# Difference between revisions of "Isomorphism"

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− | |valign="top"|{{Ref|Ad}}||valign="top"|J. Adámek, "Theory of mathematical structures", Reidel (1983) {{ | + | |valign="top"|{{Ref|Ad}}||valign="top"|J. Adámek, "Theory of mathematical structures", Reidel (1983) {{MR|0735079}} {{ZBL|0523.18001}} |

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|valign="top"|{{Ref|Co}}||valign="top"| P.M. Cohn, "Universal algebra", Reidel (1981) {{MR|0620952}} {{ZBL|0461.08001}} | |valign="top"|{{Ref|Co}}||valign="top"| P.M. Cohn, "Universal algebra", Reidel (1981) {{MR|0620952}} {{ZBL|0461.08001}} |

## Latest revision as of 22:01, 5 March 2012

2010 Mathematics Subject Classification: *Primary:* 18-01, *Secondary:* 00A0508-0118Axx18Dxx [MSN][ZBL]

An isomorphism is a correspondence (relation) between objects or systems of objects
expressing the equality of their structures in some sense. An
isomorphism in an arbitrary
category is an invertible
morphism, that is, a morphism $\def\phi{\varphi}\phi$ for which there exists
a morphism $\phi^{-1}$ such that $\phi^{-1}\phi$ and $\phi\phi^{-1}$ are both identity morphisms.

The concept of an isomorphism arose in connection with concrete algebraic systems (initially, with groups) and was extended in a natural way to wider classes of mathematical structures. A classical example of isomorphic, "identically constructed" , systems is the set $\R$ of real numbers with the operation of addition and the set $P$ of positive real numbers with the operation of multiplication.

Let $\mathfrak{A}$ and $\mathfrak{A'}$ be algebraic systems (cf. Algebraic system) of the same type, written in the signature $$\{F_i: i\in I\}\cup\{P_j: j\in J\}$$ with function symbols $F_i$, $i\in I$, and predicate symbols $P_j$, $j\in J$:

$$ A = \langle A; \{F_i: i\in I\},\; \{P_j: j\in J\}\rangle,$$ $$ A' = \langle A'; \{F_i: i\in I\},\; \{P_j: j\in J\}\rangle.$$

An isomorphism, or isomorphic mapping, from $A$ onto $A'$ is a one-to-one mapping $\phi$ from the set $A$ onto the set $A'$ with the properties $$\def\a{\alpha} \phi(F_i(\a_1,\dots,\a_{n_i})) = F_i(\phi(\a_1),\dots,\phi(\a_{n_i})),$$

$$P_j(\a_1,\dots,\a_{m_j})\Leftrightarrow P_j(\phi(\a_1),\dots,\phi(\a_{m_j}))$$

for all $\a_1,\a_2,\dots$ in $A$ and all $i\in I$, $j\in J$. Thus, in every category of algebraic systems, an isomorphism is a homomorphism that is a bijection. An isomorphism of an algebraic system onto itself is called an automorphism.

The relation of isomorphism is reflexive, symmetric and transitive, that is, it is an equivalence relation splitting any set on which it is defined into disjoint equivalence classes — the classes of pairwise-isomorphic systems. A class of algebraic systems which is a union of such classes is called an abstract class (cf. Algebraic systems, class of).

#### Comments

The isomorphism between $\R$ and $P$ mentioned in the main article above can be explicitly given by the means of the exponential mapping or its inverse, the logarithmic function (cf. also Exponential function, real).

#### References

[Ad] | J. Adámek, "Theory of mathematical structures", Reidel (1983) MR0735079 Zbl 0523.18001 |

[Co] | P.M. Cohn, "Universal algebra", Reidel (1981) MR0620952 Zbl 0461.08001 |

[Mi] | B. Mitchell, "Theory of categories", Acad. Press (1965) pp. 7 MR0202787 Zbl 0136.00604 |

**How to Cite This Entry:**

Isomorphism.

*Encyclopedia of Mathematics.*URL: http://encyclopediaofmath.org/index.php?title=Isomorphism&oldid=21169