APPENDIX
557
‘ obscurity ’ of Archimedes; while, as regards Vieta, he has
shown that the statement quoted is based on an entire mis
apprehension, and that, so far from suspecting a fallacy in
Archimedes’s proofs, Yieta made a special study of the treatise
On Spirals and had the greatest admiration for that work.
But, as in many cases in Greek geometry where the analy
sis is omitted or even (as Wallis was tempted to suppose) of
set purpose hidden, the reading of the completed synthetical
proof leaves a certain impression of mystery; for there is
nothing in it to show ivhy Archimedes should have taken
precisely this line of argument, or how he evolved it. It is
a fact that, as Pappus said, the sub tangent-property can be
established by purely ‘ plane ’ methods, without recourse to
a ‘solid’ vtvcns (whether actually solved or merely assumed
capable of being solved). If, then, Archimedes chose the more
difficult method which we actually find him employing, it is
scarcely possible to assign any reason except his definite
predilection for the form of proof by reductio ad absurdum
based ultimately on his famous ‘Lemma’ or Axiom.
It seems worth while to re-examine the whole question of
the discovery and proof of the property, and to see how
Archimedes’s argument compares with an easier ‘ plane ’ proof
suggested by the figures of some of the very propositions
proved by Archimedes in the treatise.
In the first place, we may be sure that the property was
not discovered by the steps leading to the proof as it stands.
I cannot but think that Archimedes divined the result by an
argument corresponding to our use of the differential calculus
for determining tangents. He must have considered the
instantaneous direction of the motion of the point P describ
ing the spiral, using for this purpose the parallelogram of
velocities. The motion of P is compounded of two motions,
one along OP and the other at right angles to it. Comparing
the distances traversed in an instant of time in the two direc
tions, we see that, corresponding to a small increase in the
radius vector r, we have a small distance traversed perpen
dicularly to it, a tiny arc of a circle of radius r subtended by
the angle representing the simultaneous small increase of the
angle 0 (AOP). Now r has a constant ratio to 6 which we call
a (when 6 is the circular measure of the angle 6). Consequently