Jesús de la Peña Hernández
- HAGA ́s THEOREM
Enunciation:
Let the square FIJH whose side measures one unit. If we fold vertex F over the mid-point of
JI, three right-angled triangles ∆(abc); ∆(xyz); ∆(def) are obtained in such a way that their
sides keep the proportion 3,4,5. Besides, beingx=^12 , it is also a=^23- HAGA ́s THEOREM EXTENSION
3.1 For any value of x, THE PERIMETER of ∆(abc) equals the sum of perimeters of
∆(xyz) and ∆(def).
Moreover, the perimeter of ∆(abc) is equal to half the perimeter of square FIJH.
3.2 KOHJI and MITSUE FUSHIMI
If x=^13 , it follows that a=^12 ; and if x=^14 , it ́s a=^25- HAGA ́s THEOREM DEMONSTRATION; likewise its extension will be demonstrated for
any value of x.
Fig. 1 is a square whose side is equal to 1. F is folded over the upper side, being x the inde-
pendent variable. By so doing, fig. 2 is produced. In Fig. 3 BA is drawn perpendicular to JI through
B, so BA and EF are parallel. Fold BF is perpendicular to DE because DE is the perpendicular bisec-
tor of BF. Therefore ABEF is a quadrilateral having perpendicular diagonals and opposite vertices (B
and F) equidistant from the intersection point of those diagonals; moreover, opposite sides BA and
EF are parallel as said hereby. Consequently this quadrilateral is a rhomb.
JIH F=
c=
xa b
y zd
fexxxa bcy zed
fa bc
y zf
FFdJ IDHVE
A1 23
Bp