the market-place and triggered mass

the market-place and triggered massive investments in industry
as well as in academic research and writing. It met the demands
of increasing spatial resolution in imagery and almost explosive
amounts of geospatial data that required processing within a
specific time-frame. It has been put forward briefly  for a deeper
elaboration the reader is referred to Burnett and Blaschke (2002),
Lang (2005) or Lang (2008)  that an early `technopositivistic'
tendency has also generated high levels of interest in ontological,
epistemological and methodological questions of scale, multiscale
data handling, and data fusion, to name just a few areas.
It has also led to a rediscovery of inimitable original thinking
on the construction of space, on spatial cognition and on the
(near)-decomposability of systems (Koestler, 1967; Simon, 1973;
Wu and Loucks, 1995). We also have to accept that the human
mind is not designed to handle large-scale continuous chaos, nor
does it function optimally when dealing with large-scale perfect
uniformity (Cutter et al., 2002). The large palette of technical
solutions paired with a plethora of geospatial information
necessitates a plurality of solutions. Today, the bottleneck in
large volume `high throughput' geospatial imagery environments
 such as in industrial image processing under standardised
conditions  is a sound methodology in the world of ``conditioned
information'' (Lang, 2008). Lacking the required space for a
thorough discussion of recent and future research questions it is
instead recommended that the reader refer to Lang (2008), and
critically revisit the `old readings' of Simon and Koestler. Only
with sound methodologies, we will be able to build on integrated,
real-time, and mobile GPS/GIS/remote sensing technologies  a
topic that has been excluded from this paper  to create a highly
interactive, geospatial, decision-support environment.