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A propositional calculus is a formal, deduction system, or proof theory for reasoning with propositional formulas. Propositional calculi are a part of propositional logic, which is any symbolic logic such that the simplest expressions it distinguishes are whole sentences. It is also
extensional. (Compare, by
contrast, predicate logic and modal logic, which also have their own calculi.)
A calculus, or proof theory is that part of a logical system which
determines how to construct arguments: to derive conclusions from premises. It is a set of
axioms (which may be an empty set), and a set of inference rules for
deriving new well-formed formulas (wffs) from a given set
of wffs. It must thus include or be defined in terms of a formal
grammar, which will state all of the allowable expressions, the wffs, in the language. Any grammar will in general also be
given a semantics, which explains those features (truth, implication) that are,
presumably, of interest. Ideally the axioms and inference rules of a calculus are chosen such that if the formulas in a set are
semantically true then any formulas derivable from them are also true. (Hence a calculus is formulated independently of a
semantics, but with the aim of agreeing with it.)
In a propositional calculus the vocabulary consists of atomic sentences and sentential operators or connectives. The
wffs are all sentences; they include the atomic sentences and any sentences built
up from those and the sentential operators.
In what follows we will outline a standard propositional calculus. Many different such formulations exist which are all more
or less equivalent but differ in (1) which sentential operators they allow, (hence, which language or grammar they are designed
for); (2) which (if any) axioms, and which inference rules are used; and (3) in what form derivations are presented. There is no
limit to the number of such systems that can be devised.
Grammar
The vocabulary is composed of:
- The capital letters of the alphabet. These abbreviate complete sentences which are atomic in the sense that they cannot be
decomposed into smaller sentences.
- Symbols denoting the following connectives (or logical operators): ¬, ∧, ∨, →,
↔
- The left parenthesis and the right parenthesis: (, ).
The set of wffs is recursively defined by the following rules:
- Basis: Letters of the alphabet (usually capitalized such as A, B, etc.) are
wffs.
- Inductive Clause I: If φ is a wff, then ¬ φ is a wff.
- Inductive Clause II If φ and ψ are wffs, then (φ ∧ ψ), (φ ∨
ψ), (φ → ψ), and (φ ↔ ψ) are wffs.
- Closure Clause: Nothing else is a wff.
Repeated applications of these three rules permit the generation of complex wffs. For example:
- By rule 1, A is a wff.
- By rule 2, ¬ A is a wff.
- By rule 1, B is a wff.
- By rule 3, ( ¬ A ∨ B ) is a wff.
Calculus
For simplicity, we will use a natural deduction system, which
has no axioms; or, equivalently, which has an empty axiom set.
Derivations using our calculus will be laid out in the form of a list of numbered lines, with a single wff and a
justification on each line. Any premisses will be at the top, with a "p" for their justification. The conclusion will be
on the last line. A derivation will be considred complete if every line follows from previous ones by correct application of a
rule. (For a contrasting approach, see proof-trees).
Axioms
Our axiom set is the empty set.
Inference rules
Our propositional calculus has ten inference rules. These rules allow us to derive other true formulas given a set of formulas
that are assumed to be true. The first eight simply state that we can infer certain wffs from other wffs. The last two rules
however use hypothetical reasoning in the sense that in the premise of the rule we temporarily assume an (unproven) hypothesis to
be part of the set of inferred formulas to see if we can infer a certain other formula. Since the first eight rules don't do this
they are usually described as non-hypothetical rules, and the last two as hypothetical rules.
- Double Negative Elimination: From the
wff ¬ ¬ φ, we may infer φ
- Conjunction Introduction: From any wff
φ and any wff ψ, we may infer ( φ ∧ ψ ).
- Conjunction Elimination: From any wff (
φ ∧ ψ ), we may infer φ and ψ
- Disjunction Introduction: From any wff
φ, we may infer (φ ∨ ψ) where ψ is any wff.
- Disjunction Elimination: From wffs of
the form ( φ ∨ ψ ), ( φ → χ ), and ( ψ → χ ), we may infer χ.
- Biconditional Introduction: From
wffs of the form ( φ → ψ ) and ( ψ → φ ), we may infer ( φ ↔ ψ ).
- Biconditional Elimination: From the
wff ( φ ↔ ψ ), we may infer ( φ → ψ ) and ( ψ → φ ).
- Modus Ponens: From wffs of the form φ and ( φ
→ ψ ), we may infer ψ.
- Conditional Proof: If ψ can be derived while assuming
the hypothesis φ, we may infer ( φ → ψ ).
- Reductio ad Absurdum: If we can derive both ψ and
¬ ψ while assuming the hypothesis φ, we may infer ¬ φ.
- An example of using the rules should be inserted here
Soundness and completeness of the rules
The crucial properties of this set of rules is that they are sound and complete. Informally this means that
the rules are correct and that no other rules are required. These claims can be made more formal as follows.
We define a truth assignment as a function that maps propositional variables to true or false.
Informally such a truth assignment can be understood as the description of a possible state of affairs (or possible worlds) where
certain statements are true and others are not. The semantics of formulas can then be formalized by defining for which "state of
affairs" they are considered to be true, which is what is done by the following definition.
We define when such a truth assignment A satisfies a certain wff with the following rules:
- A satisfies the propositional variable P iff A(P) =
true
- A satisfies ¬ φ iff A does not satisfy φ
- A satisfies (φ ∧ ψ) iff A satisfies φ and ψ
- A satisfies (φ ∨ ψ) iff A satisfies φ or ψ
- A satisfies (φ → ψ) iff it is not the case that A satisfies φ but not ψ
- A satisfies (φ ↔ ψ) iff A satisfies both φ and ψ or satisfies them both not
With this definition we can now formalize what it means for a formula φ to be implied by a certain set S of
formulas. Informally this is true if in all worlds that are possible given the set of formulas S the formula φ also
holds. This leads to the following formal definition: We say that a set S of wffs semantically entails (or
implies) a certain wff φ if all truth assignments that satisfy all the formulas in S also satisfy
φ.
Finally we define syntactical entailment such that φ is syntactically entailed by S iff we can derive
it with the inference rules that were presented above in a finite number of steps. This allows us formulate exactly what it means
for the set of inference rules to be sound and complete:
- Soundness
- If the set of wffs S syntactically entails wff φ then S semantically entails φ
- Completeness
- If the set of wffs S semantically entails wff φ then S syntactically entails φ
For the above set of rules this is indeed the case.
- ... a sketch of proof would be nice ...
Sketch of a soundness proof
(For most logical systems, this is the comparatively "simple" direction of proof)
Notational conventions: Let "G" be a variable ranging over sets of sentences. Let "A", "B", and "C" range over sentences. For
"G syntactically entails A" we write "G proves A". For "G semantically entails A" we write "G implies A".
We want to show: (A)(G)(If G proves A then G implies A)
We note that "G proves A" has an inductive definition, and that gives us the immediate resources for demonstrating claims of
the form "If G proves A then . . ." So our proof proceeds by induction.
- I. Basis. Show: If A is a member of G then G implies A
- [II. Basis. Show: If A is an axiom, then G implies A]
- III. Inductive step: (a) Assume for arbitrary G and A that if G proves A then G implies A. (If necessary, assume this for
arbitrary B, C, etc. as well)
-
- (b) For each possible application of a rule of inference to A, leading to a new sentence B, show that G implies B.
(N.B. Basis Step II can be omitted for the above calculus, which is a natural deduction system and so has no axioms. Basically, it involves showing that each of the axioms is
a (semantic) logical truth.)
The Basis step(s) demonstrate(s) that the simplest provable sentences from G are also implied by G, for any G. (The is simple,
since the semantic fact that a set implies any of its members, is also trivial.) The Inductive step will systematically cover all
the further sentences that might be provable--by considering each case where we might reach a logical conclusion using an
inference rule--and shows that if a new sentence is provable, it is also logically implied. (For example, we might have a rule
telling us that from "A" we can derive "A or B". In III.(a) We assume that if A is provable it is implied. We also know that if A
is provable then "A or B" is provable. We have to show that then "A or B" too is implied. We do so by appeal to the semantic
definition and the assumption we just made. A is provable from G, we assume. So it is also implied by G. So any semantic
valuation making all of G true makes A true. But any valuation making A true makes "A or B" true, by the defined semantics for
"or". So any valuation which makes all of G true makes "A or B" true. So "A or B" is implied.) Generally, the Inductive step will
consist of a lengthy but simple case-by-case analysis of all the rules of inference, showing that each "preserves" semantic
implication.
By the definition of provability, there are no sentences provable other than by being a member of G, an axiom, or following by
a rule; so if all of those are semantically implied, the deduction calculus is sound.
Sketch of completeness proof
(This is usually the much harder direction of proof.)
We adopt the same notational conventions as above.
We want to show: If G implies A, then G proves A. We proceed by contraposition: We show instead that If G does not
prove A then G does not imply A.
- I. G does not prove A. (Assumption)
- II. If G does not prove A, then we can construct an (infinite) "Maximal Set", G*, which is a superset of G and which also
does not prove A.
- (a)Place an "ordering" on all the sentences in the language. (e.g., alphabetical ordering), and number them E1, E2, . .
.
- (b)Define a series Gn of sets (G0, G1 . . . )inductively, as follows. (i)G0=G. (ii) If {Gk, E(k+1)} proves A, then G(k+1)=Gk.
(iii) If {Gk, E(k+1)} does not prove A, then G(k+1)={Gk, E(k+1)}
- (c)Define G* as the union of all the Gn. (That is, G* is the set of all the sentences that are in any Gn).
- (d) It can be easily shown that (i) G* contains (is a superset of) G (by (b.i)); (ii) G* does not prove A (because if it
proves A then some sentence was added to some Gn which caused it to prove A; but this was ruled out by definition); and (iii) G*
is a "Maximal Set" (with respect to A): If any more sentences whatever were added to G*, it would prove A.
(Because if it were possible to add any more sentences, they should have been added when they were encountered during the
construction of the Gn, again by definition)
- III. If G* is a Maximal Set (wrt A), then it is "truth-like". This means that it contains the sentence "A" only if it does
not contain the sentence not-A; If it contains "A" and contains "If A then B" then it also contains "B"; and so
forth.
- IV. If G* is truth-like there is a "G*-Canonical" valuation of the language: one that makes every sentence in G* true and
everything outside G* false while still obeying the laws of semantic composition in the language.
- V. A G*-canonical valuation will make our original set G all true, and make A false.
- VI. If there is a valuation on which G are true and A is false, then G does not (semantically) imply A.
QED.
Other logical calculi
Propositional calculus is about the simplest kind of logical calculus in any current use. (Aristotelian "syllogisitic"
calculus, which is largely supplanted in modern logic, is in some ways simpler--but in other ways more complex--than
propositional calculus.) It can be extended in several ways.
The most immediate way to develop a more complex logical calculus is to introduce rules that are sensitive to more
fine-grained details of the sentences being used. When the "atomic sentences" of propositional logic are broken up into terms, variables, predicates, and quantifiers, they yield
first-order logic, or first-order predicate logic, which keeps
all the rules of propositional logic and adds some new ones. (For example, from "All dogs are mammals" we may infer "If Rover is
a dog then Rover is a mammal.)
With the tools of first-order logic it is possible to formulate a number of theories, either with explicit axioms or by rules
of inference, that can themselves be treated as logical calculi. Arithmetic is
the best known of these; others include Set theory and Mereology
Modal logic also offers a variety of inferences that cannot be captured in
propositional calculus. For example, from "Necessarily p" we may infer that p. From p we may infer "It
is possible that p".
Many-valued logics are those allowing sentences to have values
other than true and false. (For example, neither and both are standard "exra values";
"continuum logic" allows each sentence to have any of an infinite number of "degrees of truth" between true and
false.) These logics often require calculational devices quite distinct from propositional calculus.
See also
External links
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