G.I.S. a Brief History
Essay by review • February 9, 2011 • Research Paper • 2,056 Words (9 Pages) • 1,784 Views
G.I.S.
"A Brief History"
Although a relatively new addition to the Geographic field, with most of its main innovations in the last 40 years, G.I.S. (Geographic Information Systems) had several precursors. A history of this field has been attempted and usually takes several volumes to fulfill this goal. This paper will not attempt a full history, but will hit upon some of the Ideas and high points of this fledgling technology through the history of Canada's own CGIS, believed widely as the worlds first GIS. Most of these new uses for G.I.S. took place within the last forty years and its history is still being written today. In order to understand the history and ideas leading to G.I.S. it is also helpful to understand what G.I.S. is.
What exactly is G.I.S.? That is a question that will give one various answers depending on who you ask, or what field they are in. G.I.S. is an interdisciplinary science with uses in; Geography, Cartography, Remote Sensing, Geology, Surveying, Statistics, Computer Science, Biology and Civil Engineering to name a few. The easiest way to explain G.I.S. according to (Delaney pg2) is to examine each letter of the acronym. G (geographic) refers to the real, spatial world, and a quality or quantity that is spatially distributed (Delaney pg2). This requires that the data be used in a recognized coordinate system. Such systems used could be a Latitude/Longitude system, an x, y coordinate or even an easting and northing pair. Figure A shows an example of a geographical coordinate system.
Figure A.
I (information) "identifies that we have some data (measurements) within the context of a system of meaning" (Delaney pg 3). Some of the information must come from map coordinates. "Other information may be related to attributes (derived from a name or label), or topology" (Delaney p3). An example for information can be seen in Figure B.
Figure B.
S (system) refers to the linkage of separate entities (Delaney). Such entities could be the computer hardware, the software, the data and the user. "When these entities are combined, or linked, they form a system of interactions and interdependencies" (Delaney pg3). An example of a system is found in Figure C.
Figure C.
G.I.S. is different from mapping and computer aided cartography because of its analytical capacity. It is also different from CAD programs because it performs spatial operations. G.I.S. is also different from a database management system due to its cartographic interface. Due to the fact that GIS is computer based, and has all the advantages of a computer tool, GIS can be an accurate, efficient, effective as well as cost effective tool.
Any great idea or multiples of ideals usually do not spring up overnight. There are usually precursors or a conglomerate of ideas that lead up to the present. G.I.S. is no different. GIS has evolved out of a long tradition of map making. A good place to start would be with base maps. The idea of portraying different layers of data on a series of base maps, and relating things geographically, has been around much longer than computers. Maps drawn by the French Cartographer Louis-Alexander Berthier of the Battle of Yorktown (American Revolution) contained hinged overlays to show troop movements (Foresman pg 3). In the mid-19th Century an "Atlas to Accompany the Second report of the Irish Railway Commissioners showed population, traffic flow, geology and topography superimposed on the same base map" (American Cartographer). In 1819 Pierre Charles Dupin of France used the first choropleth map, and possibly the first modern statistical map, "used shadings from black to white to show the intensity of illiteracy in France" (Geomatica). Another fine example of an early use of geographical analysis would be that of, Dr. John Snow who used a map showing the locations of death by cholera in central London in September, 1854 to track the source of the outbreak to a contaminated well (American Cartographer).
Mapping innovations were not the only technologies leading to our modern day GIS. Computers had to first be invented and then made more robust in terms of speed and memory. In 1623 the first known mechanical adding machine known as the Calculating Clock was built in Germany. In 1890 the Hollerith Company (known today as IBM) invented and used the first punch card machine to tabulate the U.S. Census. The speed at which data could be retrieved was increased dramatically with the Memex. This information retrieval system could help "someone find information based in association and context rather than strict categorical indexing" (Geomatica). Finally the first digital computer was invented in 1944 by Harvard graduate, Howard H. Aiken. Aiken's 50 foot long 8 foot tall 5 ton behemoth known as the Mark 1 consisted of many calculators which worked on parts of the same problem under the guidance of a single control unit. Instructions were read in on paper tape, data was provided on punched cards, and the device could only perform operations in the sequence in which they were received. This of course led to faster and smaller computers that can perform many operations at once, as well as memory only conventionalized in science fiction books of the 1950's.
"The advent of geographic information systems was the result not of academic inquiry but rather of the growing societal need for geographical information, of a change in the technology that made such systems possible and of private sector vision and government foresight that initiated and sustained their development" (Foresman pg21). This took place in the early 1960's in Canada. Competition for the potential uses of Canada's land and resources became a concern for the Government (Foresman). The rural depopulation was increasing due to many marginal farms with nonviable incomes. The Canadian Government knew that monitoring and planning the utilization of its vast resources was of great importance according to Foresman. In 1961 The Land use in Canada, Resources for Tomorrow Conference was held and attended by Canada's senior resource scientists as well as the prime minister himself. Geographical data that would be of use for land management decisions and in the detail to support these at national and regional levels meant that the maps needed to be at scales between 1:250,000 and 1:20,000 (Tomlinson pg22). With a country the size of Canada this meant many maps at these scales. "The
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