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Universal Parabolic Constant


LatusRectum

Just as the ratio of the arc length of a semicircle to its radius is always pi, the ratio P of the arc length of the parabolic segment formed by the latus rectum of any parabola to its semilatus rectum (and focal parameter) is a universal constant

P=sqrt(2)+ln(1+sqrt(2))
(1)
=sqrt(2)+sinh^(-1)1
(2)
=sqrt(2)+cosh^(-1)(sqrt(2))
(3)
=2.2955871...
(4)

(OEIS A103710). This can be seen from the equation of the arc length of a parabolic segment

 s=1/2sqrt(x^2+4h^2)+(x^2)/(4h)ln((2h+sqrt(x^2+4h^2))/x)
(5)

by taking s/a and plugging in h=a and x=2a.

The other conic sections, namely the ellipse and hyperbola, do not have such universal constants because the analogous ratios for them depend on their eccentricities. In other words, all circles are similar and all parabolas are similar, but the same is not true for ellipses or hyperbolas (Ogilvy 1990, p. 84).

The area of the surface generated by revolving x=e^y for y in (-infty,0] about the y-axis is given by

A=piP
(6)
=7.211799724...
(7)

(Love 1950, p. 288; OEIS A103713) and the area of the surface generated by revolving y=cosx for x in [-pi/2,pi/2] about the x-axis is

A=2piP
(8)
=14.4235994...
(9)

(Love 1950, p. 288; OEIS A103714).

The expected distance from a randomly selected point in the unit square to its center (square point picking) is

d^_=1/6P
(10)
=0.3825978582...
(11)

(Finch 2003, p. 479; OEIS A103712).

P is an irrational number. It is also a transcendental number, as can be seen as follows. If P were algebraic, then P-sqrt(2)=ln(1+sqrt(2)) would also be algebraic. But then, by the Lindemann-Weierstrass theorem, e^(ln(1+sqrt(2)))=1+sqrt(2) would be transcendental, which is a contradiction.

The mean cylindrical radius of a hemicube constructed from unit cube is equal to 8P/3.


See also

Focal Parameter, Latus Rectum, Lindemann-Weierstrass Theorem, Parabola, Parabolic Segment, Semilatus Rectum

This entry contributed by Sylvester Reese

This entry contributed by Jonathan Sondow

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References

Finch, S. R. Mathematical Constants. Cambridge, England: Cambridge University Press, p. 479, 2003.Love, C. E. Differential and Integral Calculus, 4th ed. New York: Macmillan, 1950.Ogilvy, C. S. Excursions in Geometry. New York: Dover, 1990.Sloane, N. J. A. Sequences A103710, A103711, A103712, A103713, and A103714 in "The On-Line Encyclopedia of Integer Sequences."

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Universal Parabolic Constant

Cite this as:

Reese, Sylvester and Sondow, Jonathan. "Universal Parabolic Constant." From MathWorld--A Wolfram Web Resource, created by Eric W. Weisstein. https://mathworld.wolfram.com/UniversalParabolicConstant.html

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