On the Sphere and Cylinder.
BookI.
I first set out the
axioms and the assumptions which I have used for the proofs of my propositions.
Definitions.
1. There are in a plane
certain terminated bent lines, which either lie wholly on the same side of the
straight lines joining their extremities, or have no part of them on the other
side.
2. I apply the term
concave in the same direction to a line such that, if any two points on it are
taken, either all the straightlines connecting the points fall on the same side
of the line, or some fall on one and the same side while others fall on the
line itself, but none on the other side.
3. Similarly also there
are certain terminated surfaces, not themselves being in a plane but having
their extremities in a plane, and such that they will either be wholly on the
same side of the plane containing their extremities, or have no part of them on
the other side.
4. I apply the term
concave in the same direction to surfaces such that, if any two points on them
are taken, the straightlines connecting the points either all fall on the same
side of the surface, or some fall on one and the same side of it while some fall
upon it, but none on the other side.
5. I use the term solid
sector, when a cone cuts a sphere, and has its apex at the centre of the
sphere, to denote the figure comprehdned by the surface of the cone and the
surface of the sphere included within the cone.
6. I apply the term
solid rhombus, when two cones with the same base have their apices on opposite
sides of the plane of the base in such a position that their axes lie in a
straightline, to denote the solid figure made up of both the cones.
Assumptions.
1. Of all lines which
have the same extremities the straightline is the least.
2. Of other lines in a
plane and having the same extremities, [any two] such are unequal whenever both
are concave in the same direction and one of them is either wholly included
between the other and the straightline which has the same extremities with it,
or is partly included by, and is partly common with, the other; and that [line]
which is included is the lesser[ of the two].
3. Similarly, of
surfaces which have the same extremities, if those extremities are in a plane,
the plane is the least [in area].
4. Of other surfaces
with the same extremities, the extremities being in a plane, [any two] such are
unequal whenever both are concave in the same direction and one surface is
either wholly included between the other and the plane which has the same
extremities with it, or is partly included by, and partly common with, the
other; and that [surface] which is included is the lesser[ of the two in area].
5. Further, of unequal
lines, unequal surfaces, and unequal solids, the greater exceeds the less by
such a magnitude as, when added to itself, can be made to exceed any assigned
magnitude among those which are comparable with [it and with] one another.
These things being
premised, if a polygon be inscribed in a circle, it is plain that the perimeter
of the inscribed polygon is less than the circumference of the circle; for each
of the sides of the polygon is less than that part of the circumference of the
circle which is cut off by it."
Prop.1. If a polygon be
circumscribed about a circle, the perimeter of the circumscribed polygon is
greater than the perimeter of the circle.
Prop.2. Given two
unequal magnitudes, it is possible to find two unequal straightlines such that
the greater straightline has to the less a ratio than the greater magnitude has
to the less.
Prop.3. Given two
unequal magnitudes and a circle, it is possible to inscribe a polygon in the
circle and to describe another about it so that the side of the circumscribed
polygon may have to the side of the inscribed polygon a ratio less than that of
the greater magnitude to the less.
Prop.4. Again, given two
unequal magnitudes and a sector, it is possible to describe a polygon about the
sector and to inscribe another in it so that the side of the circumscribed
polygon may have to the side of the inscribed polygon a ratio less than the
greater magnitude has to the less.
Prop.5. Given a circle
and two unequal magnitudes, to describe a polygon about the circle and inscribe
another in it, so that the circumscribed polygon may have to the inscribed a
ratio less than the greater magnitude has to the less.
Prop.6. Similarly
we an show that, given two unequal
magnitudes and a sector, it is possible to circumscribe a polygon about the
sector and inscribe in it another similar one so that the circumscribed may
have to the inscribed a ratio less than the greater magnitude has to the less.
And it is likewise clear
that, if a circle or a sector, as well as a certain area, be given, it is
possible, by inscribing regular polygons in a circle or sector, and by
continually inscribing such in the remaining segments, to leave segments of the
circle or sector which are [together] less than the given area. For this is
proved in theElements. [Eucl.XII.2.]
But it is yet to be
proved that, given a circle or sector and an area, it is possible to describe a
polygon about the circle or sector, such that the area remaining between the
circumference and the circumscribed figure is less than the given area."
Prop.7. If in an
isosceles cone [i.e. a right circular cone] a pyramid be inscribed having an
equilateral base, the surface of the pyramid excluding the base is equal to a
triangle having its base equal to the perimeter of the base of the pyramid and
its height equal to the perpendicular drawn from the apex on one side of the
base.
Prop.8. If a pyramid be
circumscribed about an isosceles cone, the surface of the pyramid excluding its
base is equal to a triangle having its base equal to the perimeter of the base
of the pyramid and its height equal to the side [i.e. a generator] of the cone.
Prop.9. If in the
circular base of an isosceles cone a chord be placed and from its extremities
straightlines be drawn to the apex of the cone, the triangle so formed will be
less than the portion of the surface of the cone intercepted between the lines
drawn to the apex.
Prop.10. If in the plane
of the circulase base of an isosceles cone two tangents be drawn to the circle
meeting in a point, and the points of contact and the point of concourse of the
tangents be respectively joined to the apex of the cone, the sum of the two
triangles formed by the joining lines and the two tangents are together greater
than the included portion of the surface of the cone.
Prop.11. If a plane
parallel to the axis of a right cylinder cut the cylinder, the part of the
surface of the cylinder cut off by the plane is greater than the area of the
parallelogram in which the plane cuts it.
Prop.12. If at the
extremities of two generators of any right cylinder tangents be drawn to the
circular bases in the planes of those bases respectively, and if the pairs of
tangents meet, the parallelograms formed by each generator and the two
corresponding tangents respectively are together greater than the included
portion of the surface of the cylinder between the two generators.
[The proofs of these two
prop.s follow exactly the methods of Props.9,10 respectively, and it is
therefore unnecessary to reproduce them.]
From the properties thus
proved it is clear (1) that, if a pyramid be inscribed in an isosceles cone,
the surface of the pyramid excluding the base is less than the surface of the
cone [excluding the base], (2) that, if a pyramid be circumscribed about an
isosceles cone, the surface of the pyramid excluding the base is greater than
the surface of the cone excluding the base.
It is also clear from
what has been proved both (1) that, if a prism be inscribed in a right
cylinder, the surface of the prism made up of its parallelograms [i.e.
excluding its bases] is less than the surface of the cylinder excluding its bases,
and (2) that, if a prism be circumscribed about a right cylinder, the surface
of the prism made up of its parallelograms is greater than the surface of the
cylinder excluding its bases."
Prop.13. The surface of
any right cylinder excluding the bases is equal to a circle whose radius is a
meanproportional between the side [i.e. a generator] of the cylidner and the
diameter of its base.
Prop.14. The surface of
any isosceles cone excluding the base is equal to a circle whose radius is a
meanproportional between the side of the cone [a generator] and the radius of
the circle which is the base of the cone.
Prop.15. The surface of
any isosceles cone has the same ratio to its base as the side of the cone has
to the radius of the base.
Prop.16. If an isosceles
cone be cut by a plane parallel to the base, the portion of the surface of the
cone between the parallel planes is equal to a circle whose radius is a
meanproportional between (1) the portion of the side of the cone intercepted by
the parallel planes and (2) the line which is equal to the sum of the radii of
the circles in the parallel planes.
Lemmas.
1. Cones having equal
height have the same ratio as their bases; and those having equal bases have
the same ratio as their heights. [Eucl.XII.11.]
2. If a cylinder be cut
by a plane parallel to the base, then, as the cylinder is to the cylinder, so
is the axis to the axis. [Eucl.XII.14.]
3. The cones which have
the same bases as the cylinders [and equal height] are in the same ratio as the
cylinders. [Eucl.XII.13.]
4. Also the bases of
equal cones are reciprocallyproportional to their heights; and those cones
whose bases are reciprocallyproportional to their heights are equal.
[Eucl.XII.15.]
5. Also the cones, the
diameters of whose bases have the same ratio as their axes, are to one another
in the triplicateratio of the diameters of the bases. [Eucl.XII.12.]
Prop.17. If there be two
isosceles cones, and the surface of one cone be equal to the base of the other,
while the perpendicular from the centre of the base [of the first cone] on the
side of that cone is equal to the height [of the second], the cones will be
equal.
Prop.18. Any solid
rhombus consisting of isosceles cones is equal to the cone which has its base
equal to the surface of one of the cones composing the rhombus and its height
equal to the perpendicular drawn from the apex of the second cone to one side
of the first cone.
Prop.19. If an isosceles
cone be cut by a plane parallel to the base, and on the resulting circular
section a cone be described having as its apex the centre of the base [of the
first cone], and if the rhombus so formed be taken away from the whole cone,
the part remaining will be equal to the cone with base equal to the surface of
the portion of the first cone between the parallel planes and with height equal
to the perpendicular drawn from the centre of the base of the first cone on one
side of that cone.
Prop.20. If one of the
two isosceles cones forming a rhombus be cut by a plane parallel to the base
and on the resullting circular section a cone be described having the same apex
as the second cone, and if the resulting rhombus be taken from the whole
rhombus, the remainder will be equal to the cone with base equal to the surface
of the portion of the cone between the parallel planes and with height equal to
the perpendicular drawn from the apex of the second cone to the side of the
first cone.
Prop.21. A regular
polygon of an even number of sides being inscribed in a circle, As
ABC...A'...C'B'A, so that AAj' is a diameter,
if two angular points
next but one to each other, as B, B', be joined, and the other lines parallel
to BB' and joining pairs of angular points be drawn, as CC', DD'...,
then (BB'+CC'+...):AA' =
A'B:BA.
Prop.22. If a polygon be
described in a segment of a circle LAL' so that all its sides excluding the
base are equal and their number even, as LK...A...K'L', A being the middle
point of the segment, and if the lines BB', CC',... parallel to the base LL'
and joining pairs of angular points be drawn,
then
(BB'+CC'+...+LM):AM=A'B:BA, where M is the middlepoint of LL' and AA' is the
diameter throughM.
Prop.23. The surface of
the sphere is greater than the surface described by the revolution of the
polygon inscribed in the great circle about the diameter of the great circle.
Prop.24. If a reulgar
polygon AB...A'...B'A, the number of whose sides is a multiple of four, be inscribed
in a great circle of a sphere,
andif BB' subtending two
sides be joined, and all the other lines parallel to BB' and joining pairs of
angular points be drawn,
then the surface of the
figure inscribed in the sphere by the revolution of the polygon about the
diameter AA' is equal to a circle the square of whose radius is equal to the
rectangle BA(BB'+CC'+...).
Prop.25. The surface of
the figure inscribed in a sphere as in the last prop., consisting of portions
of conical surfaces, is less than fourtimes the greatest circle in the sphere.
Prop.26. The figure
inscribed as above in a sphere is equal [in volume] to a cone whose base is a
circle equal to the surface of the figure inscribed in the sphere and whose
height is equal to the perpendicular drawn from the centre of the sphere to one
side of the polygon./
Prop.27. The figure
inscribed in the sphere as before is less than fourtimes the cone whose base is
equal to a great circle of the sphere and whose height is equal to the radius
of the sphere.
Prop.28. The surface of
the figure circumscribed to the given sphere is greater than that of the sphere
itself.
Prop.29. In a figure
circumscribed to a sphere in the manner shown in the previous prop., the
surface is equal to a circle the square on whose radius is equal to
AB(BB'+CC'+...).
Prop.30. The surface of
a figure circumscribed as before about a sphere is greater than fourtimes the
great circle of the sphere.
Prop.31. The solid of
revolution circumscribed as before about a sphere is equal to a cone whose base
is equal to the surface of the solid and whose height is equal to the radius of
the sphere.
Cor. The solid
circumscribed about the smaller sphere is greater than four times the cone
whose base is a great circle of the sphere and whose height is equal to the
radius of the sphere.
Prop.32. If a regular
polygon with 4n sides be inscribed in a great circle of a sphere, as
ab...a'...b'a, and a similar polygon AB...A'...B'A be described about the great
circle,
andif the polygons
resolve with the great circle about the diameters aa', AA' respectively, so
that they describe the surfaces of solid figures inscribed in and circumscribed
to the sphere respectively
then (1) the surfaces of
the circumscribed and inscribed figures are to one another in the
duplicateratio of their sides,
and (2) the figures
themselves [i.e. their volumes] are in the triplicateratio of their sides.
Prop.33. The surface of
any sphere is equal to fourtimes the greatest circle in it.
Prop.34. Any sphere is
equal to fourtimes the cone which has tis base equal to the greatest circle in
the sphere and it sheight equal to the radius of the sphere.
Cor. From what has been
proved it follows that every cylinder whose base is the greatest circle in a
sphere and whose height is equal to the diameter of the sphere is 3/2 of the
sphere, and its surface together with it sbases is 3/2 of the surface of the
sphere.
Prop.35. If in a segment
of a circle LAL', where A is the middle point of the arc, a polygon
LK...A...K'L' be inscribed of which LL' is one side, while the other sides are
2n in number and all equal, and if the polygon resolve with the segment about
the diameter AM, generating a solidfigure inscribed in a segment of a sphere,
then the surface of the inscribed solid is equal to a circle the sphere on
whose radius is equal to the rectangle
AB(BB'+CC'+...+KK'+(LL'/2).
Prop.36. The surface of
the figure inscribed as before in the segment of a sphere is less than that of
the segment of the sphere.
Prop.37. The surface of
the solid figure inscribed in the segment of the sphere by the revolution of
LK...A...K'L' about AM is less than a circle with radius equal toAL.
Prop.38. Thed
solidfigure described as before in a segment of a sphere less than a
hemisphere, together with the cone whose base is the base of the segment and
whose apex is the centre of the sphere, is equal to a cone whose base is equal
to the surface of the inscribed solid and whose height is equal to the
perpendicular from the centre of the sphere on any side of the polygon.
Cor. The cone whose base
is a circle with radius equal to AL and whose height is equal to the radius of
the sphere is greater than the sum of the inscribed solid and the cone OLL'.
Prop.39. The surface of
the solid figure so circumscribed about the sector of the sphere [excluding its
base] will be greater than that of the segment of the sphere whose base is the
circle on ll' as diameter.
Cor. The surface of the
figure so described about the sector of the sphere is equal to a circle the
square on whose radius is equal to the rectangle
AB(BB'+CC'+...+KK'+(1/2)LL').
Prop.40. The surface of
the figure circumscribed to the sector as before is greater than a circle whose
radius is equal to al.
Cor.1. The volume of the
figure circumscribed about the sector together with the cone whose apex is O
and base the circle on LL' as diameter, is equal to the volume of a cone whose
base is equal to the surface of the circumscribed figure and whose height is
ON.
Cor.2. The volume of the
circumscribed figure with the cone OLL' is greater than the cone whose base is
a circle with radius equal to al and whose height is equal to the radius (Oa)
of the inner sphere.
Prop.41. Let lal' be a
segment of a great circle of a sphere which is less than a semicircle.
Suppose a polygon
inscribed in the sector Olal' such that the sides lk,...ba, ab',lllk'l' are 2n
in number and all equal. Let a similar polygon be circumscribed about the
sector so that its sides are parallel to those of the first polygon; and draw
the circle circumscribing the outer polygon.
Now let the polygons and
circles revolve together about OaA, the radius bisecting the segment lal'.
Then (1) the surfaces of
the outer and inner solids of revolution so described are in the ratio of
A*Bsquare to a*bsquare,
and (2) their volumes
together with the corresponding cones with the same base and with apex O in
each case are as A*Bsquare to a*bsquare.
Prop.42. If lal' be a
segment of a sphere less than a hemisphere and Oa the radius perpendicular to
the base of the segment, the surfaces of the segment is equal to a circle whose
radius is equal to al.
Prop.43. Even if the
segment of the sphere is greater than a hemisphere, its surface is still equal
to a circle whose radius is equal to al.
Prop.44. The volume of
any sector of a sphere is equal to a cone whose base is equal to the surface of
the segment of the sphere included in the sector, and whose height is equal to
the radius of the sphere.
On the sphere and
cylinder. BookII.
Prop.1. Problem. Given a
cone or a cylinder, to find a sphere equal to the cone or to the cylinder.
Prop.2. If BAB' be a
segment of a sphere, BB' a diameter of the base of the segment, and O the
centre of the sphere, and if AA' be the diameter of the sphere bisecting BB' in
M,
then the volume of the
segment is equal to that of a cone whose base is the same as that of the
segment and whose height is h, where h:AM = OA'+A'M:A'M.
Cor. The segment BAB' is
to a cone with the same base and equal height in the ratio of OA'+A'M to A'M.
Prop.3. Problem. to cut
a given sphere by a plane so that the surfaces of the segments may have to one
another a given ratio.
Prop.4. Problem. To cut
a given sphere by a plane so that the volumes of the segments are to one
another in a given ratio.
Note. The solution of
the subsidiary problem to which the original problem ofProp.4 is reduced, and
of which Archimedes promises a discussion, is given in a highlyinteresting and
important note byEutocius, who introduces the subject with the following
explanation.
The investigation which
follows may be thus reproduced. The general problem is,
Given two straightlines
AB, AC and an area D, to divide AB at M so that AM:AC = D:M*Bsquare.
Prop.5. Problem. To
construct a segment of a sphere similar to one segment and equal in volume to
another.
Prop.6. Problem. Given
two segments of spheres, to find a third segment of a sphere similar to one of
the given segments and having its surface equal to that of the other.
Prop.7. From a given
sphere to cut off a segment by a plane so that the segment may have a given
ratio to the cone which has the same base as the segment and equal height.
Prop.8. If a sphere be
cut by a plane not passing through the centre into two segments A'BB', ABB', of
which A'BB' is the greater,
then the ratio (segment
A'BB'):(Segment ABB') < (surface of A'BB')square:(surface of ABB')square,
but >(surface of
A'BB')power3/2 : (surface of ABB')power3/2.
[The text of Archimedes
adds an alternative proof of this prop., which is here omitted, because it is
in fact neither clearer nor shorter than the above.]
Prop.9. Of all segments
of spheres which have equal surfaces the hemisphere is the greatest in volume.
Measurement of a circle.
Prop.1. The area of any
circle is equal to a rightangledtriangle in which one of the sides about the
rightangle is equal to the radius, and the other to the circumference, of the
circle.
Prop.2. The area of a
circle is to the square on its diameter as 11 to 14.
Prop.3. The ratio of the
circumference of any circle to its diameter is less than 3*(1/7), but greater
than 3*(10/71).
On Conoids and
spheroids.
Introduction.
Definitions.
Lemma. If in an
ascending arithmeticalprogression consisting of the magnitudes A1, A2, ... An
the common difference be equal to the least term A1,
then n.An < 2(A1 + A2
+ ... + An)
and > 2(A1 + A2 + ...
+ An-1)
[The proof of this is
given incidentally in the treatise OnSpirals.Prop.11. By placing lines side by side
to represent the terms of the progression and then producing each so as to make
it equal to the greatest term, Archimedes gives the equivalent of the following
proof.]
Prop.1. If A1, B1, C1,
... K1 and A2, B2, C2, ... K2 be twoseries of magnitudes such that
A1:B1 = A2:B2,
B1:C1 = B2:C2, and so
on.
andif A3, B3, C3, ... K3
and A4, B4, C4, ... K4 be two other series such that
A1:A3 = A2:A4,
B1:B3 = B2:B4, and so
on,
then
(A1+B1+C1+...+K1):(A3+B3+C3+...+K3) = (A2+B2+C2+...+K2):(A4+B4+...+K4).
Cor. If any terms in the
third and fourth series corresponding to terms in the first and second be left
out, the result is the same. For example, if the last terms K3, K4 are absent,
(A1+B1+C1+...+K1):(A3+B3+C3+...+I3)
=
(A2+B2+C2+...+K2):(A4+B4+C4+...+I4), where I immediatelyprecedes K in each
series.
Lemma toProp.2.
[OnSpirals, Prop.10] If A1, A2, A3, ... An be n lines forming an ascending
arithmeticalprogression in which the common difference is equal to the least
term A1,
then (n+1)An-square +
A1(A1+A2+A3+...+An)
= 3(A1-square +
A2-square + A3-square + .... + An-square.)
Cor.1. From this it is
evident that
n*An-square <
3(A1-square + A2-square + ... + An-square).
Also An-square = A1{An +
2(An-1 + An-2 + ... + A1)}, as above,
so that An-square >
A1(An + An-1 + ... + A1),
and therefore An-square
+ A1(A1+A2+...+An)<2An-square.
It follows from the
prop. that
n*An-square >
3(A1-square + A2-square + ... + An-1-square).
Cor.2. All these results
will hold if we substitude similar figures for squares on all the lines; for
similar figures are in the duplicateratio of their sides.
Prop.2. If A1, A2, ...
An be any number of areas such that
A1 = Ax + x-square
A2 = a*2x + (2x)-square
A3 = a*3x + (3x)-square
...
An = a*nx + (nx)-square,
then n*An:(A1+A2+...+An)
< (a+nx):(u/2+nx/3),
and
n*An:(A1+A2+...+An-1) > (a+nx):(a/2+nx/3).
Prop.3. (1) If TP, TP'
be two tangents to any conic meeting in T,
andif Qq, Q'q' be any
two chords parallel respectively to TP, TP' and meeting in O,
then QO*Oq:Q'O*Oq' =
TP-square:TP'-square.
And this is proved in
the elements of conics. i.e. in the treatises on conics byAristaeus and Euclid.
(2) If QQ' be a chord of
a prabola bisected in V by the diameter PV,
and if PV be of constant
length,
then the areas of the
triangle PQQ' and of the segment PQQ' are both constant whatever be the
direction of QQ'.
Prop.4. The area of any
ellipse is to that of the auxiliary circle as the minor axis to the major.
Prop.5. If AA', BB' be
the major and minor axis of an ellipse respectively,
and if d be the diameter
of any circle,
then (area of
ellipse):(area of circle) = AA'*BB':d-square.
Prop.6. The area of
ellipses are as the rectangle under their axes. This follows at once from
Props.4.5.
Cor. The areas of
similar ellipses are as the squares of corresponding axes.
Prop.7. Given an ellipse
with centre C, and a line CO drawn perpendicular to its plane, it is possible
to find a circular cone with vertex O and such that the given ellipse is a
section of it [or, in other words, to find the circular sections of the cone
with vertex O passing through the circumference of the ellipse.]
Prop.8. Given an ellipse, a plane through one
of its axes AA' and perpendicular to the plane of the llipse, and a line CO
drawn from C, the centre, in the given plane through AA' but not perpendicular
to AA', it is possible to find a cone with vertex O such that the given ellipse
is a section of it [or, in other words, to find the circular sections of the
cone with vertex O whose surface passes through the circumference of the
ellipse.]
Prop.9. Given an
ellipse, a plane through one of its axes and perpendicular to that of the
ellipse, and a straightline CO drawn from the centre C of the ellipse in the
given plane through the axis but not perpendicular to that axis, it is possible
to find a cylinder with axis OC such that the ellipse is a section of it [or,
in other words, to find the circular sections of the cylinder with axis OC
whose surface passes through the circumference of the given ellipse.]
Prop.10. It was proved
by the earlier geometers that any two cones have to one another the ratio
compounded of the ratios of their bases and of their heights. [This follows
fromEucl.XII.11. and .14. taken together.] The same method of proof will show
that any segments of cone have to one another the ratio compounded of the
ratios of their bases and of their heights.
The prop. that any
'frustum' of a cylinder is triple of the conical segment which has the same
base as the frustum and equal height is also proved in the same manner as the
prop. that the cylinder is triple of the cone which has the same base as the
cylinder and equal height. [This prop. was prroved by Eudocux, as stated in the
preface to OnTheSphereAndCylinder.I. Cf. Eucl.XII.10.]
Prop.11. (1) If a
praboloid of revolution be cut by a plane through, or parallel to, the axis,
the section will be a parabola equal to the original parabola which by its
revolution generates the paraboloid. And the axis of the section will be the
intersection between the cutting plane and the plane through the axis of the
paraboloid at right angles to the cutting plane.
If the paraboloid be cut
by a plane at rightangles to its axis, the section will be a circle whose
centre is on the axis.
(2) If a hyperboloid of
revolution be cut by a plane through the axis, parallel to the axis, or through
the centre, the section will be a hyperbola,
(a) if the section be
through the axis, equal,
(b) if parallel to the
axis, similar,
(c) if through the
centre, not similar, to the original hyperbola which by its revolution
generates the hyperboloid. And the axis of the section will be the intersection
of the cutting plane and the plane through the axis of the hyperboloid at
rightangles to the cutting plane.
Any section of the
hyperboloid by a plane at rightangles to the axis will be a circle whose centre
is on the axis.
(3) If any of the
spheroidal figures be cut by a plane through the axis or parallel to the axis,
the section will be an ellipse,
(a) if the section be
through the axis, equal,
(b) if parallel to the
axis, similar, to the ellipse which by its revolution generates the figure. And
the axis of the section will be the intersection of the cutting plane and the
plane through the axis of the spheroid at rightangles to the cutting plane.
If the section be by a
plane at rightangles to the axis of the spheroid, it will be a circle whose
centre is on the axis.
(4) If any of the said
figures be cut by a plane through the axis,
and if a perpendicular
be drawn to the plane of section from any point on the surface of the figure by
not on the section, that perpendicular will fall within the section.
And the proofs of all
these props. are evident.
Prop.12. If a paraboloid
of revolution be cut by a plane neither parallel nor perpendicular to the axis,
and if the plane through
the axis perpendicular to the cutting plane intersect it in a straightline of
which the portion intercepted within the paraboloid is RR',
the section of the
paraboloid will be an ellipse whose major axis is RR' and whose minor axis is
equal to the perpendicular distance between the lines through R, R' parallel to
the axis of the paraboloid.
Prop.13.14. If a
hyperboloid of revolution be cut by a plane meeting all the generators of the
enveloping cone,
or if an 'oblong'
spheroid be cut by a plane not perpendicular to the axis,
and if a plane through
the axis intersect the cutting plane at right angles in a straightline on which
the hyperboloid or spheroid intercepts a length RR',
then the section by the
cuttingp lane will be an ellipse whose major axis is RR'.
[Archimedes begins
Prop.14 for the spheroid with the remark that, when the cutting plane passes
through or is parallel to the axis, the case is clear.]
Cor.1. If the spheroid
be a 'flat' spheroid,
then section will be an
ellipse, and everything will proceed as before except that RR' will in this
case be the minor axis.
Cor.2. In all conoids or
spheroid parallel sections will be similar, since the ratio
O*A-square:O*P-square the same for all the parallel sections.
Prop. 15. (1) If from
any point on the surface of a conoid a line be drawn,
in the case of the
paraboloid, parallel to the axis,
and, in the case of the
hyperboloid, parallel to any line passing through the vertex of the enveloping
cone,
the part of the
straightline which is in the same direction as the convexity of the surface
will fall without it,
and the part which is in
the other direction within it.
(2) If a plane touch a
conoid without cutting it,
it will touch it at one
point only,
and the plane drawn
through the point of contact and the axis of the concoid will be at rightangles
to the plane which touches it.
Prop.16. (1) If a plane
touch any of the spheroidal figures without cutting it,
it will touch at one
point only,
and the plane through
the point of contact and the axis will be at rightangles to the tangent plane.
This is proved by the
same method as the last prop.
(2) If any conoid or
spheroid be cut by a plane through the axis,
and if through any
tangent to the resulting conic a plane be erected at right angles to the plane
of section,
the plane so erected
will touch the conoid or spheroid in the same point as that in which the line
touches the conic.
Prop.17. If two parallel
planes touch any of the spheroidal figures, and another plane be drawn parallel
to the tangent planes and passing through the centre,
the line through any
point of the circumference of the resulting section parallel to the chord of
contact of the tangent planes will fall outside the spheroid.
This is proved at once
by reduction to a plane prop.
Prop.18. Any spheroid
figure which is cut by a plane through the centre is divided, both as regards
its surface and its volume, into two equal parts by that plane.
[To prove this,
Archimedes takes another equal and similar spheroid, divides it similarly by a
plane through the centre, and then uses the method of application.]
Prop.19.20. Given a
segment cut off by a plane from a praboloid or hyperboloid of revolution, or a
segment of a spheroid less than half the spheroid also cut off by a plane,
it is possible to
inscribe in the segment one solid figure and to circumscribe about it another
solid figure, each made up of cylinders or 'frusta' of cylinders of equal
height, and such that the circumscribed figure exceeds the inscribed figure by
a volume less than that of any given solid.
Prop.21.22. Any segment
of a paraboloid of revolution is half as large again as the cone or segment of
a cone which has the same base and the same axis.
Prop.23. If from a
paraboloid of revolution two segments be cut off,
then one by a plane
perpendicular to the axis, the other by a plane not perpendicular to the axis,
and if the axes of the
segments are euqla,
then the segments will
be equal in volume.
Prop.24. If from a paraboloid of revolution two
segments be cut off by planes drawn in any manner,
then the segments will
be to one another as the squares on their axes.
Prop.25.26. In any
hyperboloid of revolution,
if A be the vertex and
AD the axis of any segment cut off by a plane,
and if CA be the semidiameter
of the hyperboloid through A (CA being of course in the same straight line with
AD),
then (segment):(cone
with same base and axis) = (AD+3CA):(AD+2CA).
Prop.27.28.29.30. (1) In
any spheroid whose centre is C,
if a plane meeting the
axis cut off a segment not greater than half the spheroid and having A for its
vertex and AD for its axis,
and if A'D be the axis
of the remaining segment of the spheroid,
then (first
segment):(cone or segment of cone with the same base and axis)
= CA+A'D:A'D
[=3CA-AD:2CA-AD].
(2) As a particular
case, if the plane passes through the centre,
so that the segment is
half the spheroid, half the spheroid is double of the cone or segment of a cone
which has the same vertex and axis.
Prop.31.32. If a plane
divide a spheroid into two unequal segments,
and if AN, A'N be the
axes of the lesser and greater segments respectively,
while C is the centre of
the spheroid,
then (greater
segment):(cone or segment of cone with same base and axis) = CA+AN:AN.
On Spirals.
Prop.1. If a point move
at a uniform rate along any line, and two lengths be taken on it,
then they will be
proportional to the times of describing them.
Prop.2. If each of two
points on different lines respectively move along them each at a uniform rate,
and if lengths be taken,
one on each line, forming pairs,
such that each pair are
described in equal times,
then the lengths will be
proportionals.
Prop.3. Given any number
of circles, it is possible to find a straightline greater than the sum of all
their circumferences.
Prop.4. Given two
unequal lines, viz. a straightline and the circumference of a circle, It is
possible to find a straightline less than the greater of the two lines and
greater than the less.
Prop.5. Given a circle
with centre O, and the tangent to it at a point A, it is possible to draw from
O a straightline OPF, meeting the circle in P and the tangent in F,
such that, if c be the
circumference of any given circle whatever,
then FP:OP <
(arcAP):c.
Prop.6. Given a circle
with centre O, a chord AB less than the diameter, and OM the perpendicular on
AB from O, it is possible to draw a straightline OFP, meeting the chord AB in F
and the circle in P,
such that FP:PB = D:E,
where D:E is any given
ratio less than BM:MO.
Prop.7. Given a circle
with centre O, a chord AB less than the diameter, and OM the perpendicular on
it from O, it is possible to draw from O a straightline OPF, meeting the circle
in P and AB produced in F,
such that FP:PB = D:E,
where D:E is any given ratio greater than BM:MO.
Prop.8. Given a circle
with centre O, a chord AB less than the diameter, the tangent at B, and the
perpendicular OM from O on AB, it is possible to draw from O a straightline
OFP, meeting the chord AB in F, the circle in P and the tangent in G,
such that FP:BG = D:E,
where D:E is any given ratio less than BM:MO.
Prop.9. Given a circle
with centre O, a chord AB less than the diameter, the tangent at B, and the
perpendicular OM from O on AB, it is possbiel to draw from O a straightline
OPGF', meeting the circle in P, the tangent in G, and AB produced in F,
such that FP:BG = D:E,
where D:E is any given ratio greater than BM:MO.
Prop.10. If A1, A2, A3,
..., An be n lines forming an ascending arithmeticalprogression in which the
common difference is equal to A1, the least term,
then (n+1)*An-square +
A1(A1+A2+...+An)
= 3(A1-square +
A2-square + ... + An-square).
Prop.11. If A1, A2, ...,
An be n lines forming an ascending arithmeticalprogression [in which the common
difference is equal to A1, the least term],
then (n-1)*An-square :
(An-square + An-1-square + ... + A2-square) < An-square : {An*A1 +
1/3*(An-A1)-square}
but (n-1)+An-square :
(An-1-square + An-2-square + ... + A1-square) > An-square : {An*A1 +
1/3*(An-A1)square).
Cor. The results in the
above prop. are equallytrue if similar figures be substituted for square on the
several lines.
Def.s.
1. Spiral.
2. Origin of the spiral.
3. Initial line in the
revolution.
4. The first distance.
The second distance.
5. The first area. The
second area.
6. The forward
revolution. The backward revolution.
7. The first cicle. The
second circle.
Prop.12. If any number
of straightlines drawn from the origin to meet the spiral make equal angles
with one another,
then the lines will be
in arithmetical progression.
[The proof is obvious.]
Prop.13. If a
straightline touch the spiral,
then it will touch it in
onepointonly.
Prop.14. If O be the
origin, and P, Q two points on the first turn of the spiral,
and if OP, OQ produced
meet the first circle AKP'Q' in P', Q' respectively, OA being the initial line,
then OP:OQ = (arc
AKP'):(arc AKQ').
Prop.15. If P,Q be
points on the second turn of the spiral, and OP, OQ meet the first circle
AKP'Q' in P', Q' as in the last prop.
and if c be the circumference
of the first circle,
then OP:OQ = c+(arc
AKP'):c+(arc AKQ').
Prop.16.17. If BC be the
tangent at P, any point on the spiral, PC being the forward part of BC,
and if OP be joined,
then the angle OPC is
obtuse
while the angle OPB is
acute.
Prop.18.19. I. If OA be
the initial line, A the end of the first turn of the spiral,
and if the tangent to
the spiral at A be drawn,
then the straightline OB
drawn from O perpendicular to OA will meet the said tangent in some point B,
and OB will be equal to
the circumference of the first circle.
II. If A' be the end of
the second turn,
then the perpendicular
OB will meet the tangent at A' in some point B',
and OB' will be equal to
2 (circumference of second circle).
III. Generally, if An be
the end of the nth turn,
and OB meet the tangent
at An in Bn,
then OBn = ncn, where cn
is the circumference of the nth circle.
Prop.20. I. If P be any
point on the first turn of the spiral and OT be drawn perpendicular to OP,
then OT will meet the
tangent at P to the spiral in some point in T,
and if the circle drawn
with centre O and radius OP meet the initial line in K,
then OT is equal to the
arc this circle between K and P measured in the forward direction of the
spiral.
II. Generally, if P be a
point on the nth turn,
and the notation be as
before,
while p represents the
circumference of the circle with radius OP,
then OT = (n-1)p + arcKP
(measured forward).
Prop.21.22.23. Given an
area bounded by any arc of a spiral and the lines joining the extremities of
the arc to the origin, it is possible to circumscribe about the area one
figure, and to inscribe in it another figure, each consisting of similar
sectors of circles, and such that the circumscribed figure exceeds the
inscribed by less than any assigned area.
Cor. Since the area
bounded by the spiral is intermediate in magnitude between the circumscribed
and inscribed figures, it follows that
(1) a figure can be
circumscribed to the area such that it exceeds the area by less than any
assigned space,
(2) a figure can be
inscribed such that the area exceeds it by less than any assigned space.
Prop.24. The area
bounded by the first turn of the spiral and the initial line is equal to
onethird of the first circle [=1/3*pie*(2piea)-square, where the spiral is
r=a*thetha].
[The same proof shows
equally that, if OP be anyradius vector in the first turn of the spiral, the
arae of the portion of the spiral bound thereby is equal to onethird of that
sector of the circle drawn with radius OP which is bounded by the initial line
and OP, measured in the forward direction from the initial line.]
Prop.25.26.27.
[25.] If A2 be the end
of the second turn of the spiral, the area bounded by the second turn and
OA-square is to the area of the second circle in the ratio of 7 to 12, being
the ratio of {r2r1 + (1/3)(r2-r1)-square} to r2-square, where r1, 42 are the
radii of the first and second circles respectively.
[26.] If BC be any arc measured in the forward
direction on any turn of a spiral, not being greater than the complete turn,
and if a circle be drawn
with O as centre and OC as radius meeting OB in B',
then (area of spiral
between OB, OC):(sector OB'C) = {OC*OB + (1/3)(OC-OB)-square : OC-square}.
[27.] If R1 be the area
of the first turn of the spiral bounded by the initial line, R2 the area of the
ring added by the second complete turn, R3 that of the ring added by the third
turn, and so on,
then R3=2R2, R4=3R2,
R5=4R2, ..., Rn=(n-1)R2.
Also R2=6R1.
[Archimedes's proof of
Prop.25 is, mutatismutandis, the same as his proof of the more general Prop.26.
The latter will accordingly be given here, and applied toProp.25 as a
particular case.]
Prop.28. If O be the
origin and BC any arc measured in the forward direction on any turn of the
spiral,
let two circles be drawn
(1) with centre O, and radius OB, meeting OC in C',
and (2) with centre O and
radius OC, meeting OB produced in B'.
Then, if E denote the
area bounded by the larger circular arc B'C, the line B'B, and the spiral BC,
while F denotes the area
bounded by the smaller arc BC', the line CC' and the spiral BC,
E:F = {OB+(2/3)(OC-OB)}
: {OB+(1/3)(OC-OB)}.
On the equilibrium of
planes, or The centres of Gravity of planes.
BookI.
I postulate the
following.
1. Equal weights at
equal distances are in equilibrium, and equal weights at unequal distances are
not in equilibrium but incline towards the weight which is at the greater
distance.
2. If, when weights at
certain distances are in equilibrium, something be added to one of the weights,
they are not in equilibrium but incline towards that weight to which the
addition was made.
3. Similarly, if
anything be taken away from one of the weights, they are not in equilibrium but
incline towards the weight from which nothing was taken.
4. When equal and
similar plane figures coincide if applied ot one another, their centres of gravity
similarlycoincide.
5. In figures which are
unequal but similar the centres of gravity will be similarlysituated. By points
similarlysituated in relation to similar figure I mean points such that, if
straightlines be drawn from them to the equal angles, they make equal angles
with the corresponding sides.
6. If magnitudes at
certain distances be in equilibrium, (other) magnitudes equal to them will also
be in equilibrium at the same distances.
7. In any figure whose
perimeter is concave in (one and) the same direction the centre of gravity must
be within the figure.
Prop.1. Weights which
balance at equal distances are equal.
Prop.2. Unequal weights
at equal distances will not balance but will incline towards the greater
weight.
Prop.3. Unequal weights
will balance at unequal distances, the greater weight being at the lesser
distance.
Prop.4. If two equal
weights have not the same centre of gravity, the centre of gravity of both
taken together is at the middle point of the line joining their centre of
gravity.
[Proved fromProp.3. by
reductioadabsurdum. Archimedes assumes that the centre of gravity of both
together is on the straightline joining the centres of gravity of each, saying
that this had been proved before. The allusion is no doubt to the lost
treatise, OnLevers.]
Prop.5. If three equal
magnitudes have their centres of gravity on a straightline at equal distances,
the centre of gravity of the system will coincide with that of the middle
magnitude.
[This followsimmediately
fromProp.4.]
Cor.1. The same is true
of any odd number of magnitudes if those which are at equal distances from the
middle one are equal, while the distances between their centres of gravity are
equal.
Cor.2. If there be an
even number of magnitudes which their centres of gravity situated at equal
distances on one straightline,
and if the two middles
ones be equal,
while those which are
equidistant from them (on each side) are equal respectively,
then the centre of gravity
of the system is the middle point of the line joining the centres of gravity of
the two middle ones.
Prop.6.7. Two
magnitudes, whether commensurable [Prop.6.] or incommensurable [Prop.7.],
balance at distances reciprocallyproportional to the magnitudes.
Prop.8. If AB be a
magnitude whose centre of gravity is C,
and AD a part of it
whose centre of gravity is F,
then the centre of
gravity of the remaining part will be a point G on FC produced such that
GC:CF = (AD):(DE).
Prop.9. The centre of
gravity of any parallelogram lies on the straightline joining the middle points
of opposite sides.
Prop.10. The centre of
gravity of a parallelogram is the point of intersection of its diagnoals.
Prop.11. If abc, ABC be
two similar triangles, and g, G two points in them similarlysituated with
respect to them respectively,
then, if g be the centre
of gravity of the triangle abc,
G must be the centre of
gravity of the triangle ABC.
Prop.12. Given two
similar triangles abc, ABC, and d, D the middle points of bc, BC respectively,
then, if the centre of
gravity of abc lie on ad,
that of ABC will lie on
AD.
Prop.13. In any triangle
the centre of gravity lies on the straightline joining any angle to the middle
point of the opposite side.
Prop.14. It follows at
once from the last prop. that the centre of gravity of any triangle is at the
intersection of the lines drawn from any two angles to the middle points of the
opposite sides respectively.
Prop.15. If AD, BC be
the two parallel sides of a trapezium ABCD, AD being the smaller,
and if AD, BC be
bisected at E, F respectively,
then the centre of
gravity of the trapezium is at a point G on EF
such that GE:GF =
(2BC+AD):(2AD+BC).
On the equilibrium of
planes, BookII.
Prop.1. If P, P' be two
parabolic segments and D, E their centres of gravity respectively,
then the centre of
gravity of the two segments taken together will be at a point C on DE
determined by the relation P:P' = CE:CD.
Definitions and lemmas
preliminary toProp.2.
If in a segment bounded
by a straightline and a section of a rightangled cone [a parabola] a triangle
be inscribed having the same base as the segment and equal height,
if again triangles be
inscribed in the remaining segments having the same bases as the segments and
equal height,
and if in the remaining
segments triangles be isncribed in the same manner,
let the resulting figure
be said to be inscribed in the recognised manner in the segment.
And it is plain,
(1) that the lines
joining the two angles of the figure so inscribed which are nearest to the
vertex of the segment, and the next pairs of angles in order, will be parallel
to the base of the segment,
(2) that the said lines
will be bisected by the diameter of the segment, and
(3) that they will cut
the diameter in the proportions of the successive odd numbers, the number one
having reference to [the length adjacent to] the vertex of the segment.
And these properties will
have to be proved in their proper places.
[The last words indicate
an intention to give these prop.s in their proper connexion with systematic
proofs; but the intention does not appear to have been carried out, or at least
we know of no lost work ofArchimedes in which they could have appeared. The
results can however be easilyderived from prop.s given in
theQuadratureOfTheParabola as follows.]
Prop.2. If a figure be
inscribed in the recognised manner in a parabolic segment,
then the centre of
gravity of the figure so inscribed will lie on the diameter of the segment.
Prop.3. If BAB', bab' be
two similar parabolic segments whose diameters are AO, ao respectively,
and if a figure be
inscribed in each segment "in the recognised manner, the number of sides
in each figure being equal,
then the centres of
gravity of the inscribed figures will divide AO, ao in the same ratio.
[Archimedes enunciates
this prop. as true of similar segments, but it is equally true of segments
which are not similar, as the course of the proof will show.]
Prop.4. The centre of
gravity of any parabolic segment cut off by a straightline lies on the diameter
of the segment.
Prop.5. If in a
parabolic segment a figure be inscribed in the recognised manner,
then the centre of
gravity of the segment is nearer to the vertex of the segment than the centre
of gravity of the inscribed figure is.
Prop.6. Given a segment
of a parabola cut off by a straightline, it is possible to inscribe in it in
the recognised manner a figure such that the distance between the centres of
gravity of the segment and of the inscribed figure is less than any assigned
length.
Prop.7. If there be two
similar parabolic segments,
then the centres of
gravity divide their diameter in the same ratio.
[This prop., though
enunciated of similar segments only, like Prop.3 on which it depends, is
equallytrue of any segments. This fact did not escapeARchimedes, who uses the
prop. in its more general form for the proof of Prop.8 immediately following.]
Prop.8. If AO be the
diameter of a parabolic segment,
and G its centre of
gravity,
then AG = (3/2)GO.
Prop.9.Lemma. If a, b,
c, d be fourlines in continuedproportion and in descending order of magnitude,
and if d:(a-d) =
x:(3/5)(a-c),
and
(2a+4b+6c+3d):(5a+10b+10c+5d) = y:(a-c),
it is required to prove
that x+y = (2/5)a.
[The following is the
proof given byArchimedes, with the only difference that it is set out in
algebraical isntead of geometricalnotation. This is done in the particular case
simply in order to make the proof easier to follow. Archimedes exhibits his lines
in the figure reproduced in the margin, but, now that it is possible to use
algebraicalnotation, there is no advantage in using the figure and the more
cumbrous notation which only obscures the course of the proof.]
Prop.10. If PP'B'B be
the portion of a parabola intercepted between two parallel chords PP', BB'
bisected respectively in N, O by the diameter ANO (N being nearer than O to A,
the vertex of the segments),
and if NO be divided
into five equal parts of which LM is the middle one (L being nearer than M to
N),
then, if G be a point on
LM such that
LG:GM =
B*O-square*(2PN+BO):P*N-square*(2BO+PN),
G will be the centre of
gravity of the area PP'B'B.
The Sandreckoner.
I say then that, even if
a sphere were made up of the sand, as great as Aristarchus supposes the sphere
of the fixed stars to be, I shall still prove that, of the numbers named in the
Principles [** was apparently the title of the work sent toZeuxippus. Cf. the
note attached to the enumeration of lost works ofArchimedes in the
Introduction, ChapterII., ad fin.], some exceed in multitude the number of the
sand which is equal in magnitude to the sphere referred to, provided that the
following assumptions be made.
1. the perimeter of the
earth is about 3 000 000 stadia and not greater.
2. The diameter of the
earth is greater than the diameter of the moon, and the diameter of the sun is
greater than the diameter of the earth.
3. The diameter of the
sun is about 30 times the diameter of the moon and not greater.
4. The diameter of the
sun is greater than the side of the chiliagon inscribed in the greatest circle
in the (sphere of the) universe.
[Up to this point the
treatise has been literally translated because of the historial interest
attaching to the ipsissima verba ofArchimedes on such a subject. The rest of
the work can now be morefreelyreproduced, and, before proceeding to the
math.contents of it, it is only necessary to remark that Archimedes next
describes how he arrived at a higher and a lower limit for the angle subtended
by the sun. This he did by taking a long rod or ruler, fastening on the end of
it a small cylinder or disc, pointing the rod in the direction of the sun just
after its rising (so that it was possible to look directly at it), then putting
the cylinder at such a distance that it just concealed, and just failed to
conceal, the sun, and lastly measuring the angles subtended by the cylinder. He
explains also the correction which he thought it necessary to make because
"the eye does not see from one point but from a certain area".]
To prove that (on this
assumption) the diameter of the sun is greater than the side of a chiliagon, or
figure with 1000 equal sides, inscribed in a great circle of the 'universe'.
5. Suppose a quantity of
sand taken not greater than a poppyseed, and suppose that it contains not more
than 10 000 grains.
Next suppose that the
diameter of the poppyseed to be not less than (1/40)th of a fingerbreath.
Orders and periods of
numbers.
Octads.
Theorem.
Application to the
number of the sand.
Conclusion.
Quadrature of the
parabola.
Prop.1. If from a point
on a parabola a straightline be drawn which is either itself the axis or
parallel to the axis, as PV,
and if QQ' be a chord
parallel to the tangent to the parabola at P and meeting PV in V,
then QV = VQ'.
Conversely, if QV = VQ',
then the chord QQ' will
be parallel to the tangent at P.
Prop.2. If in a parabola
QQ' be a chord parallel to the tangent at P,
and if a straightline be
drawn through P which is either itself the axis or parallel to the axis, and
which meets QQ' in V and the tangent at Q to the parabola in T,
then PV = PT.
Prop.3. If from a point
on a parabola a straightline be drawn which is either itself the axis or
parallel to the axis, as PV,
and if from two other
points Q, Q' on the parabola straightlines be drawn parallel to the tangent at
P and meeting PV in V, V' respectively,
then PV:PV' =
Q*V-square:Q'*V'-square.
And these prop.s are
proved in the elements of conics. [i.e. in the treatises on conics by Euclid
and Aristaeus.]
Prop.4. If Qq be the
base of any segment of a parabola, and P the vertex of the segment,
and if the diameter
through any other point R meet Qq in O and QP (produced if necessary) in F,
then QV:VO = OF:FR.
Prop.5. If Qq be the
base of any segment of a parabola, P the vertex of the segment, and PV its
diameter,
and if the diameter of
the parabola through any other point R meet Qq in O and the tangent in Q in E,
then QO:Oq = ER:RO.
Prop.6.7. Suppose a
lever AOB placedhorizontally and supported at its middle point O.
Let a triangle BCD in
which the angle C is right or obtuse be suspended from B and O,
so that C is attached to
O and CD is in the same vertical line with O.
Then, if P be such an
area as, when suspended from A, will keep the system in equilibrium,
P = (1/3)*TriangleBCD.
Prop.8.9. Suppose a
lever AOB placedhorizontally and supported at its middle point O.
Let a triangle BCD,
rightangled or obtuseangled at C, be suspended from the points B, E on OB, the
angular point C being so attached to E that the side CD is in the some vertical
line with E.
Let Q be an area such
that AO:OE = TriangleBCD:Q.
Then, if an area P
suspended from A keep the system in equilibrium,
P<TriangleBCD, but
>Q.
Prop.10.11 Suppose a
lever AOB placed horizontally and supported at O, its middle point.
Let CDEF be a trapezium
which can be so placed that its parallel sides CD, FE are vertical,
while C is
verticallybelow O, and the other sides CF, DE meet B.
Let EF meet BO in H,
and let the trapezium be
suspended by attaching F to H and C to O.
Further, suppose Q to be
an area such that
AO:OH = (trapeziumCDEF):Q.
Prop.12.13. If the
trapezium CDEF be placed as in the last prop.s,
except that CD is
vertically below a point L on OB instead of being below O,
and the trapezium is
suspended from L, H,
suppose that Q, R are
areas such that
AO:OH = (trapezium
CDEF): Q,
and AO:OL = (trapezium
CDEF):R.
If then an area P
suspended from A keep the system in equilibrium,
P>R, but <Q.
Prop.14.15. Let Qq be
the base of any segment of a parabola.
Then, if two lines be
drawn from Q,q, each parallel to the axis of the parabola and on the same side
of Qq as the segment is,
either (1) the angles so
formed at Q,q are both rightangles,
or (2) one is acute and
the other obtuse.
In the latter case let
the angle at q be the obtuseangle.
Prop.16. Suppose Qq to
be the base of a parabolic segment,
q being not more distant
than Q from the vertex of the parabola.
Draw through q the
straightline qE parallel to the axis of the parabola to meet the tangent at Q
in E.
It is required to prove
that
(area of
segment)=(1/3)*TriangleEqQ.
Prop.17. It is now
manifest that the area of any segment of a parabola is fourthirds of the
triangle which has the same base as the segment and equal height.
Def. In segments bounded
by a straightline and any curve. Base. Height. Vertex.
Prop.18. If Qq be the
base of a segment of a parabola, and V the middle point of Qq,
and if the diameter
through V meet the curve in P,
then P is the vertex of
the segment.
Prop.19. If Qq be a
chord of a parabola bisected in V by the diameter PV,
and if RM be a diameter
bisecting QV in M, and RW be the ordinate from R to PV,
then PV = (4/3)RM.
Prop.20. If Qq be the
base, and P the vertex, of a parabolic segment,
then the triangle PQq is
greater than the half the segment PQq.
Cor. It follows that it
is possible to isncribe in the segment a polygon such that the segments left over
are together less than any assigned area.
Prop.21. If Qq be the
base, and P the vertex, of any parabolic segment,
and if R be the vertex
of the segment cut off by PQ,
then TrianglePQq =
8*TrianglePRQ.
Prop.22. If there be a
series of areas A, B, C, D,... each of which is fourtimes the next in order,
and if the largest, A,
be equal to the triangle PQq inscribed in a parabolic segment PQq and having
the same base with it and equal height,
then (A+B+C+D+...) <
(area of segment PQq).
Prop.23. Given a series
of areas A, B, C, D ... Z, of which A is the greatest,
and each is equal to
four times the next in order,
then A+B+C+...+Z+(1/3)Z
= (4/3)A.
Prop.24. Every segment
bounded by a parabola and a chord Qq is equal to fourthirds of the triangle
which has the same base as the segment and equal height.
On Floating bodies.
BookI.
Postulate1. Let it be
supposed that a fluid is of such a character that, its parts lying evenly and
being continuous, that part which is thrust the less is driven along by that
which is thrust the more; and that each of its parts is thrust by the fluid
which is above it in a perpendicular direction if the fluid be sunk in anything
and compressed by anything else.
Prop.1. If a surface be
cut by a plane alwayspassing through a certain point,
and if the section be
always a circumference [of a circle] whose centre is the aforesaid point,
then the surface is that
of a sphere.
Prop.2. The surface of
any fluid at rest is the surface of a sphere whose centre is the same as that
of the earth.
Prop.3. Of solids those
which, size for size, are of equal weight with a fluid will, if let down into
the fluid, be immersed
so that they do not
project above the surface but do not sink lower.
Prop.4. A solid lighter
than a fluid will, if immersed in it, not be completelysubmerged, but part of
it will project above the surface.
Prop.5. Any solid
lighter than a fluid will, if placed in the fluid, be so far immersed that the
weight of the solid will be equal to the weight of the fluid displaced.
Prop.6. If a solid
lighter than a fluid be forciblyimmersed in it,
then the solid will be
driven upwards by a force equal to the difference between its weight and the
weight of the fluid displaced.
Prop.7. A solid heavier
than a fluid will, if placed in it, descend to the bottom of the fluid,
and the solid will, when
weighted in the fluid, be lighter than its true weight by the weight of the
fluid displaced.
[This prop. may, I
think, safely be regarded as decisive of the question how ARchimedes determined
the prop.s of gold and silver contained in the famous crown. the prop. suggests
in fact the following method.]
Prop.8. If a solid in
the form of a segment of a sphere, and of a substance lighter than a fluid, be
immersed in it so that its base does not touch the surface,
then the solid will rest
in such a position that its axis is perpendicular to the surface;
and, if the solid be
forced into such a position that its base touches the fluid on one side and be
then set free,
then it will not remain
in that position but will return to the symmetrical position.
[The proof of this prop.
is wanting in the latin version ofTarTaglia. Commandinus supplied a proof of
his own in his edition.]
Prop.9. If a solid in
the form of a segment of a sphere, and of a substance lighter than a fluid, be
immersed in it so that its base is completely below the surface,
then the solid will rest
in such a position that its axis is perpendicular to the surface.
[The proof of this prop.
has only survived in a mutilated form. It deals moreover with only one case out
of three which are distinguished at the beginning, viz. that in which the
segment is greater than a hemisphere, while figures only are given for the
cases where the segment is equal to, or less than, a hemisphere.]
On floating bodies.
BookII.
Prop.1. If a solid
lighter than a fluid be at rest in it,
then the weight of the
solid will be to that of the same volume of the fluid as the immersed portion
of the solid is to the whole.
Prop.2. If a right
segment of paraboloid of revolution whose axis is not greater than (3/4)p,
where p is the principal parameter of the generating parabola, and whose
specific gravity is less than that of a fluid, be placed in the fluid with is
axis inclined to the vertical at any angle,
but so that the base of
the segment does not touch the surface of the fluid,
then the segment of the
paraboloid will not remain in that position but will return to the position in
which its axis is vertical.
Prop.3. If a right
segment of a paraboloid of revolution whose axis is not greater than (3/4)p,
where p is the parameter, and whose specific gravity is less than that of a
fluid, be placed in the fluid with its axis inclined at any angle to the
vertical,
but so that is base is
entirely submerged,
then the solid will not
remain in that position but will return to the position in which the axis is
vertical.
Prop.4. Given a right
segment of a paraboloid of revolution whose axis AN is greater than (3/4)p,
where p is the parameter, and whose specific gravity is less than that of a
fluid but bears to it a ratio not less than (AN-(3/4)p)-square:A*N-square,
if the segment of the
paraboloid be placed in the fluid with its axis at any inclination to the
vertical,
but so that its base
does not touch the surface of the fluid,
then it will not remain
in that position but will return to the position in which its axis is vertical.
Prop.5. Givena right
segment of a paraboloid of revolution such that its axis AN is greater than
(3/4)p, where p is the parameter, and its specific gravity is less than that of
a fluid but in a ratio to it not greater than the ratio {A*N-square - (AN -
(3/4)p)-square}:A*N-square,
if the segment be placed
in the fluid with its axis inclined at any angle to the vertical,
but so that its base is
completely submerged,
then it will not remain
in that position but will return to the position in which AN is vertical.
Prop.6. If a right
segment of a paraboloid lighter than a fluid be such that its axis AM is
greater than (3/4)p, but AM:(1/2)p < 15:4,
and if the segment be
placed in the fluid with its axis so inclined to the vertical that its base
touches the fluid,
then it will never
remain in such a position that the base touches the surface in one point only.
Prop.7. Given a right
segment of a praboloid of revolution lighter than a fluid
and such that its axis
AM is greater than (3/4)p, but AM:(1/2)p < 15:4,
if the segment be placed
in the fluid
so that its base is
entirely submerged,
then it will never rest
in such a position that the base touches the surface of the fluid at one point
only.
Prop.8. Given a solid in
the form of a right segment of a paraboloid of revolution whose axis AM is
greater than (3/4)p,
but such that AM:(1/2)P
< 15:4, and whose gravity bears to that of a fluid a ratio less than
(AM-(3/4)p)-square : A*M-square,
then, if the solid be
placed in the fluid so that its base does not touch the fluid and its axis is
inclined at an angle to the vertical,
then the solid will not
return to the position in which its axis is vertical and will not remain in any
position except that in which its axis makes with the surface of the fluid a
certain angle to be described.
Prop.9. Given a solid in
the form of a right segment of a paraboloid of revolution whose axis AM is
greater than (3/4)p, but such that AM:(1/2)p < 15:4, and whose specific
travity bears to that of a fluid a ratio greater than
{A*M-square-(AM-(3/4)p)-square}:A*M-square,
then, if the solid be
placed in the fluid with its axis inclined at an angle to the vertical but so
that its base is entirely below the surface,
then the solid will not
return to the position in which its axis is vertical and will not remain in any
position except that in which its axis makes with the surface of the fluid an
angle equal to that described in the last prop.
Prop.10. Given a solid
in the form fo a right segment of a paraboloid of revolution in which the axis
AM is of a length such that AM:(1/2)p > 15:4,
and supposing the solid
placed in a fluid of greater specific gravity so that its base is entirely
above the surface of the fluid,
to investigate the
positions of rest.
Preliminary.
(Enunciation.)
(Proof.)
Book of lemmas.
Prop.1. If two circles
touch at A,
and if BD, EF be
parallel diameters in them,
then ADF is a
straightline.
Prop.2. Let AB be the
diameter of a semicircle,
and let the tangents to
it at B and at any other point D on it meet in T.
If now DE be drawn
perpendicular to AB,
and if AT, DE meet in F,
then DF = FE.
Prop.3. Let P be any
point on a segment of a circle whose base is AB,
and let PN be
perpendicular to AB.
TAke D on AB so that AN
= ND.
If now pQ be an arc
equal to the arc PA,
and BQ be joined,
then BQ, BD shall be
equal.
Prop.4. If AB be the
diameter of a semicircle and N any point on AB,
and if semicircles be
described within the first semicircle and having AN, BN as diameters
respectively,
then the figure included
between the circumferences of the three semicircles is "what Archimedes
called an **";
and its area is equal to
the circle on PN as diameter, where PN is perpendicular to AB and meets the
original semicircle in P.
Prop.5. Let AB be the
diameter of a semicircle, C any point on AB, and CD perpendicular to it,
and let semicircles be
described within the first semicircle and having AC, CB as diameters.
Then, if two circles be
drawn touching CD on different sides and each touching two of the semicircles,
then the circls so drawn
will be equal.
[As pointed out by an
arabian scholiat Al-Kau-Hi, this prop. may be stated moregenerally. If, instead
of one point on C on AB, we have two points C, D, and semicircles be described
on AC, BD as diameters,
and if, instead of the
perpendicular to AB through C, we take the radical axis of the twosemicircles,
then the circles
described on different sides of the radical axis and each touching it as well
as two of the semicircles are equal.
The proof is similar and
presents no difficulty.]
Prop.6. Let AB, the
diameter of a semicircle, be divided at C
so that AC = (3/2)CB [or
in any ratio].
Describe semicircles
within the first semicircle and on Ac, CB as diameters,
and suppose a circle
drawn touching all three semicircles.
If GH be the diameter of
this circle,
to find the relation betwen
GH and AB.
Prop.7. If circles be
circumscribed about and inscribed in a square,
then the circumscribed
circle is double of the inscribed circle.
Prop.8. If AB be any
chord of a circle whose centre is O,
and if AB be produced to
C
so that BC is equal to
the radius;
if further CO meet the
circle in D and be produced to meet the circle a second time in E,
then the arc AE will be
equal to threetimes the arc BD.
Prop.9. If in a circle
two chords AB, CD which do not pass through the centre intersect at right
angles,
then (arc AD)+(arc CB) =
(arc AC)+(arc DB).
Prop.10. Suppose that
TA, TB are two tangents to a circle,
while TC cuts it.
Let BD be the chord
through B parallel to TC,
and let AD meet TC in E.
Then, if EG be drawn
perpendicular to BD,
it will bisect it in H.
Prop.11. If two chords
AB, CD in a circle intersect at right angles in a point O, not being the
centre,
then A*O-square +
B*O-square + C*O-square + D*O-square = (diamter)-square.
Prop.12. If AB be the
diameter of a semicircle,
and TP, TQ the tangents
to it from any point T,
and if AQ, BP be joined
meeting in R,
then TR is perpendicular
to AB.
Prop.13. If a diameter
AB of a circle meet any chord CD, not a diameter, in E,
and if AM, BN be drawn
perpendicular to CD,
then CN = DM.
Prop.14. Let ACB be a
semicircle on AB as diameter,
and let AD, BE be equal
lengths measured along AB from A, B respectively.
On AD, BE as diameters
describe semicircles on the side towards C,
and on DE as diameter a
semicircle on the opposite side.
Let the perpendicular to
AB through O, the centre of the first semicircle, meet the opposite semicircles
in C, F respectively.
Then shall the area of
the figure bounded by the circumference of all the semicircles ("which
archimedes calls 'Salinon;") be equal to the area of the circle on CF as
diameter.
Prop.15. Let AB be the
diameter of a circle, AC a side of an inscribed regular polygon, D the middle
point of the arc AC.
Join AC and produce it
to meet BA produced in E;
join AC, DB meeting in
F,
and draw FM
perpendicular to AB.
Then EM = (radius of
circle).
The Cattleproblem.
It is required to find
the number of bulls and cows of each of fourcolours, or to find eight unknown
qualities. The first part of the problem connects the unknowns by seven simple
equations; and the second part adds two more conditions to which the unknowns
must be subject.
Wunn's problem.
The Method ofArchimedes
traeting of mechanical problems.
First then I will set
out the very first theorem which became known to me by means ofMechanics,
namely that, Any segment of a section of a rightangled cone (i.e. a parabola)
is fourthires of the triangle which has the same base and equal height,
and after this I will
give each of the other theorems investigated by the same method. Then, at the
end of the book, I will give the geometrical [proofs of the prop.s]...
[I premise the following
prop.s which I shall use int he course of the work.]
1. If from [one
magnitude another magnitude be subtracted which has not the same centre of
gravity,
then the centre of
gravity of the remainder is found by] producing [the straightline joining the
centres of gravity of the whole magnitude and of the subtracted part in the
direction of the centre of gravity of the whole] and cutting off from it
alength which has to the distance between the said centres of gravity the ratio
which the weight of the subtracted magnitude has to the weight of the
remainder. [OnTheQuilibriumOfPlanes, I.8.]
2. If the centres of
gravity of any number of magnitudes whatever be on the same straightline,
then the centre of
gravity of the magnitude made up of all of them will be on the same
straightline. [Ibid. I.5.]
3. The centre of gravity
of any straightline is the point of bisection of straightline. [Ibid. I.4.]
4. The centre of gravity
of any triangle is the point in which the straightlines drawn from the angular
points of the triangle to the middle points of the (opposite) sides cut one
another. [Ibid. I.13,14.]
5. The centre of gravity
of any parallelogram is the point in which the diagonals meet. [I.10.]
6. The centre of gravity
of a circle is the point which is also the centre [of the circle].
7. The centre of gravity
of any cylinder is the point of bisection of the axis.
8. The centre of gravity
of any cone is [the point which divides its axis so that] the portion [adjacent
to the vertex is] triple [of the portion adjacent to the base].
[All these prop.s have
already been] proved. [The problem of finding the centre of gravity of a cone
is notsolved in any extant work ofArchimedes. It may have been solved either in
a separate treatise, such as the **, which is lost, or perhaps in a larger
mechanical work of which the extant books OnTheQuilibriumOfplaned formed only a
part.
[Besides these I require
also the following prop., which is easily proved:
If in two series of
magnitudes those of the first series are, in order, proportional to those of
the second series and further] the magnitudes [of the first series], either all
or some of them, are in any ratio whatever [to those of a third series],
and if the magnitudes of
the second series are in the same ratio to the corresponding magnitudes [of a
fourth series],
then the sum of the
magnitudes of the first series has to the sum of the selected magnitudes of the
third series the same ratio which the sum of the magnitudes of the second
series has to the sum of the (corresponding) selected magnitudes of the fourth
series. [OnConoidsAndSpheroids, Prop.1.]"
Prop.1. Let ABC be a segment of a parabola bounded by
the straightline AC and the parabola ABC,
and let D be the middle
point of AC.
Draw the straightline
DBE parallel to the axis of the parabola and join AB, BD.
Then shall the segment
ABC be 4/3 of the triangle ABC.
Prop.2. We can
investigate by the same method the prop.s that
(1) Any sphere is (in
respect of solid content) four times the cone with base equal to a great circle
of the sphere and height equal to its radius; and
(2) the cylinder with
base equal to a great circle of the sphere and height equal to the diameter is
1*(1/2) times the sphere.
Prop.3. By this method
we can also investigate the theorem that
A cylinder with base
equal to the greatest circle in a spheroid and height equal to the axis of the
spheroid
is 1*(1/2) times the
spheroid;
and, when this is
established, it is plain that
If any spheroid be cut
by a plane through the centre and at right angles to the axis,
then the half of the
spheroid is double of the cone which has the same base and the same axis as the
segment (i.e. the half of the spheroid).
Prop.4. Any segment of a
rightangled conoid (i.e. a paraboloid of revolution) cut off by a plane at rightangles to the axis
is 1*(1/2) times the cone which has the same base and the same axis as the
segment.
Prop.5. The centre of
gravity of a segment of a rightangled conoid (i.e. a paraboloid of revolution)
cut off by a plane at rightangles to the axis
is on the straightline
which is the axis of the segment,
and divides the said
straightline in wuch a way that the portion of it adjacent to the vertex is
double of the remaining portion.
Prop.6. The centre of
gravity of any hemisphere [is on the straightline which] is its axis,
and divides the said
straightline in such a way that the portion of it adjacent to the surface of
the hemisphere has to the remaining portion the ratio which 5 has to 3.
Prop.7. We can also
investigate by the same method the thoerem that
[Any segment of a sphere
has] to a cone [with the same base and height the ratio which the sum of the
radius of the sphere and the height of the complementary segment has to the
height of the complementary segment.]
[There is a lacuna here;
but all that is missing is the construction, and the construction is easily
understood by means of the figure. BAD is of course the segment of the sphere
the volume of which is to be compared with the volume of a cone with the same
base and height.]
Prop.8. [The nunciation,
the settingout, and a few words of the construction are missing.
The enunciation,
however, can be supplied from that of Prop.9, with which it must be identical
except that it cannot refer to "any segment", and the presumption
therefore is that the prop. was enunciated with reference to one kind of
segment only, i.e. either a segment greater than a hemisphere of a segment less
than a hemisphere.
Heiberg's figure
corresponds to the case of a segment greater than a hemisphere. The segment
investigated is of course the segment BAD. The settingout and construction are
selfevident from the figure.]
Prop.9. In the same way
we can investigate the theorem that
The centre of gravity of
any segment of a sphere is on the straightline which is the axis of the
segment, and divides this straightline in such a way that the part of it
adjacent to the vertex of the segment has to the remaining part the ratio which
the sum of the axis of the segment and fourtimes the axis of the complementary
segment has to the sum of the axis of the segment and double the axis of the
complementary segment.
[As this theorem relates
to "any segment" but states the same result as that proved in the
preceding prop., it follows that Prop.8. must have related to one kind of segment,
either a segment greater than a semicircle (as in Heiberg's figure of Prop.8)
or a segment less than semicircle; and the present prop. completed the proof
for both kinds of segments. It would only require a slight change in the
figure, in any case.]
Prop.10. By this method
too we can investigate the theorem that
[A segment of an
obtuseangled conoid (i.e. a hyperboloid of revolution) has to the cone which
has] the same base [as the segment and equal height the same ratio as the sum
of the axis of the segment and three times] the "annex to the axis"
(i.e. half the transverse axis of the hyperbolic section through the axis of
the hyperboloid or, in other words, the distance between the vertex of the
segment and the vertex of the enveloping cone) has to the sum of the axis of
the segment and double of the "annex". [The text has
"triple" (**) in the last line instead of "double". As
there is a considerable lacuna before the last few lines, a theorem about the
centre of gravity of a segment of a hyperboloid of revolution may have fallen
out.] [this is the theorem proved inOnConoidsAndSpheroids.25.], "and also
many other theorems, which as the method has been made clear by means of the
foregoing examples, I will omit, in order that I may now proceed to compass the
proofs of the theorems mentioned above."
Prop.11. If in a right
prism with square bases a cylinder be inscribed having its bases in opposite
square faces and touching with is surface the remaining four parallelogrammic
faces,
and if through the centre
of the circle which is the base of the cylinder and one side of the opposite
square face a plane be drawn,
then the figure cut off
by the plane so drawn is onesixthpart of the whole prism.
"This can be
investigated by the method, and, when it is set out, I will go back to the
proof of it by geometrical considerations."
[The investigations by
the mechanical method is contained in the two props., 11,12. Prop.13 gives
another solution which, although it contains no mechanics, is still of the character
which Archimedes regards as inconclusive, since it assumes that the solid is
actually made up of parallel plane sections and that an auxiliary parabola is
actually made up of parallel straightlines in it. Prop.14 added the conclusive
geometrical proof.]
Prop.12.
[The rest of the proof
is missing, but, as Zeuthen says, the result obtained and the method of arrving
at it are plainlyindicated by the above.
Archimedes wishes to
prove that the half cylinder PQR, in the place where it is, balances the prism
GHM, in the place where it is, about H as fixed point.]
Prop.13. Let there be a
right prism with square bases, one of which is ABCD;
in the prism let a
cylinder be inscribed, the base of which is the circle EFGH touching the sides
of the square ABCD in E, F, G, H.
[the above prop. and the
next are peculiarly interesting for the fact that the parabola is an auxiliary
curve introduced for the sole purpose of analyticallyreducing the required
cubature to the known quadrature of the parabola.]
Prop.14. [There are
large gaps in the exposition of this geometrical proof, but the way in which
the methodofexhaustion was applied, and the parallelism between this and other
applications of it, are clear. The first fragment shows that solid figures made
up of prisms were circumscribed and inscribed to the portion of the cylinder.
The parallel triangular faces of these prisms were perpendicular to GE in the
figure of Prop.13; they divided GE into equal portions of the requisite
smallness; each section of the portion of the cylinder by such a plane was a
triangular face common to an inscribed and a circumscribed right prism. The
planes also produced prisms in the prism cut off by the same oblique plane as
cuts off the portion of the cylinder and standing on GD as base.
The number of parts into
which the parallel planes divided Ge was made great enough to secure that the
circumscribed figure exceeded the inscribed figure by less than a small
assigned magnitude.
The second part of the
proof began with the assumption that the portion of the cylinder is > (2/3)
of the prism cut off; and this was proved to be impossible, by means of the use
of the auxiliary parabola and the prop.
MN:ML =
M*N-square:M*O-square, which are employed inProp.13.
We may supply the
missing proof as follows.
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