# Logical conjunction

Logical connective AND From Wikipedia, the free encyclopedia

Logical connective AND From Wikipedia, the free encyclopedia

In logic, mathematics and linguistics, *and* () is the truth-functional operator of **conjunction** or **logical conjunction**. The logical connective of this operator is typically represented as ^{[1]} or or (prefix) or or ^{[2]} in which is the most modern and widely used.

AND | |
---|---|

Definition | |

Truth table | |

Logic gate | |

Normal forms | |

Disjunctive | |

Conjunctive | |

Zhegalkin polynomial | |

Post's lattices | |

0-preserving | yes |

1-preserving | yes |

Monotone | no |

Affine | no |

Self-dual | no |

The *and* of a set of operands is true if and only if *all* of its operands are true, i.e., is true if and only if is true and is true.

An operand of a conjunction is a **conjunct**.^{[3]}

Beyond logic, the term "conjunction" also refers to similar concepts in other fields:

- In natural language, the denotation of expressions such as English "and";
- In programming languages, the short-circuit and control structure;
- In set theory, intersection.
- In lattice theory, logical conjunction (greatest lower bound).

**And** is usually denoted by an infix operator: in mathematics and logic, it is denoted by a "wedge" (Unicode U+2227 ∧ LOGICAL AND),^{[1]} or ; in electronics, ; and in programming languages, ** &**,

`&&`

`and`

In mathematics, the conjunction of an arbitrary number of elements can be denoted as an iterated binary operation using a "big wedge" ⋀ (Unicode U+22C0 ⋀ N-ARY LOGICAL AND):^{[5]}

**Logical conjunction** is an operation on two logical values, typically the values of two propositions, that produces a value of *true* if and only if (also known as iff) both of its operands are true.^{[2]}^{[1]}

The conjunctive identity is true, which is to say that AND-ing an expression with true will never change the value of the expression. In keeping with the concept of vacuous truth, when conjunction is defined as an operator or function of arbitrary arity, the empty conjunction (AND-ing over an empty set of operands) is often defined as having the result true.

The truth table of :^{[1]}^{[2]}

F | F | F |

F | T | F |

T | F | F |

T | T | T |

In systems where logical conjunction is not a primitive, it may be defined as^{[6]}

It can be checked by the following truth table (compare the last two columns):

F | F | T | T | F | F |

F | T | F | T | F | F |

T | F | T | T | F | F |

T | T | F | F | T | T |

or

It can be checked by the following truth table (compare the last two columns):

F | F | T | T | T | F | F |

F | T | T | F | T | F | F |

T | F | F | T | T | F | F |

T | T | F | F | F | T | T |

As a rule of inference, conjunction introduction is a classically valid, simple argument form. The argument form has two premises, and . Intuitively, it permits the inference of their conjunction.

- ,
- .
- Therefore,
*A*and*B*.

or in logical operator notation:

Here is an example of an argument that fits the form *conjunction introduction*:

- Bob likes apples.
- Bob likes oranges.
- Therefore, Bob likes apples and Bob likes oranges.

Conjunction elimination is another classically valid, simple argument form. Intuitively, it permits the inference from any conjunction of either element of that conjunction.

- and .
- Therefore, .

...or alternatively,

- and .
- Therefore, .

In logical operator notation:

...or alternatively,

A conjunction is proven false by establishing either or . In terms of the object language, this reads

This formula can be seen as a special case of

when is a false proposition.

If implies , then both as well as prove the conjunction false:

In other words, a conjunction can actually be proven false just by knowing about the relation of its conjuncts, and not necessary about their truth values.

This formula can be seen as a special case of

when is a false proposition.

Either of the above are constructively valid proofs by contradiction.

**commutativity: yes**

**associativity: yes ^{[7]}**

**distributivity:** with various operations, especially with *or*

others | ||||||||||||||||||||||||||||||||||||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|

with exclusive or: with material nonimplication: with itself: |

**idempotency: yes**

**monotonicity: yes**

**truth-preserving: yes**

When all inputs are true, the output is true.

(to be tested) |

**falsehood-preserving: yes**

When all inputs are false, the output is false.

(to be tested) |

**Walsh spectrum: (1,-1,-1,1)**

**Nonlinearity: 1** (the function is bent)

If using binary values for true (1) and false (0), then *logical conjunction* works exactly like normal arithmetic multiplication.

In high-level computer programming and digital electronics, logical conjunction is commonly represented by an infix operator, usually as a keyword such as "`AND`

", an algebraic multiplication, or the ampersand symbol `&`

(sometimes doubled as in `&&`

). Many languages also provide short-circuit control structures corresponding to logical conjunction.

Logical conjunction is often used for bitwise operations, where `0`

corresponds to false and `1`

to true:

`0 AND 0`

=`0`

,`0 AND 1`

=`0`

,`1 AND 0`

=`0`

,`1 AND 1`

=`1`

.

The operation can also be applied to two binary words viewed as bitstrings of equal length, by taking the bitwise AND of each pair of bits at corresponding positions. For example:

`11000110 AND 10100011`

=`10000010`

.

This can be used to select part of a bitstring using a bit mask. For example, `1001`

= **1**101 AND 0000**1**000`0000`

extracts the fourth bit of an 8-bit bitstring.**1**000

In computer networking, bit masks are used to derive the network address of a subnet within an existing network from a given IP address, by ANDing the IP address and the subnet mask.

Logical conjunction "`AND`

" is also used in SQL operations to form database queries.

The Curry–Howard correspondence relates logical conjunction to product types.

The membership of an element of an intersection set in set theory is defined in terms of a logical conjunction: if and only if . Through this correspondence, set-theoretic intersection shares several properties with logical conjunction, such as associativity, commutativity and idempotence.

As with other notions formalized in mathematical logic, the logical conjunction *and* is related to, but not the same as, the grammatical conjunction *and* in natural languages.

English "and" has properties not captured by logical conjunction. For example, "and" sometimes implies order having the sense of "then". For example, "They got married and had a child" in common discourse means that the marriage came before the child.

The word "and" can also imply a partition of a thing into parts, as "The American flag is red, white, and blue." Here, it is not meant that the flag is *at once* red, white, and blue, but rather that it has a part of each color.

- And-inverter graph
- AND gate
- Bitwise AND
- Boolean algebra
- Boolean conjunctive query
- Boolean domain
- Boolean function
- Boolean-valued function
- Conjunction/disjunction duality
- Conjunction elimination
- Conjunction (grammar)
- De Morgan's laws
- First-order logic
- Fréchet inequalities
- Homogeneity (linguistics)
- List of Boolean algebra topics
- Logical disjunction
- Logical graph
- Negation
- Operation
- Peano–Russell notation
- Propositional calculus

Seamless Wikipedia browsing. On steroids.

Every time you click a link to Wikipedia, Wiktionary or Wikiquote in your browser's search results, it will show the modern Wikiwand interface.

Wikiwand extension is a five stars, simple, with minimum permission required to keep your browsing private, safe and transparent.