<--found on Ignacio Larrosa Canestro's website at -->
Ignacio Larrosa Canestro's website
<--with a table containing entries as follows (translated from Spanish to English):-->
- rhombic structure of a decagon and verious decagrams
- Q-swing
- quadrilateral to triangle
- quadrilateral to rectangle
- rectangle to square
- hinged equilateral triangle to square
- regular pentagon to square
- regular pentagon to square
- regular hexagon to square
- regular heptagon to square (Gavin Theobald's)
- regular octagon to square (from Persian Interlocks manuscript)
- {12} to {4} (Harry Lindgren's)
- Greek Cross to {4}
- Latin Cross to {4}
- Maltese Cross to {4} (not A.E. Hill's 7-piece beauty)
- generalized Maltese Cross to {4} (Harry Lindgren's)
- hexagram to square (Harry Bradley's)
- mitre to square (Henry E. Dudeney)
- house to square (Sam Loyd, see PHD)
- parhexagon to square (PDF)
- pentagons for 7^2+24^2 =25^2 (David Collison's method in DPF)
- 2 squares to 1 (more than 4 pieces!)
- 4 pentagons to 1 (see DPF)
- 5 pentagons to 1 (see DPF)
- 8 heptagons to 1 (see better result in DPF)
- 2 octagons to 1 (see better result in DPF)
- 4 octagons to 1
- 4 enneagons to 1
- {5/2}s for (sin 2 pi/5)^2+(cos 2 pi/5)^2 = 1 (Varsady in DPF or HD)
- {7/2}s for (sin 2 pi/7)^2+(cos 2 pi/7)^2 = 1 (me in DPF)
- {7/3} to two {7}s (me in DPF)
- {12/5} to Latin Cross (Harry Lindgren's)
- Fibonacci expansion paradox (Fig. 23.9 PDF)
- rectangular paradox
- another rectangular paradox