.L., 1989. Old-growth red 
spruce communities in the Mid-Appalachians, Vegetation, 
85, pp.45-56. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996