Geography 140
Introduction to Physical Geography
Lecture: Maps (Introduction)
I. A map is a symbolized representation of all or part of the earth's (or,
indeed, any celestial object's or space's) surface on a flat sheet.
A. Uses
1. Allows us to get a sense of relative location, of spatial
relationships, on a scale that goes way beyond our perspective here
in one little place on Earth. This sense, of course, is of great
importance to all kinds of geographers and many people in many
other disciplines and walks of life (just try to get around in L.A.
without a "Tommy Guide").
2. Additionally, they can convey all kinds of information beyond that
of mere location, if the mapmaker chooses data and symbolism
properly.
3. A map, being flat (and possibly foldable) is much more portable and
convenient than a globe!
B. The science concerned with map design, construction, reproduction, and
publication is called "cartography." Mapmakers are called
"cartographers."
C. The purpose of this section of the lecture is to help you understand
better how to read different kinds of maps and to sensitize you to
some of their limitations.
II. The essential and biggest limitation of any map is the physical
impossibility of transferring a curved surface, like the earth's, onto a
flat one without distortion and error. I cannot emphasize this enough:
There is simply no such thing as a perfect map. We are stuck with this
limitation, though, because maps are so useful in spite of their inherent
defects. Since we can't eliminate these defects, the best we can do is
understand them and control them for the purposes of a given map's
planned use. This is the task of "projection," of how we transfer a
spheroidal surface onto a flat one.
A. Properties of a map. Ideally, a map would possess a number of
important properties. Unhappily, no one map can retain all of them
(or we'd have a perfect map, which is an impossibility). It is the
task of a cartographers to figure out which of these are most
important to retain for a given purpose and then project the round
earth onto the flat map in such a way that the key properties are
retained (at the expense of less important properties). Here are
those properties that you, as a cartographer, try to pick and choose
among for emphasis in a given map:
1. True direction. Map directions of N-S-E-W and every direction in
between could duplicate those in the real world. If N points to
the top of the map (which is a cultural convention), then W is at
right angles, 90° to the left. Actually, only the Mercator
projection (more on that later) shows true direction in the sense
of true headings. Other maps are "true direction" in the sense
that a straight line on them is a great circle route, the direction
of the shortest distance between two places. This quality is what
is meant most of the time when a map is said to preserve "true
direction." Oh, and the Mercator projection is not a "true
direction" map in this sense of the words, because a constant
compass heading will not take you on the shortest path to your
destination (great circle route). Confused? The lecture on
projections will organize your confusion. I hope.
2. Equidistant (true distance or scale): This means that, since a map
is a miniaturized representation of the earth, it would be nice if
all places on the map were reduced in the exact same amount as all
other places on the map. This is, sadly, not possible, as
projection of a sphere onto a flat surface means some areas are
shown at larger scales than average and some at smaller scales.
Scale can be true in certain directions, though.
3. True shape or conformality. The shape of a landmass is shown
accurately, but at the cost of accurate representation of area.
4. Equivalence of area. If area is accurately shown, shape is thrown
off. Conformality and true area are mutually exclusive virtues.
If you have one, you can't have the other:
![[ Difference between conformal and true area maps ]](https://home.csulb.edu/~rodrigue/geog140/conformalarea.jpg)
A and B are conformal: They show the same shape. A and C are true
area, but certainly NOT conformal in shape. Equivalence of area
might not be important to a navigator, but it is very important for
a lot of classroom and media uses to show various distributions.
On to the next lecture, on map projections.
This next lecture looks like a lot of material, but don't faint: Most of it
is pictures, and I've included a study guide at the end of it.
Document and © maintained by Dr.
Rodrigue
First placed on web: 09/16/00
Last revised: 02/16/01