Nothing Special   »   [go: up one dir, main page]

The quadratrix or trisectrix of Hippias (also quadratrix of Dinostratus) is a curve which is created by a uniform motion. It is one of the oldest examples for a kinematic curve (a curve created through motion). Its discovery is attributed to the Greek sophist Hippias of Elis, who used it around 420 BC in an attempt to solve the angle trisection problem (hence trisectrix). Later around 350 BC Dinostratus used it in an attempt to solve the problem of squaring the circle (hence quadratrix).

Quadratrix (red); snapshot of E and F having completed 60% of their motions

Definition

edit
 
Quadratrix as a plane curve for side length  
 
Quadratrix as a function for  

Consider a square  , and an inscribed quarter circle arc centered at   with radius equal to the side of the square. Let   be a point that travels with a constant angular velocity along the arc from   to  , and let   be a point that travels simultaneously with a constant velocity from   to   along line segment  , so that   and   start at the same time at   and arrive at the same time at   and  . Then the quadratrix is defined as the locus of the intersection of line segment   with the parallel line to   through  .[1][2]

If one places such a square   with side length   in a (Cartesian) coordinate system with the side   on the  -axis and with vertex   at the origin, then the quadratix is described by a planar curve   with   This description can also be used to give an analytical rather than a geometric definition of the quadratrix and to extend it beyond the   interval. It does however remain undefined at the singularities of   except for the case of   where the singularity is removable due to   and hence yields a continuous planar curve on the interval  .[3][4]

To describe the quadratrix as simple function rather than planar curve, it is advantageous to swap the  -axis and the  -axis, that is to place the side   on the  -axis rather than on the  -axis. Then the quadratrix forms the graph of the function[5][6]  

Angle trisection

edit
 
Quadratrix compass
 
Angle trisection

The trisection of an arbitrary angle using only ruler and compasses is impossible. However, if the quadratrix is allowed as an additional tool, it is possible to divide an arbitrary angle into   equal segments and hence a trisection ( ) becomes possible. In practical terms the quadratrix can be drawn with the help of a template or a quadratrix compass (see drawing).[1][2]

Since, by the definition of the quadratrix, the traversed angle is proportional to the traversed segment of the associated squares' side dividing that segment on the side into   equal parts yields a partition of the associated angle as well. Dividing the line segment into   equal parts with ruler and compass is possible due to the intercept theorem.

For a given angle   (at most 90°) construct a square   over its leg  . The other leg of the angle intersects the quadratrix of the square in a point   and the parallel line to the leg   through   intersects the side   of the square in  . Now the segment   corresponds to the angle   and due to the definition of the quadratrix any division of the segment   into   equal segments yields a corresponding division of the angle   into   equal angles. To divide the segment   into   equal segments, draw any ray starting at   with   equal segments (of arbitrary length) on it. Connect the endpoint   of the last segment to   and draw lines parallel to   through all the endpoints of the remaining   segments on  . These parallel lines divide the segment   into   equal segments. Now draw parallel lines to   through the endpoints of those segments on  , intersecting the trisectrix. Connecting their points of intersection to   yields a partition of angle   into   equal angles.[5]

Since not all points of the trisectrix can be constructed with circle and compass alone, it is really required as an additional tool next to compass and circle. However it is possible to construct a dense subset of the trisectrix by circle and compass, so while one cannot assure an exact division of an angle into   parts without a given trisectrix, one can construct an arbitrarily close approximation by circle and compass alone.[2][3]

Squaring of the circle

edit
 
Squaring of a quarter circle with radius 1

Squaring the circle with ruler and compass alone is impossible. However, if one allows the quadratrix of Hippias as an additional construction tool, the squaring of the circle becomes possible due to Dinostratus' theorem. It lets one turn a quarter circle into square of the same area, hence a square with twice the side length has the same area as the full circle.

According to Dinostratus' theorem the quadratrix divides one of the sides of the associated square in a ratio of  .[1] For a given quarter circle with radius r one constructs the associated square ABCD with side length r. The quadratrix intersect the side AB in J with  . Now one constructs a line segment JK of length r being perpendicular to AB. Then the line through A and K intersects the extension of the side BC in L and from the intercept theorem follows  . Extending AB to the right by a new line segment   yields the rectangle BLNO with sides BL and BO the area of which matches the area of the quarter circle. This rectangle can be transformed into a square of the same area with the help of Euclid's geometric mean theorem. One extends the side ON by a line segment   and draws a half circle to right of NQ, which has NQ as its diameter. The extension of BO meets the half circle in R and due to Thales' theorem the line segment OR is the altitude of the right-angled triangle QNR. Hence the geometric mean theorem can be applied, which means that OR forms the side of a square OUSR with the same area as the rectangle BLNO and hence as the quarter circle.[7]

Note that the point J, where the quadratrix meets the side AB of the associated square, is one of the points of the quadratrix that cannot be constructed with ruler and compass alone and not even with the help of the quadratrix compass based on the original geometric definition (see drawing). This is due to the fact that the two uniformly moving lines coincide and hence there exists no unique intersection point. However relying on the generalized definition of the quadratrix as a function or planar curve allows for J being a point on the quadratrix.[8][9]

Historical sources

edit

The quadratrix is mentioned in the works of Proclus (412–485), Pappus of Alexandria (3rd and 4th centuries) and Iamblichus (c. 240 – c. 325). Proclus names Hippias as the inventor of a curve called quadratrix and describes somewhere else how Hippias has applied the curve on the trisection problem. Pappus only mentions how a curve named quadratrix was used by Dinostratus, Nicomedes and others to square the circle. He neither mentions Hippias nor attributes the invention of the quadratrix to a particular person. Iamblichus just writes in a single line, that a curve called a quadratrix was used by Nicomedes to square the circle.[10][11][12]

From Proclus' name for the curve, it is conceivable that Hippias himself used it for squaring the circle or some other curvilinear figure. However, most historians of mathematics assume that Hippias invented the curve, but used it only for the trisection of angles. According to this theory, its use for squaring the circle only occurred decades later and was due to mathematicians like Dinostratus and Nicomedes. This interpretation of the historical sources goes back to the German mathematician and historian Moritz Cantor.[11][12]

See also

edit

References

edit
  1. ^ a b c Hischer, Horst (2000), "Klassische Probleme der Antike – Beispiele zur "Historischen Verankerung"" (PDF), in Blankenagel, Jürgen; Spiegel, Wolfgang (eds.), Mathematikdidaktik aus Begeisterung für die Mathematik – Festschrift für Harald Scheid, Stuttgart/Düsseldorf/Leipzig: Klett, pp. 97–118
  2. ^ a b c Henn, Hans-Wolfgang (2003), "Die Quadratur des Kreises", Elementare Geometrie und Algebra, Verlag Vieweg+Teubner, pp. 45–48
  3. ^ a b Jahnke, Hans Niels (2003), A History of Analysis, American Mathematical Society, pp. 30–31, ISBN 0821826239; excerpt, p. 30, at Google Books
  4. ^ Weisstein, Eric W., "Quadratrix of Hippias", MathWorld
  5. ^ a b Dudley, Underwood (1994), The Trisectors, Cambridge University Press, pp. 6–8, ISBN 0883855143; excerpt, p. 6, at Google Books
  6. ^ O'Connor, John J.; Robertson, Edmund F., "Quadratrix of Hippias", MacTutor History of Mathematics Archive, University of St Andrews, p. cur
  7. ^ Holme, Audun (2010), Geometry: Our Cultural Heritage, Springer, pp. 114–116, ISBN 9783642144400
  8. ^ Delahaye, Jean-Paul (1999),   – Die Story, Springer, p. 71, ISBN 3764360569
  9. ^ O'Connor, John J.; Robertson, Edmund F., "Dinostratus", MacTutor History of Mathematics Archive, University of St Andrews, p. bio
  10. ^ van der Waerden, Bartel Leendert (1961), Science Awakening, Oxford University Press, p. 146
  11. ^ a b Gow, James (2010), A Short History of Greek Mathematics, Cambridge University Press, pp. 162–164, ISBN 9781108009034
  12. ^ a b Heath, Thomas Little (1921), A History of Greek Mathematics, Volume 1: From Thales to Euclid, Clarendon Press, pp. 182, 225–230

Further reading

edit
edit