In mathematics, Pappus's hexagon theorem (attributed to Pappus of Alexandria) states that
A,B,C,
a,b,c,
X,Y,Z
Ab
aB,Ac
aC,Bc
bC
AbCaBc
It holds in a projective plane over any field, but fails for projective planes over any noncommutative division ring.[1] Projective planes in which the "theorem" is valid are called pappian planes.
If one considers a pappian plane containing a hexagon as just described but with sides
Ab
aB
Bc
bC
u
If the Pappus line
u
g,h
A,B,C
a,b,c
x,y,z
A\capb
a\capB, A\capc
a\capC, B\capc
b\capC
Pappus's theorem is a special case of Pascal's theorem for a conic—the limiting case when the conic degenerates into 2 straight lines. Pascal's theorem is in turn a special case of the Cayley–Bacharach theorem.
The Pappus configuration is the configuration of 9 lines and 9 points that occurs in Pappus's theorem, with each line meeting 3 of the points and each point meeting 3 lines. In general, the Pappus line does not pass through the point of intersection of
ABC
abc
Bc,bC,XY
x,y,z
X,Y,Z
Bc,bC,XY
If the affine form of the statement can be proven, then the projective form of Pappus's theorem is proven, as the extension of a pappian plane to a projective plane is unique.
Because of the parallelity in an affine plane one has to distinct two cases:
g\not\parallelh
g\parallelh
Case 1: The lines
g,h
S=g\caph
S=(0,0), A=(0,1), c=(1,0)
B,C
B=(0,\gamma), C=(0,\delta), \gamma,\delta\notin\{0,1\}
Bc, Cb
b=(\tfrac{\delta}{\gamma},0)
Ab,Ba
a=(\delta,0)
Ca
-1
Ac
Case 2:
g\parallelh
c=(0,0), b=(1,0), A=(0,1), B=(\gamma,1), \gamma\ne0
Ab\parallelBa
cB\parallelbC
C=(\gamma+1,1)
a=(\gamma+1,0)
Ac\parallelCa
Choose homogeneous coordinates with
C=(1,0,0), c=(0,1,0), X=(0,0,1), A=(1,1,1)
AC,Ac,AX
x2=x3, x1=x3, x2=x1
B,Y,b
B=(p,1,1), Y=(1,q,1), b=(1,1,r)
p,q,r
XB,CY,cb
x1=x2p, x2=x3q, x3=x1r
a
rqp=1
Cb,cB
XY
x2=x1q, x1=x3p, x3=x2r
Z
rpq=1
pq=qp
X,Y,Z
The proof above also shows that for Pappus's theorem to hold for a projective space over a division ring it is both sufficient and necessary that the division ring is a (commutative) field. German mathematician Gerhard Hessenberg proved that Pappus's theorem implies Desargues's theorem.[4] In general, Pappus's theorem holds for some projective plane if and only if it is a projective plane over a commutative field. The projective planes in which Pappus's theorem does not hold are Desarguesian projective planes over noncommutative division rings, and non-Desarguesian planes.
The proof is invalid if
C,c,X
Because of the principle of duality for projective planes the dual theorem of Pappus is true:
If 6 lines
A,b,C,a,B,c
G,H
X:=(A\capb)(a\capB),
Y:=(c\capA)(C\capa),
Z:=(b\capC)(B\capc)
U
G,H
U
GH
If in the affine version of the dual "little theorem" point
U
Because the statement of Thomsen's theorem (the closure of the figure) uses only the terms connect, intersect and parallel, the statement is affinely invariant, and one can introduce coordinates such that
P=(0,0), Q=(1,0), R=(0,1)
(0,λ).
In addition to the above characterizations of Pappus's theorem and its dual, the following are equivalent statements:
\left|\begin{matrix} A&B&C\\ a&b&c\\ X&Y&Z\end{matrix} \right|
That is, if
ABC,abc,AbZ,BcX,CaY,XbC,YcA,ZaB
XYZ
(A,B,C)
AB,CD,
EF
DE,FA,
BC
AD,BE,
CF
In its earliest known form, Pappus's Theorem is Propositions 138, 139, 141, and 143 of Book VII of Pappus's Collection.[9] These are Lemmas XII, XIII, XV, and XVII in the part of Book VII consisting of lemmas to the first of the three books of Euclid's Porisms.
The lemmas are proved in terms of what today is known as the cross ratio of four collinear points. Three earlier lemmas are used. The first of these, Lemma III, has the diagram below (which uses Pappus's lettering, with G for Γ, D for Δ, J for Θ, and L for Λ).
Here three concurrent straight lines, AB, AG, and AD, are crossed by two lines, JB and JE, which concur at J. Also KL is drawn parallel to AZ.Then
KJ : JL :: (KJ : AG & AG : JL) :: (JD : GD & BG : JB).These proportions might be written today as equations:[10]
KJ/JL = (KJ/AG)(AG/JL) = (JD/GD)(BG/JB).The last compound ratio (namely JD : GD & BG : JB) is what is known today as the cross ratio of the collinear points J, G, D, and B in that order; it is denoted today by (J, G; D, B). So we have shown that this is independent of the choice of the particular straight line JD that crosses the three straight lines that concur at A. In particular
(J, G; D, B) = (J, Z; H, E).It does not matter on which side of A the straight line JE falls. In particular, the situation may be as in the next diagram, which is the diagram for Lemma X.
Just as before, we have (J, G; D, B) = (J, Z; H, E). Pappus does not explicitly prove this; but Lemma X is a converse, namely that if these two cross ratios are the same, and the straight lines BE and DH cross at A, then the points G, A, and Z must be collinear.
What we showed originally can be written as (J, ∞; K, L) = (J, G; D, B), with ∞ taking the place of the (nonexistent) intersection of JK and AG. Pappus shows this, in effect, in Lemma XI, whose diagram, however, has different lettering:
What Pappus shows is DE.ZH : EZ.HD :: GB : BE, which we may write as
(D, Z; E, H) = (∞, B; E, G).The diagram for Lemma XII is:
The diagram for Lemma XIII is the same, but BA and DG, extended, meet at N. In any case, considering straight lines through G as cut by the three straight lines through A, (and accepting that equations of cross ratios remain valid after permutation of the entries,) we have by Lemma III or XI
(G, J; E, H) = (G, D; ∞ Z).Considering straight lines through D as cut by the three straight lines through B, we have
(L, D; E, K) = (G, D; ∞ Z).Thus (E, H; J, G) = (E, K; D, L), so by Lemma X, the points H, M, and K are collinear. That is, the points of intersection of the pairs of opposite sides of the hexagon ADEGBZ are collinear.
Lemmas XV and XVII are that, if the point M is determined as the intersection of HK and BG, then the points A, M, and D are collinear. That is, the points of intersection of the pairs of opposite sides of the hexagon BEKHZG are collinear.
ABC
abc
Aa,Bb
Cc