Contemporary schools of thought in the philosophy of mathematics include: artistic, Platonism, mathematicism, logicism, formalism, conventionalism, intuitionism, constructivism, finitism, structuralism, embodied mind theories (Aristotelian realism, psychologism, empiricism), fictionalism, social constructivism, and non-traditional schools. However, many of these schools of thought are mutually compatible. For example, most living mathematicians are together Platonists and formalists, give a great importance to
aesthetic, and consider that axioms should be chosen for the results they produce, not for their coherence with human intuition of reality (conventionalism).
Platonism Mathematicism Max Tegmark's
mathematical universe hypothesis (or
mathematicism) goes further than Platonism in asserting that not only do all mathematical objects exist, but nothing else does. Tegmark's sole postulate is:
All structures that exist mathematically also exist physically. That is, in the sense that "in those [worlds] complex enough to contain self-aware substructures [they] will subjectively perceive themselves as existing in a physically 'real' world".
Logicism Logicism is the thesis that mathematics is reducible to logic, and hence nothing but a part of logic. Logicists hold that mathematics can be known
a priori, but suggest that our knowledge of mathematics is just part of our knowledge of logic in general, and is thus
analytic, not requiring any special faculty of mathematical intuition. In this view,
logic is the proper foundation of mathematics, and all mathematical statements are necessary
logical truths.
Rudolf Carnap (1931) presents the logicist thesis in two parts: In deductivism, the Pythagorean theorem is not an absolute truth, but a relative one, if it follows deductively from the appropriate axioms. The same is held to be true for all other mathematical statements. Formalism need not mean that mathematics is nothing more than a meaningless symbolic game. It is usually hoped that there exists some interpretation in which the rules of the game hold. (Compare this position to
structuralism.) But it does allow the working mathematician to continue in his or her work and leave such problems to the philosopher or scientist. Many formalists would say that in practice, the axiom systems to be studied will be suggested by the demands of science or other areas of mathematics. A major early proponent of formalism was
David Hilbert, whose
program was intended to be a
complete and
consistent axiomatization of all of mathematics. Hilbert aimed to show the consistency of mathematical systems from the assumption that the "finitary arithmetic" (a subsystem of the usual
arithmetic of the positive
integers, chosen to be philosophically uncontroversial) was consistent. Hilbert's goals of creating a system of mathematics that is both complete and consistent were seriously undermined by the second of
Gödel's incompleteness theorems, which states that sufficiently expressive consistent axiom systems can never prove their own consistency. Since any such axiom system would contain the finitary arithmetic as a subsystem, Gödel's theorem implied that it would be impossible to prove the system's consistency relative to that (since it would then prove its own consistency, which Gödel had shown was impossible). Thus, in order to show that any
axiomatic system of mathematics is in fact consistent, one needs to first assume the consistency of a system of mathematics that is in a sense stronger than the system to be proven consistent. Hilbert was initially a deductivist, but, as may be clear from above, he considered certain metamathematical methods to yield intrinsically meaningful results and was a realist with respect to the finitary arithmetic. Later, he held the opinion that there was no other meaningful mathematics whatsoever, regardless of interpretation. Other formalists, such as
Rudolf Carnap,
Alfred Tarski, and
Haskell Curry, considered mathematics to be the investigation of
formal axiom systems.
Mathematical logicians study formal systems but are just as often realists as they are formalists. Formalists are relatively tolerant and inviting to new approaches to logic, non-standard number systems, new set theories, etc. The more games we study, the better. However, in all three of these examples, motivation is drawn from existing mathematical or philosophical concerns. The "games" are usually not arbitrary. The main critique of formalism is that the actual mathematical ideas that occupy mathematicians are far removed from the string manipulation games mentioned above. Formalism is thus silent on the question of which axiom systems ought to be studied, as none is more meaningful than another from a formalistic point of view. Recently, some formalist mathematicians have proposed that all of our
formal mathematical knowledge should be systematically encoded in
computer-readable formats, so as to facilitate
automated proof checking of mathematical proofs and the use of
interactive theorem proving in the development of mathematical theories and computer software. Because of their close connection with
computer science, this idea is also advocated by mathematical intuitionists and constructivists in the "computability" tradition—.
Conventionalism The French
mathematician Henri Poincaré was among the first to articulate a
conventionalist view. Poincaré's use of
non-Euclidean geometries in his work on
differential equations convinced him that
Euclidean geometry should not be regarded as
a priori truth. He held that
axioms in geometry should be chosen for the results they produce, not for their apparent coherence with human intuitions about the physical world.
Intuitionism In mathematics, intuitionism is a program of methodological reform whose motto is that "there are no non-experienced mathematical truths" (
L. E. J. Brouwer). From this springboard, intuitionists seek to reconstruct what they consider to be the corrigible portion of mathematics in accordance with Kantian concepts of being, becoming, intuition, and knowledge. Brouwer, the founder of the movement, held that mathematical objects arise from the
a priori forms of the volitions that inform the perception of empirical objects. A major force behind intuitionism was
L. E. J. Brouwer, who rejected the usefulness of formalized logic of any sort for mathematics. His student
Arend Heyting postulated an
intuitionistic logic, different from the classical
Aristotelian logic; this logic does not contain the
law of the excluded middle and therefore frowns upon
proofs by contradiction. The
axiom of choice is also rejected in most intuitionistic set theories, though in some versions it is accepted. In intuitionism, the term "explicit construction" is not cleanly defined, and that has led to criticisms. Attempts have been made to use the concepts of
Turing machine or
computable function to fill this gap, leading to the claim that only questions regarding the behavior of finite
algorithms are meaningful and should be investigated in mathematics. This has led to the study of the
computable numbers, first introduced by
Alan Turing. Not surprisingly, then, this approach to mathematics is sometimes associated with theoretical
computer science.
Constructivism Like intuitionism, constructivism involves the regulative principle that only mathematical entities which can be explicitly constructed in a certain sense should be admitted to mathematical discourse. In this view, mathematics is an exercise of the human intuition, not a game played with meaningless symbols. Instead, it is about entities that we can create directly through mental activity. In addition, some adherents of these schools reject non-constructive proofs, such as using proof by contradiction when showing the existence of an object or when trying to establish the truth of some proposition. Important work was done by
Errett Bishop, who managed to prove versions of the most important theorems in
real analysis as
constructive analysis in his 1967
Foundations of Constructive Analysis. Finitism Finitism is an extreme form of
constructivism, according to which a mathematical object does not exist unless it can be constructed from
natural numbers in a
finite number of steps. In her book
Philosophy of Set Theory,
Mary Tiles characterized those who allow
countably infinite objects as classical finitists, and those who deny even countably infinite objects as strict finitists. The most famous proponent of finitism was
Leopold Kronecker, who said:
Ultrafinitism is an even more extreme version of finitism, which rejects not only infinities but finite quantities that cannot feasibly be constructed with available resources. Another variant of finitism is Euclidean arithmetic, a system developed by
John Penn Mayberry in his book
The Foundations of Mathematics in the Theory of Sets. Mayberry's system is Aristotelian in general inspiration and, despite his strong rejection of any role for operationalism or feasibility in the foundations of mathematics, comes to somewhat similar conclusions, such as, for instance, that super-exponentiation is not a legitimate finitary function.
Structuralism Structuralism is a position holding that mathematical theories describe structures, and that mathematical objects are exhaustively defined by their
places in such structures, consequently having no
intrinsic properties. For instance, it would maintain that all that needs to be known about the number 1 is that it is the first whole number after 0. Likewise all the other whole numbers are defined by their places in a structure, the
number line. Other examples of mathematical objects might include
lines and
planes in geometry, or elements and operations in
abstract algebra. Structuralism is an
epistemologically realistic view in that it holds that mathematical statements have an objective truth value. However, its central claim only relates to what
kind of entity a mathematical object is, not to what kind of
existence mathematical objects or structures have (not, in other words, to their
ontology). The kind of existence mathematical objects have would clearly be dependent on that of the structures in which they are embedded; different sub-varieties of structuralism make different ontological claims in this regard. The
ante rem structuralism ("before the thing") has a similar ontology to
Platonism. Structures are held to have a real but abstract and immaterial existence. As such, it faces the standard epistemological problem of explaining the interaction between such abstract structures and flesh-and-blood mathematicians . The
in re structuralism ("in the thing") is the equivalent of
Aristotelian realism. Structures are held to exist inasmuch as some concrete system exemplifies them. This incurs the usual issues that some perfectly legitimate structures might accidentally happen not to exist, and that a finite physical world might not be "big" enough to accommodate some otherwise legitimate structures. The
post rem structuralism ("after the thing") is
anti-realist about structures in a way that parallels
nominalism. Like nominalism, the
post rem approach denies the existence of abstract mathematical objects with properties other than their place in a relational structure. According to this view mathematical
systems exist, and have structural features in common. If something is true of a structure, it will be true of all systems exemplifying the structure. However, it is merely instrumental to talk of structures being "held in common" between systems: they in fact have no independent existence.
Embodied mind theories Embodied mind theories hold that mathematical thought is a natural outgrowth of the human cognitive apparatus which finds itself in our physical universe. For example, the abstract concept of
number springs from the experience of counting discrete objects (requiring the human senses such as sight for detecting the objects, touch; and signalling from the brain). It is held that mathematics is not universal and does not exist in any real sense, other than in human brains. Humans construct, but do not discover, mathematics. The cognitive processes of pattern-finding and distinguishing objects are also subject to
neuroscience; if mathematics is considered to be relevant to a natural world (such as from
realism or a degree of it, as opposed to pure
solipsism). Its actual relevance to reality, while accepted to be a trustworthy approximation (it is also suggested the
evolution of perceptions, the body, and the senses may have been necessary for survival) is not necessarily accurate to a full realism (and is still subject to flaws such as
illusion, assumptions (consequently; the foundations and axioms in which mathematics have been formed by humans), generalisations, deception, and
hallucinations). As such, this may also raise questions for the modern
scientific method for its compatibility with general mathematics; as while relatively reliable, it is still limited by what can be measured by
empiricism which may not be as reliable as previously assumed (see also: 'counterintuitive' concepts in such as
quantum nonlocality, and
action at a distance). Another issue is that one
numeral system may not necessarily be applicable to problem solving. Subjects such as
complex numbers or
imaginary numbers require specific changes to more commonly used axioms of mathematics; otherwise they cannot be adequately understood. Alternatively, computer programmers may use
hexadecimal for its 'human-friendly' representation of
binary-coded values, rather than
decimal (convenient for counting because humans have ten fingers). The axioms or logical rules behind mathematics also vary through time (such as the invention and adaptation of
zero). As
perceptions from the human brain are subject to
illusions, assumptions, deceptions, (induced)
hallucinations, cognitive errors or assumptions in a general context, it can be questioned whether they are accurate or strictly indicative of truth (see also:
philosophy of being), and the nature of
empiricism itself in relation to the universe and whether it is independent to the senses and the universe. The human mind has no special claim on reality or approaches to it built out of math. If such constructs as
Euler's identity are true then they are true as a map of the human mind and
cognition. Embodied mind theorists thus explain the effectiveness of mathematics—mathematics was constructed by the brain in order to be effective in this universe. The most accessible, famous, and infamous treatment of this perspective is
Where Mathematics Comes From, by
George Lakoff and
Rafael E. Núñez. In addition, mathematician
Keith Devlin has investigated similar concepts with his book
The Math Instinct, as has neuroscientist
Stanislas Dehaene with his book
The Number Sense.
Aristotelian realism Aristotelian realism holds that mathematics studies properties such as symmetry, continuity and order that can be literally realized in the physical world (or in any other world there might be). It contrasts with Platonism in holding that the objects of mathematics, such as numbers, do not exist in an "abstract" world but can be physically realized. For example, the number 4 is realized in the relation between a heap of parrots and the universal "being a parrot" that divides the heap into so many parrots. Aristotelian realism is defended by
James Franklin and the Sydney School in the philosophy of mathematics and is close to the view of
Penelope Maddy that when an egg carton is opened, a set of three eggs is perceived (that is, a mathematical entity realized in the physical world). A problem for Aristotelian realism is what account to give of higher infinities, which may not be realizable in the physical world. The Euclidean arithmetic developed by
John Penn Mayberry in his book
The Foundations of Mathematics in the Theory of Sets it makes statements like come out as uncertain, contingent truths, which we can only learn by observing instances of two pairs coming together and forming a quartet.
Karl Popper was another philosopher to point out empirical aspects of mathematics, observing that "most mathematical theories are, like those of physics and biology, hypothetico-deductive: pure mathematics therefore turns out to be much closer to the natural sciences whose hypotheses are conjectures, than it seemed even recently." Popper also noted he would "admit a system as empirical or scientific only if it is capable of being tested by experience." Contemporary mathematical empiricism, formulated by
W. V. O. Quine and
Hilary Putnam, is primarily supported by the
indispensability argument: mathematics is indispensable to all empirical sciences, and if we want to believe in the reality of the phenomena described by the sciences, we ought also believe in the reality of those entities required for this description. That is, since physics needs to talk about
electrons to say why light bulbs behave as they do, then electrons must
exist. Since physics needs to talk about numbers in offering any of its explanations, then numbers must exist. In keeping with Quine and Putnam's overall philosophies, this is a naturalistic argument. It argues for the existence of mathematical entities as the best explanation for experience, thus stripping mathematics of being distinct from the other sciences. Putnam strongly rejected the term "
Platonist" as implying an over-specific
ontology that was not necessary to
mathematical practice in any real sense. He advocated a form of "pure realism" that rejected mystical notions of
truth and accepted much
quasi-empiricism in mathematics. This grew from the increasingly popular assertion in the late 20th century that no one
foundation of mathematics could be ever proven to exist. It is also sometimes called "postmodernism in mathematics" although that term is considered overloaded by some and insulting by others. Quasi-empiricism argues that in doing their research, mathematicians test hypotheses as well as prove theorems. A mathematical argument can transmit falsity from the conclusion to the premises just as well as it can transmit truth from the premises to the conclusion. Putnam has argued that any theory of mathematical realism would include quasi-empirical methods. He proposed that an alien species doing mathematics might well rely on quasi-empirical methods primarily, being willing often to forgo rigorous and axiomatic proofs, and still be doing mathematics—at perhaps a somewhat greater risk of failure of their calculations. He gave a detailed argument for this in
New Directions. Quasi-empiricism was also developed by
Imre Lakatos. The most important criticism of empirical views of mathematics is approximately the same as that raised against Mill. If mathematics is just as empirical as the other sciences, then this suggests that its results are just as fallible as theirs, and just as contingent. In Mill's case the
empirical justification comes directly, while in Quine's case it comes indirectly, through the coherence of our scientific theory as a whole, i.e.
consilience after
E.O. Wilson. Quine suggests that mathematics seems completely certain because the role it plays in our web of belief is extraordinarily central, and that it would be extremely difficult for us to revise it, though not impossible. For a philosophy of mathematics that attempts to overcome some of the shortcomings of Quine and Gödel's approaches by taking aspects of each see
Penelope Maddy's
Realism in Mathematics. Another example of a realist theory is the
embodied mind theory.
Fictionalism Mathematical fictionalism was brought to fame in 1980 when
Hartry Field published
Science Without Numbers, which rejected and in fact reversed Quine's indispensability argument. Where Quine suggested that mathematics was indispensable for our best scientific theories, and therefore should be accepted as a body of truths talking about independently existing entities, Field suggested that mathematics was dispensable, and therefore should be considered as a body of falsehoods not talking about anything real. He did this by giving a complete axiomatization of
Newtonian mechanics with no reference to numbers or functions at all. He started with the "betweenness" of
Hilbert's axioms to characterize space without coordinatizing it, and then added extra relations between points to do the work formerly done by
vector fields. Hilbert's geometry is mathematical, because it talks about abstract points, but in Field's theory, these points are the concrete points of physical space, so no special mathematical objects at all are needed. Having shown how to do science without using numbers, Field proceeded to rehabilitate mathematics as a kind of
useful fiction. He showed that mathematical physics is a
conservative extension of his non-mathematical physics (that is, every physical fact provable in mathematical physics is already provable from Field's system), so that mathematics is a reliable process whose physical applications are all true, even though its own statements are false. Thus, when doing mathematics, we can see ourselves as telling a sort of story, talking as if numbers existed. For Field, a statement like is just as fictitious as "
Sherlock Holmes lived at 221B Baker Street"—but both are true according to the relevant fictions. Another fictionalist,
Mary Leng, expresses the perspective succinctly by dismissing any seeming connection between mathematics and the physical world as "a happy coincidence". This rejection separates fictionalism from other forms of anti-realism, which see mathematics itself as artificial but still bounded or fitted to reality in some way. By this account, there are no metaphysical or epistemological problems special to mathematics. The only worries left are the general worries about non-mathematical physics, and about
fiction in general. Field's approach has been very influential, but is widely rejected. This is in part because of the requirement of strong fragments of
second-order logic to carry out his reduction, and because the statement of conservativity seems to require
quantification over abstract models or deductions.
Social constructivism Social constructivism sees mathematics primarily as a
social construct, as a product of culture, subject to correction and change. Like the other sciences, mathematics is viewed as an empirical endeavor whose results are constantly evaluated and may be discarded. However, while on an empiricist view the evaluation is some sort of comparison with "reality", social constructivists emphasize that the direction of mathematical research is dictated by the fashions of the social group performing it or by the needs of the society financing it. However, although such external forces may change the direction of some mathematical research, there are strong internal constraints—the mathematical traditions, methods, problems, meanings and values into which mathematicians are enculturated—that work to conserve the historically defined discipline. This runs counter to the traditional beliefs of working mathematicians, that mathematics is somehow pure or objective. But social constructivists argue that mathematics is in fact grounded by much uncertainty: as
mathematical practice evolves, the status of previous mathematics is cast into doubt, and is corrected to the degree it is required or desired by the current mathematical community. This can be seen in the development of analysis from reexamination of the calculus of Leibniz and Newton. They argue further that finished mathematics is often accorded too much status, and
folk mathematics not enough, due to an overemphasis on axiomatic proof and peer review as practices. The social nature of mathematics is highlighted in its
subcultures. Major discoveries can be made in one branch of mathematics and be relevant to another, yet the relationship goes undiscovered for lack of social contact between mathematicians. Social constructivists argue each speciality forms its own
epistemic community and often has great difficulty communicating, or motivating the investigation of
unifying conjectures that might relate different areas of mathematics. Social constructivists see the process of "doing mathematics" as actually creating the meaning, while social realists see a deficiency either of human capacity to abstractify, or of human's
cognitive bias, or of mathematicians'
collective intelligence as preventing the comprehension of a real universe of mathematical objects. Social constructivists sometimes reject the search for foundations of mathematics as bound to fail, as pointless or even meaningless. Contributions to this school have been made by
Imre Lakatos and
Thomas Tymoczko, although it is not clear that either would endorse the title. More recently
Paul Ernest has explicitly formulated a social constructivist philosophy of mathematics. Some consider the work of
Paul Erdős as a whole to have advanced this view (although he personally rejected it) because of his uniquely broad collaborations, which prompted others to see and study "mathematics as a social activity", e.g., via the
Erdős number.
Reuben Hersh has also promoted the social view of mathematics, calling it a "humanistic" approach, similar to but not quite the same as that associated with Alvin White; one of Hersh's co-authors,
Philip J. Davis, has expressed sympathy for the social view as well.
Beyond the traditional schools Unreasonable effectiveness Rather than focus on narrow debates about the true nature of mathematical
truth, or even on practices unique to mathematicians such as the
proof, a growing movement from the 1960s to the 1990s began to question the idea of seeking foundations or finding any one right answer to why mathematics works. The starting point for this was
Eugene Wigner's famous 1960 paper "
The Unreasonable Effectiveness of Mathematics in the Natural Sciences", in which he argued that the happy coincidence of mathematics and physics being so well matched seemed to be unreasonable and hard to explain.
Popper's two senses of number statements Realist and constructivist theories are normally taken to be contraries. However,
Karl Popper argued that a number statement such as can be taken in two senses. In one sense it is irrefutable and logically true. In the second sense it is factually true and falsifiable. Another way of putting this is to say that a single number statement can express two propositions: one of which can be explained on constructivist lines; the other on realist lines.
Philosophy of language Mohan Ganesalingam has analysed mathematical language using tools from formal linguistics. Ganesalingam notes that some features of natural language are not necessary when analysing mathematical language (such as
tense), but many of the same analytical tools can be used (such as
context-free grammars). One important difference is that mathematical objects have clearly defined
types, which can be explicitly defined in a text: "Effectively, we are allowed to introduce a word in one part of a sentence, and declare its
part of speech in another; and this operation has no analogue in natural language." ==Arguments==