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[email protected]
Associate Professor
University of Latvia
Institute of Mathematics and Computer Science

LU studentiem

My favorite (printed) textbook
on mathematical logic, since many years:
"
Introduction to Mathematical Logic"
by Elliott Mendelson

StudyWeb Award
Diploma

What is Mathematics:
G�del's Theorem and Around

Hyper-textbook for students,
by Karlis Podnieks

English version - Russian version


Diploma
  My best mathematical paper and publication list My book about probabilities
Gallery Hegel, Marx, and Goedel's theorem. An Essay. Kurt G�del and his famous theorem. Lecture slides.
Digital mathematics and non-digital mathematics Trying to understand non-formalists. An Essay. "Let X = X But Not Necessarily",
by William J. Greenberg

Introduction to Mathematical Logic

Hyper-textbook for students
by Vilnis Detlovs and Karlis Podnieks
University of Latvia

Quote of the Day

From: Harvey Friedman ...
Sent: Monday, January 17, 2005 4:09 AM
Subject: [FOM] Atlanta Meeting

...
I asked the panel members whether they were interested in this line of investigation: no simple axiom settling the continuum hypothesis.
Woodin responded by saying that, overwhelmingly, he really wanted to know whether the continuum hypothesis is true or false. He is far more interested in pursuing that, as he is now, than any considerations of simplicity, which for him, was a side issue.
Martin responded by saying that the projective determinacy experience showed that one could have axioms with simple statements, but with very complicated explanations as to why they are correct.
I did not have an opportunity to respond to Martin's statement - I would have said that by the standards of axioms for set theory, projective determinacy is NOT simple. It is far more complicated than any accepted axiom for set theory.
I did ask Cohen specifically to comment on whether simplicity (of a new axiom to settle the continuum hypothesis) was important for him. Cohen responded by saying that such an axiom, for him, must be simple.
Let me end here with something concrete. In my papers in Fund. Math., and in J. Math. Logic, it is proved that all 3 quantifier sentences in set theory (epsilon,=) are decided in a weak fragment of ZF, and there is a 5 quantifier sentence that is not decided in ZFC (it is equivalent to a large
cardinal axiom over ZFC). All of the axioms of ZF are an at most four quantifier sentence and an at most five quantifier axiom scheme. It has been shown that AxC over ZF is equivalent to a five quantifier sentence (see Notre Dame Journal, not me). Show that over ZFC, any equivalence of the
continuum hypothesis requires a lot more quantifiers. Show that over ZFC, any statement consistent with ZFC that settles the continuum hypothesis, requires a lot more quantifiers.
...

Full text at http://www.cs.nyu.edu/pipermail/fom/2005-January/008756.html

Previous quotes

What is mathematics?

Four provably equivalent definitions of mathematics:

Mathematics is the part of science you could continue to do if you woke up tomorrow and discovered the universe was gone.
I do not know the author of this elegant definition put on the web by Dave Rusin.

The human mind has first to construct forms, independently, before we can find them in things.
Albert Einstein, see Quotations by Albert Einstein

In mathematics you don't understand things. You just get used to them.
John von Neumann, see Quotations by John von Neumann).

Mathematicians are mad tailors: they are making "all the possible clothes" hoping to make also something suitable for dressing...
Stanislaw Lem, "Summa Technologiae" (sorry - my own English translation, the initial version of this aphorism may be due to David van Dantzig, see Quotations by David van Dantzig)

My Main Theses

I define mathematical theories as stable self-contained systems of reasoning, and formal theories - as mathematical models of such systems. Working with stable self-contained models mathematicians have learned to draw a maximum of conclusions from a minimum of premises. This is why mathematical modeling is so efficient.

For me, Goedel's results are the crucial evidence that stable self-contained systems of reasoning cannot be perfect (just because they are stable and self-contained). Such systems are either very restricted in power (i.e. they cannot express the notion of natural numbers with induction principle), or they are powerful enough, yet then they lead inevitably either to contradictions, or to undecidable propositions.

For humans, Platonist thinking is the best way of working with stable self-contained systems. Thus, a correct philosophical position of a mathematician should be: a) Platonism - on working days - when I'm doing mathematics (otherwise, my "doing" will be inefficient), b) Advanced Formalism - on weekends - when I'm thinking "about" mathematics (otherwise, I will end up in mysticism). (The initial version of this aphorism is due to Reuben Hersh).

Next step

The idea that stable self-contained system of basic principles is the distinctive feature of mathematical theories, can be regarded only as the first step in discovering the nature of mathematics. Without the next step, we would end up by representing mathematics as an unordered heap of mathematical theories!

In fact, mathematics is a complicated system of interrelated theories each representing some significant mathematical structure (natural numbers, real numbers, sets, groups, fields, algebras, all kinds of spaces, graphs, categories, computability, all kinds of logic, etc.).

Thus, we should think of mathematics as a "two-dimensional" activity. Most of a mathematician's working time is spent along the first dimension (working in a fixed mathematical theory, on a fixed mathematical structure), but, sometimes, he/she needs also moving along the second dimension (changing his/her theories/structures or, inventing new ones).

Do we need more than this, to understand the nature of mathematics?

Whether your own philosophy of mathematics
is Platonism, or not,

can be easily determined by using the following test. Let us consider the twin prime number sequence:

(3, 5), (5, 7), (11, 13), (17, 19), (29, 31), (41, 43), (59, 61), (71,73), (101, 103), (107,109),
(137, 139), (149, 151), (179, 181), (191, 193), ..., (1787, 1789), ..., (1871, 1873), ...,
(1931, 1933), (1949, 1951), (1997, 1999), (2027, 2029), ...

It is believed that there are infinitely many twin pairs (the famous twin prime conjecture), yet the problem remains unsolved up to day. Suppose, someone has proved that the twin prime conjecture is unprovable in set theory. Do you believe that, still, the twin prime conjecture possesses an "objective truth value"? Imagine, you are moving along the natural number system:

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, ...

And you meet twin pairs in it from time to time: (3, 5), (5, 7), (11, 13), (17, 19), (29, 31), (41, 43), (59, 61), (71,73), ... It seems there are only two possibilities:

a) We meet the last pair and after that moving forward we do not meet any twin pairs (i.e. the twin prime conjecture is false),

b) Twin pairs appear over and again (i.e. the twin prime conjecture is true).

It seems impossible to imagine a third possibility...

If you think so, you are, in fact, a Platonist. You are used to treat natural number system as a specific "world", very like the world of your everyday practice. You are used to think that any sufficiently definite assertion about things in this world must be either true or false. And, if you regard natural number system as a specific "world", you cannot imagine a third possibility: maybe, the twin prime conjecture is neither true nor false. Still, such a possibility would not surprise you if you would realize that the natural number system contains not only some information about real things of human practice, it also contains many elements of fantasy. Why do you think that such a fantastic "world" (a kind of Disneyland) should be completely perfect? To continue click here.

Disappointed?

Visit the online resource center Foundations of Mathematics by Alexander Sakharov.

Visit Stanley N. Burris, the author of "Logic For Mathematics & Computer Science" (1998, Prentice Hall), especially his Supplementary Text.

Visit Peter Suber, his Kurt Godel in Blue Hill, Notes on Logic Notation on the Web, and Glossary of First-Order Logic.

Try searching for "mathematical logic" at Search the web!

mathematical logic, foundations of mathematics, philosophy of mathematics, logic, mathematical, what is mathematics, online, web, book, Internet, tutorial, textbook, foundations, mathematics, teaching, learning, study, student, Podnieks, Karlis, philosophy, free, download