Bicorn

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In geometry, the bicorn, also known as a cocked hat curve due to its resemblance to a bicorne, is a rational quartic curve defined by the equation^[1] $${\displaystyle y^2(a^2-x^2)={(x^2+2ay-a^2)}^2.}$$ It has two cusps and is symmetric about the y-axis.^[2]

In 1864, James Joseph Sylvester studied the curve $${\displaystyle y^4-x{y}^3-8x{y}^2+36x^{2}y+16x^2-27x^3=0}$$ in connection with the classification of quintic equations; he named the curve a bicorn because it has two cusps. This curve was further studied by Arthur Cayley in 1867.^[3]

The bicorn is a plane algebraic curve of degree four and genus zero. It has two cusp singularities in the real plane, and a double point in the complex projective plane at ${\displaystyle (x=0,z=0)}$. If we move ${\displaystyle x=0}$ and ${\displaystyle z=0}$ to the origin and perform an imaginary rotation on ${\displaystyle x}$ by substituting ${\displaystyle ix/z}$ for ${\displaystyle x}$ and ${\displaystyle 1/z}$ for ${\displaystyle y}$ in the bicorn curve, we obtain $${\displaystyle {(x^2-2az+a^2{z}^2)}^2=x^2+a^2{z}^2.}$$ This curve, a limaçon, has an ordinary double point at the origin, and two nodes in the complex plane, at ${\displaystyle x=\pm i}$ and ${\displaystyle z=1}$.^[4]

The parametric equations of a bicorn curve are $${\displaystyle \begin{array}{cc}x& =a\sin \theta \\ y& =a\frac{(2+\cos \theta ){\cos }^2\theta }{3+{\sin }^2\theta }\end{array}}$$ with ${\displaystyle -\pi \le \theta \le \pi .}$

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