n-curve

We take the functional theoretic algebra C[0, 1] of curves. For each loop γ at 1, and each positive integer n, we define a curve ${\displaystyle {\gamma }_n}$ called n-curve.^{[clarification needed]} The n-curves are interesting in two ways.

1. Their f-products, sums and differences give rise to many beautiful curves.
2. Using the n-curves, we can define a transformation of curves, called n-curving.

A curve γ in the functional theoretic algebra C[0, 1], is invertible, i.e.

${\displaystyle {\gamma }^{-1}}$

exists if

${\displaystyle \gamma (0)\gamma (1)\ne 0.}$

If ${\displaystyle {\gamma }^{*}=(\gamma (0)+\gamma (1))e-\gamma }$, where ${\displaystyle e(t)=1,\mathrm{\forall }t\in [0,1]}$, then

${\displaystyle {\gamma }^{-1}=\frac{{\gamma }^{*}}{\gamma (0)\gamma (1)}.}$

The set G of invertible curves is a non-commutative group under multiplication. Also the set H of loops at 1 is an Abelian subgroup of G. If ${\displaystyle \gamma \in H}$, then the mapping ${\displaystyle \alpha \to {\gamma }^{-1}\cdot \alpha \cdot \gamma }$ is an inner automorphism of the group G.

We use these concepts to define n-curves and n-curving.

If x is a real number and [x] denotes the greatest integer not greater than x, then ${\displaystyle x-[x]\in [0,1].}$

If ${\displaystyle \gamma \in H}$ and n is a positive integer, then define a curve ${\displaystyle {\gamma }_n}$ by

${\displaystyle {\gamma }_n(t)=\gamma (nt-[nt]).}$

${\displaystyle {\gamma }_n}$ is also a loop at 1 and we call it an n-curve. Note that every curve in H is a 1-curve.

Suppose ${\displaystyle \alpha ,\beta \in H.}$ Then, since ${\displaystyle \alpha (0)=\beta (1)=1,\text{ the f-product }\alpha \cdot \beta =\beta +\alpha -e}$.

Let us take u, the unit circle centered at the origin and α, the astroid. The n-curve of u is given by,

${\displaystyle u_n(t)=\cos (2\pi nt)+i\sin (2\pi nt)}$

and the astroid is

${\displaystyle \alpha (t)={\cos }^3(2\pi t)+i{\sin }^3(2\pi t),0\le t\le 1}$

The parametric equations of their product ${\displaystyle \alpha \cdot u_n}$ are

${\displaystyle x={\cos }^3(2\pi t)+\cos (2\pi nt)-1,}$

${\displaystyle y={\sin }^3(2\pi t)+\sin (2\pi nt)}$

See the figure.

Since both ${\displaystyle \alpha \text{ and }{u}_n}$ are loops at 1, so is the product.

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The unit circle is

${\displaystyle u(t)=\cos (2\pi t)+i\sin (2\pi t)}$

and its n-curve is

${\displaystyle u_n(t)=\cos (2\pi nt)+i\sin (2\pi nt)}$

The parametric equations of their product

${\displaystyle u\cdot u_n}$

are

${\displaystyle x=\cos (2\pi nt)+\cos (2\pi t)-1,}$

${\displaystyle y=\sin (2\pi nt)+\sin (2\pi t)}$

See the figure.

Let us take the Rhodonea Curve

${\displaystyle r=\cos (3\theta )}$

If ${\displaystyle \rho }$ denotes the curve,

${\displaystyle \rho (t)=\cos (6\pi t)[\cos (2\pi t)+i\sin (2\pi t)],0\le t\le 1}$

The parametric equations of ${\displaystyle {\rho }_n-\rho }$ are

${\displaystyle x=\cos (6\pi nt)\cos (2\pi nt)-\cos (6\pi t)\cos (2\pi t),}$

${\displaystyle y=\cos (6\pi nt)\sin (2\pi nt)-\cos (6\pi t)\sin (2\pi t),0\le t\le 1}$

If ${\displaystyle \gamma \in H}$, then, as mentioned above, the n-curve ${\displaystyle {\gamma }_n\text{ also }\in H}$. Therefore, the mapping ${\displaystyle \alpha \to {\gamma }_n^{-1}\cdot \alpha \cdot {\gamma }_n}$ is an inner automorphism of the group G. We extend this map to the whole of C[0, 1], denote it by ${\displaystyle {\varphi }_{{\gamma }_n,e}}$ and call it n-curving with γ. It can be verified that

${\displaystyle {\varphi }_{{\gamma }_n,e}(\alpha )=\alpha +[\alpha (1)-\alpha (0)]({\gamma }_n-1)e.}$

This new curve has the same initial and end points as α.

Let ρ denote the Rhodonea curve ${\displaystyle r=\cos (2\theta )}$, which is a loop at 1. Its parametric equations are

${\displaystyle x=\cos (4\pi t)\cos (2\pi t),}$

${\displaystyle y=\cos (4\pi t)\sin (2\pi t),0\le t\le 1}$

With the loop ρ we shall n-curve the cosine curve

${\displaystyle c(t)=2\pi t+i\cos (2\pi t),0\le t\le 1.}$

The curve ${\displaystyle {\varphi }_{{\rho }_n,e}(c)}$ has the parametric equations

${\displaystyle x=2\pi [t-1+\cos (4\pi nt)\cos (2\pi nt)],y=\cos (2\pi t)+2\pi \cos (4\pi nt)\sin (2\pi nt)}$

See the figure.

It is a curve that starts at the point (0, 1) and ends at (2π, 1).

Let χ denote the Cosine Curve

${\displaystyle \chi (t)=2\pi t+i\cos (2\pi t),0\le t\le 1}$

With another Rhodonea Curve

${\displaystyle \rho =\cos (3\theta )}$

we shall n-curve the cosine curve.

The rhodonea curve can also be given as

${\displaystyle \rho (t)=\cos (6\pi t)[\cos (2\pi t)+i\sin (2\pi t)],0\le t\le 1}$

The curve ${\displaystyle {\varphi }_{{\rho }_n,e}(\chi )}$ has the parametric equations

${\displaystyle x=2\pi t+2\pi [\cos (6\pi nt)\cos (2\pi nt)-1],}$

${\displaystyle y=\cos (2\pi t)+2\pi \cos (6\pi nt)\sin (2\pi nt),0\le t\le 1}$

See the figure for ${\displaystyle n=15}$.

In the FTA C[0, 1] of curves, instead of e we shall take an arbitrary curve ${\displaystyle \beta }$, a loop at 1. This is justified since

${\displaystyle L_1(\beta )=L_2(\beta )=1}$

Then, for a curve γ in C[0, 1],

${\displaystyle {\gamma }^{*}=(\gamma (0)+\gamma (1))\beta -\gamma }$

and

${\displaystyle {\gamma }^{-1}=\frac{{\gamma }^{*}}{\gamma (0)\gamma (1)}.}$

If ${\displaystyle \alpha \in H}$, the mapping

${\displaystyle {\varphi }_{{\alpha }_n,\beta }}$

given by

${\displaystyle {\varphi }_{{\alpha }_n,\beta }(\gamma )={\alpha }_n^{-1}\cdot \gamma \cdot {\alpha }_n}$

is the n-curving. We get the formula

${\displaystyle {\varphi }_{{\alpha }_n,\beta }(\gamma )=\gamma +[\gamma (1)-\gamma (0)]({\alpha }_n-\beta ).}$

Thus given any two loops ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ at 1, we get a transformation of curve

${\displaystyle \gamma }$ given by the above formula.

This we shall call generalized n-curving.

Let us take ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ as the unit circle ``u.’’ and ${\displaystyle \gamma }$ as the cosine curve

${\displaystyle \gamma (t)=4\pi t+i\cos (4\pi t)0\le t\le 1}$

Note that ${\displaystyle \gamma (1)-\gamma (0)=4\pi }$

For the transformed curve for ${\displaystyle n=40}$, see the figure.

The transformed curve ${\displaystyle {\varphi }_{u_n,u}(\gamma )}$ has the parametric equations

Denote the curve called Crooked Egg by ${\displaystyle \eta }$ whose polar equation is

${\displaystyle r={\cos }^3\theta +{\sin }^3\theta }$

Its parametric equations are

${\displaystyle x=\cos (2\pi t)({\cos }^{3}2\pi t+{\sin }^{3}2\pi t),}$

${\displaystyle y=\sin (2\pi t)({\cos }^{3}2\pi t+{\sin }^{3}2\pi t)}$

Let us take ${\displaystyle \alpha =\eta }$ and ${\displaystyle \beta =u,}$

where ${\displaystyle u}$ is the unit circle.

The n-curved Archimedean spiral has the parametric equations

${\displaystyle x=2\pi t\cos (2\pi t)+2\pi [({\cos }^{3}2\pi nt+{\sin }^{3}2\pi nt)\cos (2\pi nt)-\cos (2\pi t)],}$

${\displaystyle y=2\pi t\sin (2\pi t)+2\pi [({\cos }^{3}2\pi nt)+{\sin }^{3}2\pi nt)\sin (2\pi nt)-\sin (2\pi t)]}$

See the figures, the Crooked Egg and the transformed Spiral for ${\displaystyle n=20}$.

• Sebastian Vattamattam, "Transforming Curves by n-Curving", in Bulletin of Kerala Mathematics Association, Vol. 5, No. 1, December 2008
• Sebastian Vattamattam, Book of Beautiful Curves, Expressions, Kottayam, January 2015 Book of Beautiful Curves

• The Siluroid Curve

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