Ordered ring
partially ordered ring
A ring 
(not necessarily associative) which is a partially ordered group under addition and in which for any elements 
the inequalities 
and 
imply 
and 
. Every ring is an ordered ring for the trivial order. As examples of ordered rings one may take an ordered field; the ring of real functions on a set 
, where 
means that 
for all 
; or a matrix ring over an ordered ring 
, where, by definition, 
if 
for all 
. If 
is an ordered ring, then the set
 |
is called its positive cone. The positive cone of an ordered ring completely defines the order: 
if and only if 
. A subset 
of a ring 
can serve as the positive cone for some order if and only if
 |
The equation 
is equivalent to the totality of the order (cf. Totally ordered set).
An ordered ring that is totally ordered or lattice-ordered is accordingly called a totally ordered or lattice-ordered ring (cf. also Archimedean ring). Lattice-ordered rings turn out to be distributive lattices, and their additive groups are torsion-free (cf. Lattice-ordered group). Certain questions in the theory of associative rings and, in particular, in the theory of radicals have analogues in associative lattice-ordered rings. The class of rings which allow a lattice-ordered ring structure is not axiomatizable. If 
are elements of a lattice-ordered ring and 
, then the following relations hold:
 |
 |
Ideals in lattice-ordered rings which are convex subgroups (cf. Convex subgroup) of the additive group are called 
-ideals. The quotient ring by an 
-ideal can be made into a lattice-ordered ring in a natural way. The homomorphism theorem holds.
A lattice-ordered ring 
is called a functional ring or an 
-ring if it satisfies any of the following equivalent conditions: 1) 
is isomorphic to a lattice-ordered subring of a direct product of totally ordered rings; 2) for any 
one has the implication
 |
3) for any subset 
of 
the set
 |
is an 
-ideal; and 4) for any 
,
 |
Condition 4) shows that 
-rings form a variety of signature 
. Neither of the equations in this condition is a consequence of the other. Not every 
-ring can be imbedded in an 
-ring with a unit element. If 
are elements of an 
-ring and 
, then one has
 |
 |
 |
as well as the implication 
.
An order of an ordered ring 
with a positive cone 
can be extended to a total order such that 
becomes a totally ordered ring if and only if for any finite set 
in 
one can choose 
or 
such that in the semi-ring generated by 
and the elements 
the sum of any two non-zero elements is non-zero. With 
one obtains a criterion for the possibility of having a total order on the ring.
References
| [1] | G. Birkhoff, "Lattice theory" , Colloq. Publ. , 25 , Amer. Math. Soc. (1973) |
| [2] | A.A. Vinogradov, "The non-axiomatizability of lattice-ordered rings" Math. Notes , 21 (1977) pp. 253–254 Mat. Zametki , 21 : 4 (1977) pp. 449–452 |
| [3] | L. Fuchs, "Partially ordered algebraic systems" , Pergamon (1963) |
| [4] | A. Bigard, K. Keimel, S. Wolfenstein, "Groupes et anneaux reticulés" , Springer (1977) |
| [5] | G.W. Brumfiel, "Partially ordered rings and semi-algebraic geometry" , Cambridge Univ. Press (1979) |
| [6] | S.A. Steinberg, "Radical theory in lattice-ordered rings" Symp. Mat. Ist. Naz. Alta Mat. , 21 (1977) pp. 379–400 |
| [7] | S.A. Steinberg, "Examples of lattice-ordered rings" J. of Algebra , 72 : 1 (1981) pp. 223–236 |
Comments
For a survey of the current state-of-the-art in the field see the second part of [a1].
References
| [a1] | J. Martinez (ed.) , Ordered algebraic structures , Kluwer (1989) |
Ordered ring. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Ordered_ring&oldid=12730