BCI-algebra
Algebras introduced by K. Iséki in [a4] as a generalized version of BCK-algebras (cf. BCK-algebra). The latter were developed by Iséki and S. Tannaka in [a6] to generalize the set difference in set theory, and by Y. Imai and Iséki in [a3] as the algebras of certain propositional calculi. It turns out that Abelian groups (cf. Abelian group) are a special case of BCI-algebras. One may take different axiom systems for BCI-algebras, and one such system says that a BCI-algebra is a non-empty set $X$ with a binary relation $\ast$ and a constant $0$ satisfying
i) 
;
ii) 
;
iii) $x \ast x = 0$;
iv) $x \ast y = 0$ and $y \ast x = 0$ imply that $x = y$;
v) $x \ast 0 = 0$ implies that $x=0$.
A partial order $\leq$ may be defined by $x \leq y$ if and only if $x \ast y = 0$. A very useful identity satisfied by $X$ is 
. One can then develop many of the usual algebraic concepts. An ideal is a set 
with the properties that 
and that whenever 
and 
, then 
. The ideal is implicative if 
and 
imply that 
. It is known that one always has 
. An ideal 
is closed if whenever 
then 
. While ideals in general are not subalgebras, closed ideals are. A subalgebra simply means a subset containing 
and closed under 
that is itself a BCI-algebra under 
.
The subset 
of all elements 
forms an ideal, called the 
-radical of 
. The algebra 
is a BCK-algebra if and only if 
, and 
is 
-semi-simple if and only if 
. In the latter case, 
satisfies the identity 
for all 
and 
. It then follows that one can define an operation 
on 
by 
, and 
. This makes 
into an Abelian group with 
as the identity. Conversely, every Abelian group 
can be given a BCI-algebra structure by 
. It follows that the category of Abelian groups is equivalent to the subcategory of the category of BCI-algebras formed by the 
-semi-simple BCI-algebras. Here, a homomorphism 
from one BCI-algebra to another is a function satisfying 
. In general, 
always contains a 
-semi-simple BCI-subalgebra, namely its 
-semi-simple part 
. Of course, also 
, since it can be verified easily that the induced partial order in a 
-semi-simple BCI-algebra is always trivial. Clearly, 
is 
-semi-simple if 
, and 
is a BCK-algebra if 
. Note that for a 
-semi-simple BCI-algebra, the closed ideals are precisely the subgroups of the associated Abelian group structure.
Some of the homological algebra properties of BCI-algebras are known. For example, it is known that a BCI-algebra is injective if and only if it is 
-semi-simple and its associated Abelian group structure is divisible (cf, also Divisible group).
Fuzzy ideals of BCI-algebras are described in [a1] and [a2].
References
| [a1] | C.S. Hoo, "Fuzzy ideals of BCI and MV-algebras" Fuzzy Sets and Systems , 62 (1994) pp. 111–114 |
| [a2] | C.S. Hoo, "Fuzzy implicative and Boolean ideals of MV-algebras" Fuzzy Sets and Systems , 66 (1994) pp. 315–327 |
| [a3] | Y. Imai, K. Iséki, "On axiom systems of propositional calculi, XIV" Proc. Japan Acad. Ser. A, Math. Sci. , 42 (1966) pp. 19–22 |
| [a4] | K. Iséki, "An algebra related with a propositional calculus" Proc. Japan Acad. Ser. A, Math. Sci. , 42 (1966) pp. 26–29 |
| [a5] | K. Iséki, "On BCI-algebras" Math. Seminar Notes (Kobe University) , 8 (1980) pp. 125–130 |
| [a6] | K. Iséki, S. Tanaka, "An introduction to the theory of BCK-algebras" Math. Japon. , 23 (1978) pp. 1–26 |
BCI-algebra. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=BCI-algebra&oldid=54783