Material conditional
The material conditional is a binary operation commonly used in logic. When the conditional symbol is interpreted as material implication, a formula is true unless is true and is false.
Material implication is used in all the basic systems of classical logic as well as some nonclassical logics. It is assumed as a model of correct conditional reasoning within mathematics and serves as the basis for commands in many programming languages. However, many logics replace material implication with other operators such as the strict conditional and the variably strict conditional. Due to the paradoxes of material implication and related problems, material implication is not generally considered a viable analysis of conditional sentences in natural language.
Notation
In logic and related fields, the material conditional is customarily notated with an infix operator. The material conditional is also notated using the infixes and. In the prefixed Polish notation, conditionals are notated as. In a conditional formula, the subformula is referred to as the antecedent and is termed the consequent of the conditional. Conditional statements may be nested such that the antecedent or the consequent may themselves be conditional statements, as in the formula.History
In Arithmetices Principia: Nova Methodo Exposita, Peano expressed the proposition "If, then " as Ɔ with the symbol Ɔ, which is the opposite of C. He also expressed the proposition as Ɔ. Hilbert expressed the proposition "If A, then B" as in 1918. Russell followed Peano in his Principia Mathematica, in which he expressed the proposition "If A, then B" as. Following Russell, Gentzen expressed the proposition "If A, then B" as. Heyting expressed the proposition "If A, then B" as at first but later came to express it as with a right-pointing arrow. Bourbaki expressed the proposition "If A, then B" as in 1954.Semantics
Truth table
From a classical semantic perspective, material implication is the binary truth functional operator which returns "true" unless its first argument is true and its second argument is false. This semantics can be shown graphically in the following truth table:One can also consider the equivalence.
The conditionals where the antecedent is false, are called "vacuous truths".
Examples are...
- ... with false: "If Marie Curie is a sister of Galileo Galilei, then Galileo Galilei is a brother of Marie Curie."
- ... with true: ''"If Marie Curie is a sister of Galileo Galilei, then Marie Curie has a sibling."''
Analytic tableaux
The validity of f-implicational formulas can be semantically established by the method of analytic tableaux. The logical rules are
F
|
T
F
|
T
F
┌────────┴────────┐
F T
| |
CONTRADICTION CONTRADICTION
F
|
T
F
┌────────┴────────┐
F T
| |
T CONTRADICTION
F
|
CONTRADICTION
Hilbert-style proofs can be found here or here.
1. F
| // from 1
2. T
3. F
| // from 3
4. T
5. F
| // from 5
6. T
7. F
┌────────┴────────┐ // from 2
8a. F 8b. T
X ┌────────┴────────┐ // from 4
9a. F 9b. T
X X
A Hilbert-style proof can be found here.
Syntactical properties
The semantic definition by truth tables does not permit the examination of structurally identical propositional forms in various logical systems, where different properties may be demonstrated. The language considered here is restricted to f-implicational formulas.Consider the following natural deduction rules.
| Implication Introduction If assuming one can derive, then one can conclude. is an assumption that is discharged when applying the rule. | Implication Elimination This rule corresponds to modus ponens. |
| Double Negation Elimination | Falsum Elimination From falsum one can derive any formula. |
- Minimal logic: By limiting the natural deduction rules to Implication Introduction and Implication Elimination, one obtains minimal logic.
- Intuitionistic logic: By adding Falsum Elimination as a rule, one obtains intuitionistic logic.
- Classical logic: If Double Negation Elimination is also permitted, the system defines classical logic.
A selection of theorems (classical logic)
- Import-export:
- Negated conditionals:
- Or-and-if:
- Commutativity of antecedents:
- Left distributivity:
- Antecedent strengthening:
- Transitivity:
- Simplification of disjunctive antecedents:
- Reflexivity:
- Totality:
- Conditional excluded middle:
Discrepancies with natural language
In the mid-20th century, a number of researchers including H. P. Grice and Frank Jackson proposed that pragmatic principles could explain the discrepancies between natural language conditionals and the material conditional. On their accounts, conditionals denote material implication but end up conveying additional information when they interact with conversational norms such as Grice's maxims. Recent work in formal semantics and philosophy of language has generally eschewed material implication as an analysis for natural-language conditionals. In particular, such work has often rejected the assumption that natural-language conditionals are truth functional in the sense that the truth value of "If P, then Q" is determined solely by the truth values of P and Q. Thus semantic analyses of conditionals typically propose alternative interpretations built on foundations such as modal logic, relevance logic, probability theory, and causal models.
Similar discrepancies have been observed by psychologists studying conditional reasoning, for instance, by the notorious Wason selection task study, where less than 10% of participants reasoned according to the material conditional. Some researchers have interpreted this result as a failure of the participants to conform to normative laws of reasoning, while others interpret the participants as reasoning normatively according to nonclassical laws.