Order 8: 243-246, 1991. 0 1991 Kluwer Academic
243 Publishers.
Printed
in the Netherlank
[2] x [ 31 x N is not a Cir...
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Order 8: 243-246, 1991. 0 1991 Kluwer Academic
243 Publishers.
Printed
in the Netherlank
[2] x [ 31 x N is not a Circle Order CHIANG
LIN
Department
of Mathematics,
Communicated
National
Central
University,
Chung-Li,
Taiwan,
R.O.C.
by I. Rival
(Received: 30 October 1989; accepted: 30 May 1991) The result stated in the title is proved in this note. Actually we show that S x N is not a circle order, where S = {( 1, I), (1,2), (1,3), (2, I), (2, 3)}. Furthermore this non-circle order is critical in the sense that (S - {x}) x N is a circle order for any x in S. Abstract.
AMS Key
subject words.
classification
(1991).
06A06.
Poset, circle order, dimension.
1. Introduction A poset P is called a circle order if one can assign to each x E P a circular disc C, such that x < y in P -S C, c C,,. It is asked [3] whether every three-dimensional poset is a circle order. For finite posets this problem is still open. As for infinite posets this is much simpler. Scheinerman and Wierman [2] proved that [n] x [n] x N is not a circle order for some large n, where [n] is the poset { 1 < 2 < 3 < * * * < rz} andNistheposet(1. Let {CX I x E P> be a circular disk representation of P such that nxeP interior of C, # 0. We may assume that the origin of the plane is in the interior of each C,. Then it is easy to see that {c I x E P} is a disk representation of P. 0
nx.PC Z0.Hence fLp
In fact we will use Lemma 1 only for Condition question. QUESTION.
(2). Here we have a subsidiary
Suppose P is a circle order. Does this imply that P is a circle order?
2. Main Results THEOREM 2. {( 1, 1), ( 1,2), (1, 3), (2, 1), (2,3)) x N is not a circle order. Proof. Let P = {( 1, 1), (1,2), ( 1,3), (2, l), (2, 3)) x N. Since P contains a least element, it follows from Lemma l(2) that we only need to show that P is not a circle order. We can see that P is isomorphic to Q, where Q = ((1, 11, (1,3), (2, 11, (2,2), (293)) x -N. We will show that Q is not a circle order. Suppose, on the contrary, that Q is a circle order. Let C(i, j, -k) be a circular disk for each (i, j, -k) E Q such that C(i, j, -k) c C(i’, j’, -k’)o (i, j, -k) < (i’, j’, -k’). Define C(i,j) = hEN C(i, j, -k). For circular disks C, and C, we say that C, is internally tangent to C, if C, is properly contained in C,, and C, is tangent to C,. As the arguments in [2] we have ( 1) each C(i, j) is a circular disk (furthermore we may assume each C(i, j) is a nondegenerate disk, since we can add a positive constant to the radius of each C(i, j, -k)) and (2) C(i, j) is either equal or internally tangent to C(i’, j’) if (i, j) < (i’, j’). Hence C( 1, 1) is either equal or internally tangent to C(2,3). Then either C(2, 1) = C( 1,3) or C(2, 1) is tangent to C( 1, 3), since C(1, 1) c C(1, 3) E C(2, 3) and C(1, 1) E C(2, 1) E C(2, 3). CLAIM. (1) C(2, 1) = C(1, 3); (2) each C(2, 1, -n) is tangent to C(2, 1). We check the claim as follows. (1) Suppose, on the contrary, that C(2, 1) # C( 1, 3). Assume, without loss of generality, that C(2, 1) is internally tangent to C( 1, 3), say at a point z. Then, C( 1, 3, -n) is tangent to C( 1, 3) at z for all n in N, otherwise C(2, 1, -Z) c C( 1, 3, -m) for some l, m in N, which is impossible. On the other hand C( 1, 1) is internally tangent to C( 1, 3) at z. This follows from the facts that C( 1, 1) E C(2, 1) and C(2, 1) is internally tangent to C( 1,3) at z
[2] x [3] x N IS NOT A CIRCLE ORDER
245
and C( 1, 1) is either equal or internally tangent to C( 1,3). Therefore C( 1, 1, -n) is either equal or tangent to C( 1, 3) at z for all n, since C( 1, 1) c C( 1, 1, -n) c C(173, -n). Hence, for any m, n in N, either C(l, 1, -n) c C(l, 3, -m) or C(L 3, -m) G C( 1, 1, -n), which is impossible if n < m. This contradiction confirms Claim (1). (2) Suppose C(2, 1, -n) is not tangent to C(2, 1) for some n. Then C( 2, 1, -n) 3 C( 1, 3, -m) for some m, which is impossible. This contradiction confirms Claim (2). Similarly, we also have C( 2,2) = C( 1, 3) and each C(2,2, -n) is tangent to C(2,2). Let C = C(2,2) = C( 1, 3) = C( 2, 1). Suppose each C( 2, 1, -n) is tangent to C at a point x and each C(2,2, -n) is tangent to C at a point y. We consider two cases. Case 1. x = y. Then for all m, n in N, either C(2, 1, -n) c C( 2,2, -m) or C(2,2, -m) E C(2, 1, -n), which is impossible when n < m. Case 2. x # y. Then C(2, 1, -n) and C(2,2, -n) are not contained in each other, which is impossible. This completes the proof of the theorem. 0 The non-circle order in Theorem 2 is critical in the following sense. Let S be the poset {(l,l), (1,2), (1,3), (2, l), (2,3)}. Then (S - {x}) x N is a circle order for any x E S. This is explained as follows. If x = (1, 3) or (1,2), then (S - {x}) x N is isomorphic to [2] x [2] x N, which is a circle order because of Theorem 3. Otherwise (S - (xl) x N is either a product of two nontrivial chains or one of the two posets in Theorem 4(3), and these posets are circle orders because of Theorem 4. THEOREM 3. [2] x [ 21 x N is a circle order. Proof. It suffices to show that [2] x [2] x -N is a circle order because of Lemma l(2). In the following we will assign a circular disk C(i,j, -n) in the plane E2 for each (i,j, -n) E [2] x [2] x -N so that (i,j, -n) < (i’,j’, -n’) o C(i,j, -n) c C(i’,j’, -n’). Let C(2,2, - 1) be the disk with ( -2,O), (2,O) E E2 as the end points of its diameter, and C(2, 1, - 1) the disk with ( - 2,0), ( 1,0) E E2 as end points of its diameter, and C( 1,2, - 1) the disk with ( - LO), (2,O) E E2 as the end points of its diameter. Define C( 1, 1, -n), C(2,2, --n - l), C(1,2, --n - l), C(2, 1, --n - 1) from C( 1,2, -n), C( 2, 1, -n) recursively as follows. Let C( 1, 1, -n) be the disk lying below X-axis with its boundary passing through (0, - l), and internally tangent to C(l, 2, -n) and C(2, 1, -n). Let (0, t) E E2 be the center of C(l, 1, -n). Let C(2, 1, -n - 1) be the disk internally tangent to C(2, 1, - 1) at (1,0) and tangent to the line y = ( - 1 + t)/2. Let C( 1,2, --n - 1) be the disk internally tangent to C( 1,2, - 1) at ( - 1,0) and tangent to the line y = ( - 1 + r)/2. And lastly C(2,2, --n - 1) is the disk with its center at (0,O) and its boundary passing through (0, t). We can see that C( 2, 1, -n - 1) and C( 1,2, -n - 1) are internally tangent to C(2,2,-n-l).Itisnothardtocheckthat{C(i,j,-n)(l~i~2,1~j~2,n~N} is a disk representation for [2] x [2] x -N, and this completes the proof. q
246
CHIANG
LIN
THEOREM
4. (1) Every two-dimensional countable poset is a circle order. (2) The product of two nontrivial chains is a two-dimensional poset.
(3) The posets ((1, 11, (1,2), (1,3), (2, I>} XN and {tL2),
tL3),
(2,3), (2, 1))
x N are both two-dimensional. Proof. (1) Let P be a 2-dimensional countable poset. Suppose rr, , z2 are two linear extensions realizing P, i.e., q, rr2 are functions with n, : P + R + and n2: P + R+ such that x < y in P o n,(x) < q(y) for i = 1,2. Now for each x E P let C, be the circular disk in the plane E* with (-A,(X), 0), (n,(x), 0) l E* as the end points of its diameter. It is each to see that {CX 1x E P> is a disk representation for P.
(2) is trivial. (3) Let ~5, L2 be linear extensions of the L,={(1,1,1)~(1,2,1)c(1,3,1)~(1,1,2)~(1,2,2)~(1,3,2)~~~~~(1,1,n)