Then, since a straight line GF through the centre cuts a straight line AC not through the centre at right angles,
it also bisects it; [III. 3]
therefore AG is equal to GC.
Since, then, the straight line AC has been cut into equal parts at G and into unequal parts at E,
the rectangle contained by AE, EC together with the square on EG is equal to the square on GC; [II. 5]
Let the square on GF be added;
therefore the rectangle AE, EC together with the squares on GE, GF is equal to the squares on CG, GF.
But the square on FE is equal to the squares on EG, GF, and the square on FC is equal to the squares on CG, GF; [I. 47]
therefore the rectangle AE, EC together with the square on FE is equal to the square on FC.
And FC is equal to FB;
therefore the rectangle AE, EC together with the square on EF is equal to the square on FB.
For the same reason, also, the rectangle DE, EB together with the square on FE is equal to the square on FB.
But the rectangle AE, EC together with the square on FE was also proved equal to the square on FB;
therefore the rectangle AE, EC together with the square on FE is equal to the rectangle DE, EB together with the square on FE.
Let the square on FE be subtracted from each;
therefore the rectangle contained by AE, EC which remains is equal to the rectangle contained by DE, EB.