Counterexamples in Analysis (Dover Books on Mathematics)

But it was a Faustian bargain, because immediately a host of bizarre and counterintuitive examples were discovered - continuous functions that were nowhere differentiable, nonmeasurable sets, one-to-one pairing of points between the line and the plane. These peculiar entities were deeply disturbing to many.

Poincare said "Logic sometimes makes monsters. For half a century we have seen a mass of bizarre functions which appear to be forced to resemble as little as possible honest functions which serve some purpose... In former times when one invented a new function it was for a practical purpose; today one invents them purposely to show up defects in the reasoning of our fathers and one will deduce from them only that."

These counterexamples displayed features that were nowhere to be found in the physical universe. When Richard Feynman was a physics graduate student at Princeton, he would tease his mathematician friends that mathematics was so easy that he could instantly decide the truth or falsehood of any mathematical statement they could give him. One day they challenged him with the grand-daddy of all the paradoxes, the Banach-Tarski paradox: That the unit ball in R3 could be divided into a finite number of pieces, and the pieces could, by rigid translation and rotation, be reassembled into two unit balls. But they made a mistake: instead of saying "unit ball in R3", they said "apple". Feynman quickly pointed out that the nonmeasurable pieces, that they had so rigorously defined, must split apart even every electron of the apple.

When I was a graduate student in mathematics, "Counterexamples in Analysis" was my favorite book, and I had a lot of fun amazing my fellow graduate students by quoting from it. Since then, however, I have swung around more to the viewpoint of Poincare and Feynman: "Logic sometimes makes monsters." From either viewpoint, however, the counterexamples are immensely entertaining.

Rating:
Summary: Indispensable for students of real analysis
Review: Graduate students of mathematics, just buy this book - no questions asked. You need the examples and this level of understanding. For the price there are just no questions - buy it!

Rating:
Summary: Gives you the extra edge
Review: In this book, the authors present counterexamples of notions that seem "obvious" by handwaving or instinct. Some of the (counter)examples are well-known (ordered space which is cauchy complete but not complete) and some are highly contrived (two non homeomorphic topological spaces which is countinuous one-to-one image of each other). The latter categories is what makes this book useful.

You cant learn analysis by reading this book -- but you can learn how analysis works. I personally recommend this book to those who wants to work in analysis at least until graduate school. Mastering the book is a good preparation for oral exams and quals, and would increase your general understanding of the subject.

Topics range from real number system, differentiation and integration, sequence and series, measure, function in two variables, plane sets, topological space and function space.

Rating:
Summary: A Bestiary of Analysis Monsters
Review: It can happen to anybody. There you are, minding your own business, when the though hits you: Does every continuous function have a derivative somewhere? You try to prove that it must. It sure seems like it must. How could it not? Hours slip by, and you've made no progress. What do you do? You pick up Gelbaum and Olmsted's classic "Counterexamples in Analysis". There on page 38 is an example of a continuous function that has no derivative; none; anywhere. No wonder you couldn't prove it.

It turns out that questions of the form "Does A always imply B?" entail proofs with two very different flavors, depending on whether the answer is affirmative or negative. The affirmative variety can be very difficult, as it usually deals with an infinity of things. But a negative answer requires only one solitary example of an A that is not a B; this is affectionately known as a "counter-example". These are the slickest little proofs around--often a one liner--and they can provide a lot of insight. Here's a trickier one: Are all linear functions continuous? Surprisingly, the answer is "no", which means there is a counter-example. Gelbaum and Olmsted show how to construct a discontinuous linear function. Case closed. They also provide examples of

A perfect nowhere dense set

A linear function space that is a lattice but not an algebra

A connected compact set that is not an arc

A divergent series whose general term approaches zero

A nonuniform limit of bounded functions that is not bounded

I won't give away any more (although there are hundreds). The book has chapters on real numbers, functions and limits, differentiation, sequences, infinite series, set and measure on the real axis, functions of two variables, metric and topological spaces, and more. Each section begins with a brief summary of the basic concepts and definitions, then launches into a list of terse counter-examples. This is simply indispensable for students of mathematical analysis, as it can help to explain why you cannot weaken those seemingly stringent hypotheses to various theorems; if you do, one of these quirky counter-examples will rush in and ruin your day. This is a great book to have on hand. I highly recommend it. (I won't tell you how it ends.)

Rating:
Summary: Counterexamples
Review: It's a pity that this book is out of print. You learn all this wonderful theorems at the colleg. But where are the limits? Why some theorems have so strange assumption? Well, this books will provide you with answers, sometimes surprising ones. For example: Two functions whose squares are Lebesgue-integrable and the square of whose sum is not Lebesgue-integrable. And this book is full of examples of this kind, nearly 240 answers to a wide area of basic analysis. One of the advantages of this book: You must not seek for a long time to find the example you are looking for. The examples are sorted in chapters each covering a distinct part of analysis. At last let me cite Mr. Gelbaum himself to characterize the scope of his book: "At the risk of oversimplification, we might say that (aside from definitions, statements and hard work) mathematics consists of two classes - proofs and counterexamples, and the mathematical discovery is directed toward two major goals - the formulation of proofs and and the construction of counterexamples." And cursing Goedel, if none of both succeeds. "Most mathematical books concentrate on the first class, the body of proofs of true statements. In the present volume we adress ourselves to the second class of mathematical objects, the counterexamples for false statements."

Rating:
Summary: Very Good To Have On Your Shelf
Review: The counterexamples here are a wonderful aid to educating intuition about definitions in Real Variables. It may sound strange, but I always thought of this book as entertaining reading: If you glance at the table of contents, you'll may find youself saying, "wait, no, that can't -- well, I guess so, but what does that look like?" In later conversations you may find youself saying: "wait a second, I seem to recall seeing somewhere a continuous nowhere differentiable function," or someting of the sort. Unfortunately, there are not a whole lot of these creatures in the book, but they are worth spending some (enjoyable) time with.