Trifolium curve

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The trifolium curve (also three-leafed clover curve, 3-petaled rose curve, and pâquerette^{nl:madeliefje} de mélibée) is a type of quartic plane curve. The name comes from the Latin terms for 3-leaved, defining itself as a folium shape with 3 equally sized leaves.^[1]

It is described as

x^{4}+2x^{2}y^{2}+y^{4}-x^{3}+3xy^{2}=0.\,

By solving for y by substituting y² and its square, the curve can be described by the following function(s):

y=\pm {\sqrt {\frac {-2x^{2}-3x\pm {\sqrt {16x^{3}+9x^{2}}}}{2}}},\,\,y^{2}={\frac {-x(2x+3)\pm x{\sqrt {16x+9}}}{2}}

Due to the separate ± symbols, it is possible to solve for 4 different answers at a given (positive) x-coordinate; 2 y-values per negative x-coordinate. One sees 2 resp. 1 pair(s) of solutions, mirroring points on the curve.

It has a polar equation of

$r=-a\cos(3\theta )$

and a Cartesian equation of

$(x^{2}+y^{2})[y^{2}+x(x+a)]=4a\cdot xy^{2}.$

The area of the trifolium shape is defined by the following equation:

$A={\frac {1}{2}}\int _{0}^{\pi }cos^{2}(3\theta )d\theta \,$ ^[2] $=\pi a^{2}/4$

And it has a length of

$6a\int _{0}^{\tfrac {\pi }{2}}{\sqrt {1-{\frac {8}{9}}sin^{2}t}}*dt\thickapprox 6,7a$ ^[3]

The trifolium was described by J.D. Lawrence as a form of Kepler's folium when

$b\in (0,4,a)$ ^[4]

A more present definition is when ${\textstyle a=b.}$

The trifolium was described by Dana-Picard as

$(x^{2}+y^{2})^{3}-x(x^{2}-3y^{2})=0$

He defines the trifolium as having three leaves and having a triple point at the origin made up of 4 arcs. The trifolium is a sextic curve meaning that any line through the origin will have it pass through the curve again and through its complex conjugate twice.^[5]

The trifolium is a type of rose curve when $k=3$ ^[6]

Gaston Albert Gohierre de Longchamps was the first to study the trifolium, and it was given the name Torpille because of its resemblance to fish.^[7]

The trifolium was later studied and given its name by Henry Cundy and Arthur Rollett.^[8]

References

^ See also trefoil arch.
^ Barile, Margherita; Weisstein, Eric. "Trifolium Curve Equations". mathworld.wolfram.com.
^ Ferreol, Robert (2017). "Regular Trifolium". mathcurve.com.
^ Lawrence, J. Dennis (1972). A catalog of special plane curves. New York: Dover Publications. ISBN 978-0486602882. Retrieved 19 July 2024.
^ Dana-Picard, Thierry (June 2019). "Automated Study of a Regular Trifolium". Mathematics in Computer Science. 13 (1–2): 57–67. doi:10.1007/s11786-018-0351-7. Retrieved 19 July 2024.
^ Lee, Xah. "Rose Curve Information". xahlee.info.
^ de Longchamps, Gaston (1884). Cours de Mathématiques Spéciales: Geométrie Analytique à Deux Dimensions (in French). France: Nabu Press. ISBN 9781145247291. {{cite book}}: ISBN / Date incompatibility (help)
^ Cundy, Henry Martyn; Rollett, Arthur P. (2007). Mathematical models (3., repr ed.). St. Albans: Tarquin Publications. ISBN 978-0906212202.

[1] See also trefoil arch.

[2] Barile, Margherita; Weisstein, Eric. "Trifolium Curve Equations". mathworld.wolfram.com.

[3] Ferreol, Robert (2017). "Regular Trifolium". mathcurve.com.

[4] Lawrence, J. Dennis (1972). A catalog of special plane curves. New York: Dover Publications. ISBN 978-0486602882. Retrieved 19 July 2024.

[5] Dana-Picard, Thierry (June 2019). "Automated Study of a Regular Trifolium". Mathematics in Computer Science. 13 (1–2): 57–67. doi:10.1007/s11786-018-0351-7. Retrieved 19 July 2024.

[6] Lee, Xah. "Rose Curve Information". xahlee.info.

[7] Longchamps, Gaston (1884). Cours de Mathématiques Spéciales: Geométrie Analytique à Deux Dimensions (in French). France: Nabu Press. ISBN 9781145247291. {{cite book}}: ISBN / Date incompatibility (help)

[8] Cundy, Henry Martyn; Rollett, Arthur P. (2007). Mathematical models (3., repr ed.). St. Albans: Tarquin Publications. ISBN 978-0906212202.

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See also

References