Cardioid
The curve given by the polar equation
sometimes also written
where π b=a/2
.
The cardioid has Cartesian equation
and the parametric equations
The cardioid is a degenerate case of the limaΓ§on. It is also a 1-cusped epicycloid (with π r=r
) and is the catacaustic
formed by rays originating at a point on the circumference of a circle
and reflected by the circle.
The cardioid has a cusp at the origin.
The name cardioid was first used by de Castillon in Philosophical Transactions of the Royal Society in 1741. Its arc length was
found by la Hire in 1708. There are exactly three parallel tangents to the cardioid with any given gradient. Also,
the tangents at the ends of any chord
through the cusp point are at right
angles. The length of any chord through the cusp
point is π 2a
.
The cardioid may also be generated as follows. Draw a circle π C
and fix a point π A
on it. Now draw a set of circles
centered on the circumference of π C
and passing through π A
. The envelope of these circles
is then a cardioid (Pedoe 1995). Let the circle π C
be centered at the origin and have radius
1, and let the fixed point be π A=(1,0)
. Then the radius of a circle centered at an angle π theta
from (1, 0) is
| π r^2 | π = | π (0-costheta)^2+(1-sintheta)^2 |
(6)
|
| π Image | π = | π cos^2theta+1-2sintheta+sin^2theta |
(7)
|
| π Image | π = | π 2(1-sintheta). |
(8)
|
If the fixed point π A
is not on the circle, then the resulting envelope is
a limaçon instead of a cardioid.
The arc length, curvature, and tangential angle are
See also
Cardioid Coordinates, Circle, Cissoid, Coin Paradox, Conchoid, Heart Curve, Lemniscate, Limaçon, Logarithmic Spiral, Mandelbrot Set, NephroidExplore with Wolfram|Alpha
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References
Archibald, R. C. "The Cardioide and Some of Its Related Curves." Inaugural dissertation der Mathematischen und Naturwissenschaftlichen FacultΓ€t der Kaiser-Wilhelms-UniversitΓ€t, Strassburg zur Erlangung der DoctorwΓΌrde. Strassburg, France: J. Singer, 1900.Beyer, W. H. CRC Standard Mathematical Tables, 28th ed. Boca Raton, FL: CRC Press, p. 214, 1987.Gray, A. "Cardioids." Β§3.3 in Modern Differential Geometry of Curves and Surfaces with Mathematica, 2nd ed. Boca Raton, FL: CRC Press, pp. 54-55, 1997.Kabai, S. Mathematical Graphics I: Lessons in Computer Graphics Using Mathematica. PΓΌspΓΆkladΓ‘ny, Hungary: Uniconstant, p. 123, 2002.Lawrence, J. D. A Catalog of Special Plane Curves. New York: Dover, pp. 118-121, 1972.Lockwood, E. H. "The Cardioid." Ch. 4 in A Book of Curves. Cambridge, England: Cambridge University Press, pp. 34-43, 1967.MacTutor History of Mathematics Archive. "Cardioid." http://www-groups.dcs.st-and.ac.uk/~history/Curves/Cardioid.html.Pedoe, D. Circles: A Mathematical View, rev. ed. Washington, DC: Math. Assoc. Amer., pp. xxvi-xxvii, 1995.Smith, D. E. History of Mathematics, Vol. 2: Special Topics of Elementary Mathematics. New York: Dover, p. 326, 1958.Wells, D. The Penguin Dictionary of Curious and Interesting Geometry. London: Penguin, pp. 24-25, 1991.Yates, R. C. "The Cardioid." Math. Teacher 52, 10-14, 1959.Yates, R. C. "Cardioid." A Handbook on Curves and Their Properties. Ann Arbor, MI: J. W. Edwards, pp. 4-7, 1952.Referenced on Wolfram|Alpha
CardioidCite this as:
Weisstein, Eric W. "Cardioid." From MathWorld--A Wolfram Resource. https://mathworld.wolfram.com/Cardioid.html