International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
  
"Now And For The Future", provides an optimistic vision of 
the country for a new century. At the same time it 
acknowledges that the implementation of a sustainable 
development strategy requires ideas, determination and action 
on behalf of all Canadians, across all sectors of society (Natural 
Resources Canada, 2001). The third Sustainable Development 
Strategy “Moving Forward” formulates for the next three years 
a results-base action plan, guided by a unified, forward thinking 
vision and organizational commitment to sustainable 
development that encompass all of the Department's diverse 
activities and enables the Government of Canada to address the 
utilization of resources in a comprehensive manner, from a 
national perspective (Natural Resources Canada, 2004). 
2.2 The Sustainable Development through Knowledge 
Integration Program 
The Sustainable Development through Knowledge Integration 
(SDKI) program was initiated in June 2003. The program 
focuses largely on a number of issues related to Natural 
Resources Canada’s requirements for sustainable development. 
It builds on the concept that Earth Sciences Sector’s (ESS) 
geospatial information could and should be used to support 
decision and policy making. The SDKI program will move 
select components of the ESS's research, information and 
knowledge assets into the decision support environments of 
government, industry and the public. It will develop technology 
that facilitates integration of ESS information and knowledge 
assets, and will enhance Natural Resources Canada’s capacity 
to disseminate policy pertaining to Canada's mineral, energy 
and forestry resources and their responsible use (Richardson, 
2003). 
The Sustainable Development through Knowledge Integration 
program comprises several theme based application projects 
and two system and methods development projects. The theme 
projects are: Transport-Related Energy Sustainability in 
Canadian Urban Areas, Sustainable Management and 
Rehabilitation of Mine Sites for Decision Support, Forestland 
Disturbances Monitoring, and Mapping for Sustainable 
Development Planning and Reporting. The systems and 
methods development projects are: the PATHWAYS-Decision 
Support System for Sustainable Development and Visualization 
of Integrated Knowledge for Sustainable Development 
Decision Making (SDKI-Vis). 
2.3 Visualization of Integrated Knowledge for Sustainable 
Development Decision Making 
The SDKI-Vis project focuses on removing barriers to the 
effective communication of geospatial information to policy 
and decision makers. The project addresses the translation of 
quantitative science output into qualitative presentation 
thereby demonstrating the results of modelling undertaken 
within the SDKI theme projects such as urban analysis, forest 
disturbances, mines, water and hazards. Forecasts resulting 
from SDKI themes will be presented using methods such as 
dynamic visualization or 3D interactive terrain representation. 
Additionally, it will identify, assess and publish a suite of 
advanced Web-based visualization techniques. More generic 
visualization methods could be applied to other programs 
conducted in the Earth Sciences Sector dealing with integrated 
knowledge based on geospatial data and information. The 
project also involves development of a long-term strategy for 
visualization primarily applied to the SDKI program, with 
potential links to other ESS programs such as Northern 
Development. 
348 
3.0 CARTOGRAPHIC PERSPECTIVE ON GEOSPATIAL 
VISUALIZATION 
Throughout the ages, various types of maps and images have 
been used to communicate information. Societal change and 
rapid technological evolution have had a significant impact on 
how maps are produced, distributed and used. Today, maps 
have evolved from static representations of the world to 2D or 
3D interactive digital representations. In addition to graphical 
representation, maps can now be enriched with multimedia 
through the addition of sound and animation, thus expanding 
the channels of information available to map users. These new 
era maps often themselves become a mechanism for data 
exploration and analysis, as new interactive distribution 
systems such as the Internet are increasingly used for their 
dissemination (Cartwright, 1999). 
As cartographic visualization is based increasingly on new 
technologies, the richness of human-to-human communication 
is often lost as virtual environments can hamper spontaneous 
engagement. However, many researchers believe that the most 
dynamic and collaborative communication occurs when both 
high and low technology tools are used (Bosselmann, 1998; Al- 
Kodmany, 2001). Cartographic visualization is not meant to 
replace traditional tools for decision-making, but both augment 
and enhance these tools. 
One of the most fundamental issues in cartographic and graphic 
communication involves the suitability of the method used to 
represent data, ie, graphs, charts, tables, maps, 3D 
representation and animation. For example, cartographers warn 
against using choropleth maps that distribute a risk evenly over 
a surface when in fact the risk is not homogenous to such an 
extreme degree that it follows the choropleth boundaries. 
Another issue is the use of visual variables, namely the hue, 
size, shape, value, texture and orientation of data symbolized 
(Bertin, 1983). Web-based visualization is no longer limited to 
2D static maps but includes dynamic and 3D representations. 
In this case the visual variables described by Bertin are further 
extended to encompass 3D dynamic representation and Virtual 
Reality Modelling Language (VRML), which are dynamically 
linked with databases. Once the data is represented, the means 
of interaction must be considered to allow the user to 
manipulate variables to create different scenarios. The key to 
effective data exploration and analysis is the means of 
interacting with data through functional and user friendly 
interfaces. 
4.1 WEB-BASED VISUALIZATION TECHNIQUES 
This section discusses some of the techniques that were 
successfully used for the communication of geospatial 
information for Nunavut, Canada. Most of these techniques 
have been developed within a visualization project conducted 
by the Mapping Services Branch of the Earth Sciences Sector. 
4.1 Mapping Services Branch Visualization Project 
In April 1999 a new territory called Nunavut was created in 
Canada’s north. To commemorate the creation of Nunavut, the 
Mapping Services Branch published a special topographic map 
of Iqaluit, the capital city of Nunavut, and initiated two 
cartographic visualization projects. One project focused on 
developing various interactive visualization techniques suitable 
for presentation of topographic information of the region 
[http://maps NRCan.gc.ca/visualization]. The second project 
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