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In mathematics, the adjective trivial is frequently used for objects (for example, groups or topological spaces) that have a very simple structure. The noun triviality usually refers to a simple technical aspect of some proof or definition. The origin of the term in mathematical language comes from the medieval trivium curriculum. The antonym nontrivial is commonly used by mathematicians to indicate a statement or theorem that is not obvious or easy to prove.
Trivial and nontrivial solutionsEdit
In mathematics, the term trivial is frequently used for objects (for examples, groups or topological spaces) that have a very simple structure.
Examples are as follows:
- empty set: the set containing no or null members.
- trivial group: the mathematical group containing only the identity element.
- trivial ring: a ring defined on a singleton set.
Trivial can also be used to describe solutions to an equation that have a very simple structure, but for the sake of completeness cannot be omitted. These solutions are called the trivial solutions. For example, consider the differential equation
- , the zero function
while a nontrivial solution is
- , the exponential function.
The differential equation with boundary conditions is important in math and physics, for example describing a particle in a box in quantum mechanics, or standing waves on a string. It always has the solution . This solution is considered obvious and is called the "trivial" solution. In some cases, there may be other solutions (sinusoids), which are called "nontrivial".
Similarly, mathematicians often describe Fermat's Last Theorem as asserting that there are no nontrivial integer solutions to the equation when n is greater than 2. Clearly, there are some solutions to the equation. For example, is a solution for any n, but such solutions are all obvious and uninteresting, and hence "trivial".
In mathematical reasoningEdit
Trivial may also refer to any easy case of a proof, which for the sake of completeness cannot be ignored. For instance, proofs by mathematical induction have two parts: the "base case" that shows that the theorem is true for a particular initial value such as n = 0 or n = 1 and then an inductive step that shows that if the theorem is true for a certain value of n, it is also true for the value n + 1. The base case is often trivial and is identified as such, although there are situations where the base case is difficult but the inductive step is trivial. Similarly, one might want to prove that some property is possessed by all the members of a certain set. The main part of the proof will consider the case of a nonempty set, and examine the members in detail; in the case where the set is empty, the property is trivially possessed by all the members, since there are none. (See also Vacuous truth.)
A common joke in the mathematical community is to say that "trivial" is synonymous with "proved"—that is, any theorem can be considered "trivial" once it is known to be true. Another joke concerns two mathematicians who are discussing a theorem; the first mathematician says that the theorem is "trivial". In response to the other's request for an explanation, he then proceeds with twenty minutes of exposition. At the end of the explanation, the second mathematician agrees that the theorem is trivial. These jokes point out the subjectivity of judgments about triviality. The joke also applies when the first mathematician says the theorem is trivial, but is unable to prove it himself. Often, as a joke, the theorem is then referred to as "intuitively obvious". Someone experienced in calculus, for example, would consider the statement that
- to be trivial. However, to someone with no knowledge of integral calculus, this is not obvious at all.
Triviality also depends on context. A proof in functional analysis would probably, given a number, trivially assume the existence of a larger number. When proving basic results about the natural numbers in elementary number theory though, the proof may very well hinge on the remark that any natural number has a successor (which should then in itself be proved or taken as an axiom, see Peano's axioms).
In some texts, a trivial proof refers to a statement involving a material implication where the consequent, or Q, in P→Q, is always true. Here, the proof follows simply from noting that Q is always true, as the implication is then true regardless of the truth value of the antecedent, P.
A related concept is a vacuous truth, where the antecedent, P, in the material implication P→Q is always false. Here, the implication is always true regardless of the truth value of the consequent, Q.
- In number theory, it is often important to find factors of an integer number N. Any number N has four obvious factors: ±1 and ±N. These are called "trivial factors". Any other factor, if any exist, would be called "nontrivial".
- The matrix equation , where is a fixed matrix, is an unknown vector, and is the zero vector, has an obvious solution . This is called the "trivial solution". If it has other solutions , they would be called "nontrivial"
- In the mathematics of group theory, there is a very simple group with just one element in it; this is often called the "trivial group". All other groups, which are more complicated, are called "nontrivial".
- In graph theory the trivial graph is a graph which has only 1 vertex and no edges.
- Database theory has a concept called functional dependency, written . The dependence is true if Y is a subset of X, so this type of dependence is called "trivial". All other dependences, which are less obvious, are called "nontrivial".
- It can be shown that Riemann's zeta function has zeros at the negative even numbers -2, -4, ... Though the proof is comparatively easy, this result would still not normally be called trivial; however, it is in this case, for its other zeros are not generally known and have important applications and involve open questions (such as the Riemann hypothesis); and so, the negative even numbers are called the trivial zeros, and any other zeros are called non-trivial.
- Zachmanoglou, E. C.; Thoe, Dale W. (1986). Introduction to Partial Differential Equations with Applications. p. 309.
- Chartrand, Gary; Polimeni, Albert D.; Zhang, Ping (2008). Mathematical proofs : a transition to advanced mathematics (2nd ed.). Boston: Pearson/Addison Wesley. p. 68. ISBN 978-0-3-2139053-0.
- Yan, Song Y. (2002). Number Theory for Computing (2nd, illustrated ed.). Berlin: Springer. p. 250. ISBN 3-540-43072-5.
- Jeffrey, Alan (2004). Mathematics for Engineers and Scientists (Sixth ed.). CRC Press. p. 502. ISBN 1-58488-488-6.