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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004
People and organisations have collected information for
thousands of years. All through that time some of this
information has been georeferenced - in some way. From the
early census information in the Middle East, historical battles
and event and records such as the Domesday Book can often be
referenced to a location and often very accurately.
Today there is a greater perception of the need to georeference
information arising from the growing recognition, largely at
government level, of the real value of geographic information in
delivering solutions and establishing more effective ways of
analysing information. Such information will be collected to
satisfy an application such as property values for taxation, river
quality samples, crop health, highway traffic statistics etc. As
such this information may or may not be suited to serve in other
applications. However when conflated with other datasets the
quality and usefulness of the data will generally improve. albeit
at a cost of resolving many discrepancies that will inevitably be
found.
3.4 Are we moving towards coherence or chaos?
As technology improves one would expect maturity and the
integration across datasets to emerge, but there are several
recognised barriers.
Business Priorities
Organisations, as we have seen, collect information to meet a
business need whether they are in government or the private
sector. Resources are often scarce and therefore business
priorities are the major objectives to be met. As a consequence
the cost of extending a datasets capability for perhaps the sole
benefit of the third party is rarely an attractive proposition.
Boundaries of the enterprise
While there may be a coming of minds at international levels
over key issues such as global warming, this then transforms
when we return home to manage national priorities. This “silo
mentality" often surfaces and will strengthen down to the
state/region/department levels of government. Further this
continues to local government/municipality level where the
remit of elected officers is their local area and in many respects
quite rightly so. Hence each of these “levels” of administration
tends to establish barriers to information sharing and exchange.
Differences in specification and practice are evident across
different parts of government in almost every country. In
several European countries data maintenance can be distributed
across the same level of government e.g. detailed information is
mapped by municipalities in Denmark and Italy. However very
significant differences in the nature and the content of the data
will often be found from one municipality to another. In larger
countries e.g. Germany the federal states and the mapping
agency have achieved a common standard (ATKIS) for some
datasets.
New Technology for all
New technology is a boon to the commercial and public sectors
alike. The cost of entry into operational data collection is now
much lower than 10 years ago. New technologies such as GPS,
digital imagery and mobile PCs make it easier to get in a car
and go out and collect data such as street centrelines and
attributes. LIDAR and airborne radar require more investment
but are increasingly being operated and are providing new and
289
different sources of data. The growth in the availability of new
datasets is significant and in many countries now offers
alternatives to the traditional reference data.
Little standardisation
The ISO 191xx family of GI standards [www.isotc21 l.org] are
now emerging, and are starting to provide a common model.
However the ability of the majority of these standards to
influence real data standardisation is limited to the provision of
a simple profile at this stage, but this is a start. Elsewhere, such
as the UK the British Standards for geographic information
provide a tighter model for some datasets e.g. street
information. However these standards fall short in terms of
providing a generic model to support several application areas
and have so far encouraged divergence rather than reuse of
definitive information.
Generally there are few models to support a coherent structure
and form of georeferencing and data collection. It's not
uncommon for organisations to adopt new digital methods as a
direct replication of the tried and tested paper methods
processes — it's perceived as the line of least risk. Hence data
such as environmentally sensitive sites may be collected at
small scales of say 1:25,000 while the cadastre may be
maintained at 1:2,000. When a third party attempts to develop
an automated process to determine whether any properties fall
within the environmental area, the reliability of the results
would be limited and liability on the provider potentially
significant.
Summary
The combination of new technology, the limits and priorities of
the business enterprise and the lack of effective standards
provides barriers to seamless information exchange and hence
automated GI based services.
4. THE DIGITAL NATIONAL FRAMEWORK
4.1 Joined-up geography
The need to provide a vision for better integration of geographic
information has been emerging for several years in many
countries. Great Britain has enjoyed a robust mapping
infrastructure for over 200 years and this has been reinforced at
regular intervals, for example in 1938 through a fundamental
review [Ordnance Survey, 1938] that established the core
foundations for today's GI infrastructure in Great Britain. While
the growth in the use of GI in Great Britain has been
significant, for all the reasons explained earlier, it remains
difficult to easily link or share applications and some reference
information and thereby automate analysis processes. The
concept of the Digital National Framework [DNF] was born in
1999 following a period of consultation in GI and the
publication of several reports on the benefits of GI [e.g.
OXERA, 1999].
OS MasterMap
From the DNF concept OS MasterMap quickly evolved. OS
MasterMap is as a layered database of reference information of
which the first deliverable, in November 2001, was the detailed
and definitive topographic framework for England, Wales and
Scotland. There are over 430,000,000 features in the
