written
is
a measure of the "number of elements of the set". The
cardinality of a finite set is equal to the number of elements of the
set. For infinite sets ardinality is measured using either
bijections/injections or cardinal numbers.
University Maths Notes: Set Theory - Cardinality
The cardinality of a setwrittenis
a measure of the "number of elements of the set". The
cardinality of a finite set is equal to the number of elements of the
set. For infinite sets ardinality is measured using either
bijections/injections or cardinal numbers.
have
the same cardinality if there exists an injective (one to one) and
surjective (onto) function fromto
The
set
of
odd natural numbers has the same cardinality as the set of natural
numbers
with
the function from
to
given
by
All
infinite countable sets have the same cardinality as
the
smallest set with infinite cardinality
to
then
If
there is an injective but no bijective function then the cardinality
ofis
greater than the cardinality ofThe
cardinality of the set
of
real numbers is greater than the cardinality offor
this reason.
The cardinality of a set can be defined in terms of equivalence relations. The equivalence classof a set A under this relation then consists of all those sets which have the same cardinality as A.
WE check that the equivalence axioms are satisfied:
since
the identity function fromto
itself is bijective and surjective.
there
exists an injective and surjective function
and
is
well defined because
is
injective and surjective hence
there
exists an injective and surjective functionand
there
exists an injective and surjective function
so
is
an injective and surjective function fromto
so
Any set
with
cardinality less than
is said to be a finite set.
Any setthat
has the same cardinality as
is a countably infinite set.
Any setwith
cardinality greater than
is
said to be uncountable.
The cardinality of the continuum (
)
is greater than that of the natural numbers (
);
that is, there are more real numbersthan
whole numbers
Because for any open interval
in
there
exists a bijection (eg
from
that interval ontothe
cardinality ofis
equal to the cardinality of any open interval in
Cardinal
arithmetic can be used to show not only that the number of points
inis
equal to the number of points in any open interval ofand
to the number of points on a plane and, indeed, in
for
any
That the cardinal number ofis
equal to the cardinal number ofmay
be demonstrated with the use of space filling curves, which
demonstrate a bijection fromto
and
the set of all functions fromtoboth
have cardinality