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Principia Mathematica
Principia Mathematica, the landmark work written by
Alfred North Whitehead and
Bertrand Russell,
and published in three volumes, in 1910, 1912 and 1913. Written as a
defense of logicism (i.e., the view that mathematics is in some
significant sense reducible to logic) the book was instrumental in
developing and popularizing modern mathematical logic. It also served
as a major impetus for research in the foundations of mathematics
throughout the twentieth century. Next to Aristotle's
Organon, it remains the most influential book on logic ever
written.
Interested readers may also wish to view the
Logicism is the view that (some or all of) mathematics can be reduced
to (formal) logic. It is often explained as a two-part thesis. First,
it consists of the claim that all mathematical truths can be
translated into logical truths or, in other words, that the vocabulary
of mathematics constitutes a proper subset of the vocabulary of
logic. Second, it consists of the claim that all mathematical proofs
can be recast as logical proofs or, in other words, that the theorems
of mathematics constitute a proper subset of the theorems of logic. In
Bertrand Russell's words, it is the logicist's goal "to show that all
pure mathematics follows from purely logical premises and uses only
concepts definable in logical
terms."[1]
In its essentials, logicism was first advocated in the late seventeenth
century by Gottfried Leibniz. Later, the idea was defended in
greater detail by
Gottlob Frege.
During the critical movement initiated in the 1820s, mathematicians
such as Bernard Bolzano, Niels Abel, Louis Cauchy and Karl Weierstrass
succeeded in eliminating much of the vagueness and many of the
contradictions present in the mathematical theories of their day. By
the late 1800s, William Hamilton had also introduced ordered couples
of reals as the first step in supplying a logical basis for the
complex numbers. In much the same spirit, Karl Weierstrass, Richard
Dedekind and Georg Cantor had also all developed methods for founding
the irrationals in terms of the rationals. Using work by
H.G. Grassmann and Richard Dedekind, Guiseppe Peano had then gone on
to develop a theory of the rationals based on his now famous axioms
for the natural numbers. Thus, by Frege's day, it was generally
recognized that a large portion of mathematics could be derived from a
relatively small set of primitive notions.
Even so, it was not until 1879, when Frege developed the necessary
logical apparatus, that the project of logicism could be said to have
become technically plausible. Following another five years' work,
Frege arrived at the definitions necessary for logicising arithmetic
and, during the 1890s, he worked on many of the essential
derivations. However, with the discovery of paradoxes such as
Russell's paradox
at the turn of the century, it appeared that additional resources
would need to be postulated if logicism were to succeed.
By 1903, both Whitehead and Russell had reached this same conclusion.
By this time, both men were in the initial stages of preparing second
volumes to earlier books on related topics: Whitehead's 1898 A
Treatise on Universal Algebra and Russell's 1903 The
Principles of Mathematics. Since their research overlapped
considerably, they began collaborating on what would eventually become
Principia Mathematica. By agreement, Russell worked primarily
on the philosophical parts of the project (including the
philosophically rich Introduction, the theory of descriptions, and the
no-class theory), while the two men collaborated on the technical
derivations. Intially, it was thought that the project might take a
year to complete.
Unfortunately, after almost a decade of difficult work on the part
of both men, Cambridge University Press concluded that publishing
Principia would result in an estimated loss of approximately 600
pounds. Although the press agreed to assume half this amount and the
Royal Society agreed to donate another 200 pounds, that still left a
100-pound deficit. Only by each contributing 50 pounds were the authors
able to see their work through to publication.
Today there is not a major academic library anywhere in the world
that does not possess a copy of this landmark publication.
Achieving Principia's main goal proved to be
controversial. Primarily at issue were the kinds of assumptions that
Whitehead and Russell needed to complete their project. Although
Principia succeeded in providing detailed derivations of many
major theorems in set theory, finite and transfinite arithmetic, and
elementary measure theory, two axioms in particular were arguably
non-logical in character: the axiom of infinity and the axiom of
reducibility. The axiom of infinity in effect stated that there exists
an infinite number of objects. Thus, it made the kind of assumption
that is generally thought to be empirical rather than logical in
nature. The axiom of reducibility was introduced as a means of
overcoming the not completely satisfactory effects of the theory of
types, the theory that Russell and Whitehead used to restrict the
notion of a well-formed expression, and so to avoid paradoxes such as
Russell's paradox.
Although technically feasible, many critics concluded that the axiom
of reducibility was simply too ad hoc to be justified
philosophically. As a result, the question of whether mathematics
could be reduced to logic, or whether it could be reduced only to set
theory, remained open.
Despite these criticisms, Principia Mathematica proved to be
remarkably influential in at least three other ways. First, it
popularized modern mathematical logic to an extent undreamt of by its
authors. By using a notation superior in many ways to that of Frege,
Whitehead and Russell managed to convey the remarkable expressive
power of modern predicate logic in a way that previous writers had
been unable to achieve. Second, by exhibiting so clearly the deductive
power of the new logic, Whitehead and Russell were able to show how
powerful the modern idea of a formal system could be, thus opening up
new work in what was soon to be called metalogic. Third, Principia
Mathematica reaffirmed clear and interesting connections between
logicism and two main branches of traditional philosophy, namely
metaphysics and epistemology, thus initiating new and interesting work
in both these and other areas.
Thus, not only did Principia introduce a wide range of
philosophically rich notions (such as propositional function, logical
construction, and type theory), it also set the stage for the
discovery of classical metatheoretic results (such as those of Kurt
Gödel and others) and initiated a tradition of common technical
work in fields as diverse as philosophy, mathematics, linguistics,
economics and computer science.
Today there remains controversy over the ultimate substantive
contribution of Principia, with some authors holding that,
with the appropriate modifications, logicism remains a feasible
project. Others hold that the philosophical and technical
underpinnings of the Whitehead/Russell project simply remain too weak
or confused to be of much use to the logicist. Interested readers are
encouraged to consult Hale and Wright (2001), Quine (1966a), Quine
(1966b), Landini (1998) and Linsky (1999).
Principia Mathematica originally appeared in three
volumes. Together these three volumes are divided into six
parts. Volume 1 begins with a lengthy Introduction containing sections
entitled "Preliminary Explanations of Ideas and Notations," "The
Theory of Logical Types," and "Incomplete Symbols." It also contains
Part I, entitled "Mathematical Logic," which contains sections on "The
Theory of Deduction," "Theory of Apparent Variables," "Classes and
Relations," "Logic of Relations," and "Products and Sums of Classes";
and Part II, entitled "Prolegomena to Cardinal Arithmetic," which
contains sections on "Unit Classes and Couples," "Sub-Classes,
Sub-Relations, and Relative Types," "One-Many, Many-One and One-One
Relations," "Selections," and "Inductive Relations."
Volume 2 begins with a "Prefatory Statement of Symbolic Conventions."
It then continues with Part III, entitled "Cardinal Arithmetic," which
itself contains sections on "Definition and Logical Properties of
Cardinal Numbers," "Addition, Multiplication and Exponentiation," and
"Finite and Infinite"; Part IV, entitled Relation-Arithmetic," which
contains sections on "Ordinal Similarity and Relation-Numbers,"
"Addition of Relations, and the Product of Two Relations," "The
Principle of First Differences, and the Multiplication and
Exponentiation of Relations," and "Arithmetic of Relation-Numbers";
and the first half of Part V, entitled "Series," which contains
sections on "General Theory of Series," "On Sections, Segments,
Stretches, and Derivatives," and "On Convergence, and the Limits of
Functions."
Volume 3 continues Part V with sections on "Well-Ordered Series,"
"Finite and Infinite Series and Ordinals," and "Compact Series,
Rational Series, and Continuous Series." It also contains Part VI,
entitled "Quantity," which itself contains sections on "Generalization
of Number," "Vector-Families," "Measurement," and "Cyclic
Families."
A fourth volume was planned but never completed.
Contemporary readers (i.e., those who have learned logic in the second
half of the twentieth century or later) will find the book's notation
somewhat antiquated and clumsy. Even so, the book remains one of the
great scientific documents of the twentieth century.
- Chihara, Charles (1973) Ontology and the Vicious Circle
Principle, Ithaca: Cornell University Press.
- Church, Alonzo (1978) "A Comparison of Russell's Resolution of the
Semantical Antinomies with that of Tarski," Journal of Symbolic
Logic, 41, 747-760. Repr. in Irvine, A.D., Bertrand Russell:
Critical Assessments, vol. 2, New York and London: Routledge,
1999, 96-112.
- Church, Alonzo (1974) "Russellian Simple Type Theory,"
Proceedings and Addresses of the American Philosophical
Association, 47, 21-33.
- Copi, Irving (1971) The Theory of Types, London:
Routledge and Kegan Paul.
- Frege, Gottlob (1893, 1903) Grundgesetze der Arithmetik,
Band I (1893), Band II (1903), Jena: Verlag Hermann Pohle. Ed. and
trans. in part by M. Furth as The Basic Laws of Arithmetic,
Berkeley: University of California Press, 1964.
- Hale, Bob, and Crispin Wright (2001) The Reason's Proper
Study, Oxford: Clarendon Press.
- Landini, Gregory (1998) Russell's Hidden Substitutional
Theory, New York and Oxford: Oxford University Press.
- Linsky, Bernard (1999) Russell's Metaphysical Logic,
Stanford: CSLI Publications.
- Quine, W.V (1960) Word and Object, Cambridge: MIT
Press.
- Quine, W.V (1966a) Selected Logic Papers, New York:
Random House.
- Quine, W.V (1966b) Ways of Paradox, New York: Random
House.
- Ramsey, Frank P. (1931) The Foundations of Mathematics,
London: Kegan, Paul, Trench, Trubner.
- Rodriguez-Consuegra, Francisco (1991) The Mathematical
Philosophy of Bertrand Russell, Boston: Birkhäuser Press.
- Russell, Bertrand (1903) Principles of Mathematics,
Cambridge: Cambridge University Press.
- Russell, Bertrand (1919) Introduction to Mathematical
Philosophy, London: George Allen and Unwin.
- Russell, Bertrand (1948) "Whitehead and Principia
Mathematica," Mind, 57, 137-138.
- Russell, Bertrand (1955) My Philosophical Development,
London and New York: Routledge.
- Urquhart, Alasdair (1988) "Russell's Zig-Zag Path to the Ramified
Theory of Types," Russell, 8, 82-91.
- Whitehead, Alfred North (1898) A Treatise on Universal
Algebra, Cambridge: Cambridge University Press.
- Whitehead, Alfred North (1906) On Mathematical Concepts of the
Material World, London: Dulau.
- Whitehead, Alfred North, and Bertrand Russell (1910, 1912, 1913)
Principia Mathematica, 3 vols, Cambridge: Cambridge
University Press. Second edition, 1925 (Vol. 1), 1927 (Vols 2,
3). Abridged as Principia Mathematica to *56, Cambridge:
Cambridge University Press, 1962.
- Wright, Crispin (1983) Frege's Conception of Numbers as
Objects, Aberdeen: Aberdeen University Press.
Frege, Gottlob |
Frege, Gottlob: logic, theorem, and foundations for arithmetic |
Leibniz, Gottfried Wilhelm |
logic: classical |
logicism |
propositional function |
Russell, Bertrand |
Russell’s paradox |
type theory |
Whitehead, Alfred North
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Stanford Encyclopedia of Philosophy