Implication is a logical operation on two statements, typically represented by the variables P and Q. "P implies Q" is written symbolically as "P → Q". Equivalent statements include "if P then Q", "P is sufficient for Q", and "Q is necessary for P".
The statement "if P then Q" is called a conditional statement; P is known as the antecedent and Q the consequent.
Implication, the result of "P → Q" is defined by the following table:
Note that if P is true, then Q must also be true for the implication to hold (be true). However, if P is false, Q may or may not be true and the implication still holds.
To illustrate the latter fact, consider a teacher who tells her class that any student who gets 100% on the final exam will pass the class. In other words:
- P: A student gets 100% on the final.
- Q: That student passes the class.
- P → Q: If a student gets 100% on the final, then that student passes the class.
Now consider the case in which two students do poorly on the final exam; one of them did well enough on the other exams to pass the course, but the other did not. Did the teacher lie?
No. She said nothing about students who do not get 100% on the final (i.e., the case where P is false). Unless there is a student who both got 100% on the final and did not pass the course, the teacher told the truth.
For this reason, "P → Q" can be restated as "¬(P ∧ ¬ Q)" or "not (P and not Q)", or "it is not the case that P is true and Q is false".
In summary, the following statements are equivalent:
|In symbols||In English|
|P → Q||P implies Q; if P then Q; P sufficient for Q; Q necessary for P|
|¬(P ∧ ¬Q)||not(P and not Q)|
|¬P ∨ Q||(not P) or Q [equivalent by De Morgan's laws]|
|¬Q → ¬P||not Q implies not P|
Unless and only if
The statement "P unless Q" can be translated using implication as "if not Q, then P". It might be more familiar when stated with a negated antecedent: "not P unless Q" means "if not Q then not P".
The statement "P only if Q" is equivalent to "if not Q, then not P", or just "if P then Q". Note that it is not equivalent to "P if Q", which means "if Q then P".
To illustrate how "only if" and "unless" statements work, consider the statement:
- I will pass the class only if I study hard.
What this means is:
- If I don't study hard, I won't pass the class.
Or, equivalently (as explained above):
- I can't both not study hard and pass the class.
If the last statement were not equivalent to the original, then I might be able to not study and still pass the class — but this conflicts with my original statement that it was only by studying hard that I would pass!
Using an "unless" statement to say the same thing:
- I won't pass the class unless I study hard.
This means I'll want to study hard to give myself a chance to pass, but it doesn't guarantee that I will pass; on the other hand, not studying will guarantee that I don't pass.
Symbolically, both the "only if" and "unless" versions of the statement can be written as:
- ¬ S → ¬ P: If I don't study hard, I won't pass the class.
- S = I study hard.
- P = I will pass the course.
Note that this is equivalent to:
- P → S: If I will pass the class then I study hard.
Or, rephrased to make more sense grammatically:
- If I end up passing the class then I must have studied hard.
If and only if
The phrase "if and only if" means "is logically equivalent to", or "is a necessary and sufficient condition for". It is often abbreviated iff.
- P if and only if Q
means the same thing as:
- P implies Q, and Q implies P.
Transformations of conditionals
Given a conditional statement "if P then Q", there are many ways of transforming the statement to other conditionals that may or may not be logically equivalent.
- Original: P → Q ("P implies Q")
- Contrapositive: ¬Q → ¬P ("not Q implies not P") — this is logically equivalent
- Inverse: ¬P → ¬Q ("not P implies not Q") — not equivalent
- Converse: Q → P ("Q implies P") — not equivalent
For more information, see Wikipedia:Contraposition.
- Statement in predicate logic: All squares are rectangles.
- Statement in propositional logic: If a figure is a square, then it is a rectangle.
Note how the statements in propositional logic refer to a larger context (figures) that is not explicitly stated in the predicate-logic version.