Notes on Topology
These are links to PostScript files containing notes for
various topics in topology.
I learned topology at M.I.T. from Topology: A First
Course by James Munkres. At the time, the first edition was just
coming out; I still have the photocopies we were given before the
printed version was ready!
Hence, I'm a bit biased: I still think Munkres' book is the best book
to learn from. The writing is clear and lively, the choice of topics is
still pretty good, and the exercises are wonderful. Munkres also has a
gift for naming things in useful ways (The Pasting Lemma, the Sequence
Lemma, the Tube Lemma).
(I like Paul Halmos's suggestion that things be named in descriptive
ways. On the other hand, some names in topology are terrible ---
"first countable" and "second countable" come to
mind. They are almost as bad as "regions of type I" and
"regions of type II" which you still sometimes encounter in
books on multivariable calculus.)
I've used Munkres both of the times I've taught topology, the most
recent occasion being this summer (1999). The lecture notes below follow
the order of the topics in the book, with a few minor variations.
Here are some areas in which I decided to do things differently from
- I prefer to motivate continuity by recalling the epsilon-delta
definition which students see in analysis (or calculus); therefore, I
took the pointwise definition as a starting point, and derived the
inverse image version later.
- I stated the results on quotient maps so as to emphasize the
- I prefer Zorn's lemma to the Maximal Principle; for example, in
constructing connected components, I use Zorn's lemma to construct
maximal connected sets.
- I did Tychonoff's theorem at the same time as the other stuff
on compactness. The proof for a finite product is long enough that
I decided to save some time by omitting it and just doing the
- It seems simpler to me to do Urysohn's lemma by indexing the
level sets with dyadic rationals in [0,1] rather than rationals.
- funct.ps (86,912 bytes; 5 pages):
Review of topics in set theory.
- top.ps (168,720 bytes; 6 pages):
Topological spaces, bases.
- closed.ps (55,509 bytes; 4 pages):
Closed sets and limit points.
- haus.ps (132,025 bytes; 2 pages):
- contin.ps (100,021 bytes;
3 pages): Continuous functions.
- homeo.ps (83,891 bytes; 3 pages):
- prod.ps (51,962 bytes; 3 pages):
The product topology.
- Metric spaces
- quot.ps (116,395 bytes; 5 pages):
- conn.ps (82,400 bytes; 4 pages):
- realconn.ps (55,934 bytes; 3
pages): Connected subsets of the reals.
- pathco.ps (45,136 bytes; 3 pages):
Path connectedness, local connectedness.
- compact.ps (240,878 bytes;
8 pages): Compactness (including Tychonoff's theorem).
- compreal.ps (69,020 bytes;
3 pages): Compact subsets of the reals.
- limcomp.ps (107,691 bytes;
4 pages): Limit point compactness and sequential compactness.
- loccpt.ps (70,399 bytes;
3 pages): Local compactness; the one-point compactification.
- countab.ps (40,734 bytes;
2 pages): The countability axioms.
- sep.ps (139,569 bytes;
5 pages): The separation axioms: regularity and normality.
- urysohn.ps (69,043 bytes;
2 pages): Urysohn's lemma.
- tietze.ps (45,448 bytes;
3 pages): The Tietze Extension Theorem.
Send comments about this page to:
Bruce Ikenaga's Home Page
Math Department Home Page
Millersville University Home Page
Copyright 1999 by Bruce Ikenaga