Remote Sensing Tutorial Page 15-9


As the site analysis continued, Landsat data were added to update the land use classification for some themes or data elements. Using predetermined decision criteria, a new set of simplified maps (with all but one decision theme blanked out) indicate areas of acceptability or unacceptability. By combining these factors with proper weightings, a BestSite map was generated, showing the one location that has the highest or optimum suitability. The section closes with some hints on finding GIS case studies on the Net and also presents an example of the kinds of end products obtainable with the IDRISI GIS program.


The PP&L data sets were somewhat dated, having been acquired over a period of years. One of the main contributions from Landsat was to provide an updated land-use map. From this Multispectral Scanner, false-color composite, a “cookie-cut” section appears, which represents the service area for locating the site:

False color composite Landsat image (June 1977) of the Harrisburg, Pennsylvania, service area.

ERRSAC ran this June 1977 scene through a Supervised Classification, in which we selected training sites from other data bases and field observations. This map resulted

Supervised Classification of th</div>e previous Landsat image for the Harrisburg service area

` <>`__15-17: Compare the Landsat map with the PP&L map on the previous page. What are the main similarities; the main differences? What factor(s) are largely responsible for the differences? `ANSWER <Sect15_answers.html#15-17>`__

Drawing upon the PP&L data elements, and the updated classification, we then applied a site-selection model, developed particularly for this study, to the data base. We chose six of the 43 elements as the primary criteria for establishing suitability: (1) Landforms; (2) Groundwater Supply; (3) Soil porosity; (4) Ease of Excavation; (5) Foundation Stability; (6) Distance to Surface Water (limits: 15 cells maximum linear distance). We added other factors, including several socio-economic ones, as secondary determinants.

The next illustration uses single colors (against a yellow-gray background with the river in blue as a location reference) to mark areas derived from the model analysis that were acceptable or unacceptable under the set conditions.

See text below for acceptability category displayed in each panel

Panel A highlights areas (red) of high acceptability under all conditions. In B, the yellow area denotes unfavorable groundwater. In C, the few blue dots point to areas subject to unsatisfactory porosity infill rates. The purplish-red area in D refer to an unacceptable area because of foundation instability. The green in the E panel associates with landforms, in which slope steepness rules out any use for a site. F contains large areas in light-blue that relate to difficult excavation.

We combined these elements, along with others, to produce a Best Site map, made by creating a binary mask (0s and 1s for reject or accept) for each data plane and then adding them to form this composite image:


"Best Site" map for the Harrisburg service area project.

Note that only one small area (the white square, with enlarged details in the inset) broadly meets all these conditions and the constraint of proximity to a large surface water supply as intake for steam production (also an avenue for discharge of waste water). This area is a lowlands, just south of the junction of the Juniata River with the Susquehanna that is high enough to avoid most floods. It lies between the frontal Blue Mountain (south) and Mahony Ridge (north). Although organizations use much of the surrounding area along Route 11-15, the immediate area selected for the site has only two small towns, Duncannon and Perdix, on either side and still has open lands amenable to development. A good supply of labor is nearby, including Harrisburg, whose northern suburbs are about 10 km (6 mi) away.

Admittedly, the above example is a rather simplistic exercise. But it does illustrate the manner in which GIS supports various modes of decision-making. It also demonstrates the role of timely space imagery in the process.

` <>`__15-18 Critique this Best Site final product. Is it convincing? `ANSWER <Sect15_answers.html#15-18>`__

Although closing remarks are given in the next paragraphs, we urge you to then proceed to the next page, which presents a third, and very detailed and intriguing, case study that was received from an outside contributor at almost the last moment before the present version of the Tutorial was “declared complete”.

Meanwhile, if you are new to GIS, you now should know enough to begin practicing on your own. There is a web site, sponsored by the Research Program for Environmental Planning and Geographic Information Systems (REGIS), a group of geographers at the University of California at Berkeley, that has data sets (maps, aerial photos, and space imagery) of the San Francisco Bay Area, which you can display, combine, and use to output new products. This is the BAGIS program, done with a version of GRASS, called GRASSlinks, developed at UCB by Dr. Susan Huse and her colleagues. It’s fun and a challenge to work with. Access it here (UC Berkeley Regis) site and follow the instructions to build your skills at deriving meaningful maps. Links at this site also guide you to other projects by this group. Still another site built around the San Francisco region is accessed at another Regis Program.

GIS has now been used in tens of thousands of studies. But the Internet has a dearth of good ones that go into enough detail to appraise you of what really can be done. Still, a search (try entering “GIS + Case Studies”) on the Web will lead you to some examples that at the least hint at the power of this approach. Perhaps the best affordable way to learn to use GIS is to purchase the IDRISI Program, which guides you through most of the essentials and illustrates these with examples. Look especially at their image gallery and take note of IDRISI32. To entice you to check these out, here is (a somewhat degraded) reproduction of one of those images, in this case several image windows on the IDRISI screen that are input/output to a suitability map.

One of a group of demonstration images on IDRISI�s Web site, showing

aspects of the process of determining site suitability for commercial and industrial uses. |

In the last two decades, GIS has burgeoned into a major international industry. It has become the tool of choice for many applications of map-based, spatial data to problem solving in the Information Age. Its emergence has largely paralleled that of remote sensing and the two aid each other symbiotically. In the GIS realm, remote sensing contributes a subset of input data, whose value is mainly in updating land-cover types. As a measure of the import now attached to GIS, it has grown into a staple of the geography curricula in our colleges and is probably more widely taught than remote sensing.


Primary Author: Nicholas M. Short, Sr. email: nmshort@nationi.net